A DC converter have DC converter terminals. A converter has two DC converter terminals. DCTerminals {419FDA84-5AD0-409d-BAAA-27B90163DA73}.ClientEnd Point of common coupling terminal for this converter DC side. It is typically the terminal on the power transformer or switch closest to the AC network. PccTerminal {6880D3F9-475B-4887-8B4A-332FABFC8F47}.SupplierEnd Base apparent power of the converter pole. The attribute shall be a positive value. baseS {20F0D1ED-6CE8-471e-8E4B-DCC6C4B46AA5} Converter DC current also called Id. It is converters state variable result from power flow. idc {180F58C1-0E50-4bb2-B496-E88864AF033A} Active power loss in pole at no power transfer. It is converters configuration data used in power flow. The attribute shall be a positive value. idleLoss {E9ED1BC9-CA40-4d1f-91E4-5425A18765DD} Maximum active power limit. The value is overwritten by values of VsCapabilityCurve if present. maxP {082E98FF-DDF7-4a42-A993-2A10F8464960} The maximum voltage on the DC side at which the converter should operate. It is converters configuration data used in power flow. The attribute shall be a positive value. maxUdc {75897B30-EAA3-486e-AA11-DA02461454EE} Minimum active power limit. The value is overwritten by values of VsCapabilityCurve if present. minP {8019FADD-6C6B-4979-A784-0513A1C08CB9} The minimum voltage on the DC side at which the converter should operate. It is converters configuration data used in power flow. The attribute shall be a positive value. minUdc {C442EC69-4FD8-4b00-A7A5-9356A9E1C4BF} Active power at the point of common coupling. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for a steady state solution in the case a simplified power flow model is used. p {A2886699-3439-4510-98E7-990FB4691BF3} The active power loss at a DC Pole idleLoss switchingLossIdc resitiveLossIdc2.For lossless operation PdcPac.For rectifier operation with losses PdcPaclossP.For inverter operation with losses PdcPaclossP.It is converters state variable used in power flow. The attribute shall be a positive value. poleLossP {AD13092B-56F5-4cc6-8225-93F6DFD49D2E} Reactive power at the point of common coupling. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for a steady state solution in the case a simplified power flow model is used. q {3BADAA72-01DD-4d34-99E4-FF5E7E2DD77C} Rated converter DC voltage also called UdN. The attribute shall be a positive value. It is converters configuration data used in power flow. For instance a bipolar HVDC link with value 200 kV has a 400kV difference between the dc lines. ratedUdc {85D36F1D-363A-42a6-ACDB-87AE5511D72F} It is converters configuration data used in power flow. Refer to poleLossP. The attribute shall be a positive value. resistiveLoss {170A8A5E-A487-4e0a-A458-C5CEA87D3624} Switching losses relative to the base apparent power baseS. Refer to poleLossP. The attribute shall be a positive value. switchingLoss {09B85C15-1584-4b82-AC15-9A4C7BAD2F8C} Real power injection target in AC grid at point of common coupling. Load sign convention is used i.e. positive sign means flow out from a node. targetPpcc {517A2014-C002-4bcc-A490-1878A4D3DC40} Target value for DC voltage magnitude. The attribute shall be a positive value. targetUdc {393D548F-14FB-4ae1-9269-0B18F64E442D} Linetoline converter voltage the voltage at the AC side of the valve. It is converters state variable result from power flow. The attribute shall be a positive value. uc {BDE610FA-7E72-4605-9A95-67DED66E25C1} Converter voltage at the DC side also called Ud. It is converters state variable result from power flow. The attribute shall be a positive value. udc {2546662D-C210-4dd7-9137-FF80B3B9D15C} Valve threshold voltage also called Uvalve. Forward voltage drop when the valve is conducting. Used in loss calculations i.e. the switchLoss depend on numberOfValves valveU0. valveU0 {BCE61CD4-9E6A-4c28-892B-64EADC865EFF} A DC converter terminal belong to an DC converter. DCConductingEquipment {419FDA84-5AD0-409d-BAAA-27B90163DA73}.SupplierEnd Represents the normal network polarity condition. Depending on the converter configuration the value shall be set as follows For a monopole with two converter terminals use DCPolarityKind positive and negative. For a bipole or symmetric monopole with three converter terminals use DCPolarityKind positive middle and negative. polarity {48F3E203-BD33-4146-B839-2EC1080B0020} The bus name marker used to name the bus topological node. BusNameMarker {EE3B8B0F-5740-4380-91F9-563BFD5783D7}.ClientEnd Measurements associated with this terminal defining where the measurement is placed in the network topology. It may be used for instance to capture the sensor position such as a voltage transformer PT at a busbar or a current transformer CT at the bar between a breaker and an isolator. Measurements {9C2962C4-F1BE-4c1a-9577-DB6E59B8FB49}.ClientEnd The operational limit sets at the terminal. OperationalLimitSet {E741C3E3-646B-4238-BE21-DFE9B0A603C1}.ClientEnd The line segment phases which belong to the line segment. ACLineSegmentPhases {445FD290-7977-4f2a-AC68-646609336C93}.ClientEnd The clamps connected to the line segment. Clamp {2B7C9922-26A9-4218-8BDD-1098869C8600}.SupplierEnd Cuts applied to the line segment. Cut {62963E89-E891-4b03-8000-C14788BD8E57}.ClientEnd The line faults of the line segment. LineFaults {BBA661BB-92B7-4934-988B-DF65931690EE}.ClientEnd Ground action involving clamp usage for the case when the ground is applied along the line segment instead of at its terminals. LineGroundingAction {1E3F8223-0B92-4d7f-B4A8-4D976F915A99}.ClientEnd Jumper action involving clamp usage for the case when the jumper is applied along the line segment instead of at its terminals. LineJumpingAction {9581D491-DFD1-477b-A1F8-56207CB6A28F}.ClientEnd Perlength impedance of this line segment. PerLengthImpedance {741AE432-C721-4a8d-92F4-C8B96FA98A3A}.ClientEnd WireSpacingInfo {F29D4402-D392-434d-9E98-8C35F21BD856}.SupplierEnd Zero sequence shunt charging susceptance uniformly distributed of the entire line section. b0ch {5EE8B645-9FB5-4985-8930-6CB5CAA29CE2} Positive sequence shunt charging susceptance uniformly distributed of the entire line section. This value represents the full charging over the full length of the line. bch {FFCA602E-D6F0-4fed-BAE6-D02A2C04BB65} Zero sequence shunt charging conductance uniformly distributed of the entire line section. g0ch {59D23066-ADB0-4369-BD9D-95AB3B53376F} Positive sequence shunt charging conductance uniformly distributed of the entire line section. gch {7780580B-437B-45bf-8C1E-AF5F03086378} Positive sequence series resistance of the entire line section. r {57B0CDE3-FEB1-4d13-8906-A9C7AF3C5482} Zero sequence series resistance of the entire line section. r0 {DDBBA03D-E40D-4200-941D-CFB4E24253A0} Maximum permitted temperature at the end of SC for the calculation of minimum shortcircuit currents. Used for short circuit data exchange according to IEC 60909. shortCircuitEndTemperature {5BD9D924-26C6-4f14-AB49-6D3A0C16D6BB} Positive sequence series reactance of the entire line section. x {78292BCA-9CCD-4a7a-8E36-7F7CA0D1C0BB} Zero sequence series reactance of the entire line section. x0 {14CCC61E-8CFF-4748-BB34-30167D45B278} The line segment to which the phase belongs. ACLineSegment {445FD290-7977-4f2a-AC68-646609336C93}.SupplierEnd WireInfo {B5F55F86-9C19-4914-99C2-1ACBA0197A2E}.SupplierEnd The phase connection of the wire at both ends. phase {38F4F39B-9236-46fa-9B1C-D7356BDE2E54} ReserveDemandCurve {6B2BD6A2-CC2E-4cf3-BCDE-BB717B4A931B}.SupplierEnd Edition of ASTM standard. standardEdition {DD924D6E-3005-46f7-A900-83EFD91D2B36} ASTM standard number. standardNumber {1E7A832F-80DC-4f20-8507-E960495C0EF6} Total cost of permit. payment {982DB00B-813C-4d51-AD03-3C043B628C5E} Amount that was credited todebited from an account. For example payment receivedinterest charge on arrears. amount {EE2260B6-9167-458d-9885-02A57E1DD569} CustomerAccount {FC0059FF-913A-472a-9717-BA43E0EC7EA1}.ClientEnd Unit of service. energyUnit {E9744D2F-64EF-47b5-A2D3-E531F5963CE3} Unit of currency. monetaryUnit {4E43FB70-E650-4127-8A7A-C6D6AE71A885} Multiplier for the energyUnit or monetaryUnit. multiplier {29FF04FF-B792-414a-9DBD-2E3804AEAFD7} The values connected to this measurement. AccumulatorValues {FD856524-A775-4757-941C-AF8347AF28E6}.SupplierEnd A measurement may have zero or more limit ranges defined for it. LimitSets {F88250FD-AF28-4716-BE9E-FC0C3E099E19}.SupplierEnd The set of limits. LimitSet {89D44FA0-A7BB-420d-B5B7-57A18801CE94}.ClientEnd The limit values used for supervision of Measurements. Limits {89D44FA0-A7BB-420d-B5B7-57A18801CE94}.SupplierEnd The Measurements using the LimitSet. Measurements {F88250FD-AF28-4716-BE9E-FC0C3E099E19}.ClientEnd The accumulator value that is reset by the command. AccumulatorValue {67E9A9B6-4DEA-46a1-AEFA-0FB2969ED0B8}.SupplierEnd Measurement to which this value is connected. Accumulator {FD856524-A775-4757-941C-AF8347AF28E6}.ClientEnd The command that resets the accumulator value. AccumulatorReset {67E9A9B6-4DEA-46a1-AEFA-0FB2969ED0B8}.ClientEnd MarketDocument {17256E85-4394-4e3a-95AC-8ECE9214CA71}.SupplierEnd Point {BABB4FDB-5AA4-4c38-80B1-35F9E79D3BAE}.ClientEnd Unit {ED2E671C-C32B-4348-BE5F-95F220417E34}.SupplierEnd Bid {FCF33735-6427-4091-BCD8-269E10C726B2}.SupplierEnd Trade {54A2C406-8667-40cf-88A9-3A48629020FE}.SupplierEnd Action name type for the action request. actionName {9BEE1FF9-F843-4e3b-A3FB-EC0C034E8A31} multiplier {A3961E95-7DD0-4d68-A41A-FDC07295CD2B} unit {8C27ACD4-E6D7-407f-B0AF-B545966B9337} multiplier {127E7AD6-A19D-4a00-84C2-6DE69D31A319} unit {2AF6CD50-07D6-4a91-A069-542109925F94} The normal value of active power limit. The attribute shall be a positive value or zero. normalValue {18EB554B-128C-4b2d-A121-5A56540922AC} Value of active power limit. The attribute shall be a positive value or zero. value {42566851-EDFE-4e41-B43F-685B06099B2D} multiplier {F35C1985-6CCA-44a7-898A-AC5460E4319D} unit {860D073A-9544-41bc-BD10-66C21C8B2C88} multiplier {4325598F-25F9-4cd6-BF6E-5C862888172C} unit {971E19EB-1560-4869-B75E-DE4120218C87} All assets for which this activity record has been created. Assets {D26C382F-6EE5-4987-B802-F3F3C2EBBEC9}.ClientEnd Author of this activity record. Author {C7B3A827-5B49-4da5-95A3-4EE7D07568AA}.ClientEnd Information on consequence of event resulting in this activity record. status {EA243F71-81FB-4946-8745-A91B1F263D70} BidSelfSched {B2038A6D-F6D7-42bf-BD3F-0D4F0A7C79E4}.SupplierEnd HostControlArea {8E4B9C0F-0498-44a7-BFE9-8CB6884935B0}.ClientEnd RTO {E7E0DD2A-8D53-4ec2-BEE0-BFCCE3D2E252}.ClientEnd RegisteredResource {886205D7-4ADB-42fe-A010-F455E9A5B54F}.ClientEnd SubControlArea {6E3CCC1F-13F4-4f39-8628-7EAC38F18D74}.SupplierEnd multiplier {368DCBAB-6DFC-4a81-AC07-6A40EC161ED6} unit {F9B6C9EF-4266-4494-BF85-5C9C2DF35ECF} AreaLoadCurve {A5505C4B-57CC-4a61-B752-D3A8A9F07A25}.ClientEnd CnodeDistributionFactor {423960E1-ADF0-47a5-B371-AA4201541FC9}.SupplierEnd Instruction {917AB6A6-8808-4d28-B5EB-217844E5D8B1}.ClientEnd Pnode {CAB06BAC-94AA-411c-9272-D4C6EB676F32}.SupplierEnd RTO {95DFE9B0-18E0-4c05-9AC1-211693BB8524}.ClientEnd A RegisteredResource can be associated to only one AggregateNode if not connected to a Pnode or MktConnectivityNode. RegisteredResource {E4F5F679-427A-4403-B876-8642E8E03574}.ClientEnd SubControlArea {95FCC4C7-2611-4267-9EF0-B7A30B49ECE8}.SupplierEnd Type of aggregated node anodeType {A373A6B5-0BFD-44e5-A5A1-5BBBF79E5396} Analytic score contributing to this aggregate score. AnalyticScore {2FCAEC38-A13E-4208-ADE2-DC5AC84B417A}.SupplierEnd GenDistributionFactor {909A546B-EA82-4f60-8B44-1E47722DB03E}.SupplierEnd LoadDistributionFactor {1E748A16-16A1-4251-B7F2-5AB41F4B8AB1}.SupplierEnd MPMTestResults {C0382101-491D-471a-B6BD-412F2E2BEFE1}.SupplierEnd MPMTestThreshold {3A9890C7-0792-48c5-BE74-53A2FA81C59A}.ClientEnd MktCombinedCyclePlant {667EE2EC-BAF5-4e35-9AEA-070E69E9AACF}.ClientEnd PnodeDistributionFactor {C455B6B7-BDE8-4036-B32B-EFD8413FD6B7}.SupplierEnd TACArea {172CCB30-32D5-4d42-90DE-5FC85FCBF6C3}.SupplierEnd TradingHubValues {28734C41-4653-42fe-A8E1-178A7444F6EC}.ClientEnd Aggregate Price Node Types apnodeType {185E4E21-BBA4-4b3d-8FBE-19BDACF891C8} Designated Control Area participation in LMP price measurementY Participates in both Local Market Power Mitigation LMPM and System Market Power Mitigation SMPMN Not included in LMP price measuresS Participatesin SMPM price measuresL Participatesin LMPM price measures participationCategory {8554C802-56CF-413c-BF46-14F48C1A8EE2} Date and time interval this agreement is valid from going into effect to termination. validityInterval {3A6C2397-7AD8-4787-9146-43E299D419C9} An air compressor may be a member of a compressed air energy storage plant. CAESPlant {3B7A359B-1CB5-47fc-A551-592BDCAF20F2}.ClientEnd A CAES air compressor is driven by combustion turbine. CombustionTurbine {F30399A8-ACB2-4f18-8D1C-F38C8427C14D}.ClientEnd An alert whose type is drawn from this alert type list. EnvironmentalAlert {47BAF174-F27B-42ab-8162-CA6C1C444323}.ClientEnd The environmental data authority responsible for publishing this list of alert types. EnvironmentalDataAuthority {2A299E0C-C0CE-4200-AE97-FBD32E1BCFE0}.SupplierEnd AllocationResultValues {9B469FC0-7C86-4fe8-B462-C045847DDD66}.SupplierEnd AllocationResult {9B469FC0-7C86-4fe8-B462-C045847DDD66}.ClientEnd RegisteredResource {5074A0CF-AF43-4460-BC17-3037761F765B}.ClientEnd The specific analog value used as a source. AnalogValue {234361E4-CD30-4f2c-BFED-521DBDF85CB9}.SupplierEnd The specific analog value used as a source. AnalogValue {9E09D035-D269-408f-B4BA-CF36416D09C0}.SupplierEnd The group of alternate models for which one alternate is used. AlternateModelGroup {EDA739BD-2531-485d-95AF-5B703DC34258}.SupplierEnd The data belonging to the alternate model. Dataset {CF5D1E33-0F2F-40d6-B260-30258F4FBA0D}.SupplierEnd An alternate model that can be one possiblity among alternates. AlternateModel {EDA739BD-2531-485d-95AF-5B703DC34258}.ClientEnd The values connected to this measurement. AnalogValues {434DE6F0-FCF7-4c76-9BCF-D564B2D0AB6B}.SupplierEnd A measurement may have zero or more limit ranges defined for it. LimitSets {06914CE2-9FCC-4a08-AED5-C30E3623AE01}.SupplierEnd The MeasurementValue that is controlled. AnalogValue {8D3DFD64-B2F7-4a60-AE01-416DBF5137A2}.ClientEnd The set of limits. LimitSet {EB6BDFA4-8613-420a-A583-63C11A93EF29}.ClientEnd The limit values used for supervision of Measurements. Limits {EB6BDFA4-8613-420a-A583-63C11A93EF29}.SupplierEnd The Measurements using the LimitSet. Measurements {06914CE2-9FCC-4a08-AED5-C30E3623AE01}.ClientEnd The alternate generating unit for which this measurement value applies. AltGeneratingUnit {234361E4-CD30-4f2c-BFED-521DBDF85CB9}.ClientEnd The usage of the measurement within the control area specification. AltTieMeas {9E09D035-D269-408f-B4BA-CF36416D09C0}.ClientEnd Measurement to which this value is connected. Analog {434DE6F0-FCF7-4c76-9BCF-D564B2D0AB6B}.ClientEnd The Control variable associated with the MeasurementValue. AnalogControl {8D3DFD64-B2F7-4a60-AE01-416DBF5137A2}.SupplierEnd Analytic score produced by this analytic. AnalyticScore {76956539-74D1-490a-9E7B-3CFB8A08570E}.SupplierEnd Asset on which this analytic can be performed. Asset {5EFCAC67-8919-46cc-BBF4-2FADDF364B72}.SupplierEnd Asset group on which this analytic can be performed. AssetGroup {E4171B20-7CF4-4438-BF2B-4B594B8F9704}.SupplierEnd Asset health event which can be generated by this analytic. AssetHealthEvent {77520F55-DB58-40be-AADD-146E07A79BF4}.SupplierEnd Kind of analytic this analytic is. kind {31BCCAF8-9E06-4c60-8DD2-AEC9675F37A3} The scoring scale kind. scaleKind {707B9DEE-9687-4727-9D36-95A6FFD0B1BD} Analytic which was executed to arrive at this analytic score.. Analytic {76956539-74D1-490a-9E7B-3CFB8A08570E}.ClientEnd Asset to which this analytic score applies. Asset {46666DB4-FABB-4df7-85BE-D672C18455E9}.SupplierEnd Aggregate score to which this analytic score contributed. AssetAggregateScore {2FCAEC38-A13E-4208-ADE2-DC5AC84B417A}.ClientEnd Asset group to which this analytic score applies.. AssetGroup {B95F72B4-FBDD-4755-A947-DC49BE3749E0}.ClientEnd MarketCaseClearing {193E6A14-52CA-4269-A05F-CC3FCD23A162}.SupplierEnd MarketRegionResults {F1B3EB5C-675E-4790-95CC-79C38272C39C}.SupplierEnd multiplier {8FDF9698-E454-4c56-B58E-BFEBE384F311} unit {58D1D28E-ADAB-4417-A5F4-D089FF60AE02} multiplier {6023067B-C576-43bb-8474-6B6A763AD6D2} unit {C0911890-BF89-4edd-A9AD-F0E170B0BC6A} DependentOnStage {DA34DBEB-9B66-47df-B464-9D7E5EC7EA99}.SupplierEnd DependingStage {66BEEFB3-CC6F-4eb4-B3FF-8D386E2F2D98}.SupplierEnd dependencyType {339D188B-866F-4be1-9C95-356B8C3419FC} multiplier {C363463C-85C7-487f-BE31-B6444DAB07DD} unit {C93DE952-5AF9-40cc-9792-4D2372DC5EEF} The normal apparent power limit. The attribute shall be a positive value or zero. normalValue {9698296C-5CC4-49bc-BC45-8CE841D6F3CC} The apparent power limit. The attribute shall be a positive value or zero. value {B56E8750-1658-48df-A5ED-13F144E45F95} All persons for this appointment. Persons {C9DF52B7-89D3-4d66-8D7F-13A02C9F8C6A}.ClientEnd All works for this appointment. Works {A1F0785E-E4E6-4ce3-8297-16F47D531998}.SupplierEnd Date and time reserved for appointment. meetingInterval {ADBCCBB6-CFAE-4d02-8A3E-3578942BE6DD} All documents for this approver. Documents {E773805D-E6AC-4d17-9B2A-5E6338923314}.SupplierEnd multiplier {7A1160C2-A913-4954-A9BE-9DB145518EC1} unit {46AED7DB-6F91-477e-BF3D-92F640E352E9} LoadBid {66BF4185-41CD-43e2-8659-871C1A781082}.SupplierEnd AggregateNode {A5505C4B-57CC-4a61-B752-D3A8A9F07A25}.SupplierEnd TACArea {825890F9-E350-40bd-AAE5-57E92CB28556}.ClientEnd Load forecast area type. forecastType {B4E89A91-66EF-4f3c-926F-7B31574DE439} SubControlArea {F6EC071D-A9FE-4972-8340-7B298A3F59EF}.SupplierEnd Lower regulating margin requirement in MW the amount of generation that can be dropped by control in 10 minutes lowerRegMarginReqt {66A8703B-B9C9-434b-B785-ACCC50DE5A11} Operating reserve requirement in MW where operating reserve is the generating capability that is fully available within 30 minutes. Operating reserve is composed of primary reserve t less than 10 min and secondary reserve 10 less than t less than 30 min. opReserveReqt {2F2727BE-61A6-4718-96C8-1604EB020AE4} Primary reserve requirement in MW where primary reserve is generating capability that is fully available within 10 minutes. Primary reserve is composed of spinning reserve and quickstart reserve. primaryReserveReqt {F163BA39-7D1F-4675-8357-F61225891C68} Raise regulating margin requirement in MW the amount of generation that can be picked up by control in 10 minutes raiseRegMarginReqt {E53A6FC9-0E3D-4415-9BE6-1BE06DF0B3CE} Spinning reserve requirement in MW spinning reserve is generating capability that is presently synchronized to the network and is fully available within 10 minutes spinningReserveReqt {E07262D7-1BAF-4f4a-8190-9584A2D4A280} The models that are part of the assembly descrption. ModelSpecification {63DD40D8-8901-4fa0-B3DA-04BEDB15C589}.SupplierEnd CompleteModelToBeDeleted {ABA7248F-7487-4c32-811C-B708158136CB}.SupplierEnd ModelPartVersion {181112F7-C48F-44b9-B4D1-249851E26CBA}.SupplierEnd All activity records created for this asset. ActivityRecords {D26C382F-6EE5-4987-B802-F3F3C2EBBEC9}.SupplierEnd Analytic performed on this asset. Analytic {5EFCAC67-8919-46cc-BBF4-2FADDF364B72}.ClientEnd Analytic result related to this asset. AnalyticScore {46666DB4-FABB-4df7-85BE-D672C18455E9}.ClientEnd Container of this asset. AssetContainer {84A53CE3-0404-43bd-AE48-68E902A89267}.SupplierEnd This assets deployment. AssetDeployment {3E85DBF1-9694-4145-B671-2867557FE27C}.SupplierEnd AssetFunction {B8F5E4FF-B800-45b0-88BA-6C8C4BB96BE9}.SupplierEnd Asset group of which this asset is a part. AssetGroup {D768ADB9-10E4-444c-A72E-BB74B3DBC81A}.ClientEnd Data applicable to this asset. AssetInfo {089B8A18-9B8E-4fc5-B298-9CFB28624527}.SupplierEnd AssetPropertyCurves {7B58C937-A11B-4960-AD54-6431B15F1A97}.SupplierEnd Breaker operation information for this breaker. BreakerOperation {D39D36F1-D054-4dbc-8E93-564DC921D2DB}.ClientEnd All configuration events created for this asset. ConfigurationEvents {71EA796A-141A-445d-9B0E-EF0075BFAFD2}.SupplierEnd ErpInventory {ED3450A6-CFCF-4eb3-95A3-E3511D9B6178}.SupplierEnd ErpItemMaster {84B973F4-8888-4cf6-920A-BD61CD559A80}.ClientEnd ErpRecDeliveryItems {69D45AA1-C24F-4329-AABF-24C5B1CC8A51}.SupplierEnd Financial information related to this asset. FinancialInfo {1B0E0E88-6371-4ed9-AD31-7E0799CB9AD6}.ClientEnd Location of this asset. Location {1547DDC4-B4CB-4406-B642-4E0337FC4594}.SupplierEnd Measurement related to this asset. Measurements {016DD996-A1EA-4bb6-8349-AF38EEDFF7AD}.SupplierEnd Medium with which this asset is filled. Medium {C899B2C5-BB4D-4ce8-A659-85956A304887}.ClientEnd All operational tags placed on this asset. OperationalTags {6C60E3EC-3A0D-400d-BFBB-48BE5355B286}.ClientEnd All roles an organisation plays for this asset. OrganisationRoles {D423536D-C2FE-462e-A473-046027941335}.SupplierEnd All ownerships of this asset. Ownerships {7323F8B4-3F0F-40c7-8BCA-72BFFF4394A9}.ClientEnd All power system resources used to electrically model this asset. For example transformer asset is electrically modelled with a transformer and its windings and tap changer. PowerSystemResources {9709C87C-3A85-4ce4-BA02-CEBB104E7DB5}.SupplierEnd Procedure data set that applies to this asset. ProcedureDataSet {F1E16F01-CC4F-4170-9610-3C1C6E17A43F}.ClientEnd All procedures applicable to this asset. Procedures {3458C266-F6A0-4e72-8A55-BFFF83421DE2}.ClientEnd The model of this asset. ProductAssetModel {24E0529D-66B4-4bd0-BE95-E9F7A501079C}.SupplierEnd Reconditionings {0EDF1A71-1F5E-42e5-9A94-8DFC165669B6}.SupplierEnd ReliabilityInfos {2FBB4D9A-182E-47c5-8227-76C599CC4086}.ClientEnd All work tasks on replacement of this old asset. ReplacementWorkTasks {DEDB052F-30DA-4503-94F8-99F03155CB7F}.ClientEnd Scheduled event related to this asset. ScheduledEvents {E182BB37-0828-425d-B4E7-9C8FE6B40993}.ClientEnd All nonreplacement work tasks performed on this asset. WorkTasks {7D2E82EC-1CC5-4b1b-8FF3-DFA1835C7E49}.ClientEnd Information on acceptance test. acceptanceTest {F1B2BD3C-7915-4d5c-B635-6D8F5CBFB492} Percentage of initial life expectancy that has been lost as of the last life expectancy baseline. Represents initial life expectancy current life expectancy initial life expectancy. baselineLossOfLife {C9057137-8AB2-4a74-94D4-E08DE8026332} Electronic address. electronicAddress {C4E4A775-1726-4b5f-AC3E-015B65E2B08F} In use dates for this asset. inUseDate {7B3EECE8-9580-4735-807D-E4943F216640} Indication of whether asset is currently deployed in use ready to be put into use or not available for use. inUseState {FDE23E7A-5534-4875-AE41-3608A2D1AA24} Kind of asset. Used in description of asset components in asset instance templates. kind {B01C2DC7-EF72-44c8-9B89-12F5EC808B78} was lifecycleLifecycle dates for this asset. lifecycleDate {95C2B3F1-CD1D-4b69-8062-A67BA4FFBB7B} Current lifecycle state of asset. lifecycleState {1AEA2D5B-07CF-4e49-8C00-1F7FDB5E430B} Purchase price of asset. purchasePrice {6BF8B4B9-C3A6-415c-9BAE-625A5AB0964C} Reason asset retired. retiredReason {DD8583BB-9AFA-4c53-95FB-18C39507DFDA} Status of this asset. status {8225FD52-D587-46bc-8E67-501C8255515B} The lab test standard to which this asset health analog is related. TestStandard {2E6CE9AA-C3EE-4729-8DE4-6CB4B1AC3E42}.SupplierEnd Reporting temperature of related analog value if different from reporting temperature of test standard or if there is no test standard. Reporting temperature is what gas volumes are normalized to. Different reporting temperatures are used by different sources. For example ASTM specifies 0C whereas IEC specifies 20C. Online monitors often have their own unique reporting temperatures. reportingTemperature {B72D35A3-123B-4c6c-B5CE-4541B5F9C3CB} All assets within this container asset. Assets {84A53CE3-0404-43bd-AE48-68E902A89267}.ClientEnd LandProperties {658256E1-9CC7-4618-861D-E2D5F2458763}.ClientEnd All seals applied to this asset container. Seals {FDAAA9DF-09C4-4044-B2F9-0C70CD16B243}.SupplierEnd Asset in this deployment. Asset {3E85DBF1-9694-4145-B671-2867557FE27C}.ClientEnd Base voltage of this network asset deployment. BaseVoltage {EEECBAA7-1891-4130-A184-0EB99FA07C16}.SupplierEnd Type of network role breaker is playing in this deployment applies to breaker assets only. breakerApplication {05648883-CA13-4504-85C4-84E5205C8E78} Dates of asset deployment. deploymentDate {9DA43971-BCDD-4284-8C7A-DA45FFB48F32} Current deployment state of asset. deploymentState {31CA4F11-29C2-4170-ACAC-B2B5C0110073} Kind of facility like substation or pole or building or plant or service center at which asset deployed. facilityKind {696A681B-73B3-431a-8E99-68312B0B55EE} Type of network role transformer is playing in this deployment applies to transformer assets only. transformerApplication {319660F4-7A63-445a-A1E8-D4502FBF9AE1} The lab test standard to which this asset health discrete is related. TestStandard {7AF83EF1-4332-45fc-ADCA-D6AC1324070C}.SupplierEnd Asset {B8F5E4FF-B800-45b0-88BA-6C8C4BB96BE9}.ClientEnd Analytic which can be performed on this asset group. Analytic {E4171B20-7CF4-4438-BF2B-4B594B8F9704}.ClientEnd Analytic score for this asset group. AnalyticScore {B95F72B4-FBDD-4755-A947-DC49BE3749E0}.SupplierEnd Asset which is a part of this asset group. Asset {D768ADB9-10E4-444c-A72E-BB74B3DBC81A}.SupplierEnd Kind of asset group this asset group is. kind {93FB62F0-247C-4f9c-865D-BE98FA23AC24} Analytic that initiated this asset health event. Analytic {77520F55-DB58-40be-AADD-146E07A79BF4}.ClientEnd All assets described by this data. Assets {089B8A18-9B8E-4fc5-B298-9CFB28624527}.ClientEnd Asset information nameplate for this catalog asset type. CatalogAssetType {9B683AA4-C622-4998-B81E-A7467D326D7B}.SupplierEnd All power system resources with this datasheet information. PowerSystemResources {009BA3E8-B2DD-4bef-B118-F700692FC9EA}.SupplierEnd Product asset model which conforms to this catalog asset type. ProductAssetModel {C53749B6-0642-4045-81C7-6DC6CDBC280D}.ClientEnd The location of this hazard. Locations {A7C698DB-6096-423a-918E-5D26CD309E44}.SupplierEnd Kind of hazard. kind {5D92A8E3-8FA0-418f-ACB1-3B0BE65D6268} AssetModelCatalogueItems {0DA534C6-ACF6-48ab-A8DB-496BB661F459}.ClientEnd status {9E490DCF-DD54-475b-B583-3F1ABC4FFA74} AssetModel {4AAC30DE-2757-4a42-BD3F-E6C4713581FA}.ClientEnd AssetModelCatalogue {0DA534C6-ACF6-48ab-A8DB-496BB661F459}.SupplierEnd ErpPOLineItems {6A15A364-6A16-4777-8E7A-E9C7ECF79B32}.SupplierEnd ErpQuoteLineItems {CE08E4FC-401D-4b25-B35D-68179BF78BEE}.SupplierEnd Unit cost for an asset model from a specific supplier either for a unit cost or cost per unit length. Cost is for material or asset only and does not include labor to installconstruct or configure it. unitCost {DC8E5B7D-59BC-442b-BC44-1B7A7CC87F13} All assets for this organisation role. Assets {D423536D-C2FE-462e-A473-046027941335}.ClientEnd All ownerships of this owner. Ownerships {4276D5C7-95E8-44db-84E8-C01DA2834B6C}.ClientEnd Assets {7B58C937-A11B-4960-AD54-6431B15F1A97}.ClientEnd Specification {54F87E6E-39D6-413c-AF0C-2BC67DD4F008}.ClientEnd Test standard which describes this asset string measurement. TestStandard {12941279-B146-4307-A6F4-220520C33D5E}.SupplierEnd Kind of string useful in asset domain. kind {AE564014-FF5C-4981-AC45-326E6D774FB2} Kind of analog representing temperature or pressure related to an asset. kind {AD9D9896-7DF5-4793-8CAF-73105F4ACEB6} A set of lab test results produced by this test lab. LabTestDataSet {2E1C1072-F34D-447f-A661-8FC9A06E3F6D}.ClientEnd Specimen taken by this sample taker. Specimen {B057FDCC-0EE2-422a-A257-ADAE38F4BB01}.ClientEnd All Crews having this Assignment. Crews {B597E5EE-DEFD-46c2-9B5C-1B4B22EA8086}.ClientEnd Period between the assignment becoming effective and its expiration. effectivePeriod {82CE2EE1-A6EA-4d87-B8B7-32893B2D3F52} Asynchronous machine dynamics model used to describe dynamic behaviour of this asynchronous machine. AsynchronousMachineDynamics {BA360C66-0AA8-4cb9-9E9B-1BF747B40AFC}.ClientEnd Indicates the type of Asynchronous Machine motor or generator. asynchronousMachineType {826DCE19-F54E-424d-A189-2396769F998F} Efficiency of the asynchronous machine at nominal operation as a percentage. Indicator for converter drive motors. Used for short circuit data exchange according to IEC 60909. efficiency {51FACBB4-CB35-46a8-A0B9-6482118D1FC7} Nameplate data indicates if the machine is 50 Hz or 60 Hz. nominalFrequency {F054A7B9-4A3B-4482-A339-AB83085A29F1} Nameplate data. Depends on the slip and number of pole pairs. nominalSpeed {6D8C09B8-E824-41d6-8492-1D59EA766F20} Rated mechanical power Pr in IEC 609090. Used for short circuit data exchange according to IEC 60909. ratedMechanicalPower {78EDFD71-FC20-44e4-AE1C-99B5C285C54E} Damper 1 winding resistance. rr1 {40B6255C-EC7A-4349-9F87-08C0A093611A} Damper 2 winding resistance. rr2 {6F5C5A3A-C7FA-42b8-83A1-430D4EB4EA9A} Transient rotor time constant greater than tppo. tpo {5CE90029-71A1-495b-BA37-BC57015E6E18} Subtransient rotor time constant greater than 0. tppo {B2EFC713-160B-4eb9-82D7-4D72F4628850} Damper 1 winding leakage reactance. xlr1 {2D9587B7-651E-41fd-BC62-06E2568BE5B5} Damper 2 winding leakage reactance. xlr2 {9148BA51-4D09-4ab6-8E8D-EFE8A9657B75} Magnetizing reactance. xm {9327DEB3-9DF5-4261-ABB1-3EFBCB396B51} Transient reactance unsaturated greater than or equal to xpp. xp {766CAB36-4AC9-46b8-ADA8-306DA127FE42} Subtransient reactance unsaturated. xpp {1AAA2103-E4D1-4668-84AF-F50E88A5D4CF} Synchronous reactance greater than xp. xs {DFA22160-690B-4e57-A11B-5A823C1A37EA} Asynchronous machine to which this asynchronous machine dynamics model applies. AsynchronousMachine {BA360C66-0AA8-4cb9-9E9B-1BF747B40AFC}.SupplierEnd Mechanical load model associated with this asynchronous machine model. MechanicalLoadDynamics {2E5B6ACA-CE14-4ff7-A95C-1961DD872622}.ClientEnd Turbinegovernor model associated with this asynchronous machine model. TurbineGovernorDynamics {6884320E-0E98-4316-859C-B1DF18D6ED2A}.ClientEnd Wind generator type 1 or type 2 model associated with this asynchronous machine model. WindTurbineType1or2Dynamics {28333A44-C128-4d1f-91A9-C4815D05A17C}.ClientEnd Damper 1 winding resistance. rr1 {52C7D4CA-BCD4-46ab-AABD-67ADA4E8E80C} Damper 2 winding resistance. rr2 {6E788D7D-119B-4b41-879E-A561AC49CA86} Damper 1 winding leakage reactance. xlr1 {FC3820FB-E7D7-45de-859C-1B6AD4FC148F} Damper 2 winding leakage reactance. xlr2 {7855AF2E-4E4F-4595-B225-A678B577EA3A} Magnetizing reactance. xm {872CD8BF-EA9E-4395-A522-4803021DEA77} Transient rotor time constant iToi gt AsynchronousMachineTimeConstantReactance.tppo. Typical value 5. tpo {60FE5275-E98C-4dda-BC25-2AB8939ED89E} Subtransient rotor time constant iToi gt 0. Typical value 003. tppo {9AF6DF73-4546-4e1f-B24B-F4D820C2E4E6} Transient reactance unsaturated iXi gt AsynchronousMachineTimeConstantReactance.xpp. Typical value 05. xp {4E9DA366-FEC5-4e63-8D7F-4B1CC21E3FB3} Subtransient reactance unsaturated iXi gt RotatingMachineDynamics.statorLeakageReactance. Typical value 02. xpp {F9E7E7CF-9390-47fd-AD96-379A21668D71} Synchronous reactance iXsi gt AsynchronousMachineTimeConstantReactance.xp. Typical value 18. xs {BDD25953-4C09-4ca8-9B66-836E93830D62} Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {D22E87BF-F1D2-49ef-B02C-1F3F666251B8}.ClientEnd Kind of atmospheric analog. kind {39FDC1D5-CFCE-48f0-B0BF-48A227DFBF65} The maximum altitude of the phenomenon. altitude {206D7D27-D0FB-48ad-9158-6963F4CBF74F} The base altitude of the phenomenon. base {876230B5-9A30-49d1-A573-51D2748B4E2B} The direction the phenomenon is moving. direction {BE89CE8A-A3C2-4637-9B02-E71891B34168} The maximum percentage coverage maxCoverage {F3C0D1A0-EDB0-4ba2-B329-4963A90CBC9E} The minimum percentage coverage minCoverage {CAB91E48-503C-4d29-B281-7B9015933461} The speed of the phenomenon speed {CDEFD06D-00FA-4ccc-A063-FB35C849460D} MarketDocument {56078672-F984-4496-A0EE-E53993207A8C}.ClientEnd TimeSeries {12A8F6B9-95CA-4bbd-9E17-5C2026B33D51}.SupplierEnd MktUserAttribute {3FB05567-9270-4fcb-8976-9ADA1813AE21}.SupplierEnd TimeSeries {5894E7F6-D7B8-4658-85C7-272AEC744D46}.SupplierEnd All activity records with this author. ActivityRecords {C7B3A827-5B49-4da5-95A3-4EE7D07568AA}.SupplierEnd All documents of this this author. Documents {335F0BDA-9420-40ee-B636-5FAD6485F1BB}.SupplierEnd Auxiliary agreement regulating this account. AuxiliaryAgreement {0C6F4AB9-5500-4b13-8C5F-C6441811D257}.ClientEnd All charges levied on this account. Charges {76534BC8-9FAC-414b-8310-44B6AD265341}.SupplierEnd All payments against this account. PaymentTransactions {DF6F03CB-FADB-4f4b-BE70-872C51D6376A}.SupplierEnd The total amount currently remaining on this account that is required to be paid in order to settle the account to zero. This excludes any due amounts not yet paid. balance {AC8E0A15-A0A8-4f12-9563-974C3DBE619D} Current amounts now due for payment on this account. due {15F66F3A-7CE9-49b1-AD61-C593D32E8F4B} Details of the last credit transaction performed on this account. lastCredit {3DE6E5F8-C1CA-4883-8AFC-90361B6D1A12} Details of the last debit transaction performed on this account. lastDebit {55597EAA-BEF0-4615-87B6-823B1FB2B83C} The initial principle amount with which this account was instantiated. principleAmount {B0C1A99C-CE88-4c6c-A4FE-DDE0E7842611} All auxiliary accounts regulated by this agreement. AuxiliaryAccounts {0C6F4AB9-5500-4b13-8C5F-C6441811D257}.SupplierEnd Customer agreement this nonservice related auxiliary agreement refers to. CustomerAgreement {4B0AFE27-A288-4e9f-A8F4-CA0675EB971D}.ClientEnd The interest per annum to be charged prorata on AuxiliaryAccount.dueArrears at the end of each payCycle. arrearsInterest {8D725569-1FF9-4abc-B4C2-EBA502183CE8} The fixed amount that has to be collected from each vending transaction towards settlement of this auxiliary agreement. Note that there may be multiple tokens vended per vending transaction but this is not relevant. fixedAmount {324167D0-1FEF-4817-99D1-93CD403EB07D} The minimum amount that has to be paid at any transaction towards settling this auxiliary agreement or reducing the balance. minAmount {F72DC552-EDE8-4c72-8414-837C1372D8A8} The percentage of the transaction amount that has to be collected from each vending transaction towards settlement of this auxiliary agreement when payments are not in arrears. Note that there may be multiple tokens vended per vending transaction but this is not relevant. vendPortion {C9437D9A-8E1E-4cac-8491-C8AD1C7E4B13} The percentage of the transaction amount that has to be collected from each vending transaction towards settlement of this auxiliary agreement when payments are in arrears. Note that there may be multiple tokens vended per vending transaction but this is not relevant. vendPortionArrear {2442CFE1-3D65-466c-9830-32079DA6D711} AuxillaryValues {F527F4CB-0C66-43c2-A209-EF39AAF43B83}.SupplierEnd marketType {A0C6602F-B884-4df3-A509-A83D8865DBFD} The Terminal at the equipment where the AuxiliaryEquipment is attached. Terminal {43A2A194-FB7E-4b55-8C73-A2E6C7AA2BF4}.SupplierEnd RegisteredGenerator {B773A97C-0734-453a-BE6C-701847C433D6}.SupplierEnd RegisteredLoad {E8E1ADFD-2A7D-4748-8265-3F63BD1FED9B}.SupplierEnd AuxillaryCost {F527F4CB-0C66-43c2-A209-EF39AAF43B83}.ClientEnd FiveMinAuxillaryData {6B36C00F-62F3-49c3-998C-F5EDD88A0CA8}.ClientEnd TenMinAuxillaryData {FBA403AA-DCD7-404a-9D19-752C36A45A12}.ClientEnd noLoadCostEligibilityFlag {629AD235-91A2-4581-88FE-459530081573} startUpCostEligibilityFlag {86402FE6-5A7A-4b51-B437-4D7DB00B9AB2} UnavailablitySchedule {A2312A8D-C0CB-4b47-98F8-79E9ADD45A56}.ClientEnd The period of time for which the plan is valid. validPeriod {A088B182-984A-4ac1-BD52-816F4BA9968F} High power limit. highPowerLimit {FD4F7DF7-0B32-44d4-9009-7700422B72C0} Incore thermal time constant. inCoreThermalTC {550DE289-6D8D-424c-AB23-9B8B8CEFB1BA} Low power limit. lowPowerLimit {7D7217B4-DDF4-49f6-A098-6F7BADF39FD9} Initial lower limit. lowerLimit {3AC86890-00F9-41d5-BC36-AEA2A28920F7} Pressure limit. pressureLimit {EDEA4C55-F054-4c74-BDE5-C776643DDABD} Pressure setpoint time constant. pressureSetpointTC1 {0CA605BA-5591-4f91-9D49-0BD0DCD5F3E5} Pressure setpoint time constant. pressureSetpointTC2 {1EE021B1-4FDC-459e-B0B1-1E514971B80E} Coefficient for modelling the effect of offnominal frequency and voltage on recirculation and core flow which affects the BWR power output. rfAux1 {E1BCDE63-3368-463c-8FAC-C6A8180163E4} Coefficient for modelling the effect of offnominal frequency and voltage on recirculation and core flow which affects the BWR power output. rfAux2 {C67C15E0-7617-4cef-8350-73C4AF657ECF} Coefficient for modelling the effect of offnominal frequency and voltage on recirculation and core flow which affects the BWR power output. rfAux3 {002B51A6-6E50-475a-A8E5-E4CEDB943AAF} Coefficient for modelling the effect of offnominal frequency and voltage on recirculation and core flow which affects the BWR power output. rfAux4 {BBECA461-4205-4612-B787-A46C3EB8CB63} Coefficient for modelling the effect of offnominal frequency and voltage on recirculation and core flow which affects the BWR power output. rfAux5 {F274E3B5-011E-4dea-BD43-618A502EE99E} Coefficient for modelling the effect of offnominal frequency and voltage on recirculation and core flow which affects the BWR power output. rfAux6 {38D7F89E-3572-44f0-88CA-44FF830E36AD} Coefficient for modelling the effect of offnominal frequency and voltage on recirculation and core flow which affects the BWR power output. rfAux7 {D221528C-1320-47a6-8863-14BD29F64411} Coefficient for modelling the effect of offnominal frequency and voltage on recirculation and core flow which affects the BWR power output. rfAux8 {6113CAF7-7FDA-4431-88E5-F2A5C2B65ACC} Rod pattern. rodPattern {61FA6DC6-92D1-4a4d-AB74-2EB660BABF38} Initial upper limit. upperLimit {7D050333-09EF-487e-92E8-E1603CFD27FD} All BankAccounts this Bank provides. BankAccounts {239365BB-20C7-41e5-B131-81EC3DE7F529}.ClientEnd Bank that provides this BankAccount. Bank {239365BB-20C7-41e5-B131-81EC3DE7F529}.SupplierEnd ServiceSupplier that is owner of this BankAccount. ServiceSupplier {A4F61027-A9D2-47ab-AAEA-74678D39E4DE}.ClientEnd SecurityConstraintSum {8FF929E3-7DF8-484e-9AE6-E78FD919B4C1}.SupplierEnd The base frequency. frequency {80C75B75-855F-44af-9846-BE082114E41E} Value used as base power. basePower {9F2DC83B-B801-4b29-BD57-4781BD53A50A} All qualities of this reading. ReadingQualities {DD6190AA-B446-4216-8E50-3E7421E80344}.ClientEnd Start and end of the period for those readings whose type has a time attribute such as billing seasonal or forTheSpecifiedPeriod. timePeriod {C25B71A6-CEC6-4dec-B290-ABF3D327854F} All conducting equipment with this base voltage. Use only when there is no voltage level container used and only one base voltage applies. For example not used for transformers. ConductingEquipment {B21687D9-2B46-4880-B016-06CCFA215EC3}.SupplierEnd A network asset deployment at this base voltage level. NetworkAssetDeployment {EEECBAA7-1891-4130-A184-0EB99FA07C16}.ClientEnd The topological nodes at the base voltage. TopologicalNode {6F37A2BE-FB37-4a6c-8BB1-CFC6690C1867}.ClientEnd Transformer ends at the base voltage. This is essential for PU calculation. TransformerEnds {DEF1E6AE-B7B9-43bf-9A91-E4BFC453DC4D}.ClientEnd The voltage levels having this base voltage. VoltageLevel {F610FDC8-D98D-4367-99A9-E9CA1C8A8CC5}.ClientEnd The power system resources base voltage. Shall be a positive value and not zero. nominalVoltage {D37DA22A-916B-4a33-88AB-B77C229DB882} All time schedules for this work or work task. TimeSchedules {43F7FE4D-DD21-436e-B70A-E2FCDD0B6928}.SupplierEnd All activity records for this work or work task. WorkActivityRecords {916C5FEE-0A53-4844-A34C-EA28BF6FA153}.SupplierEnd Location for this worktask. WorkLocation {4674DC66-FC6D-4b4e-B78A-2BA63838F75D}.SupplierEnd Kind of work. kind {DA7282A1-DD17-4914-B04D-33479EB8974D} Priority of work. priority {4CE5B82E-879A-46f3-9D6E-19F44D97084B} Kind of work status. statusKind {A4C16162-A8D5-4e82-840B-700281305CCE} Multiplier for value1. value1Multiplier {BC6A428D-4EE4-4fbf-A1FA-686812174A74} Value1 units of measure. value1Unit {37C7E9FF-F129-44a3-BCCA-37E3777EBA36} Multiplier for value2. value2Multiplier {333B8BA1-3E71-485a-A261-F73256259651} Value2 units of measure. value2Unit {4925B79C-CB74-46be-8D24-939D06B46582} The current state of the battery charging full etc.. batteryState {4333D713-5396-457b-9CA8-E9472945B301} Full energy storage capacity of the battery. The attribute shall be a positive value. ratedE {EB8342BE-510F-4246-935B-61E05FCC80DF} Amount of energy currently stored. The attribute shall be a positive value or zero and lower than BatteryUnit.ratedE. storedE {A40F9768-CA75-4ded-AC08-E3FBA589CF1F} Circuit {38C0C28C-00BF-4529-940D-5007F17FBB86}.ClientEnd Substation containing the bay. Substation {51152F4A-1B03-451f-BA84-6A05A6AE1630}.SupplierEnd The voltage level containing this bay. VoltageLevel {5E328091-5BC1-4fa8-9BA3-F087A215492A}.ClientEnd Breaker configuration. breakerConfiguration {94BB9838-29AB-4afe-853A-3BD683EF6B09} Busbar configuration. busBarConfiguration {696CC695-DE24-423a-9CD6-A9FED27803F8} multiplier {0866792E-8BCF-46b9-B5EB-78A00420DC3C} unit {03C0AF47-48E3-4a55-ADCF-9F68085984AC} ActionRequest {FCF33735-6427-4091-BCD8-269E10C726B2}.ClientEnd BidHourlySchedule {A5FE93CE-0535-412b-BE49-3124C08220F0}.ClientEnd ChargeProfiles {ADDC9B96-D85F-46b2-A697-B0712376B748}.SupplierEnd EnergyMarket {728667DC-DD4E-4059-AE1B-FBA6AD106FDB}.SupplierEnd MarketParticipant {4483FC15-4087-4afd-8766-1D708647568D}.SupplierEnd MitigatedBid {41CDA34B-D1DA-4d10-BD9C-9ACD84F95C4F}.ClientEnd MitigatedBidSegment {BB5D09A6-5901-41e0-9C70-FEA07F4C897A}.SupplierEnd A bid comprises one or more product bids of market products ProductBids {BCC6B1A9-977E-41f0-9C3A-DDB18F4AA27F}.ClientEnd RMRDetermination {20A022E9-69A4-4231-A566-82296460EFB1}.ClientEnd The market type DAM or RTM. marketType {0AD79637-6091-4791-A753-5B49A0506242} PnodeDistributionFactor {92BD0FDA-3BFA-4ea4-9233-9C19F31CCB39}.SupplierEnd ProductBid {566D5A4B-E23C-4c3e-81A6-C484F10859CC}.ClientEnd MarketProduct {9E7BFD17-29EA-44f9-8314-8B82238242CC}.ClientEnd ResourceBid {1733E069-3742-4625-B384-DB2661EDD78B}.ClientEnd ProductBid {ED4A9CB4-F670-45e4-B569-BC258596026F}.SupplierEnd Bid {A5FE93CE-0535-412b-BE49-3124C08220F0}.SupplierEnd MarketProduct {82238162-E851-4fa8-8103-3D73229CE310}.ClientEnd Bid Ceiling MWH bidCeiling {F9E6D809-182F-4c9a-B035-F1D3D54BDA72} Bid Ceiling MWH for generic AS versus a specific market product bidCeilingAS {3FB7D4D0-E85F-47fc-AE95-55335F2E35C1} Bid Floor MWH bidFloor {DAE1C9D9-9034-42fe-8D9F-4C70AA4EC969} Bid Floor MWH for generic AS versus a specific market product bidFloorAS {8F6EE80C-171F-4501-953C-53A40DB2663A} Bid Default PriceMWH defaultPrice {D88F9B8A-638B-4ae3-81E1-7AD10C0BD999} Market Type of the cap DAM or RTM marketType {82B18371-981D-420b-8A6A-C52BFF3C835A} BidSchedule {BD02A659-7286-4690-A25C-BEBAA6BBC2F8}.SupplierEnd BidPriceCurve {BD02A659-7286-4690-A25C-BEBAA6BBC2F8}.ClientEnd ProductBid {E6A900FF-246B-49e3-8F19-A2DBF2BB4BB5}.ClientEnd BID Type I Initial Bid F Final Bid bidType {83CAD08F-2EFA-4e2b-9F65-0D3711119AAC} Mitigation StatusS Mitigated by SMPM because of misconductL Mitigated by LMPM because of misconductR Modified by LMPM because of RMR rulesM Mitigated because of misconduct both by SMPM and LMPMB Mitigated because of misconduct both by SMPM and modified by LMLM because of RMR rulesO original mitigationStatus {1468C65A-F2D8-4810-B207-F5FEAB9684AB} AdjacentCASet {B2038A6D-F6D7-42bf-BD3F-0D4F0A7C79E4}.ClientEnd HostControlArea {A54AFE0A-D986-4114-B72E-9243C90ABC98}.ClientEnd ProductBid {62141B29-E60E-480d-B668-C305C09264D7}.ClientEnd SubControlArea {8B909238-F00E-4f58-A22C-21C482041260}.ClientEnd TransmissionContractRight {C020B2A4-890F-455d-8C69-8B0612C789BB}.ClientEnd This is a YN flag for a selfschedule of a resource per market per date and hour using a specific TR ID. It indicates whether a selfschedule using a TR is balanced with another selfschedule using the same TR ID. balancingFlag {AC993C70-50CE-483f-A753-C385580DB4C8} bidType has two types as the required output of requirements and qualified predispatch. bidType {C1025F35-7D45-4883-853E-0B0D92857365} This is a YN flag for a selfschedule of a resource per market per date and hour using a specific TR ID. It indicates whether a selfschedule using a TR has scheduling priority in DAMRTM. priorityFlag {1FE4E4F1-482A-4383-B4AB-BDDE2FE75BD2} Indication of which type of self schedule is being referenced. referenceType {29891CC3-A678-4649-AC69-557165041C41} This attribute is used to specify if a bid includes a self sched bid. If so what self sched type is it. The possible values are shown as follow but not limited toETC Existing transmission contractTOR Transmission ownership rightRMR Reliability must runRGMR Regulatory must runRMT Relaiability must takePT Price takerLPT Low price takerSP Self provisionRA Resource adequacyThis attribute is originally defined in the BidSelfSched class selfSchedType {2D4244FF-52C3-46dd-B19F-1D2CD73F8D3D} updateType {B7BC95D2-EFDB-428e-AF3E-12D9F2518CF4} GeneratingBids {DBBF1D0E-B376-4e47-A369-EB0EB0F211C5}.ClientEnd Communication addressing for a Bilateral Table used by a ICCP data provider or consumer. CommunicationLink {F8B558CB-826C-44f6-8B37-E168629E4395}.ClientEnd Agreement to information subscriber. ConsumerBilateralExchange {11CB6E16-3BAB-4d1f-A946-6B01C61E757D}.ClientEnd ICCP information in a Bilateral table that will be exposed to a remote peer. ProvidedBilateralIOPoint {D71D178C-4ECF-4cf5-A2F9-02324DC52065}.ClientEnd Agreement to information provider. ProviderBilateralExchange {82F28F28-5401-456b-9A8A-F036863F7A07}.SupplierEnd Subscriber of information from a remote peer. Consumer {11CB6E16-3BAB-4d1f-A946-6B01C61E757D}.SupplierEnd Provider of information to a remote peer. Provider {82F28F28-5401-456b-9A8A-F036863F7A07}.ClientEnd Maximum total transmission congestion charges in monetary units totalTranChargeMax {0F8E9ADB-54D9-4632-96FC-B4DBAB322F47} A BillDeterminant can have 0n ChargeComponent and a ChargeComponent can associate to 0n BillDeterminant. ChargeComponents {57B8DDF0-7B94-45b0-B5EF-5CDB1744BC85}.ClientEnd ChargeProfile {1ACFDE89-AF63-4cb5-830B-04C1DDECED28}.ClientEnd ChargeProfileData {AB69F7A6-CE60-4b02-AA54-24E729B7293B}.SupplierEnd MktUserAttribute {3D3E108F-27E6-46ff-B50B-1A3A9365B887}.SupplierEnd BlockDispatchOrder {255D77CC-5A1D-4514-B6F4-972B9DFEDB7F}.ClientEnd EnergyGroup {3BC3FBEE-55AB-447d-A7C2-53E7591E1DC1}.SupplierEnd BlockDispatchComponent {255D77CC-5A1D-4514-B6F4-972B9DFEDB7F}.SupplierEnd p {5C507EF2-C628-49a1-B4C3-EC7C12ACC184} Delay {5B3BF302-273E-40f1-A888-A5FFEDE8F08F}.ClientEnd VSCtype1 {EA954A70-DF63-404b-98A9-063F5571B46A}.SupplierEnd MktACLineSegmentEndAFlow {C683E41C-A3EC-4316-BD46-D25F17ED532B}.SupplierEnd MktACLineSegmentEndBFlow {977B9C6C-1464-4035-A670-FC92869C7E0B}.SupplierEnd MktPowerTransformerEndAFlow {6B82670E-C342-4f85-A215-9BB510562254}.SupplierEnd MktPowerTransformerEndBFlow {D9B28EF9-4971-4bb7-B90B-5D0EF7D92756}.SupplierEnd MktSeriesCompensatorEndBFlow {A6C6B3F9-7B48-423b-99F5-774083959E01}.SupplierEnd MktSeriresCompensatorEndAFlow {5C0AAF99-2DB3-4ce7-8154-9C37E518CB30}.SupplierEnd PinBranchGroup {CB739CC6-8BA5-4ceb-BD00-62D8654B263A}.ClientEnd The maximum active power flow. maximumActivePower {9BE347F3-B589-40b6-A23A-7C14B8A90CB8} The maximum reactive power flow. maximumReactivePower {3E4B96F3-6FD4-497e-9C9A-23719BCDA9C8} The minimum active power flow. minimumActivePower {211199A7-23ED-4b64-9F0B-1982FE3432C9} The minimum reactive power flow. minimumReactivePower {5FCBF43B-F5AB-4f14-95DD-45D4AACCF477} The terminal to be summed. Terminal {D1FC8C2B-42F2-4d32-95B9-1C5FE76F9BAD}.SupplierEnd The transition time from open to close. inTransitTime {9F9445D9-22B1-4328-A4D5-C3B872F33DE2} Phase trip rating. phaseTrip {B3341220-BC03-4cbf-9EDD-9CC98BC08B3F} The reporting group to which this bus name marker belongs. ReportingGroup {37254491-51A1-43fd-8EA9-325A03BB2B8F}.SupplierEnd The terminals associated with this bus name marker. Terminal {EE3B8B0F-5740-4380-91F9-563BFD5783D7}.SupplierEnd A user defined topological node that was originally defined in a planning model not yet having topology described by ConnectivityNodes. Once ConnectivityNodes has been created they may linked to user defined ToplogicalNdes using BusNameMarkers. TopologicalNode {33820695-1C8F-47c2-96B4-E770AF9728EF}.SupplierEnd A VoltageControlZone is controlled by a designated BusbarSection. VoltageControlZone {77D2F437-1BDA-463c-AC93-F25EAC4B04AF}.SupplierEnd Maximum allowable peak shortcircuit current of busbar Ipmax in IEC 609090. Mechanical limit of the busbar in the substation itself. Used for short circuit data exchange according to IEC 60909. ipMax {2E32481A-0F4F-4da0-B81F-8C1E6543F0CD} Rated current. ratedCurrent {3B7D026A-7745-455d-B83E-893E1E2164B8} Rated voltage. ratedVoltage {3F29B322-3264-420a-A5D5-5467777BBEBB} BushingInsulationPFs {77D3489A-738D-47cf-B225-42A2975A2FF3}.SupplierEnd Fixed contact of interrupter to which this bushing is attached. FixedContact {C2A54CC4-02E6-4205-BF7A-A8BAE99CDBAA}.ClientEnd Moving contact of interrupter to which this bushing is attached. MovingContact {04E4A3E7-BA8B-450c-A235-995CEAB16935}.ClientEnd Terminal to which this bushing is attached. Terminal {1E353A86-0A4E-4184-8B22-CE084F0A6AA8}.SupplierEnd Factory measured capacitance measured between the power factor tap and the bushing conductor. c1Capacitance {242160B4-1253-47f0-8CE8-259BD0368A40} Factory measured insulation power factor measured between the power factor tap and the bushing conductor. c1PowerFactor {A938536A-EEBD-4afe-99B3-EAF67D499ADA} Factory measured capacitance measured between the power factor tap and ground. c2Capacitance {27BB799E-BC81-4e20-9101-79D8C755030B} Factory measured insulation power factor measured between the power factor tap and ground. c2PowerFactor {6731CC9D-A0C1-45f5-B228-31AC10CA3A54} Kind of insulation. insulationKind {29CE8562-3D27-47a0-879E-7C180E0AB035} Rated current for bushing as installed. ratedCurrent {1C13CB85-F589-4a6f-83C4-2FB8A15F355D} Rated impulse withstand voltage also known as BIL Basic Impulse Level. ratedImpulseWithstandVoltage {5FBE3610-C895-4087-B528-DD760BF513B9} Rated linetoground voltage. Also referred to as Uy on bushing nameplate. ratedLineToGroundVoltage {C2C35B35-C556-4613-A060-B6B59752A5AE} Rated voltage. Can be referred to as Um system voltage or class on bushing nameplate. ratedVoltage {40F3B551-C8F3-4cb5-BBD3-47CDE5F3F1AC} Bushing {77D3489A-738D-47cf-B225-42A2975A2FF3}.ClientEnd TransformerObservation {DE9B5DD5-948F-45ee-967F-41C9BA2892AE}.SupplierEnd status {1F38BFA9-0F10-4b5e-B377-52D9F803F29F} Kind of test for this bushing. testKind {93705AD4-9DF6-4d8e-A55E-BCC4ECED0BB1} Projects {3E0CE628-2617-4405-B164-788B1A9E8408}.SupplierEnd Works {9F2397D7-15D3-42a6-9C58-F7D06A58CEAF}.SupplierEnd status {959E6488-8643-413b-86C3-E47079565E8D} An air compressor may be a member of a compressed air energy storage plant. AirCompressor {3B7A359B-1CB5-47fc-A551-592BDCAF20F2}.SupplierEnd A thermal generating unit may be a member of a compressed air energy storage plant. ThermalGeneratingUnit {22CD9D0F-3294-4b03-B8CD-2834FB574022}.SupplierEnd The rated energy storage capacity. The attribute shall be a positive value. energyStorageCapacity {8D0F81BA-B2B9-4e48-A3FD-10B5F6DDCBAD} The CAES plants gross rated generating capacity. The attribute shall be a positive value. ratedCapacityP {A0B5E346-09F5-4fe5-8003-8F3DD9772334} CSCtype1 {C028CE96-6309-4883-89A5-E1B91BD9EF2D}.SupplierEnd Delay {CBF65696-C189-4ab1-A0C3-34B7539B34A1}.ClientEnd CSCtype1 {AF476A35-E037-4efb-9B03-02299D031FDA}.SupplierEnd Delay {AF4309DA-72A5-4b21-80EC-9653AF6D0620}.ClientEnd Edition of CIGRE standard. standardEdition {D03822B4-79F1-4d29-9471-176EDB767B40} CIGRE standard number. standardNumber {76DAA2A9-DD76-45e3-A650-D088B3607FD3} CongestionRevenueRight {A6EF647F-83D1-46c2-83BA-498C5AC0EE5D}.ClientEnd CongestionRevenueRight {80E51726-F69E-4014-ACD6-C80A45B842AE}.SupplierEnd Kind of role the organisation is with regards to the congestion revenue rights. kind {817F0F6C-32E3-428e-AF3D-E177CD4B0ABB} Status of congestion revenue rights organisation role. status {D6062590-97D9-433a-902E-EF85BB9A46CD} CongestionRevenueRight {02556F1B-1A48-4bb0-A787-9F04C918321D}.ClientEnd Sink {6840ECDE-F677-428f-9118-D01BDF989AE0}.ClientEnd Source {C97DA9A4-D136-4894-A6A2-CA207A447300}.ClientEnd Dollar amount quantity x clearingPrice amount {A6570274-EA82-4585-B682-BA080CABD479} Clearing price of a CRR clearingPrice {9D3642DA-F58B-4d4c-84D6-0B30CE29E38D} Current source converter to which current source converter dynamics model applies. CSConverter {923E9B98-7F14-449a-BFFF-B62D5A7D53DF}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {BDBA0EFE-6EA8-41c4-B3E1-5DE008753AF0}.SupplierEnd CCAinverter {C028CE96-6309-4883-89A5-E1B91BD9EF2D}.ClientEnd CCArectifierControl {AF476A35-E037-4efb-9B03-02299D031FDA}.ClientEnd IdcInverterControl {339D9BE1-B6FE-4ebd-B884-707C77DA6C91}.ClientEnd IgnAngleContInverter {2F9E4B3A-A9A7-43b4-8FAD-55865942D1B6}.ClientEnd A combustion turbine may have an active power versus ambient temperature relationship. CombustionTurbine {BA81A687-7485-4703-80D8-BDAF921D5E98}.SupplierEnd CompatibleUnits {7E14ED1F-0F2B-406f-8316-5676CAE2C27A}.SupplierEnd status {CDA6347F-4E54-4cfe-8B8E-B1E8A9B89F34} CompatibleUnits {53544586-E3BD-4bd3-9885-4857731939B8}.SupplierEnd The amount that a given contractor will charge for performing this unit of work. bidAmount {91FD99D5-6C69-41ef-9EDB-57A269F7ECBA} status {0727D6EF-8BF0-4d38-8E0D-AECD7DF306E5} ChildCUGroups {F2337009-71FC-4039-AA2C-3883E6E5090F}.SupplierEnd CompatibleUnits {8FAE377F-EEE5-44eb-962C-214341F7F3FE}.ClientEnd DesignLocationCUs {324E1A81-07DF-4842-8F2C-ED32F058D0AD}.ClientEnd ParentCUGroups {F2337009-71FC-4039-AA2C-3883E6E5090F}.ClientEnd status {93D57A4B-103F-4d7a-9D99-5BE2A6857863} CULaborItems {86DE1A8D-1A39-4b4c-ACFB-82676C3A39CC}.ClientEnd status {1E8FF0B9-AE52-4fa9-972E-5F4A7937CBA8} CULaborCode {86DE1A8D-1A39-4b4c-ACFB-82676C3A39CC}.SupplierEnd CompatibleUnits {289D7D61-564F-42e9-B83D-CB11520403E4}.SupplierEnd QualificationRequirements {5E0A5A68-F3A6-4607-B782-EC1790EB274A}.SupplierEnd Estimated time to perform work. laborDuration {ED6A9917-8BFF-49de-ADCC-2FCCFE1DDFD0} The labor rate applied for work. laborRate {96B902E1-9183-4316-BDA9-96E36A8FD113} status {07B6AF2C-70B7-45df-A5DE-90A1D7B32C79} CompatibleUnits {7B6A93BA-1EDF-4a37-AE20-76A155009833}.SupplierEnd PropertyUnits {EBAAAA49-96BE-4f07-8F12-EAF5BDD82A20}.ClientEnd TypeMaterial {5FD8B251-F630-475d-9DE8-4E62B3FDAF21}.SupplierEnd Quantity of the TypeMaterial for this CU used to determine estimated costs based on a per unit cost or a cost per unit length specified in the TypeMaterial. quantity {B7865C97-BCCF-43a9-9374-C25AD5592D79} status {93FE8899-6378-464e-9825-65D411C30197} CompatibleUnits {05F15D8B-35FF-4170-9657-52306B692CE3}.SupplierEnd TypeAsset {855EE031-A0C0-4d02-9660-78C8C2427736}.SupplierEnd Standard usage rate for the type of vehicle. rate {D035D616-0916-471c-8F7D-AE78C8E86312} status {B124700B-0497-4f85-BC8B-0DBDC8198770} Kind of construction of this cable. constructionKind {4D9F5894-8A3B-4c56-9F9E-BFF1D7145990} Diameter over the core including any semicon screen should be the insulating layers inside diameter. diameterOverCore {05C91266-DD15-4752-9B4B-290CCEDA7AAC} Diameter over the insulating layer excluding outer screen. diameterOverInsulation {F57940EC-27FA-4a95-8C42-931C440DF9A2} Diameter over the outermost jacketing layer. diameterOverJacket {36EA38E6-9187-4dce-AC76-EC5152CA0FC2} Diameter over the outer screen should be the shields inside diameter. diameterOverScreen {4DCB270F-79BA-4b23-BE0D-F55312E45AD1} Maximum nominal design operating temperature. nominalTemperature {691CB804-F1A4-43ed-A282-4C8A5DBE1C2A} Kind of outer jacket of this cable. outerJacketKind {0F5A1D1C-E044-4a8e-841B-BAF54FBAB5F0} Material of the shield. shieldMaterial {97FE3C2C-5C0F-43be-A86D-CAB3A36C9B69} Order of a statistical calculation associated with this calculation method hierarchy. CalculationMethodOrder {00BBCC2C-664B-492b-A281-9999BD00D8C8}.ClientEnd Measurement to which this calculation method hierarchy applies. Measurement {F91A2D8A-DA8C-4273-9073-224DE84F0F21}.ClientEnd Measurement value to which this calculation method hierarchy applies. MeasurementValue {54A8E767-B481-4e4a-947E-047AC60B5490}.SupplierEnd The calculation method hierarchy of which this order of statistical calculation is a member. CalculationMethodHierarchy {00BBCC2C-664B-492b-A281-9999BD00D8C8}.SupplierEnd The statistical calculation done at this order. StatisicalCalculation {3472E24D-F0B4-42fa-AC2A-06A47816E2D7}.ClientEnd Crafts {921FF0C0-21D9-4312-8288-1512B1E7B653}.SupplierEnd Crew {A3C41283-0A33-4ee9-A5AA-105826F2A3B8}.SupplierEnd WorkTasks {99651776-E1FC-4685-A904-70049BEA9646}.SupplierEnd status {47F71C50-8EE5-4e39-A501-3EB1B1951763} Date and time interval for which this capability is valid when it became effective and when it expires. validityInterval {03816E14-5056-49e1-9FAE-0577BE620316} multiplier {6B627C28-A1CA-4e5d-973E-F3AD555F9CCB} unit {20932C4A-6600-416b-B9C4-DCC7BD3FAA98} multiplier {D62CFC12-58FC-4949-A5A3-4AD5F5F76DB8} unit {25F43457-2958-4551-82D0-499592D2953A} Payment tender this card is being used for. Tender {61A73D4C-E942-43c5-8D12-F351276DE012}.SupplierEnd All shifts operated by this cashier. CashierShifts {C62261F0-61D6-4139-B0DA-87CAB071505B}.SupplierEnd Electronic address. electronicAddress {1448C660-7C05-4dde-AB7A-593FDF7BE83E} Cashier operating this shift. Cashier {C62261F0-61D6-4139-B0DA-87CAB071505B}.ClientEnd Point of sale that is in operation during this shift. PointOfSale {5F23BDB7-8C52-4be9-BDFD-61927D2EA76C}.SupplierEnd All Receipts recorded for this Shift. Receipts {3CC80665-07B4-4a5d-9D19-56F2B340FE1D}.SupplierEnd All transactions recorded during this cashier shift. Transactions {2D10DF39-BE65-4644-A37D-1155967E0230}.SupplierEnd The amount of cash that the cashier brings to start the shift and that will be taken away at the end of the shift i.e. the cash float does not get banked. cashFloat {499AA4FB-1471-4210-B0DA-21CD21E8AC1A} Generic nameplate information associated with this catalog asset type. AssetInfo {9B683AA4-C622-4998-B81E-A7467D326D7B}.ClientEnd CompatibleUnits {29224EFF-E858-46a4-AF56-8007409442DC}.ClientEnd ErpBomItemDatas {3FB0DAAA-9E8C-499f-81CE-3F538433A48D}.SupplierEnd ErpInventoryIssues {AECF6503-964C-41a1-AA24-93AF8EF31369}.ClientEnd ErpReqLineItems {7F453A7B-93B5-4f12-8984-2FC06DB80EED}.SupplierEnd Product asset model conforming to this catalog asset type. ProductAssetModel {2558E36F-4A9B-4eab-B70C-B1D8802138AE}.ClientEnd TypeAssetCatalogue {C03D47F2-A60F-4e08-BAA2-09494FC4FFE5}.SupplierEnd Estimated unit cost or cost per unit length of this type of asset. It does not include labor to install construct or configure it. estimatedUnitCost {B4F70823-2AC7-4c7b-BBB7-8C1793012C79} Kind of asset from enumerated list. kind {63B2EAF2-BBD6-4d65-BE9E-0DD758F0AFAF} The value unit of measure and multiplier for the quantity. quantity {389C6A93-611C-4e9c-B2A6-3A3AEFEB9B7A} Data objects contained in the dataset. ChangeSetMember {D718248A-D448-492a-AE40-8C6ED4992EB3}.ClientEnd IncrementalDatasetArg {4727D339-3136-4719-B7FF-3F8D5D00B334}.ClientEnd NMProjectStage {5C7D89EE-E6F6-4bc7-9B55-013A14F63C05}.ClientEnd The project of the details of model changes. NetworkModelProjectChangeVersion {D0FD1813-3105-4ab3-AA49-9C2E1C71624E}.ClientEnd Dataset containing the data objects. Changeset {D718248A-D448-492a-AE40-8C6ED4992EB3}.SupplierEnd The CIM object holding the properties of this dataset context. Sometimes properties are not required and only the reference to the registered object is required. PropertiesObject {F527D24E-59B1-4748-B31A-660841060493}.SupplierEnd The registered CIM object. TargetObject {950EB9DD-F3F6-405e-81C4-3D00B3ABD338}.SupplierEnd Reading type for register values reportedcollected by this channel. ReadingType {D4257F98-65DB-49d2-B38F-C912709EE1BE}.ClientEnd Register whose values are collectedreported by this channel. Register {BDCC2E66-6842-4911-B918-FE7BEF381847}.ClientEnd All auxiliary accounts to which this charge has to be levied. AuxiliaryAccounts {76534BC8-9FAC-414b-8310-44B6AD265341}.ClientEnd All subcomponents of this complex charge. ChildCharges {08FE2110-76C1-4a9f-B98F-426253A4F91B}.SupplierEnd Tariff intervals to which this consumptionbased charge has to be levied. ConsumptionTariffIntervals {3C4455D4-C34E-4001-A555-8912924EE287}.ClientEnd Parent of this charge subcomponent. ParentCharge {08FE2110-76C1-4a9f-B98F-426253A4F91B}.ClientEnd Tariff intervals to which this timebased charge has to be levied. TimeTariffIntervals {0A0C819B-B021-48a1-BE23-8DEE728FFA6C}.ClientEnd The fixed portion of this charge element. fixedPortion {15E75850-C511-4c5c-838E-29D81E275C75} The kind of charge to be applied. kind {97CEDF1B-DFBB-4bec-A7D9-7E9C8847EA81} The variable portion of this charge element calculated as a percentage of the total amount of a parent charge. variablePortion {0177EE2C-2DDD-4b9d-80E4-BBAC93AA2155} A BillDeterminant can have 0n ChargeComponent and a ChargeComponent can associate to 0n BillDeterminant. BillDeterminants {57B8DDF0-7B94-45b0-B5EF-5CDB1744BC85}.SupplierEnd A ChargeType can have 0n ChargeComponent and a ChargeComponent can associate to 0n ChargeType ChargeTypes {AB9918D4-8D8B-4024-A3BF-3455722AFD23}.ClientEnd A ChargeGroup instance can have relationships with other ChargeGroup instances. ChargeGroupChild {0DEF88A8-6EA6-48a3-AC80-C41AB6B06EB2}.ClientEnd A ChargeGroup instance can have relationships with other ChargeGroup instances. ChargeGroupParent {0DEF88A8-6EA6-48a3-AC80-C41AB6B06EB2}.SupplierEnd A ChargeGroup can have 0n ChargeType. A ChargeType can associate to 0n ChargeGroup. ChargeType {26B46C92-D1DF-4b3a-8924-D21D9D817976}.ClientEnd MktUserAttribute {7E99E40A-D085-4ca0-9CA9-3E9E0C539B2A}.SupplierEnd Bid {ADDC9B96-D85F-46b2-A697-B0712376B748}.ClientEnd BillDeterminant {1ACFDE89-AF63-4cb5-830B-04C1DDECED28}.SupplierEnd ChargeProfileData {D009347D-F669-4ca5-8477-6551DC761278}.SupplierEnd PassTroughBill {7A4358BC-7C4E-4235-A405-C2C839499AA8}.SupplierEnd BillDeterminant {AB69F7A6-CE60-4b02-AA54-24E729B7293B}.ClientEnd ChargeProfile {D009347D-F669-4ca5-8477-6551DC761278}.ClientEnd A ChargeType can have 0n ChargeComponent and a ChargeComponent can associate to 0n ChargeType ChargeComponents {AB9918D4-8D8B-4024-A3BF-3455722AFD23}.SupplierEnd A ChargeGroup can have 0n ChargeType. A ChargeType can associate to 0n ChargeGroup. ChargeGroup {26B46C92-D1DF-4b3a-8924-D21D9D817976}.SupplierEnd A MajorChargeGroup can have 0n ChargeType. A ChargeType can associate to 0n MajorChargeGroup. MajorChargeGroup {90202EBC-584B-4461-94E0-1F697B9901DA}.ClientEnd MktUserAttribute {FA4D0F9A-CFBA-4b39-8AF5-D8EDA0559E55}.SupplierEnd Payment tender the cheque is being used for. Tender {96162BCD-6CF6-40e7-B42A-5D0EB89F2B16}.SupplierEnd Details of the account holder and bank. bankAccountDetail {526A3707-985E-462e-8FFA-F383ECBAB845} Kind of cheque. kind {7A48158E-EB1D-43ec-B568-545424B8E4E2} EndBay {38C0C28C-00BF-4529-940D-5007F17FBB86}.SupplierEnd EndTerminal {6876E705-D5F6-4c77-9072-D14AF881DA08}.SupplierEnd The line segment to which the clamp is connected. ACLineSegment {2B7C9922-26A9-4218-8BDD-1098869C8600}.ClientEnd ClampAction {74C6F744-E53A-4fd0-BBA8-3531659CCC10}.SupplierEnd JumperAction {74BBE709-CFEF-40a9-A120-33F704608576}.SupplierEnd The length to the place where the clamp is located starting from side one of the line segment i.e. the line segment terminal with sequence number equal to 1. lengthFromTerminal1 {812CAF19-BD75-4aff-829A-B0D38FEC4817} Clamp {74C6F744-E53A-4fd0-BBA8-3531659CCC10}.ClientEnd Switching action to perform kind {C5150C6B-F9FB-4f05-A614-AFFC5ADE5CFC} multiplier {CAB91FF9-BEA3-4206-8453-D957703207E5} unit {38101F30-DA56-4a03-8A0D-9206BC8363D5} Analog which contributes to the definition of this classification condition. EnvironmentalAnalog {8B13B03E-D662-45ec-9CC3-71515B9D13CA}.ClientEnd String measurement which contributes to the definition of this classification condition. EnvironmentalStringMeasurement {71F9989B-6173-4d71-B9F1-2184FCC3CEF5}.ClientEnd Phenomenon classification to which this condition relates. PhenomenonClassification {0E97F0E1-C420-4b89-983A-670FE0F14582}.SupplierEnd The duration of the of the condition in seconds duration {4E9DA946-BA47-490b-A874-477F89446371} The test applied to the value. test {9BDE53DB-F87F-41b2-9085-73E4492D22CD} Clearance associated with this clearance action. Clearance {DC4663C9-511F-45f1-93ED-28032F3DAC73}.SupplierEnd Clearance action to perform. kind {AB65507D-9450-4d89-8138-EE69C858E7B9} Clearance action associated with this clearance. ClearanceAction {DC4663C9-511F-45f1-93ED-28032F3DAC73}.ClientEnd All power system resources tagged through this clearance. TaggedPSRs {65134A4B-0FD0-4c17-A353-8696C19D36F6}.SupplierEnd The type of the cloud as defined by the CloudKind enumeration. kind {1D7D13FE-44D4-48f6-9D80-C9A9D6F77FD1} AggregateNode {423960E1-ADF0-47a5-B371-AA4201541FC9}.ClientEnd HostControlArea {334067AA-47A1-45ec-86D0-469477F304C9}.ClientEnd MktConnectivityNode {2E462F8F-23E2-41eb-8C60-ECC38D2C21A2}.SupplierEnd SubControlArea {69BC43A4-9AD8-4639-A0FA-43901913DEDB}.SupplierEnd A cogeneration plant has a steam sendout schedule. SteamSendoutSchedule {29FFC448-2620-47ba-BE72-7DE2E8858FD0}.ClientEnd A thermal generating unit may be a member of a cogeneration plant. ThermalGeneratingUnits {E1908858-346B-40b8-9CAB-D6DDC55C0455}.SupplierEnd The rated output active power of the cogeneration plant.The attribute shall be a positive value. ratedP {030FEBF1-8B94-4387-B87A-4A07DC971BF1} Module performing this communication function. ComModule {1E15681F-E00C-4dcf-BBE6-C8C9BD4C8E71}.ClientEnd Kind of communication direction. direction {85AAA47A-AA87-476f-B356-2A80B9E1EC45} Kind of communication technology. technology {FBCD2058-994B-456b-8124-04942073D708} All functions this communication module performs. ComFunctions {1E15681F-E00C-4dcf-BBE6-C8C9BD4C8E71}.SupplierEnd Time zone offset relative to GMT for the location of this com module. timeZoneOffset {C194C2FE-468E-46c7-9EE3-11E21A1987FE} CombinedCycleConfigurationMember {BB1E7ACE-B3AF-4ca3-BD88-721B2DC11DB7}.SupplierEnd CombinedCycleLogicalConfiguration {A4A1B572-6C63-40e3-9CEF-94B37E4A2FA0}.ClientEnd FromTransitionState {6C3E95A9-66C1-4edc-AC13-E0A6C0EE70FF}.SupplierEnd ToTransitionState {82AF9D43-F3A7-43bb-955C-D1232C819B99}.SupplierEnd CombinedCycleConfiguration {BB1E7ACE-B3AF-4ca3-BD88-721B2DC11DB7}.ClientEnd MktThermalGeneratingUnit {DF15B386-08F6-4c78-95AD-B7B10FCC1AB9}.SupplierEnd CombinedCycleConfiguration {A4A1B572-6C63-40e3-9CEF-94B37E4A2FA0}.SupplierEnd MktCombinedCyclePlant {E85573FF-D877-4da8-AD0E-F1D7EBBB5773}.SupplierEnd A thermal generating unit may be a member of a combined cycle plant. ThermalGeneratingUnits {1A607D5D-0E44-490a-B14D-8A8B2A3D7057}.SupplierEnd The combined cycle plants active power output rating. combCyclePlantRating {F3CA2ADD-B19D-4adf-A42B-1A150DE08571} FromConfiguration {6C3E95A9-66C1-4edc-AC13-E0A6C0EE70FF}.ClientEnd ToConfiguration {82AF9D43-F3A7-43bb-955C-D1232C819B99}.ClientEnd A CAES air compressor is driven by combustion turbine. AirCompressor {F30399A8-ACB2-4f18-8D1C-F38C8427C14D}.SupplierEnd A combustion turbine may have an active power versus ambient temperature relationship. CTTempActivePowerCurve {BA81A687-7485-4703-80D8-BDAF921D5E98}.ClientEnd A combustion turbine may have a heat recovery boiler for making steam. HeatRecoveryBoiler {C08435B8-5EEA-4a1c-84DE-0253F3F7AC68}.ClientEnd Default ambient temperature to be used in modelling applications. ambientTemp {32064CA8-B772-450e-B8E6-7645496A085F} Offnominal frequency effect on turbine auxiliaries. Per unit reduction in auxiliary active power consumption versus per unit reduction in frequency from rated frequency. auxPowerVersusFrequency {7AC2EB60-47A7-4ccf-BA11-18AF1C401E71} Offnominal voltage effect on turbine auxiliaries. Per unit reduction in auxiliary active power consumption versus per unit reduction in auxiliary bus voltage from a specified voltage level. auxPowerVersusVoltage {FB8443FC-B138-41de-B6C2-2FD6F45B183C} Offnominal frequency effect on turbine capability. Per unit reduction in unit active power capability versus per unit reduction in frequency from rated frequency. capabilityVersusFrequency {B67CE496-747A-4adc-9851-9208F3DDD5EB} Per unit change in power per versus unit change in ambient temperature. powerVariationByTemp {C8658500-A01B-4d0c-9BE6-C33C8EF0511C} Reference temperature at which the output of the turbine was defined. referenceTemp {A5EEFE8D-8EEC-4e8c-9AF1-329A6E210EDE} The time constant for the turbine. timeConstant {BA4EE654-7C68-4f21-AB45-228ABCB91E26} The MeasurementValue that is controlled. DiscreteValue {DF0C3745-2D94-4daa-8AA0-20AE415D601B}.ClientEnd The ValueAliasSet used for translation of a Control value to a name. ValueAliasSet {E47F1C07-76A3-4828-BB41-624EB0C9DAE0}.SupplierEnd Commitments {215A722F-0E10-4556-A345-B31B11229B80}.SupplierEnd CommitmentClearing {215A722F-0E10-4556-A345-B31B11229B80}.ClientEnd RegisteredResource {61A71384-CC3E-4247-AE63-5AD07C4A3E89}.ClientEnd the type of UC status self commitment ISO commitment or SCUC commitment commitmentType {527FACAD-30AC-4dff-A647-F8F697938812} Indicator of either a StartUp or a ShutDown. instructionType {B626E793-2768-4fab-B947-47EF25913E8A} updateType {9EA85907-611E-4875-A259-19906297D428} CommodityPrice {C7E98892-55E0-49fe-9B35-CF765FDE3A10}.ClientEnd MarketProduct {2CE15336-9D65-42db-A3CA-4D3E955778DF}.SupplierEnd Pnode {F9E2DDE2-0FFA-44c6-9186-CCF290EFA2ED}.SupplierEnd RTO {9C7DB57F-73C7-4d73-B17D-1CE635F85AF4}.ClientEnd The currency in which the Commodity is traded using the standard conventions associated with the Currency enumeration. commodityCurrency {28E7466A-68B8-43e9-A152-41C283962539} The unit of measure in which the Commodity is traded using the standard conventions associated with the UnitSymbol enumeration. commodityUnit {FA02E9BA-2CAF-4929-96E6-891A21ECF764} The unit multiplier e.g. k to convert the unit Wh to kWh using the standard conventions associated with the UnitMultiplier enumeration. commodityUnitMultiplier {B18933B5-D585-4df7-BD75-56AAB6407D67} CommodityDefinition {C7E98892-55E0-49fe-9B35-CF765FDE3A10}.SupplierEnd PnodeClearing {B037CDCC-4EA4-4d2d-8CF4-27BBEFA157FC}.ClientEnd PriceDescriptor {0E804F54-A29B-4452-B7D6-078FE7D84D1F}.SupplierEnd The time interval over which the CommodityPrice is valid using the standard conventions associated with the DateTimeInterval class. timeIntervalPeriod {DC2CF275-2E96-4e98-B34D-CF509B532E2C} ICCP data provider or consumer using communication addressing for a Bilateral table. BilateralExchangeActor {F8B558CB-826C-44f6-8B37-E168629E4395}.SupplierEnd RTUs may be attached to communication links. RemoteUnits {E4ED6E40-6C5C-406f-B61F-EFE533D3AE61}.SupplierEnd CUAllowableAction {7E14ED1F-0F2B-406f-8316-5676CAE2C27A}.ClientEnd CUContractorItems {53544586-E3BD-4bd3-9885-4857731939B8}.ClientEnd CUGroup {8FAE377F-EEE5-44eb-962C-214341F7F3FE}.SupplierEnd CULaborItems {289D7D61-564F-42e9-B83D-CB11520403E4}.ClientEnd CUMaterialItems {7B6A93BA-1EDF-4a37-AE20-76A155009833}.ClientEnd CUWorkEquipmentItems {05F15D8B-35FF-4170-9657-52306B692CE3}.ClientEnd CostType {01AD8352-4238-4d6f-96FF-7F8AD75B6EF6}.ClientEnd DesignLocationCUs {B11E2CCC-4BD2-4bb3-AC4A-FC61ADF42FD2}.SupplierEnd GenericAssetModel {29224EFF-E858-46a4-AF56-8007409442DC}.SupplierEnd Procedures {A0D146CA-A291-4aa2-8C93-C33AFCBB974E}.SupplierEnd PropertyUnit {730C905B-BBFC-44aa-A988-5BCE91C46E12}.ClientEnd Estimated total cost for perfoming CU. estCost {27A8E557-A144-4928-A41D-C08570FF0657} AssemblyManifest {ABA7248F-7487-4c32-811C-B708158136CB}.ClientEnd ModelPartVersion {C390164D-CBC2-47e2-8EAE-2EC7A1187A16}.ClientEnd Switches contained in this Composite switch. Switches {E6CD744D-0D2A-4e23-9C5E-B2A3778D7618}.SupplierEnd Breaking capacity or short circuit rating is the maximum rated current which the device can safely interrupt at the rated voltage. interruptingRating {9525C8A5-E385-4b62-8111-4C698501E6AC} Kind of composite switch. kind {5F9E9576-360F-431d-8D96-0599C1C8FA37} Phases carried if applicable. phaseCode {50FFA036-5C76-4651-9D2E-BBCCF8DC0206} Rated voltage. ratedVoltage {6C338611-59D7-4ae5-98D7-4DB6AD3E73F2} Diameter over the concentric neutral strands. diameterOverNeutral {0F237A9F-3062-4eba-A9DE-51F5E9E66097} Geometric mean radius of the neutral strand. neutralStrandGmr {50EDC85A-4806-45cf-B338-BE66FBF5B1FE} DC resistance per unit length of the neutral strand at 20 C. neutralStrandRDC20 {220DD0D7-8C30-4053-8ABD-78E61B85486B} Outside radius of the neutral strand. neutralStrandRadius {1FAB34BD-4EB6-4b0d-AEF2-50FF7BF26AA2} DesignLocationCUs {A2A64DC1-F71D-4a0f-9604-744445395515}.ClientEnd DesignLocations {01106373-66A2-47e6-BE11-C6EB50A8EA95}.ClientEnd Designs {B55CE47A-87D3-4069-AE0A-CD19D6B6247B}.ClientEnd Kind of this condition factor. kind {DE2809D1-058B-49cc-BA37-2278C6051689} status {CB453424-AEE0-4743-B871-6F83590D4D8C} multiplier {EDFA4FD2-D5E9-4dc7-AC28-EE6658BED80A} unit {19818A5D-D769-4eb2-B84D-616C971F1004} multiplier {0B66B808-85A1-479a-8EDA-29D16B739CE2} unit {D7DE7981-D0AB-452a-8C9F-E3CF24B3083A} Base voltage of this conducting equipment. Use only when there is no voltage level container used and only one base voltage applies. For example not used for transformers. BaseVoltage {B21687D9-2B46-4880-B016-06CCFA215EC3}.ClientEnd Action involving grounding operation on this conducting equipment. GroundingAction {E49D8003-4EDF-4e58-A61C-0A5F1C6165E1}.ClientEnd Jumper action involving jumping operation on this conducting equipment. JumpingAction {4D35C940-C8A8-4a53-846A-929278E1DB57}.ClientEnd Outage {EEA2935F-26F1-463e-890E-676B5DDA189A}.ClientEnd Protection equipment used to protect specific conducting equipment. ProtectionEquipments {1A223051-2D2E-4ca4-8FF1-9C8D1BDE000B}.ClientEnd The operating condition to the Conducting Equipment is changed when protective action adjustment is activated. For ShuntCompensator or other conducting equipment that operates on discrete values integer the values given in float will be rounded. ProtectiveActionAdjustment {44AD5B78-D603-43d9-A73C-68DCFE8B9C09}.SupplierEnd The status state variable associated with this conducting equipment. SvStatus {A1BADE18-494C-4d12-B7E2-2C9AF7F526ED}.ClientEnd Conducting equipment have terminals that may be connected to other conducting equipment terminals via connectivity nodes or topological nodes. Terminals {5FEF5186-7804-4dad-8E18-8C5DB7FCE6B2}.ClientEnd Segment length for calculating line section capabilities. length {3F232A26-A1CA-4477-ADA1-92AC37BFAF1D} Asset whose change resulted in this configuration event. ChangedAsset {71EA796A-141A-445d-9B0E-EF0075BFAFD2}.ClientEnd Document whose change resulted in this configuration event. ChangedDocument {E33CE794-1D36-4889-BDFB-F26AF8508188}.ClientEnd Location whose change resulted in this configuration event. ChangedLocation {5A4A6C15-ADB0-446d-8CFE-0DE670D4800F}.ClientEnd Organisation role whose change resulted in this configuration event. ChangedOrganisationRole {83D1A41E-45C6-49ba-883F-D9E6B3E0643C}.ClientEnd Person role whose change resulted in this configuration event. ChangedPersonRole {472A820F-DB21-4935-A460-E5C9B71BB861}.ClientEnd Service category whose change resulted in this configuration event. ChangedServiceCategory {460BA6C7-2417-41f6-8AC0-A21EE240B5BC}.ClientEnd Usage point whose change resulted in this configuration event. ChangedUsagePoint {BA6788B9-B467-4d11-81A1-9DFE88730490}.ClientEnd FaultCauseType {B79138C2-DB7B-43a8-A72B-77D615EB381B}.SupplierEnd PowerSystemResource {26DFEBF9-D038-4c7e-96A1-F4832AC44307}.ClientEnd Group of this ConformLoad. LoadGroup {0EFAEF28-CDEB-4076-9D2D-5AE94985E8CF}.ClientEnd The ConformLoadSchedules in the ConformLoadGroup. ConformLoadSchedules {D3B829DB-A9B9-471b-BBAC-A4FE537AA726}.SupplierEnd Conform loads assigned to this ConformLoadGroup. EnergyConsumers {0EFAEF28-CDEB-4076-9D2D-5AE94985E8CF}.SupplierEnd The ConformLoadGroup where the ConformLoadSchedule belongs. ConformLoadGroup {D3B829DB-A9B9-471b-BBAC-A4FE537AA726}.ClientEnd IndividualPnode {6DB2691B-152F-462d-B727-DE871F8AAB7A}.SupplierEnd CRRMarket {A6EF647F-83D1-46c2-83BA-498C5AC0EE5D}.SupplierEnd CRROrgRole {80E51726-F69E-4014-ACD6-C80A45B842AE}.ClientEnd CRRSegment {02556F1B-1A48-4bb0-A787-9F04C918321D}.SupplierEnd Flowgate {C6E4CA42-E336-4a8a-828E-6AF9E8F25458}.SupplierEnd CRR category represents PTP for a pointtopoint CRR or NSR for a Network Service Right. If CRR category is PTP both Source ID and Sink ID fields are required. If CRR category is NSR only one field either Source ID or Sink ID shall be not null and the other shall be null. However the NSR category will include at least three records. cRRcategory {4C520D47-2ED3-4ab0-B9D3-803FFD498DFC} Type of the CRR from the possible type definitions in the CRR System e.g. LSE ETC. cRRtype {82F8F5AE-05DF-450f-91C3-309A7F0BDF51} Hedge type Obligation or Option. An obligation type requires the holder to receive or pay the congestion rent. An option type gives the holder the option of receiving or paying the congestion rent. hedgeType {84FCF73B-EB28-4295-95EC-A9573BBD87A6} Time of Use flag of the CRR Peak ON Offpeak OFF or all 24 hours 24HR. timeOfUse {4A64E75A-59EB-4a3f-9D95-75200134BC8B} Switches {ABF72E73-E9B7-40a5-8FC4-D1B196EC3845}.SupplierEnd Information on remote connect disconnect switch. rcdInfo {6CA585CC-501E-48a4-A4CD-E442EB31B110} Container of this connectivity node. ConnectivityNodeContainer {08EEABA6-269C-44a7-8F82-7BBEFE71ADD6}.SupplierEnd Terminals interconnected with zero impedance at a this connectivity node. Terminals {C7E01609-F4E6-4a6e-8ACF-BDD413E62DE3}.ClientEnd The topological node to which this connectivity node is assigned. May depend on the current state of switches in the network. TopologicalNode {ACD76E10-125A-4f7a-A20A-475AC4334414}.SupplierEnd Connectivity nodes which belong to this connectivity node container. ConnectivityNodes {08EEABA6-269C-44a7-8F82-7BBEFE71ADD6}.ClientEnd The topological nodes which belong to this connectivity node container. TopologicalNode {88BD0C47-4CB3-44db-9A6B-20C783A24478}.ClientEnd ConstraintResults {540BF2B6-C997-4421-B8A4-58AC92F6A5E8}.SupplierEnd TimeSeries {07DEE107-FB99-4586-A9B9-7F52BB893EAE}.SupplierEnd ConstraintClearing {540BF2B6-C997-4421-B8A4-58AC92F6A5E8}.ClientEnd Flowgate {18E34024-C496-433d-B129-256CA4377357}.ClientEnd MktContingency {01D4A0B2-81CC-4497-A052-25EA792CEC6E}.SupplierEnd Noncompetitive path constraint FlagYN indicating whether the shadow price on a noncompetitive path was nonzero. competitivePathConstraint {7DD8B0A9-DE8C-4152-8CB1-EB980354318A} Type of constraint. constraintType {E6B0EE46-D092-495d-BB25-B26643C0BD64} Limit flag Maximum Minimum. limitFlag {F81636F1-0A15-488d-84ED-25BA5A2A1B62} Included in optimization YN. optimizationFlag {BDCA0BAE-8A04-49e4-ABED-626194094737} MQS change type. updateType {6178EE0C-504C-47b2-81D7-9D517390EBAE} SecurityConstraintSum {BB8340BB-8D35-4db5-B3EA-6A408762BF83}.ClientEnd All charges used to define this consumption tariff interval. Charges {3C4455D4-C34E-4001-A555-8912924EE287}.SupplierEnd Reading type for startValue. ReadingType {2C44369F-3DF4-4dcd-9036-EDC39B37AB3D}.SupplierEnd All tariff profiles defined by this consumption tariff interval. TariffProfiles {7F5C8247-4764-43ce-8B24-F568152BB763}.ClientEnd All time of use tariff intervals influenced by this consumption tariff interval. TouTariffIntervals {8AA39685-1453-4631-B85A-DA04510557D0}.SupplierEnd MWLimitSchedules {B2755079-F601-4879-9341-AAF0FDCD8B1B}.SupplierEnd MktContingency {0906BEF7-3804-4598-9F39-8339F2B0B443}.SupplierEnd SecurityConstraintSum {BF65240F-A284-4af5-8E7D-B230D8362719}.SupplierEnd The single piece of equipment to which to apply the contingency. Equipment {90FE687B-C58C-4b05-856E-6D576F7CADBE}.SupplierEnd The status for the associated equipment when in the contingency state. This status is independent of the case to which the contingency is originally applied but defines the equipment status when the contingency is applied. contingentStatus {AD281283-F48F-4f62-AA91-7039DDA80DCF} Flowgate {3A09997D-D60D-46df-B010-018CC9A81D1B}.ClientEnd RegisteredResource {B2C73AF1-CB11-4c78-BE4B-750739E77C5F}.ClientEnd TransmissionContractRight {719073AE-6982-4fac-ACA7-C131AF4340BF}.ClientEnd This value will be set to YES if the referenced Cnode is defined as the sink point in the contract. sinkFlag {46CEAB7B-6927-40b4-BC86-2217335A385A} This value will be set to YES if the referenced Cnode is defined as the source point in the contract. sourceFlag {5B875BAA-510D-462a-88D8-408D7CC444BD} BidSelfSched {C020B2A4-890F-455d-8C69-8B0612C789BB}.SupplierEnd Chain_TransmissionRightChain {1D17EEA8-4DC7-4648-B0A4-3D0516BC89C2}.ClientEnd ContractDistributionFactor {719073AE-6982-4fac-ACA7-C131AF4340BF}.SupplierEnd Ind_TransmissionRightChain {2A59E041-E065-428d-9918-A42D868C16C6}.ClientEnd RTO {A3A25A93-B38D-4be8-AFA8-1F472DA6E232}.ClientEnd SchedulingCoordinator {9344B7EF-5714-48c0-9CD5-ABBE8A690C30}.ClientEnd SubstitutionResourceList {869976B9-DCEB-44ff-8BDB-956B7D44DFE7}.SupplierEnd TREntitlement {646BBA57-9F62-43b1-9636-2CBBCFAC508B}.SupplierEnd Transmission Right type is this an individual contract right or a chain contract right. Types CHAIN or INDIVIDUAL TRType {EFAE446B-7050-4c0e-AAC4-113E462553AD} TransmissionInterfaceEntitlement {BD4EDF28-A98E-4529-8A20-3113450CEBF4}.ClientEnd Financial value of the contract contractPrice {67E2DD6E-E113-424a-8696-73DC4212B49D} type of the contract. Possible values are but not limited byETC TOR or RMR and RMT self schedules contractType {50EFBAEA-CB69-495f-8F28-B2D273379DCD} Indicator if the location associated with this contract is financial e.g. pricing nodes or physical e.g. connectivity nodes. financialLocation {A5B1AFFB-D593-409d-BFFA-66D28B68342C} Flag to indicate this contract provides financial rights in the DA Market financialRightsDAM {7CB8D5C0-F0D4-4f9a-BB9E-18FB22D3F56F} Flag to indicate this contract provides financial rights in the RT Market financialRightsRTM {A8038C1B-BED1-438c-AC6B-AD38473015F4} This indicates the latest schedule market type a contract can be applied to. This is used in conjunction with the latestSchedMinutes attribute to determine the latest time this contract can be called in. The possible values for this attribute are DAM RTM or it can be omitted. If omitted the latestSchedMinutes attribute defines the value. latestSchedMktType {02C369CF-D893-446f-B2C7-1B2FBF65C72A} Flag to indicate this contract provides physical rights in the DA Market physicalRightsDAM {A2C97CC3-4D0F-4852-A317-92969709F57C} Flag to indicate this contract provides physical rights in the RT Market physicalRightsRTM {CF9EC11A-1A0D-4ef3-8694-D84E0072300F} ErpPayables {C73FA4A3-2380-4d97-8F28-0D805D815283}.SupplierEnd WorkCostDetail {96CD6C4B-B625-48f2-823B-F52CD16FCC1F}.ClientEnd WorkTask {3123F76B-B55F-4f42-AEB4-96AA9F5254CA}.ClientEnd The amount that a given contractor will charge for performing this unit of work. bidAmount {55892BA8-8746-490a-8608-B73E9554F70D} The total amount charged. cost {6541723D-E2B5-4670-9994-B50549B996D0} status {F41D579D-4E88-4f9e-A557-D9ED371EF8B5} ControlAction {55F3693A-6960-486a-AEB0-EEBB67B10D9A}.ClientEnd Regulating device governed by this control output. PowerSystemResource {A1BE05F6-8AA3-4c36-B00D-9A3BC3D8B4D3}.ClientEnd The remote point controlling the physical actuator. RemoteControl {D8E2547F-5EE8-425a-88B2-6878C15AFEF6}.ClientEnd The unit multiplier of the controlled quantity. unitMultiplier {12032CC3-C242-4966-9865-799B40A03B62} The unit of measure of the controlled quantity. unitSymbol {704DC262-1071-4a4d-AC47-83098723EFE6} Control {55F3693A-6960-486a-AEB0-EEBB67B10D9A}.SupplierEnd The energy area that is forecast from this control area specification. EnergyArea {91910331-E0D0-4b32-9E25-EC5310A60B71}.SupplierEnd EnergyGroup {EC0B638A-E0FD-42c8-B84C-47AA469B8629}.ClientEnd The specified positive net interchange into the control area i.e. positive sign means flow into the area. netInterchange {B02AFBB9-BD7F-45e4-B361-D0EDD5F7CB79} Active power net interchange tolerance. The attribute shall be a positive value or zero. pTolerance {1384C2B5-6BFF-49b9-A768-AE4D26733146} The primary type of control area definition used to determine if this is used for automatic generation control for planning interchange control or other purposes. A control area specified with primary type of automatic generation control could still be forecast and used as an interchange area in power flow analysis. type {66C3EA41-8A06-4176-8AE5-F3970BB794FF} RegisteredResource {E2FACF8B-8529-4118-B66B-ABACB5D4B6A4}.SupplierEnd SubControlArea {ABACF27C-565A-45bd-B69C-0A1A99CECFC2}.SupplierEnd Attained. attained {B2E2A3D0-6B24-40cf-A4B5-E514512313D7} Native. native {27CBF0DC-4AFA-453e-A245-FF9C8C6D6639} The generating unit specified for this control area. Note that a control area should include a GeneratingUnit only once. GeneratingUnit {682C859C-B9CD-4dde-A959-EB89678BBBD6}.SupplierEnd A ControlAreaOperator has a collection of tie points that ring the ControlArea called a TieLine. CAChildOf {1FE3925A-54B7-4008-8CC6-93CD443CC3C0}.SupplierEnd A ControlAreaCompany controls a ControlArea. ControlledBy {1AFC6FC5-1F2B-45c1-92ED-34FE03FF7500}.ClientEnd MktControlArea {72466897-1E7B-4232-8415-B1CF11A7D241}.SupplierEnd Reconditionings {87E64861-9690-46b3-ADD5-CF931CEA7994}.SupplierEnd Kind of cooling system. coolingKind {1738008D-77A8-490f-BE53-1F63E4ED27D3} The power rating associated with type of cooling specified for this stage. powerRating {63162C86-80AD-41c4-8AC9-962B359EDA98} All locations described with position points in this coordinate system. Locations {D9DB79D8-27F1-4071-9C79-F0F1F62B4F18}.ClientEnd multiplier {58C8EF99-A30B-46a8-B471-3960E5B17784} unit {62781DDF-86F3-4cfb-93D8-B79FCCA44427} multiplier {0ED554FC-EDA3-475c-BD91-CFCF254D87AE} unit {A892F793-EFD8-4d0a-816F-C62F14DDC794} multiplier {A4686C05-46C7-4987-AD4B-F37C39B59D69} unit {8EB82F99-A67A-4ee9-9BC8-FB807B99CCB9} multiplier {683ECF7A-C52C-4696-8E3A-3871F72395A3} unit {B39B1C54-D199-470c-9AF4-0053A2144F5F} ChildCostTypes {967B42DB-FFF7-48d8-AC58-99DF4BDC3FF3}.SupplierEnd CompatibleUnits {01AD8352-4238-4d6f-96FF-7F8AD75B6EF6}.SupplierEnd ErpJournalEntries {416479A3-0381-44f8-B625-D715F8C424E6}.SupplierEnd ParentCostType {967B42DB-FFF7-48d8-AC58-99DF4BDC3FF3}.ClientEnd WorkCostDetails {5446E847-F2C9-4006-ABE5-5682B880301D}.SupplierEnd status {6C2713BB-0D7C-409f-BF66-3948CB53290E} Capabilities {921FF0C0-21D9-4312-8288-1512B1E7B653}.ClientEnd ErpPersons {19D1AD6D-1BA3-400f-BACA-BF16BDB31A48}.SupplierEnd Skills {F6C636B7-1341-45e9-9F57-F9DAF8AA60FC}.ClientEnd status {9F648612-EFEE-42e2-9402-531F257170E8} All members of this crew. CrewMembers {9C3593D0-040D-4b39-831A-6E1E5BA063DA}.SupplierEnd Type of this crew. CrewType {5A1DA3D9-8576-4f56-BED5-2A869AA8BA84}.SupplierEnd FieldDispatchHistory {2F2C04F1-3A57-404e-87F0-356183FF8B57}.ClientEnd Location {5396B10B-F4AB-46c8-B558-A0D64090E603}.ClientEnd Outage {D0947F3D-A8D0-4b21-9924-B957AF56DC82}.ClientEnd SwitchingAction {A7E0FAFD-8B4F-45b4-B614-D821AB007EF9}.ClientEnd All work assets used by this crew. WorkAssets {762660F7-4910-42bc-8748-C7841507E17A}.ClientEnd All work tasks this crew participates in. WorkTasks {D3920004-AE6C-439a-9CED-543CFED22657}.ClientEnd Status of this crew. status {299A7357-1875-4dc2-ACFB-84F3D7F2368B} Crew to which this crew member belongs. Crew {9C3593D0-040D-4b39-831A-6E1E5BA063DA}.ClientEnd All crews of this type. Crews {5A1DA3D9-8576-4f56-BED5-2A869AA8BA84}.ClientEnd Highpressure synchronous machine with which this crosscompound turbine governor is associated. HighPressureSynchronousMachineDynamics {4EEEDF69-9BB6-4d02-B662-A156239AF9B8}.SupplierEnd Lowpressure synchronous machine with which this crosscompound turbine governor is associated. LowPressureSynchronousMachineDynamics {9C225B93-4040-4753-80B9-1A3D0F2B6D81}.SupplierEnd Current source converter dynamics model used to describe dynamic behaviour of this converter. CSCDynamics {923E9B98-7F14-449a-BFFF-B62D5A7D53DF}.ClientEnd Firing angle that determines the dc voltage at the converter dc terminal. Typical value between 10 degrees and 18 degrees for a rectifier. It is converters state variable result from power flow. The attribute shall be a positive value. alpha {9D272F46-EABD-436f-9B05-3AB954FEB505} Extinction angle. It is used to limit the dc voltage at the inverter if needed. Typical value between 17 degrees and 20 degrees for an inverter. It is converters state variable result from power flow. The attribute shall be a positive value. gamma {B9AD7780-6511-4795-8FF2-0797C537AF64} Maximum firing angle. It is converters configuration data used in power flow. The attribute shall be a positive value. maxAlpha {35DA4A07-8966-4207-B9EA-CFA2F8C5556C} Maximum extinction angle. It is converters configuration data used in power flow. The attribute shall be a positive value. maxGamma {CAAD51DE-696B-4678-8DEA-868AFA1529B4} The maximum direct current Id on the DC side at which the converter should operate. It is converters configuration data use in power flow. The attribute shall be a positive value. maxIdc {6C080741-A57E-4534-A156-2380B3E712ED} Minimum firing angle. It is converters configuration data used in power flow. The attribute shall be a positive value. minAlpha {ADAF6A15-8626-4955-BD2A-A3EE3D700C84} Minimum extinction angle. It is converters configuration data used in power flow. The attribute shall be a positive value. minGamma {601E21E7-7AFC-4631-9752-EE3F81D1BEF5} The minimum direct current Id on the DC side at which the converter should operate. It is converters configuration data used in power flow. The attribute shall be a positive value. minIdc {27F20192-3FDA-4372-8F7C-B0D934DD9B2C} Indicates whether the DC pole is operating as an inverter or as a rectifier. It is converters control variable used in power flow. operatingMode {3717F511-42E5-4920-8B73-5AB13798BCF4} Kind of active power control. pPccControl {A4B32267-105D-4bc1-9A46-A87AB1DEB8CC} Rated converter DC current also called IdN. The attribute shall be a positive value. It is converters configuration data used in power flow. ratedIdc {F988CC98-3A7A-401b-B41F-1A8A47BFFE99} Target firing angle. It is converters control variable used in power flow. It is only applicable for rectifier if continuous tap changer control is used. Allowed values are within the range minAlphalttargetAlphaltmaxAlpha. The attribute shall be a positive value. targetAlpha {C7DDA4DF-A9D8-4ed1-888D-EE60728AD998} Target extinction angle. It is converters control variable used in power flow. It is only applicable for inverter if continuous tap changer control is used. Allowed values are within the range minGammalttargetGammaltmaxGamma. The attribute shall be a positive value. targetGamma {7EE02461-D04E-4c41-93DC-0D92F02D10EF} DC current target value. It is converters control variable used in power flow. The attribute shall be a positive value. targetIdc {994D8715-A3DE-4d81-A09A-F3B95325691F} InternalControlArea {BEFB4486-B77B-4cd6-A9AD-9D7F2906C32F}.SupplierEnd multiplier {86741909-5F72-4d38-8B1F-69C7C7308BE8} unit {58C58CD1-5C85-4073-ACF8-9D9F1331364E} The normal value for limit on current flow. The attribute shall be a positive value or zero. normalValue {29A541C2-CB70-432e-98FE-A50695CB2033} Limit on current flow. The attribute shall be a positive value or zero. value {22BAF153-4E49-4e43-9C3D-69D542FF6E89} Current limit number one 1 for inverse time pickup. currentLimit1 {B5A966CE-FCE6-48de-A584-63AAE323DD91} Current limit number 2 for inverse time pickup. currentLimit2 {F4B8CF9B-D578-4b92-8D43-44FC0962BDAA} Current limit number 3 for inverse time pickup. currentLimit3 {BC7E3234-BD9B-4f81-904E-3976DCB72F4D} Inverse time delay number 1 for current limit number 1. timeDelay1 {0D844B6D-81B4-4ad0-B752-47B94E9057AF} Inverse time delay number 2 for current limit number 2. timeDelay2 {DD8BCFB0-F0D9-482e-B5E3-8B4AF3BF5DD2} Inverse time delay number 3 for current limit number 3. timeDelay3 {06BCCEF9-EB0D-4f1c-887B-85AA267314A2} InternalControlArea {25FE6285-FBFC-4387-9CFA-5A909EABEF8D}.SupplierEnd NetworkModelProjectComponent2 {955D5BF8-C371-455c-9915-2EDD3CA75C50}.ClientEnd Percent of rated current for which the CT remains accurate within specified limits. accuracyLimit {A48B5A36-5966-4d5b-ACA8-C62A0DEA5B16} Power burden of the CT core. coreBurden {B15D192E-418B-49ff-B092-C2079C5B0101} Accuracy limit. accuracyLimit {70CE0EFC-E64D-4f4d-BF47-4D2D4DF02706} Maximum primary current where the CT still displays linear characteristicts. kneePointCurrent {C12DD083-946E-443f-88F2-7CA158081D4C} Maximum voltage across the secondary terminals where the CT still displays linear characteristicts. kneePointVoltage {9747ECD5-584E-4929-9755-E8B68A506B51} Maximum ratio between the primary and secondary current. maxRatio {9B3D2F96-C728-482a-B71B-BF73C441E450} Nominal ratio between the primary and secondary current i.e. 1005. nominalRatio {2FC73107-AD91-4352-B046-9A267227228D} Full load secondary FLS rating for primary winding. primaryFlsRating {31268FB9-255D-4dcc-A13E-E86A7873B171} Ratio for the primary winding tap changer. primaryRatio {4FC8F4FB-6FF3-4d94-9153-183ABEB5A97C} Rated current on the primary side. ratedCurrent {1FA61311-E265-4ea0-AE6C-88067C0F6947} Full load secondary FLS rating for secondary winding. secondaryFlsRating {2319B496-2A19-43cd-B842-8DE58971D34A} Ratio for the secondary winding tap changer. secondaryRatio {C17E99E7-988F-446f-84AB-8D8C69656B2C} Full load secondary FLS rating for tertiary winding. tertiaryFlsRating {A8B48EF1-9741-4532-8232-C2CF385CEC80} Ratio for the tertiary winding tap changer. tertiaryRatio {02842A65-0424-4997-9D90-27727F9A2FFC} An EnergyTransaction may be curtailed by any of the participating entities. EnergyTransaction {64C49984-0ED1-438b-9C5C-CE6E9784CFF1}.SupplierEnd The point data values that define this curve. CurveDatas {21D1EA17-DE1A-4a12-BCB8-293A9781EFC4}.ClientEnd The style or shape of the curve. curveStyle {34413CFC-AEF0-475f-BF0A-29A7A851625C} Multiplier for Xaxis. xMultiplier {12D6268F-205E-4580-B694-E0947E6C8EA5} The Xaxis units of measure. xUnit {A977BAEA-28F3-4642-9A6B-1C4181E494B7} Multiplier for Y1axis. y1Multiplier {3CAA546E-E6BD-4dec-830F-24D3F61F0791} The Y1axis units of measure. y1Unit {3D2E7681-5029-4fd3-AD9B-DD04C563A315} Multiplier for Y2axis. y2Multiplier {7C8CB635-5F61-43f2-9D80-B8C8A3D2A273} The Y2axis units of measure. y2Unit {C017B50F-488D-48e5-9511-6968A85AF219} Multiplier for Y3axis. y3Multiplier {AD5383B4-6D5A-4317-89E4-2D5982488252} The Y3axis units of measure. y3Unit {4194FDA4-3971-48c5-9B3F-BAE5112BF33B} The curve of this curve data point. Curve {21D1EA17-DE1A-4a12-BCB8-293A9781EFC4}.SupplierEnd Customer {B478C760-01BA-48e3-9819-23C45144AA2E}.ClientEnd {B478C760-01BA-48e3-9819-23C45144AA2E}.SupplierEnd All accounts of this customer. CustomerAccounts {793C2F8E-D6A8-4991-80CA-22D47E9F6FA8}.SupplierEnd All agreements of this customer. CustomerAgreements {12619422-3644-40fc-AA40-CC129C2C199A}.SupplierEnd All notifications required by this customer. CustomerNotifications {9979122D-C134-46ef-ACBB-9812051756B2}.ClientEnd All end devices of this customer. EndDevices {CAC11EF6-DAA4-4489-BC90-BFEC70C14E61}.SupplierEnd ErpPersons {08C6C8AA-21F3-4f0e-91C1-B7765CD6D7FA}.SupplierEnd The outage plan that identifies the customers that are affected. OutagePlan {2B68C98E-D3F5-4de1-9693-2F2E3F99F1BC}.SupplierEnd PlannedOutageNotification {C3BE4896-4663-4669-84A9-B881796117E5}.ClientEnd All trouble tickets for this customer. TroubleTickets {DB18A09B-52CE-46d9-98B1-DA9F32529CC5}.ClientEnd All the works performed for this customer. Works {07E56F99-F27D-4363-90E9-D912F7C8DEC7}.SupplierEnd Kind of customer. kind {59942DEA-7ECE-45f3-8D06-B1BFA2460799} Priority of the customer. priority {943442D7-3358-4531-9E76-773D1165CDB1} Status of this customer. status {895DF1D3-73C0-4a14-9BEE-7044014F0D00} AccountNotification {FC0059FF-913A-472a-9717-BA43E0EC7EA1}.SupplierEnd Customer owning this account. Customer {793C2F8E-D6A8-4991-80CA-22D47E9F6FA8}.ClientEnd All agreements for this customer account. CustomerAgreements {200971C2-908E-46ed-BAA2-C95ECA8EC1A5}.SupplierEnd CustomerBillingInfos {118BDA78-3371-442b-B86A-BDFA164F9F37}.ClientEnd ErpInvoicees {F954FA38-DDCE-4eeb-8C01-FA8B0D72A603}.SupplierEnd All payment transactions for this customer account. PaymentTransactions {0B5E9E95-37C0-4b1a-8C38-C1995B9D1EC8}.SupplierEnd WorkBillingInfos {86A9BD70-A4A7-4530-B205-5F62F9C1C7DB}.SupplierEnd The last amount that will be billed to the customer prior to shut off of the account. lastBillAmount {3F686220-8A43-454d-B824-A399124EF9E0} All nonservice related auxiliary agreements that refer to this customer agreement. AuxiliaryAgreements {4B0AFE27-A288-4e9f-A8F4-CA0675EB971D}.SupplierEnd Customer for this agreement. Customer {12619422-3644-40fc-AA40-CC129C2C199A}.ClientEnd Customer account owning this agreement. CustomerAccount {200971C2-908E-46ed-BAA2-C95ECA8EC1A5}.ClientEnd All demand response programs the customer is enrolled in through this customer agreement. DemandResponsePrograms {C5454F40-D260-4575-8095-135824469D69}.ClientEnd could be deprecated in the future All meter readings for this customer agreement. MeterReadings {A14F100A-AE6C-49c4-AD0C-FC8D5004074A}.ClientEnd All pricing structures applicable to this customer agreement. PricingStructures {2EF6BAD9-95F9-48bf-9408-24054A043C0F}.SupplierEnd Service category for this agreement. ServiceCategory {1CD25DA9-4F95-43aa-A7CF-B41C352C30AA}.SupplierEnd All service locations regulated by this customer agreement. ServiceLocations {C20149AA-BEFF-43c5-B26A-F75F414F345B}.SupplierEnd Service supplier for this customer agreement. ServiceSupplier {47FE73EC-DD27-4731-8091-E3020EACA869}.ClientEnd StandardIndustryCode {6081B3B7-6BE2-4dff-BD8D-9BAF5855DE67}.SupplierEnd All service delivery points regulated by this customer agreement. UsagePoints {0FEA25EE-6DB0-45d0-99F9-D5895A91A455}.SupplierEnd CustomerAccount {118BDA78-3371-442b-B86A-BDFA164F9F37}.SupplierEnd ErpInvoiceLineItems {E8BD9E1E-C04F-4135-8CAA-39D78433DF77}.SupplierEnd Kind of bill customer receives. kind {4360F5EC-725D-4a31-B84B-35841E1477B7} Amount of the last payment received from the customer. It is retained in the Customer Billing system although the details of each payment are tracked in the ERP system. lastPaymentAmt {CCF88D83-996B-46ef-BA0C-B6B669B1F9E8} Outstanding balance on the CustomerAccount as of the statement date. outBalance {EFA8E507-5E0B-45a4-BE4F-7CE222722533} Monthly amortized amount due during each billing cycle for the CustomerAccount balance for which the Payment Plan is setup. pymtPlanAmt {59600E88-1E1B-4d3f-A4F0-CC5D7C03069D} A ControlAreaOperator or CustomerConsumer may ring their perimeter with metering which can create a unique SubControlArea at the collection of metering points called a TieLine. CustChildOf {BE10D423-5810-4e4c-A856-4B2A6F2C2D59}.SupplierEnd Customer requiring this notification. Customer {9979122D-C134-46ef-ACBB-9812051756B2}.SupplierEnd Incident as a subject of this customer notification. Incident {F292A647-3328-43e1-AA6F-08A42730AF41}.ClientEnd All trouble tickets with this notification. TroubleTickets {2E2B0349-61DB-4eeb-9A2F-465DC303A460}.SupplierEnd Trigger for this notification. trigger {040F4A28-FA7C-4127-A0F0-71E7C8D0B9A5} The line segment to which the cut is applied. ACLineSegment {62963E89-E891-4b03-8000-C14788BD8E57}.SupplierEnd Action taken with this cut. CutAction {8E5D12B6-674B-468d-A0AE-F4ACDB34EC17}.ClientEnd The length to the place where the cut is located starting from side one of the cut line segment i.e. the line segment Terminal with sequenceNumber equal to 1. lengthFromTerminal1 {93B76002-D48E-4065-9B8E-AA48F771EB48} Cut on which this action is taken. Cut {8E5D12B6-674B-468d-A0AE-F4ACDB34EC17}.SupplierEnd Switching action to perform. kind {8366996C-5983-4e04-8B43-87E7D73E49A5} The central pressure of the cyclone during the time interval. centralPressure {C0BAACEB-84BC-436d-88C3-624E6F28D878} The maximum surface wind speed of the cyclone during the time interval. maxSurfaceWindSpeed {C2239DA2-1CD2-4e55-937C-C21039DF94B9} The DC connectivity node to which this DC base terminal connects with zero impedance. DCNode {B31A4B2D-8B03-4d82-8839-92F521AB47E1}.ClientEnd See association end Terminal.TopologicalNode. DCTopologicalNode {B7808724-9A0B-430d-9271-410BC33226AB}.SupplierEnd A DC conducting equipment has DC terminals. DCTerminals {12776A02-A0D8-4518-8CE7-D41CD6A5EE8F}.SupplierEnd ProtectiveActionAdjustment {83F32DD1-007E-48c2-AD47-79FF388FCEDF}.ClientEnd Rated DC device voltage. The attribute shall be a positive value. It is configuration data used in power flow. ratedUdc {3DC64F40-8B27-46c7-8B18-4E165322F0B7} The operating mode of an HVDC bipole bipolar monopolar metallic return etc. operationMode {9774066F-3156-4132-BBB8-9EA03D8C73E4} The DC nodes contained in the DC equipment container. DCNodes {DD79D292-6A01-48eb-B78A-90F96CB960FC}.ClientEnd The topological nodes which belong to this connectivity node container. DCTopologicalNode {B4C9C4A3-7B73-42b4-866B-ABC9504B8B53}.SupplierEnd Inductance to ground. inductance {B1E83180-0ADD-4e36-A3B8-4374782D1553} Resistance to ground. r {27D61E96-12D6-4bd6-B6D6-179A54519C27} The SubGeographicalRegion containing the DC line. Region {87933AA2-5F6F-4768-BCDE-772A53C5248C}.SupplierEnd Set of perlength parameters for this line segment. PerLengthParameter {2DD2B43E-76CD-494b-A33F-018342B6A5C3}.ClientEnd Capacitance of the DC line segment. Significant for cables only. capacitance {F098A35D-75A4-48ec-8152-0A986069D191} Inductance of the DC line segment. Negligible compared with DCSeriesDevice used for smoothing. inductance {BB86CC21-0C27-4f86-A8BB-F72A9048AD67} Segment length for calculating line section capabilities. length {741D3874-1585-4232-A908-CD3483A68831} Resistance of the DC line segment. resistance {D60EBC0B-45F9-4862-BAB6-2CD98EA1F720} The DC container for the DC nodes. DCEquipmentContainer {DD79D292-6A01-48eb-B78A-90F96CB960FC}.SupplierEnd DC base terminals interconnected with zero impedance at a this DC connectivity node. DCTerminals {B31A4B2D-8B03-4d82-8839-92F521AB47E1}.SupplierEnd The DC topological node to which this DC connectivity node is assigned. May depend on the current state of switches in the network. DCTopologicalNode {5A20F31D-14D7-4c51-B74F-DDC1C56849F3}.SupplierEnd Inductance of the device. inductance {42517B02-5553-4694-B74C-5398419DA9A0} Resistance of the DC device. resistance {8C0DE916-4760-4bff-AE06-9D8E367B5AE0} Capacitance of the DC shunt. capacitance {63CFE75D-E6D2-49b0-855D-E852132DCB54} Resistance of the DC device. resistance {58BABAEC-212C-4629-880D-4A098B094402} An DC terminal belong to a DC conducting equipment. DCConductingEquipment {12776A02-A0D8-4518-8CE7-D41CD6A5EE8F}.ClientEnd The connectivity node container to which the topological node belongs. DCEquipmentContainer {B4C9C4A3-7B73-42b4-866B-ABC9504B8B53}.ClientEnd The DC connectivity nodes combined together to form this DC topological node. May depend on the current state of switches in the network. DCNodes {5A20F31D-14D7-4c51-B74F-DDC1C56849F3}.ClientEnd See association end TopologicalNode.Terminal. DCTerminals {B7808724-9A0B-430d-9271-410BC33226AB}.ClientEnd Delay {8B9A7786-D683-4dac-9D0C-983AB413A565}.ClientEnd VSCtype1 {86E86FC3-61BD-4a5f-A4F1-6BDFD8ADE591}.ClientEnd Integral gain of the DC voltage regulator Kivdc. kivdc {23B47403-8625-4597-AE2F-A552BEE21969} Proportional gain of the DC voltage regulator Kpvdc. kpvdc {83302C91-E18C-45a5-835E-70A0CE8E3B07} Maximum DC voltage Vdcmax. vdcmax {20287260-E42A-4c17-A8D0-134C089205D6} Minimum DC voltage Vdcmin. vdcmin {509AD866-3153-40e6-91FF-5A0BA8EFD7B1} DERMonitorableParameter {101FBB2C-C8C9-46ef-9BE3-3EEABF000AEE}.SupplierEnd DispatchSchedule {3FA9A03E-1846-4bc5-A641-F8A630355CC2}.SupplierEnd EndDeviceGroup {AAA6DC66-3D4C-449d-8DAC-947317B28177}.SupplierEnd From the metering package this is a grouping mechanism that allows actions to be performed upon multiple EndDevices with a single command EndDeviceGroup {4611E517-A1DA-440c-BD29-668CF1F495E2}.ClientEnd From the metering package this is a grouping mechanism that allows actions to be performed upon multiple EndDevices with a single command EndDeviceGroup {F0840A17-1419-47f0-BF59-87D100492401}.SupplierEnd DERCurveData {101FBB2C-C8C9-46ef-9BE3-3EEABF000AEE}.ClientEnd DERParameter {DA256577-6C27-43ab-9A61-3AC4E0530913} DispatchSchedule {EF7AB537-05B9-4c9e-BAFA-5C4082E903B4}.ClientEnd EndDeviceGroup {56EE9BE9-6817-4022-967A-0AA909D120DE}.ClientEnd flowDirection {EA88826F-8EAD-4952-BC21-D29A1608F891} yMultiplier {422B07AD-2E28-4892-884F-66E0450D8DFE} yUnit {5426775D-93E1-4ab5-856E-A8E294E0FA42} Edition of DIN standard. standardEdition {B5112550-F76B-43b2-87A6-61C2FC48A8C5} DIN standard number. standardNumber {03FBE6F3-BCA6-4451-BDB6-5FD9511C24AF} multiplier {A51E3352-5194-435d-B70E-FCDB750E37D6} unit {C38A362A-6559-47ab-8747-99A10D4B404F} The alternate model using the data. AlternateModel {CF5D1E33-0F2F-40d6-B260-30258F4FBA0D}.ClientEnd ModelPartVersion {2494ED30-254C-4f13-8F87-6FBEE03C2A4F}.ClientEnd The profiles that describe the contents of the data set and the rules governing the contents of the data set. Profile {A554D44F-37A9-44b7-878F-CDC356BA0B3A}.SupplierEnd Dataset referenced by this argument of a model operation.. Dataset {5B31BEB7-2629-4c5a-B015-4D2B871D04D9}.SupplierEnd The type of role for this dataset role. Should only reference role types that belong to the operation type of the associated operation. OperationDatasetArgDescription {235FF3E6-E90D-4131-B4D7-7709E41BBA9D}.SupplierEnd The operation dataset roles conforming to this role type. OperationDatasetArg {235FF3E6-E90D-4131-B4D7-7709E41BBA9D}.ClientEnd MarketDocument {F49F44BE-047D-4792-8B5B-A3AA670AA0A1}.SupplierEnd TimeSeries {492E4897-E2BA-43e1-ABB0-94017A298B9D}.ClientEnd Schedules that use this DayType. SeasonDayTypeSchedules {9B2613ED-CF92-429b-B26F-0EB80C658169}.SupplierEnd Currency of this quantity. currency {B5002FB6-77FB-4f79-AF52-8498BED27EFB} Unit multiplier of this quantity. multiplier {EE76FF5C-81AF-4694-80E3-5FCA5BB2FE75} Unit of this quantity. unit {C93A29DD-02C6-49fd-90CF-3F0E40EAAEB1} DefaultBidCurve {310A11B7-605C-46ea-BD24-2F81FE8AE402}.SupplierEnd RegisteredResource {F24F3D0F-AE1B-4418-B515-B72D77505E5F}.SupplierEnd Default bid type such as Default Energy Bid Default Minimum Load Bid and Default Startup Bid bidType {5E7AEF07-C92E-43d6-9ABF-72137169F171} Minimum load cost in hr minLoadCost {FCED7648-1A1F-4a02-9ED5-04260C8348B8} onpeak offpeak or all peakFlag {2052DBBD-E4CC-4e04-97A7-F02329FB5B0F} DefaultBid {310A11B7-605C-46ea-BD24-2F81FE8AE402}.ClientEnd Default energy bid adder flag debAdderFlag {9EDCAA98-3D30-4975-B6AF-7FB6187048DF} Type of calculation basis used to define the default bid segment curve. bidSegmentCalcType {5250E18B-4E0C-445a-B3E5-E037B8196B7B} SecurityConstraintSum {59C7A4B0-0AB0-47cf-B08A-D99F0E01C0D2}.SupplierEnd BlockingFunction {5B3BF302-273E-40f1-A888-A5FFEDE8F08F}.SupplierEnd CCAinverter {CBF65696-C189-4ab1-A0C3-34B7539B34A1}.SupplierEnd CCArectifierControl {AF4309DA-72A5-4b21-80EC-9653AF6D0620}.SupplierEnd DCvoltageControl {8B9A7786-D683-4dac-9D0C-983AB413A565}.SupplierEnd IdcInverterControl {F80046F2-833E-473c-81F7-F2217DD56589}.SupplierEnd PFmode {0A11698D-6954-4f58-B75E-3CBA73047718}.SupplierEnd Pcontrol {BB5EF20F-F668-4cd3-A8C9-5EAA0AD5F5CF}.SupplierEnd Qlimiter {784225EE-19A9-4cf5-9299-DAD1950C5181}.SupplierEnd Qmode {2303C7D4-EE85-47ba-A595-6180D607EEBD}.SupplierEnd Qregulator {B244C310-A752-4f97-8CF9-0D6D0C1AB836}.SupplierEnd Umode {84D84ECC-705D-4a61-8B63-60A505B5791B}.SupplierEnd VDCOL {DA56FBC7-3797-4264-AE29-61FEBA3C58F7}.SupplierEnd Time constant. tm {046E0C92-C223-47e6-83D3-E54551B2504C} All customer agreements through which the customer is enrolled in this demand response program. CustomerAgreements {C5454F40-D260-4575-8095-135824469D69}.SupplierEnd All groups of end devices enrolled in this demand response program. EndDeviceGroups {2533FBD9-FD86-4734-8759-F972A0C201D4}.SupplierEnd All usage point groups enrolled in this demand response program. UsagePointGroups {36AB849B-4EDC-45e7-98B2-FCA2BC154E2B}.SupplierEnd Interval within which the program is valid. validityInterval {CDF96F9D-AB07-4564-B27E-B2EDAD457112} ConditionFactors {B55CE47A-87D3-4069-AE0A-CD19D6B6247B}.SupplierEnd DesignLocations {8A82D1F1-DAB4-4972-8F4B-4009DDB5610B}.ClientEnd DesignLocationsCUs {49C94F22-F928-4d51-B2E1-CB0EDE52918C}.ClientEnd ErpBOMs {385BF030-903C-4fb9-9B45-AE7199B9E2C6}.SupplierEnd ErpQuoteLineItem {F494C91F-54E1-42e7-88D5-BEAED03ACDBB}.ClientEnd Work {B42E2297-AE8B-42e0-A3FF-529C6B2C87D8}.SupplierEnd WorkCostDetails {80D53051-C6F7-4c80-B186-FF6AFCC33A66}.SupplierEnd WorkTasks {83CD7FF8-6559-45a7-AB79-BA79FC3B1C82}.SupplierEnd Estimated cost not price of design. costEstimate {AFE4F920-721B-4e16-913B-FF7548C42ECF} Kind of this design. kind {FE9AA4C0-2353-4590-96BB-0766CB6691D1} Price to customer for implementing design. price {1A85DFF8-DE4A-4eac-9FF6-73FE8C10902B} ConditionFactors {01106373-66A2-47e6-BE11-C6EB50A8EA95}.SupplierEnd DesignLocationCUs {95DC38C2-5D26-4c4a-8D5D-D38F24B0646F}.SupplierEnd Designs {8A82D1F1-DAB4-4972-8F4B-4009DDB5610B}.SupplierEnd ErpBomItemDatas {4962575B-8FF3-4dfb-8A66-0E1F572C4D90}.ClientEnd MiscCostItems {ECAD85F3-E7E4-48d0-B3DF-81B8B5795C03}.SupplierEnd WorkLocations {A50D6CAA-AFDC-4c79-A4FF-B15AE7381D4F}.SupplierEnd The legth of the span from the previous pole to this pole. spanLength {1A3D5C61-B5B2-4913-A207-14016F7AF0DB} status {C604F7EE-496E-4aae-A5DC-01CFB6F8B7C3} CUGroups {324E1A81-07DF-4842-8F2C-ED32F058D0AD}.SupplierEnd CompatibleUnits {B11E2CCC-4BD2-4bb3-AC4A-FC61ADF42FD2}.ClientEnd ConditionFactors {A2A64DC1-F71D-4a0f-9604-744445395515}.SupplierEnd DesignLocation {95DC38C2-5D26-4c4a-8D5D-D38F24B0646F}.ClientEnd Designs {49C94F22-F928-4d51-B2E1-CB0EDE52918C}.SupplierEnd WorkTasks {FCF781BC-040D-407f-A030-D5BB3656B390}.SupplierEnd A code that instructs the crew what action to perform. cuAction {CBE9C761-A1AF-48a9-BB99-1C592FC57F82} The quantity of the CU being assigned to this location. cuQuantity {B27707D1-10B7-457c-A090-4DF5771F82CC} status {FF5E175C-2EBB-4f0c-865A-C052F3A0C7CC} Phases diagnosed. phaseCode {937BAB01-A522-47f4-B440-699DD97A335D} A diagram is made up of multiple diagram objects. DiagramElements {5C4A600A-6EA7-4ac1-A144-9E7C309F375B}.ClientEnd A Diagram may have a DiagramStyle. DiagramStyle {442E3273-18B9-4a81-A9E5-42B612D453BC}.ClientEnd Coordinate system orientation of the diagram. A positive orientation gives standard righthand orientation with negative orientation indicating a lefthand orientation. For 2D diagrams a positive orientation will result in X values increasing from left to right and Y values increasing from bottom to top. A negative orientation gives the lefthand orientation favoured by computer graphics displays with X values increasing from left to right and Y values increasing from top to bottom. orientation {E434F373-9059-4d4e-8D77-8532E6D6E20A} A diagram object is part of a diagram. Diagram {5C4A600A-6EA7-4ac1-A144-9E7C309F375B}.SupplierEnd A diagram object can have 0 or more points to reflect its layout position routing for polylines or boundary for polygons. DiagramObjectPoints {4DFBB74F-9127-43ee-A7AA-04329802814F}.SupplierEnd A diagram object has a style associated that provides a reference for the style used in the originating system. DiagramObjectStyle {2D17C38C-27D8-402d-9B7B-687AC6753212}.SupplierEnd The domain object to which this diagram object is associated. IdentifiedObject {03423B70-34E0-4313-B19B-5FAFFD1F143B}.ClientEnd A diagram object can be part of multiple visibility layers. VisibilityLayers {86380B03-52EA-473d-9BFA-DCDAAE9D1275}.SupplierEnd Sets the angle of rotation of the diagram object. Zero degrees is pointing to the top of the diagram. Rotation is clockwise. DiagramObject.rotation0 has the following meaning The connection point of an element which has one terminal is pointing to the top side of the diagram. The connection point From side of an element which has more than one terminal is pointing to the top side of the diagram.DiagramObject.rotation90 has the following meaning The connection point of an element which has one terminal is pointing to the right hand side of the diagram. The connection point From side of an element which has more than one terminal is pointing to the right hand side of the diagram. rotation {57D901DD-45DA-42f6-8A86-9C0EDBB27214} A diagram object glue point is associated with 2 or more object points that are considered to be glued together. DiagramObjectPoints {1C8A6E42-935B-4a26-88C0-9F9E2AB80D36}.ClientEnd The diagram object with which the points are associated. DiagramObject {4DFBB74F-9127-43ee-A7AA-04329802814F}.ClientEnd The glue point to which this point is associated. DiagramObjectGluePoint {1C8A6E42-935B-4a26-88C0-9F9E2AB80D36}.SupplierEnd A style can be assigned to multiple diagram objects. StyledObjects {2D17C38C-27D8-402d-9B7B-687AC6753212}.ClientEnd A DiagramStyle can be used by many Diagrams. Diagram {442E3273-18B9-4a81-A9E5-42B612D453BC}.SupplierEnd Specifications {5070DD0D-A85D-4e3a-8E88-6373ED2A15DE}.SupplierEnd Depth measurement. sizeDepth {8CA22E0C-AE30-4e4b-A78F-CC7B0DEA1E13} Diameter measurement. sizeDiameter {77974126-F80A-4c77-A2BC-48E0FAD3DF66} Length measurement. sizeLength {9F24975A-B14C-464a-8A28-F46A5E7C8639} Width measurement. sizeWidth {1BECEC72-9FD0-479a-8909-0DA023E7C4CB} Speed change reference iEiisubSCsubi. Typical value 00015. esc {172C9946-71BF-4ce9-827C-06C056BD6AD5} Discontinuous controller gain iKiisubANsubi. Typical value 400. kan {88CC3392-903C-43de-A1EE-BE2D080B870A} Terminal voltage limiter gain iKiisubETLsubi. Typical value 47. ketl {83F2BC2C-2EC5-428c-98C0-FC6222093505} Discontinuous controller time constant iTiisubANsubi gt 0. Typical value 008. tan {7227B496-A2E3-4045-85FE-A26F3D5C9C5E} Time constant iTiisubDsubi gt 0. Typical value 003. td {970BD9AF-B8EA-4e22-BA31-C7078F7F3133} Time constant iTiisubLsubisub1sub gt 0. Typical value 0025. tl1 {F4408EC1-D7EE-4f4b-973E-B4070BA55DA0} Time constant iTiisubLsubisub2sub gt 0. Typical value 125. tl2 {506691B3-18F2-4c8e-92A9-0C3154858E2B} DEC washout time constant iTiisubWsubisub5sub gt 0. Typical value 5. tw5 {1B492332-80E5-422c-A56D-54FFD9FAB3CF} Regulator voltage reference iViisubALsubi. Typical value 55. val {EC9A7984-C6A5-4319-AD4D-D46AC9790C97} Limiter for Van iViisubANMAXsubi. vanmax {CE193B01-E2AE-45c6-98CD-C890EE03B4C1} Limiter iViisubOMAXsubi gt DiscExcContIEEEDEC1A.vomin. Typical value 03. vomax {EECCE353-99A8-4bfc-A7D1-AECB07E9EAD0} Limiter iViisubOMINsubi lt DiscExcContIEEEDEC1A.vomax. Typical value 01. vomin {810E9315-9BA9-4a34-B7BC-3631ECE82DE5} Limiter iViisubSMAXsubigt DiscExcContIEEEDEC1A.vsmin. Typical value 02. vsmax {2FD546AC-AFF6-4fcf-823B-0C142FD5FBA1} Limiter iViisubSMINsubi lt DiscExcContIEEEDEC1A.vsmax. Typical value 0066. vsmin {9C0ACCC9-B247-401e-B997-D81A9A60BE64} Terminal voltage level reference iViisubTCsubi. Typical value 095. vtc {B3DE8330-7230-49c7-83C8-2551D44B2303} Voltage reference iViisubTLMTsubi. Typical value 11. vtlmt {A202F3AA-46AC-4521-9CE3-0CA09A4C6DA5} Voltage limits iViisubTMsubi. Typical value 113. vtm {DD958E61-3B62-40e8-A4F6-6D0D505AB8D1} Voltage limits iViisubTNsubi. Typical value 112. vtn {ACE1B286-58AE-4e24-BAD1-16E644F811CC} Discontinuous controller time constant iTiisubD1subi gt 0. td1 {E20100A4-74B6-4ec3-9A0E-7813996D9C38} Discontinuous controller washout time constant iTiisubD2subi gt 0. td2 {8D004634-40A6-4121-A3BA-BC846E2E4DED} Limiter iViisubDMAXsubi gt DiscExcContIEEEDEC2A.vdmin. vdmax {57AB7FA7-2F12-41ee-83B3-197DFFA2DCB5} Limiter iViisubDMINsubi lt DiscExcContIEEEDEC2A.vdmax. vdmin {A7F4989B-D46C-4d29-BCA0-F3B227599743} Discontinuous controller input reference iViisubKsubi. vk {28170B37-E740-436e-80D2-7A4ED20E26D9} Reset time delay iTiisubDRsubi gt 0. tdr {4077841F-B769-4643-BA0D-C0BB0509F5F1} Terminal undervoltage comparison level iViisubTMINsubi. vtmin {689FCDEC-CF19-43df-ADCC-4C388B8D9571} Excitation system model with which this discontinuous excitation control model is associated. ExcitationSystemDynamics {A3CB1790-95C9-404f-AA0A-91B8334A0AD4}.SupplierEnd Remote input signal used by this discontinuous excitation control system model. RemoteInputSignal {912E18D5-6BA7-4363-935C-5AAF4DB0471F}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {2215F246-53D4-4620-8772-22C2E52230A8}.ClientEnd The values connected to this measurement. DiscreteValues {41BE70FA-EA78-443a-B335-3469A779A71B}.SupplierEnd The ValueAliasSet used for translation of a MeasurementValue.value to a name. ValueAliasSet {27083F43-08EC-487a-A912-C969A351E021}.ClientEnd The Control variable associated with the MeasurementValue. Command {DF0C3745-2D94-4daa-8AA0-20AE415D601B}.SupplierEnd Measurement to which this value is connected. Discrete {41BE70FA-EA78-443a-B335-3469A779A71B}.ClientEnd RegisteredResource {E391D3A8-763C-4236-AF13-BC42EC2166B1}.ClientEnd The accepted mw amount by the responder. aka response mw. acceptMW {3216C94B-7EE7-4e42-A9EE-C18A0CA630DB} The accept status submitted by the responder. enumeration type needs to be defined acceptStatus {967EE71B-9B30-4bdf-903F-9EB7F81C2393} MW amount associated with instruction. For 5 minute binding dispatches this is the Goto MW or DOT clearedMW {7FF96547-69BC-4168-8928-DB954D863201} The type of run for the market clearing. passIndicator {EC31AE13-EC8F-40be-9F3D-6A6DCDCC3217} DERCurveData {3FA9A03E-1846-4bc5-A641-F8A630355CC2}.ClientEnd DERMonitorableParameter {EF7AB537-05B9-4c9e-BAFA-5C4082E903B4}.SupplierEnd confidence {2B8421FD-D0D9-4d20-AA11-2760FB9F126F} Used to specify whether the values over an interval are constant constantYValue or linearly interpolated straightLineYValues curveStyleKind {643CD3F7-65EB-4070-8242-B44BF0061219} The unit of measure for the time axis of the dispatch schedule. timeIntervalUnit {B00E0FE8-D5BC-4ebf-BF39-9EACD6568503} The generic class to support all field end devices such as meters or smart inverters EndDevice {2FF7FB6F-CDF4-4bd3-A5ED-857FF363E2B0}.ClientEnd EndDeviceGroup is used in metering to group end devices this same class is used to group DER EndDeviceGroup {EE555BAA-0173-4a8c-ACAF-EB8D9421DF51}.ClientEnd The current level of active power for a DER group currentActivePower {90D71C31-4AD1-4d8e-B733-122B6FEAC8BF} The current level of apparent power for a DER group currentApparentPower {87595782-F158-4046-9575-2070F7060333} The current level of reactive power for a DER group currentReactivePower {4279B3B8-5ECE-4255-A60B-0E237E624B6D} The maximum level of active power to which a DER group can be set maxActivePower {C07156AE-21BC-42f1-8C27-5B599FDCA0A6} The maximum level of apparent power to which a DER group can be set maxApparentPower {94265724-8C55-419b-B959-97A6393A6B05} The maximum level of reactive power to which a DER group can be set maxReactivePower {4CCC87E4-9FE9-45cc-8F4F-6D6D5EF4E47C} The minimum level of active power to which a DER group can be set minActivePower {7F04A927-F0CB-4631-906A-8D91E64EB691} The minimum level of apparent power to which a DER group can be set minApparentPower {9C6402A0-FCD1-46fa-9CF0-9F5AE893B5D9} The minimum level of reactive power to which a DER group can be set minReactivePower {1F575DA3-88DC-493c-AC9B-A1DD4D766484} multiplier {7F29E08D-5FC0-46b1-93BB-874F7BB2F23A} unit {A747743C-3DB2-4e12-984B-0857DF0555A8} ActualDemandResponseEvents may exist that are not part of a coordinated MarketActualEvent associated to a Market. These ActualDemandResponseEvents can have many InstructionClearing Instructions for specified RegisteredResources or DemandResponse AggregateNodes. InstructionClearing {7B14AF42-A7C8-4839-AEBA-18F104ABE94C}.SupplierEnd InstructionClearingDOT {01022165-D079-41fa-B9C3-342CFFA5E537}.SupplierEnd ResourcePerformanceEvaluations {568AA2F2-D906-4139-AA0D-393E92602084}.SupplierEnd Total active power adjustment e.g. load reduction requested for this demand response event. totalPowerAdjustment {0A67C2F5-36BF-43f3-9C8D-06A954CD73C3} GenDistributionFactor {A0057A86-6FBB-46b3-A9AE-B72D9CDACC6F}.SupplierEnd LoadDistributionFactor {49BDACA6-0568-4346-BD7A-07BB3DE08C0C}.SupplierEnd SysLoadDistribuFactor {5262F3D5-E6F1-466a-998C-AE0F2E35DBDF}.SupplierEnd Market type. marketType {A61C37F5-C559-4b7c-8809-58FF3C271C76} Edition of Doble standard. standardEdition {ECE4670E-DE75-4f2b-8352-31666F287CD6} Doble standard number. standardNumber {ABD1A107-EF81-4d64-A8A6-54AF3A42CB3F} Approver of this document. Approver {E773805D-E6AC-4d17-9B2A-5E6338923314}.ClientEnd Author of this document. Author {335F0BDA-9420-40ee-B636-5FAD6485F1BB}.ClientEnd All configuration events created for this document. ConfigurationEvents {E33CE794-1D36-4889-BDFB-F26AF8508188}.SupplierEnd Editor of this document. Editor {9F6834C3-98EF-4108-BAB4-479EA61806B9}.ClientEnd Issuer of this document. Issuer {D3F6B3FF-697C-4b9b-845F-66D92692128D}.ClientEnd Status of this document. For status of subject matter this document represents e.g. Agreement Work use status attribute.Example values for docStatus.status are draft approved cancelled etc. docStatus {1898F2ED-210C-46df-AAB7-8A37EE47FB1C} Electronic address. electronicAddress {CD388106-E7BD-4660-9E52-2BDD15EA7E07} Status of subject matter e.g. Agreement Work this document represents. For status of the document itself use docStatus attribute. status {6F277455-3C17-4593-9FB7-F7059BD2EAB6} MarketDocument {65A175B6-9924-45f6-8876-8254B2486786}.ClientEnd Price {58FBC0F0-40DD-4dbd-A8BE-9C241403F4DB}.ClientEnd Quantity {3C6AC9D3-B254-422b-83E0-AD878F50E02C}.ClientEnd RegisteredResource {2883C3D9-C348-4a3e-A321-5E35C932E66E}.SupplierEnd TimeSeries {35183B72-4EB4-4c7d-BDCB-158AC35D6ACC}.ClientEnd InstructionClearingDOP {21EAE1E5-554D-4e8e-BE91-8FB6E528D842}.ClientEnd RegisteredResouce {0A0711E7-CD6A-49ca-AFBB-0BB1AE61425F}.ClientEnd Dispatched Operating Point MW mwDOP {10EE6A86-5A50-4b91-91AD-C287F12EEC14} Indication of DOP validity. Shows the DOP is calculated from the latest run YES. A NO indicator shows that the DOP is copied from a previous execution.Up to 2 intervals can be missed. runIndicatorDOP {0BF77B7A-C011-47d0-8F36-EB1FC2218A10} updateType {3A01D202-092F-48c4-A98E-CE9001DD10B4} InstructionClearingDOT {CEC60D6E-B919-43a0-9B3B-92AE42278138}.ClientEnd RegisteredResource {090DD6C1-3007-4b20-A995-9A43659E6687}.SupplierEnd Flag indicating whether or not the resource was in compliance with the instruction plusminus 10.Directs if a unit is allowed to set the price expost pricing. compliantIndicator {5C2DDA7A-E4FE-4fb1-AE1C-58F1B89F8027} Regulation Status YesNo. regulationStatus {5857EC73-37BB-4e8f-BFAC-79D78E2B1A97} WireSpacingInfos {18C29DE2-77AC-4a90-9E3D-065A8BC002CE}.ClientEnd Part of current that constitutes the arrears portion. arrears {0910CAA8-10E1-4c33-B334-41D83198EC03} Part of current that constitutes the charge portion charges Charge.fixedPortion Charge.variablePortion. charges {5CE62A2B-0CD9-43ed-95A6-51E11BF0ABFF} Current total amount now due current principle arrears interest charges. Typically the rule for settlement priority is interest dues then arrears dues then current dues then charge dues. current {D16FCD2A-FB4F-4b0b-9A6F-BC591ABE0C6C} Part of current that constitutes the interest portion. interest {76933F35-C90B-44ad-84D5-7ABEB79796A0} Part of current that constitutes the portion of the principle amount currently due. principle {E4EBB98D-4B22-46ba-9415-B8DBF47C1D07} MktMeasurement {10B4C6E2-CE00-43d6-91C5-CA7BF16D48A2}.SupplierEnd A control area can receive dynamic schedules from other control areas Receive_SubControlArea {83DC5357-DC69-4c13-B260-5026E5DFD942}.SupplierEnd A control area can send dynamic schedules to other control areas Send_SubControlArea {CB9AAC47-376D-4a7e-9E56-D14A4F86E63E}.SupplierEnd Edition of EPA standard. standardEdition {C09A42E0-AD45-42c7-9898-09A86B390774} EPA standard number. standardNumber {D44EBFAB-2963-4cf3-A66D-EEC8D0FD66CD} Nominal resistance of device. r {6063FBE9-5BE7-424a-AC8F-116EF8F9A799} The depth below the earths surface of the earthquakes focal point. focalDepth {223FD0E0-7F8D-4779-A758-05F04C5101B9} All documents for this editor. Documents {9F6834C3-98EF-4108-BAB4-479EA61806B9}.SupplierEnd multiplier {10B02EE7-C719-4b76-AF42-2DB6CDACF235} unit {7F887802-EF0E-4dc3-9D85-EED40B85E697} A thermal generating unit may have one or more emission allowance accounts. ThermalGeneratingUnit {0EFC6C1E-3654-4ea3-8239-30E44E8AE7C6}.SupplierEnd The type of emission for example sulfur dioxide SO2. The y1AxisUnits of the curve contains the unit of measure e.g. kg and the emissionType is the type of emission e.g. sulfur dioxide. emissionType {8E04793A-9D24-4870-AD87-04672F8E25D4} The source of the emission value. emissionValueSource {16976F7B-25CE-4278-B31F-FB77890C44B1} A thermal generating unit may have one or more emission curves. ThermalGeneratingUnit {754BD49F-EE90-408a-AEBF-B56AA6C8DA69}.SupplierEnd The emission content per quantity of fuel burned. emissionContent {2D3A1FFE-0A0D-4611-AB59-A8FFA7C779BD} The type of emission which also gives the production rate measurement unit. The y1AxisUnits of the curve contains the unit of measure e.g. kg and the emissionType is the type of emission e.g. sulfur dioxide. emissionType {BD126748-C143-460f-B135-9839304819C6} Customer owning this end device. Customer {CAC11EF6-DAA4-4489-BC90-BFEC70C14E61}.ClientEnd DispatchablePowerCapability {2FF7FB6F-CDF4-4bd3-A5ED-857FF363E2B0}.SupplierEnd All end device controls sending commands to this end device. EndDeviceControls {5BFE769E-C4DE-4ab2-9C07-508135C7CD60}.ClientEnd All events reported by this end device. EndDeviceEvents {180BCB9D-1019-4de2-A8A5-3E3FFC3F9022}.ClientEnd All end device functions this end device performs. EndDeviceFunctions {2D6571AD-1092-4ed8-985C-487191687354}.SupplierEnd All end device groups referring to this end device. EndDeviceGroups {ECC0A3D0-FE2F-4df0-B5E6-AB34DDF3162B}.ClientEnd End device data. EndDeviceInfo {2131605C-1AA8-4b31-8DC3-70BFAB2B02BE}.SupplierEnd Service location whose service delivery is measured by this end device. ServiceLocation {E1374558-A400-46da-9FB2-5F7497097A3D}.ClientEnd Usage point to which this end device belongs. UsagePoint {6B05F0D3-B04B-4b78-AF42-4AC3046EF869}.ClientEnd Time zone offset relative to GMT for the location of this end device. timeZoneOffset {7C36F17C-4DDF-4f83-A483-664F1357B439} End device control issuing this end device action. EndDeviceControl {0BF8F40B-72F8-4982-ACED-E7FDF669BA66}.ClientEnd Amount of time the action of this control is to remain active. duration {67B2260C-8823-4042-A63F-C5DDC04678C2} End device action issued by this end device control. EndDeviceAction {0BF8F40B-72F8-4982-ACED-E7FDF669BA66}.SupplierEnd Type of this end device control. EndDeviceControlType {FC153ACC-DBB0-4502-A82D-045850FF2C2F}.SupplierEnd All end device groups receiving commands from this end device control. EndDeviceGroups {47178028-E658-4042-AB65-A6F4DDD8ABF6}.ClientEnd All end devices receiving commands from this end device control. EndDevices {5BFE769E-C4DE-4ab2-9C07-508135C7CD60}.SupplierEnd All usage point groups receiving commands from this end device control. UsagePointGroups {DD9C2BA9-EDBB-4e7b-852C-9AD603C00339}.SupplierEnd All usage points receiving commands from this end device control. UsagePoints {86BE91D2-4532-408d-85BE-C4192311A77E}.SupplierEnd if applicable Price signal used as parameter for this end device control. priceSignal {B374E41E-03C8-4bf8-B26E-23AD77EAC544} Timing for the control actions performed on the device identified in the end device control. primaryDeviceTiming {1E749747-5E54-49cf-AEF9-F9DE873855A6} if control has scheduled duration Date and time interval the control has been scheduled to execute within. scheduledInterval {96304D21-4C37-4450-A079-7EF1740F370E} Timing for the control actions performed by devices that are responding to event related information sent to the primary device indicated in the end device control. For example load control actions performed by a PAN device in response to demand response event information sent to a PAN gateway server. secondaryDeviceTiming {EAA38A87-29EC-4853-AB61-4971ED15A45E} All end device controls of this type. EndDeviceControls {FC153ACC-DBB0-4502-A82D-045850FF2C2F}.ClientEnd End device that reported this end device event. EndDevice {180BCB9D-1019-4de2-A8A5-3E3FFC3F9022}.SupplierEnd All details of this end device event. EndDeviceEventDetails {4154C6F2-6B3E-4dd6-812B-AF5BE1AD1C57}.SupplierEnd Type of this end device event. EndDeviceEventType {7D8504D4-36F9-40b3-B1FF-D401222F3166}.SupplierEnd Set of measured values to which this event applies. MeterReading {DF4C0081-227B-4d2d-A692-33F732385A32}.ClientEnd Usage point for which this end device event is reported. UsagePoint {8DB1B043-3C92-412a-967D-F037C7FA8E36}.SupplierEnd End device owning this detail. EndDeviceEvent {4154C6F2-6B3E-4dd6-812B-AF5BE1AD1C57}.ClientEnd Value including unit information. value {299CCA34-1297-4caf-996D-2178AC151F8E} All end device events of this type. EndDeviceEvents {7D8504D4-36F9-40b3-B1FF-D401222F3166}.ClientEnd End device that performs this function. EndDevice {2D6571AD-1092-4ed8-985C-487191687354}.ClientEnd All registers for quantities metered by this end device function. Registers {EFFC4614-770D-4c79-9E7C-AD272DF81815}.ClientEnd DERFunction {AAA6DC66-3D4C-449d-8DAC-947317B28177}.ClientEnd DERGroupDispatch {4611E517-A1DA-440c-BD29-668CF1F495E2}.SupplierEnd DERGroupForecast {F0840A17-1419-47f0-BF59-87D100492401}.ClientEnd DERMonitorableParameter {56EE9BE9-6817-4022-967A-0AA909D120DE}.SupplierEnd All demand response programs this group of end devices is enrolled in. DemandResponsePrograms {2533FBD9-FD86-4734-8759-F972A0C201D4}.ClientEnd DispatchablePowerCapability {EE555BAA-0173-4a8c-ACAF-EB8D9421DF51}.SupplierEnd All end device controls sending commands to this end device group. EndDeviceControls {47178028-E658-4042-AB65-A6F4DDD8ABF6}.SupplierEnd All end devices this end device group refers to. EndDevices {ECC0A3D0-FE2F-4df0-B5E6-AB34DDF3162B}.SupplierEnd status {19594095-DC78-4d0c-99AE-1F2CA363D2C9} version {CC16E974-92E2-4713-A63A-597B5CC46631} All end devices described with this data. EndDevices {2131605C-1AA8-4b31-8DC3-70BFAB2B02BE}.ClientEnd Inherent capabilities of the device i.e. the functions it supports. capability {3C69187E-19A8-4011-B110-F17BD943C14F} Rated current. ratedCurrent {A902CC64-04CD-4f25-B6F0-71B08A465357} Rated voltage. ratedVoltage {08DB4030-817C-45a6-833E-CC55FC5DFC02} Duration of the end device control action or the business event that is the subject of the end device control. duration {3F7A241F-6ED7-4f3f-B536-249808517061} Start and end time of an interval during which end device control actions are to be executed. interval {201051B2-B1EF-4f25-A09B-621B198E73D2} Kind of randomisation to be applied to the end device control actions to be executed. randomisation {38C0C045-CAA0-4943-A7B8-51C9D1BC8637} The control area specification that is used for the load forecast. ControlArea {91910331-E0D0-4b32-9E25-EC5310A60B71}.ClientEnd EnergyConnection {B5880CAA-2E1F-4e7e-8CBF-6E8FE1C9519B}.ClientEnd EnergyGroup {58AE497B-672B-4bcb-AABC-468888BDB9A9}.SupplierEnd EnergyComponent {B5880CAA-2E1F-4e7e-8CBF-6E8FE1C9519B}.SupplierEnd EnergyConsumerAction {FED8229A-5B6E-4728-A961-4E85004FEA54}.SupplierEnd The individual phase models for this energy consumer. EnergyConsumerPhase {FE0DC706-B203-4f07-87D5-6218B836646E}.SupplierEnd Load dynamics model used to describe dynamic behaviour of this energy consumer. LoadDynamics {4F34241A-F054-4f5c-8638-560DED3C98B4}.ClientEnd The load response characteristic of this load. If missing this load is assumed to be constant power. LoadResponse {ABB1EF4C-2A3F-4c47-8D73-B51ADA827E97}.SupplierEnd The energy consumer is assigned to this power cut zone. PowerCutZone {10EFC7AF-BD27-4bf9-A05B-BA2A5970F59A}.ClientEnd Active power of the load. Load sign convention is used i.e. positive sign means flow out from a node.For voltage dependent loads the value is at rated voltage.Starting value for a steady state solution. p {5F072D7C-989F-4221-92F2-238C409B4AC2} Active power of the load that is a fixed quantity and does not vary as load group value varies. Load sign convention is used i.e. positive sign means flow out from a node. pfixed {1B9A4235-96FD-4754-9AE5-58493961AAA7} Fixed active power as a percentage of load group fixed active power. Used to represent the timevarying components. Load sign convention is used i.e. positive sign means flow out from a node. pfixedPct {BC15E69E-B780-4792-A3BD-227A4984C490} The type of phase connection such as wye or delta. phaseConnection {7B4A86FE-9F52-4fcc-BAB3-328AC0CECA82} Reactive power of the load. Load sign convention is used i.e. positive sign means flow out from a node.For voltage dependent loads the value is at rated voltage.Starting value for a steady state solution. q {3F213833-3540-4d30-9F05-5A94C9AA1B79} Reactive power of the load that is a fixed quantity and does not vary as load group value varies. Load sign convention is used i.e. positive sign means flow out from a node. qfixed {156252BF-EDEF-4053-A545-045260EE2C8B} Fixed reactive power as a percentage of load group fixed reactive power. Used to represent the timevarying components. Load sign convention is used i.e. positive sign means flow out from a node. qfixedPct {A4B42063-2491-41f9-AAF0-08CF42E84FF5} EnergyConsumer {FED8229A-5B6E-4728-A961-4E85004FEA54}.ClientEnd Switching action to perform kind {5BEC25F0-DFF3-4618-AEF2-952866483784} The energy consumer to which this phase belongs. EnergyConsumer {FE0DC706-B203-4f07-87D5-6218B836646E}.ClientEnd Active power of the load. Load sign convention is used i.e. positive sign means flow out from a node.For voltage dependent loads the value is at rated voltage.Starting value for a steady state solution. p {E2356BA8-AADE-4948-A4C5-84D19C9BE6E0} Active power of the load that is a fixed quantity. Load sign convention is used i.e. positive sign means flow out from a node. pfixed {2934D006-53E8-45e9-BC88-AFB3914CF82C} Fixed active power as per cent of load group fixed active power. Load sign convention is used i.e. positive sign means flow out from a node. pfixedPct {8A9A40B2-4F06-4307-B603-2ECFE0E1732B} Phase of this energy consumer component. If the energy consumer is wye connected the connection is from the indicated phase to the central ground or neutral point. If the energy consumer is delta connected the phase indicates an energy consumer connected from the indicated phase to the next logical nonneutral phase. phase {58399B74-5465-48b8-9E03-F04C4DBC4462} Reactive power of the load. Load sign convention is used i.e. positive sign means flow out from a node.For voltage dependent loads the value is at rated voltage.Starting value for a steady state solution. q {E4F2B21F-8B60-4e52-875C-A9F4C40C84DA} Reactive power of the load that is a fixed quantity. Load sign convention is used i.e. positive sign means flow out from a node. qfixed {9F37746E-4202-4b8f-9D11-D8ABC32FF9CD} Fixed reactive power as per cent of load group fixed reactive power. Load sign convention is used i.e. positive sign means flow out from a node. qfixedPct {D0DF196B-DFA2-4115-9104-3460409B3DF4} BlockDispatchInstruction {3BC3FBEE-55AB-447d-A7C2-53E7591E1DC1}.ClientEnd ControlArea {EC0B638A-E0FD-42c8-B84C-47AA469B8629}.SupplierEnd EnergyComponent {58AE497B-672B-4bcb-AABC-468888BDB9A9}.ClientEnd EnergyTypeReference {1B0AA3EB-EBFC-4e11-A7A4-13206AA305E0}.SupplierEnd SvPowerFlow {9E145EE8-2544-4933-9DE4-FB008FF09419}.ClientEnd p {47D83F72-648B-45a6-9177-ADB63ABC3401} Bids {728667DC-DD4E-4059-AE1B-FBA6AD106FDB}.ClientEnd MarketResults {1BCDE256-7739-44fd-A327-E54563BBB888}.SupplierEnd RTO {7B226990-9273-4097-A3EE-975B7273F323}.SupplierEnd RegisteredResources {27C8750F-C833-4de8-B407-CF325D392A50}.SupplierEnd Settlements {53E470E2-1BB8-49d7-B69A-D59030A5D75A}.SupplierEnd EnergyTransactions {7865A63E-2D94-453e-A45B-329DA7F65903}.ClientEnd FTRs {38EA7E7F-BA90-431d-816C-66C5286F4757}.SupplierEnd RegisteredGenerator {984F3E09-1CA2-412e-9D3B-1138442A36D1}.SupplierEnd EPI type such as wholesale or retail energyPriceIndexType {5D711A0C-F970-4134-A790-959969FF112A} Valid period for which the energy price index is valid. validPeriod {7E58A026-A6F3-4690-9DF2-801317CCB4FF} The Source for an EnergyTransaction is an EnergyProduct which is injected into a ControlArea. Typically this is a ServicePoint. EnergyTransactions {729CC4C8-25A1-41af-8A6B-09D7625F32E2}.ClientEnd GenerationProvider {824933A0-9111-4506-81AD-C90C98EB9B66}.SupplierEnd A Marketer may resell an EnergyProduct. ResoldBy_Marketer {FFB388F3-6858-48ca-82BF-9BB8CF25DE4B}.SupplierEnd A Marketer holds title to an EnergyProduct. TitleHeldBy_Marketer {45B2E11F-1F87-46d0-BEDA-714E73AB2B7B}.SupplierEnd An EnergyTransaction shall have at least one EnergyProfile. EnergyTransaction {C129CB64-7DC6-41aa-94F3-0DC8A2B978D7}.SupplierEnd TransactionBid {E51D8A6A-35CA-4b26-B4D3-9E33C8AF5D95}.SupplierEnd Energy Source of a particular Energy Scheduling Type. EnergySource {9E393194-24E9-4f6c-9801-8D38633121C9}.ClientEnd Energy Scheduling Type of an Energy Source. EnergySchedulingType {9E393194-24E9-4f6c-9801-8D38633121C9}.SupplierEnd Action taken with this energy source. EnergySourceAction {15E4933B-E1C8-4343-A4C1-6F00DC252FE6}.ClientEnd The individual phase information of the energy source. EnergySourcePhase {774C7E8B-ABB6-4d42-9F1A-8C31613909B9}.ClientEnd High voltage source active injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for steady state solutions. activePower {5924942C-E957-4adf-B544-6038926E70E8} Phasetophase nominal voltage. nominalVoltage {AC811957-8FE6-4c92-A301-20AE9D3BFA24} This is the maximum active power that can be produced by the source. Load sign convention is used i.e. positive sign means flow out from a TopologicalNode bus into the conducting equipment. pMax {00037DC7-8613-4877-928B-BA846313A376} This is the minimum active power that can be produced by the source. Load sign convention is used i.e. positive sign means flow out from a TopologicalNode bus into the conducting equipment. pMin {244B567C-A52D-4a89-9432-42EF3E26CD0C} Positive sequence Thevenin resistance. r {EF264738-8B04-4eea-A024-F7D5E2DAA0F3} Zero sequence Thevenin resistance. r0 {864DC9B8-D243-400b-AF81-9495FD47BA0B} High voltage source reactive injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for steady state solutions. reactivePower {28125ED6-484D-4da2-A713-555556D025B4} Negative sequence Thevenin resistance. rn {A36F03C0-ADF9-46ed-8051-6A031F820282} Phase angle of aphase open circuit used when voltage characteristics need to be imposed at the node associated with the terminal of the energy source such as when voltages and angles from the transmission level are used as input to the distribution network. The attribute shall be a positive value or zero. voltageAngle {445142BE-097F-4954-9E89-325CE9D4D70E} Phasetophase open circuit voltage magnitude used when voltage characteristics need to be imposed at the node associated with the terminal of the energy source such as when voltages and angles from the transmission level are used as input to the distribution network. The attribute shall be a positive value or zero. voltageMagnitude {A7B0DCB7-7ADA-4e63-A635-CEDCC43343BE} Positive sequence Thevenin reactance. x {511C3E9E-75F0-42fd-8E16-A972A3C23E6D} Zero sequence Thevenin reactance. x0 {60183FA3-68AD-4510-B89D-3F5F9A1D1F77} Negative sequence Thevenin reactance. xn {2BCE8602-2CB1-48b8-97AE-9163CC618BC7} Energy source on which this action is taken. EnergySource {15E4933B-E1C8-4343-A4C1-6F00DC252FE6}.SupplierEnd Switching action to perform. kind {53675AFA-3C31-4e93-BE1C-7A40BDA35158} The energy sourceto which the phase belongs. EnergySource {774C7E8B-ABB6-4d42-9F1A-8C31613909B9}.SupplierEnd Phase of this energy source component. If the energy source wye connected the connection is from the indicated phase to the central ground or neutral point. If the energy source is delta connected the phase indicates an energy source connected from the indicated phase to the next logical nonneutral phase. phase {0F8C51FC-C6FB-41e8-9023-EE4C8AA358E6} An EnergyTransaction may be curtailed by any of the participating entities. CurtailmentProfiles {64C49984-0ED1-438b-9C5C-CE6E9784CFF1}.ClientEnd EnergyPriceCurves {7865A63E-2D94-453e-A45B-329DA7F65903}.SupplierEnd The Source for an EnergyTransaction is an EnergyProduct which is injected into a ControlArea. Typically this is a ServicePoint. EnergyProduct {729CC4C8-25A1-41af-8A6B-09D7625F32E2}.SupplierEnd An EnergyTransaction shall have at least one EnergyProfile. EnergyProfiles {C129CB64-7DC6-41aa-94F3-0DC8A2B978D7}.ClientEnd Energy is transferred between interchange areas Export_SubControlArea {FE5AFCF1-5AF3-41b8-A9F4-38F6BDF94098}.ClientEnd Energy is transferred between interchange areas Import_SubControlArea {2143F763-800E-436a-B8FB-44CEB5B9E1EB}.ClientEnd An EnergyTransaction may have a LossProfile. LossProfiles {0E272DF7-73BF-495c-AEAE-1F184C3A0031}.ClientEnd A dynamic energy transaction can act as a pseudo tie line. TieLines {F598C617-D4AC-4af6-8714-13A45A6CFB71}.SupplierEnd TransmissionReservation {AC1E24EF-9143-4c28-B275-913E3666B245}.ClientEnd Maximum congestion charges in monetary units. congestChargeMax {D060A9B8-A278-439d-8A10-BC9DAD0F37E4} Delivery point active power. deliveryPointP {F6874DA3-064D-4792-9469-1B66229ADBE9} Transaction minimum active power if dispatchable. energyMin {1D2E5BB6-B89B-4547-B9A6-4277624C3DCE} Receipt point active power. receiptPointP {A3DFB79A-E8BA-4741-A303-5BA2833A0682} Approve Deny Study state {D5E3908F-E2A8-44f9-AE49-5B600C31942F} EnergyGroup {1B0AA3EB-EBFC-4e11-A7A4-13206AA305E0}.ClientEnd kind {F480474F-E711-4470-92B8-B4ECAEB83994} The list of alert types from which the type of this alert is drawn. AlertTypeList {47BAF174-F27B-42ab-8162-CA6C1C444323}.SupplierEnd Environmental data provider for this alert. EnvironmentalDataProvider {ACFE0532-D3AF-4f98-950B-B9B06426E751}.SupplierEnd Type of location to which this environmental alert applies. EnvironmentalLocationKind {36C399B4-711A-4109-91F3-44F367B8F1B3}.SupplierEnd The interval for which this weather alert is in effect. inEffect {BEC3F7C0-9592-4780-85CE-57AB1E77AFF6} Classification condition which this analog helps define. ClassificationCondition {8B13B03E-D662-45ec-9CC3-71515B9D13CA}.SupplierEnd Observation or forecast with which this environmental analog measurement is associated. EnvironmentalInformation {6901EAB0-A9FB-4874-AC91-147B47110113}.SupplierEnd Monitoring station which provides this environmental analog measurement. EnvironmentalMonitoringStation {C0F501A7-2245-4a22-A8A6-E8BC3E6BBBB9}.SupplierEnd The reporting capability this environmental value set helps define. ReportingCapability {33EE49E4-C5C2-447f-B5D2-DA0AF83C0024}.SupplierEnd Code representing the coverage of the weather condition. coverageKind {8ACD984F-A238-4e25-A7C9-957F72060D0C} Code representing the intensity of the weather condition. intensityKind {5CCD093C-5C15-448f-84C8-71DF39536243} Probability of weather condition occurring during the time interval expressed as a percentage. Applicable only when weather condition is related to a forecast not an observation. probabilityPercent {80B9FACF-F5A0-439f-BE98-3FFC9B761B19} Code representing the type of weather condition. weatherKind {E804C8CA-6BBB-4d4a-BB1C-BF2E36C21A55} A specific version of a list of alerts published by this environmental data authority. AlertTypeList {2A299E0C-C0CE-4200-AE97-FBD32E1BCFE0}.ClientEnd Phenomenon classification defined by this environmental data authority. PhenomenonClassification {A0D7C120-ECE6-4c9b-B9F6-B37F0029DA01}.ClientEnd Alert issued by this environmental data provider. EnvironmentalAlert {ACFE0532-D3AF-4f98-950B-B9B06426E751}.ClientEnd Environmental information provided by this environmental data provider. EnvironmentalInformation {FF5E2F77-FC5C-40cd-AA83-A72FE1FC7C06}.ClientEnd Observation or forecast with which this environmental discrete integer is associated. EnvironmentalInformation {BC06D77F-CD71-4f36-9D8A-7E8192355052}.SupplierEnd Kind of environmental discrete integer. kind {DF3B1AE2-0DCD-4d35-97ED-5C30CE23F31C} Forecast or observation related to this environmental event. EnvironmentalInformation {7DDC866E-3A61-461b-8E5F-92509F7E781D}.SupplierEnd Environmental analog associated with this observation or forecast. EnvironmentalAnalog {6901EAB0-A9FB-4874-AC91-147B47110113}.ClientEnd Environmental data provider supplying this environmental information. EnvironmentalDataProvider {FF5E2F77-FC5C-40cd-AA83-A72FE1FC7C06}.SupplierEnd Environmental discrete integer associated with this observation or forecast. EnvironmentalDiscrete {BC06D77F-CD71-4f36-9D8A-7E8192355052}.ClientEnd Environmental event to which this forecast or observation relates. EnvironmentalEvent {7DDC866E-3A61-461b-8E5F-92509F7E781D}.ClientEnd EnvironmentalPhenomenon {F4F99E9D-5DA9-4ea5-B1C7-69F676562B14}.ClientEnd Environmental string measurement associated with this forecast or observation. EnvironmentalStringMeasurement {4492BBDD-51E1-414b-8D40-F554831AB71A}.ClientEnd Environmental alert applying to location of this type. EnvironmentalAlert {36C399B4-711A-4109-91F3-44F367B8F1B3}.ClientEnd Environmental phenomenon for which this location is of relevance. EnvironmentalPhenomenon {230EC626-6F7A-420a-849C-C0C8A1FD4A45}.ClientEnd Location of this instance of ths kind of environmental location. Location {153D33F0-C3EC-4cda-8188-6776F6BD789B}.SupplierEnd The kind of location. Typical values might be center extent primary secondary etc. kind {1CB2D9F7-AF43-42f0-BCC6-6AF5A8756332} Environmental analog measurement provided by this monitoring station. EnvironmentalAnalog {C0F501A7-2245-4a22-A8A6-E8BC3E6BBBB9}.ClientEnd Location of this monitoring station. Location {17713B5C-F047-400e-ADE7-5B55F485CA85}.SupplierEnd One of the reporting capabilities of this monitoring station. ReportingCapability {6335EFF8-1839-4f0f-A97C-CC890F5D5411}.ClientEnd TimeSeries {6E714075-8668-4e58-A652-65C0CBEF02BF}.ClientEnd UsagePoint {11F52D5E-EFC9-4c29-A3F6-7C2E9E192F0C}.SupplierEnd The time offset from UTC a.k.a. GMT configured in the station clock not necessarily the time zone in which the station is physically located.This attribute exists to support management of utility monitoring stations and has no direct relationship to the manner in which time is expressed in EnvironmentalValueSet. timeZoneOffset {34BCB6AC-3B39-43ea-A37A-C5FBFB3924C9} The forecast or observation of which this phenomenon description is a part. EnvironmentalInformation {F4F99E9D-5DA9-4ea5-B1C7-69F676562B14}.SupplierEnd Location of relevance to this environmental phenomenon. EnvironmentalLocationKind {230EC626-6F7A-420a-849C-C0C8A1FD4A45}.SupplierEnd The classification of this phenomenon. PhenomenonClassification {CEAA1D59-2A12-4a25-A69D-ACC8789B4E11}.SupplierEnd The timestamp of the phenomenon as a single point or time interval. timeInterval {B2C5E855-5376-4537-8E1A-C847A2AB3600} Classification condition which this string measurement helps define. ClassificationCondition {71F9989B-6173-4d71-B9F1-2184FCC3CEF5}.SupplierEnd Observation or forecast with which this environmental string is associated. EnvironmentalInformation {4492BBDD-51E1-414b-8D40-F554831AB71A}.SupplierEnd Additional equipment container beyond the primary equipment container. The equipment is contained in another equipment container but also grouped with this equipment container. AdditionalEquipmentContainer {43EA076F-F51B-4617-BC39-6D3939D5CEFD}.ClientEnd The contingency equipments in which this equipment participates. ContingencyEquipment {90FE687B-C58C-4b05-856E-6D576F7CADBE}.ClientEnd Equipment limit series calculation component to which this equipment contributes. EqiupmentLimitSeriesComponent {CEFBFF28-402F-45fe-88FA-EF5E6D724964}.ClientEnd Container of this equipment. EquipmentContainer {68BA73EF-8533-48ba-964A-DE0F722292D2}.ClientEnd EquipmentUnavailabilitySchedule {D5BE88A6-8696-43ec-A291-81AFED41113B}.ClientEnd All faults on this equipment. Faults {6B3EA616-0934-425c-A898-1D84DADF5261}.ClientEnd Limit dependencymodels organized under this equipment as a means for organizing the model in a tree view. LimitDependencyModel {CEF63A20-BB9F-4d20-85B7-C4EF0AB5624F}.ClientEnd The operational limit sets associated with this equipment. OperationalLimitSet {AEB22FF5-0EEF-4e3a-BE8C-07931F2FAE92}.ClientEnd All operational restrictions for this equipment. OperationalRestrictions {A11D842D-BDDB-42a4-B8FB-43C199D5E3BA}.ClientEnd All outages in which this equipment is involved. Outages {7CB5F824-2EAC-4c6e-B3CE-B2B245253D31}.ClientEnd PinEquipment {83B2D8C8-5F34-4fbe-A13F-090F6823061D}.ClientEnd Protective action is controlling equipment. This can be direct signals from the control center or emulation of action done by protection equipment. ProtectiveActionEquipment {C2B4064B-C361-4230-9F19-21614F4EFABE}.ClientEnd All usage points connected to the electrical grid through this equipment. UsagePoints {3E4B9C55-FCC6-42ec-B364-27C62004847F}.ClientEnd WeatherStation {C35B9B9D-C271-4005-801D-B7B44FF8D8C7}.SupplierEnd The additonal contained equipment. The equipment belong to the equipment container. The equipment is contained in another equipment container but also grouped with this equipment container. Examples include when a switch contained in a substation is also desired to be grouped with a line contianer or when a switch is included in a secondary substation and also grouped in a feeder. AdditionalGroupedEquipment {43EA076F-F51B-4617-BC39-6D3939D5CEFD}.SupplierEnd Contained equipment. Equipments {68BA73EF-8533-48ba-964A-DE0F722292D2}.SupplierEnd The terminal connecting to the bus to which the fault is applied. Terminal {2CF11C93-156B-4725-864D-F54BFFEBEEB6}.SupplierEnd Equipment contributing toward the series limit. The reference here is to Equipment rather than a specific limit on the equipment so the grouiping can be reused for multiple limits of different types on the same instance of equipment. Equipment {CEFBFF28-402F-45fe-88FA-EF5E6D724964}.SupplierEnd Equipment {D5BE88A6-8696-43ec-A291-81AFED41113B}.SupplierEnd UnavailabilitySwitchAction {A621ED73-8721-4170-8819-24FA003C3372}.ClientEnd UnavailablitySchedule {E688F5A4-D2F9-4a84-85F2-980B6307E7AB}.SupplierEnd Negative sequence series resistance from terminal sequence 1 to terminal sequence 2. Used for short circuit data exchange according to IEC 60909.EquivalentBranch is a result of network reduction prior to the data exchange. negativeR12 {B1A62182-45DA-4986-9AD7-77E0AA97A1B9} Negative sequence series resistance from terminal sequence 2 to terminal sequence 1. Used for short circuit data exchange according to IEC 60909.EquivalentBranch is a result of network reduction prior to the data exchange. negativeR21 {20639149-2242-4312-872C-16CD27A6283C} Negative sequence series reactance from terminal sequence 1 to terminal sequence 2. Used for short circuit data exchange according to IEC 60909.Usage EquivalentBranch is a result of network reduction prior to the data exchange. negativeX12 {CD82466D-D982-4513-8CAA-27FB73559F16} Negative sequence series reactance from terminal sequence 2 to terminal sequence 1. Used for short circuit data exchange according to IEC 60909.Usage EquivalentBranch is a result of network reduction prior to the data exchange. negativeX21 {EEF7F824-5B80-4eb2-AA46-C3AB841CA150} Positive sequence series resistance from terminal sequence 1 to terminal sequence 2 . Used for short circuit data exchange according to IEC 60909. EquivalentBranch is a result of network reduction prior to the data exchange. positiveR12 {B2DB32FB-D03F-4e20-A232-010D8CBEA16D} Positive sequence series resistance from terminal sequence 2 to terminal sequence 1. Used for short circuit data exchange according to IEC 60909.EquivalentBranch is a result of network reduction prior to the data exchange. positiveR21 {8BB8921A-0D66-4f17-9E3F-D86911D7AB83} Positive sequence series reactance from terminal sequence 1 to terminal sequence 2. Used for short circuit data exchange according to IEC 60909.Usage EquivalentBranch is a result of network reduction prior to the data exchange. positiveX12 {334AD4DB-EC20-4576-BB4A-A0F37E316CA7} Positive sequence series reactance from terminal sequence 2 to terminal sequence 1. Used for short circuit data exchange according to IEC 60909.Usage EquivalentBranch is a result of network reduction prior to the data exchange. positiveX21 {F95AFB29-D445-4d86-A53E-D91AEB6534D7} Positive sequence series resistance of the reduced branch. r {1F492DF7-2255-4d8e-A86F-7B7DD78A06E7} Resistance from terminal sequence 2 to terminal sequence 1 .Used for steady state power flow. This attribute is optional and represent unbalanced network such as offnominal phase shifter. If only EquivalentBranch.r is given then EquivalentBranch.r21 is assumed equal to EquivalentBranch.r.Usage rule EquivalentBranch is a result of network reduction prior to the data exchange. r21 {0D332096-38C6-43f9-BC78-C72F55A7C7C7} Positive sequence series reactance of the reduced branch. x {AEAF2B71-B7BD-41c0-9844-C69DBC580F24} Reactance from terminal sequence 2 to terminal sequence 1. Used for steady state power flow. This attribute is optional and represents an unbalanced network such as offnominal phase shifter. If only EquivalentBranch.x is given then EquivalentBranch.x21 is assumed equal to EquivalentBranch.x.Usage rule EquivalentBranch is a result of network reduction prior to the data exchange. x21 {2C83250C-F22A-4f91-AC53-6D8D5FEB8868} Zero sequence series resistance from terminal sequence 1 to terminal sequence 2. Used for short circuit data exchange according to IEC 60909.EquivalentBranch is a result of network reduction prior to the data exchange. zeroR12 {68167E61-E4CA-4823-A369-4F220EB91141} Zero sequence series resistance from terminal sequence 2 to terminal sequence 1. Used for short circuit data exchange according to IEC 60909.Usage EquivalentBranch is a result of network reduction prior to the data exchange. zeroR21 {D0CD7162-A205-4651-8224-59E6C312851E} Zero sequence series reactance from terminal sequence 1 to terminal sequence 2. Used for short circuit data exchange according to IEC 60909.Usage EquivalentBranch is a result of network reduction prior to the data exchange. zeroX12 {A782C660-AD8E-4742-AE66-1A5F14EF6D97} Zero sequence series reactance from terminal sequence 2 to terminal sequence 1. Used for short circuit data exchange according to IEC 60909.Usage EquivalentBranch is a result of network reduction prior to the data exchange. zeroX21 {959BBBCF-5B65-41ea-B459-8A0496C293CD} The equivalent where the reduced model belongs. EquivalentNetwork {DFE42640-1DEE-47f2-9A22-0AB6F405CCCD}.SupplierEnd The reactive capability curve used by this equivalent injection. ReactiveCapabilityCurve {FC08DB44-00BE-4bc5-8DE9-3538FD5307B8}.ClientEnd Maximum active power of the injection. maxP {329CBFA1-4D02-4d6a-B33F-FCA214810625} Maximum reactive power of the injection. Used for modelling of infeed for load flow exchange. Not used for short circuit modelling. If maxQ and minQ are not used ReactiveCapabilityCurve can be used. maxQ {D033683B-6C04-4090-94B3-212F9C58C3A6} Minimum active power of the injection. minP {67E14F5B-B16F-40c9-9756-B082E67BF7BF} Minimum reactive power of the injection. Used for modelling of infeed for load flow exchange. Not used for short circuit modelling. If maxQ and minQ are not used ReactiveCapabilityCurve can be used. minQ {D4D5B759-8DC7-41ec-BFEE-EF85D3E20724} Equivalent active power injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for steady state solutions. p {794BBD16-A21F-4f57-BFF6-6413DF1DC6D5} Equivalent reactive power injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for steady state solutions. q {CFD61B60-96D7-45db-83AD-D2441020B6F6} Positive sequence resistance. Used to represent ExtendedWard IEC 60909.Usage ExtendedWard is a result of network reduction prior to the data exchange. r {35F3E67E-F428-439e-ABE0-284CC8BBBD7C} Zero sequence resistance. Used to represent ExtendedWard IEC 60909.Usage ExtendedWard is a result of network reduction prior to the data exchange. r0 {48277F25-31FB-4e9d-9F09-482886F04693} Negative sequence resistance. Used to represent ExtendedWard IEC 60909.Usage ExtendedWard is a result of network reduction prior to the data exchange. r2 {17951FC2-83D8-4363-9ED5-EE48ADC75FD6} The target voltage for voltage regulation. The attribute shall be a positive value. regulationTarget {6BE562FD-1C81-4544-8594-DBA144DAB96E} Positive sequence reactance. Used to represent ExtendedWard IEC 60909.Usage ExtendedWard is a result of network reduction prior to the data exchange. x {C2694F5C-8E2F-4a91-941B-06C03D805B37} Zero sequence reactance. Used to represent ExtendedWard IEC 60909.Usage ExtendedWard is a result of network reduction prior to the data exchange. x0 {D5B4C735-2A8A-414e-B4DC-34A67427B5BD} Negative sequence reactance. Used to represent ExtendedWard IEC 60909.Usage ExtendedWard is a result of network reduction prior to the data exchange. x2 {0FE79852-D304-4aec-9BDA-940C762DA50E} The associated reduced equivalents. EquivalentEquipments {DFE42640-1DEE-47f2-9A22-0AB6F405CCCD}.ClientEnd Positive sequence shunt susceptance. b {013695BA-2127-409a-A827-96AED518B7C9} Positive sequence shunt conductance. g {431696B8-B418-463e-9EC1-39699EED25EC} Design {385BF030-903C-4fb9-9B45-AE7199B9E2C6}.ClientEnd ErpBomItemDatas {4F7E7578-757A-4e21-A7A7-CA0EA44803ED}.ClientEnd DesignLocation {4962575B-8FF3-4dfb-8A66-0E1F572C4D90}.SupplierEnd ErpBOM {4F7E7578-757A-4e21-A7A7-CA0EA44803ED}.SupplierEnd TypeAsset {3FB0DAAA-9E8C-499f-81CE-3F538433A48D}.ClientEnd ErpPersons {A11130EF-055F-4b39-8ED5-B1CB36A71F99}.ClientEnd Asset {ED3450A6-CFCF-4eb3-95A3-E3511D9B6178}.ClientEnd status {82391F6C-A439-421d-8C71-89BF4089B22E} status {71513360-2580-4e69-837A-CA97E3815CF1} CustomerAccount {F954FA38-DDCE-4eeb-8C01-FA8B0D72A603}.ClientEnd ErpInvoiceLineItems {B388BA85-144F-45a8-B558-748EB75E28A1}.ClientEnd Total amount due on this invoice based on line items and applicable adjustments. amount {91EB3FCD-2691-43d5-9C52-8D724F04F256} Kind of media by which the CustomerBillingInfo was delivered. billMediaKind {38133B40-01E4-4645-9F85-44B3C7034150} Kind of invoice default is sales. kind {62986491-D126-49c7-9BD6-9780E991F505} ComponentErpInvoiceLineItems {399C8F34-12B4-4bf2-894A-35EFA1225605}.ClientEnd ContainerErpInvoiceLineItem {399C8F34-12B4-4bf2-894A-35EFA1225605}.SupplierEnd Customer billing for services rendered. 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An invoice is required for this to occur. ErpInvoiceLineItem {534AB3AB-C172-46ba-AEC1-987D567FA252}.SupplierEnd ErpQuote {3DD4AB8B-A4F0-42c7-A8BA-5A675F7A44FB}.SupplierEnd ErpReqLineItem {9B596E61-9131-4334-9DFD-E4640D172E40}.SupplierEnd status {A0C2ADE4-3221-421c-A1D7-AB1FA4C8C572} Assets {69D45AA1-C24F-4329-AABF-24C5B1CC8A51}.ClientEnd ErpInvoiceLineItem {F490DDDB-7EF8-43cf-807E-6C93CBF5BC47}.SupplierEnd ErpPOLineItem {2241AA6A-7CB0-468a-87C6-B912D051C941}.SupplierEnd ErpReceiveDelivery {082173E2-98D3-4ec3-BC53-B4812303F891}.SupplierEnd status {D9150A1E-05C1-4693-92ED-E6675A766190} ErpInvoiceLineItem {319D17D5-7DA7-4431-BB15-F0903631C52D}.ClientEnd ErpJournalEntries {1CA7637E-994E-45af-9C55-1D91D2DCD1E8}.SupplierEnd ErpPayments {7EE5F395-6702-418f-928E-85FD14AA3B35}.SupplierEnd ErpReceivable {D1F3B831-CBFF-422a-8F15-C485016CFA7B}.SupplierEnd status {E303B5E2-9EC3-4450-A37F-E39DE20A38BC} ErpRecLineItems {D1F3B831-CBFF-422a-8F15-C485016CFA7B}.ClientEnd ErpRecDelvLineItems {082173E2-98D3-4ec3-BC53-B4812303F891}.ClientEnd ErpPOLineItem {4DB55D31-B4E9-4481-AB5D-D170CEB9DC09}.SupplierEnd ErpQuoteLineItem {9B596E61-9131-4334-9DFD-E4640D172E40}.ClientEnd ErpRequisition {109F4694-10BD-4f5d-A24F-10ACB4A0EAE7}.SupplierEnd TypeAsset {7F453A7B-93B5-4f12-8984-2FC06DB80EED}.ClientEnd TypeMaterial {3878A953-62BF-4865-AD6B-E5B11C7EB681}.ClientEnd Cost of material. cost {49E07097-720E-4ce4-8920-34C58859E416} status {D26CD3B5-912A-448d-BCBD-5E6F852CEAF2} ErpReqLineItems {109F4694-10BD-4f5d-A24F-10ACB4A0EAE7}.ClientEnd LandProperty {86405B23-FBDA-4f53-A547-5BE7134DF39C}.ClientEnd status {27F5B1B0-6FD4-41c6-A376-A8417DB1B68C} ErpProjectAccounting {FA05B30D-6288-4ec8-A234-C0AE064BBE4A}.SupplierEnd ErpTimeSheet {6C8E20D2-28EF-4a77-ACA0-D8B0EAFABC9B}.ClientEnd status {B378075A-5792-4b9c-9B91-B0C144CF06D0} ErpTimeEntries {6C8E20D2-28EF-4a77-ACA0-D8B0EAFABC9B}.SupplierEnd Outage {ABABDC87-C805-4e9a-86E2-7C263386DF76}.SupplierEnd provides the confidence level that this ERT can be accomplished. This may be changedupdated as needed. confidenceKind {0EDCEE1C-781D-4e73-BBAF-7CC348F50C47} ExPostLossResults {0AE3C025-1AC4-4c40-A3B6-07906E76D2B3}.ClientEnd ExPostLoss {0AE3C025-1AC4-4c40-A3B6-07906E76D2B3}.SupplierEnd SubControlArea {82BD4DEF-763E-4739-B4DC-07A529BF1E77}.SupplierEnd ExPostMarketRegionResults {201C7552-E3C8-41b0-B33F-E52769ABD221}.ClientEnd ExPostMarketRegion {201C7552-E3C8-41b0-B33F-E52769ABD221}.SupplierEnd MarketRegion {801B61F8-BE1E-447c-ACAC-D47A715E668A}.SupplierEnd ExPostResults {9A951836-7F48-4542-A2E5-8EFAF5543E7F}.ClientEnd ExPostPricing {9A951836-7F48-4542-A2E5-8EFAF5543E7F}.SupplierEnd Pnode {E05F725E-CEBB-458d-9E58-0F2247135211}.ClientEnd ExPostResourceResults {E2D7DF58-9B4D-4496-B6BF-A9375B343F69}.ClientEnd ExPostResource {E2D7DF58-9B4D-4496-B6BF-A9375B343F69}.SupplierEnd RegisteredResource {A5DD0CDB-1742-4212-BFFE-9A1405F36B62}.SupplierEnd Status of equipment status {F85DC6A0-AA8C-47f6-934B-EBBCAA94539E} Voltage regulator gain iKai gt 0. Typical value 400. ka {E352E9FC-7564-45c2-8A93-27C93EF60D93} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 02. kc {28720421-E00D-427e-BF08-E224BB66AA5B} Demagnetizing factor a function of exciter alternator reactances iKdi gt 0. Typical value 038. kd {EDEC8C87-FD52-4865-B7E1-8946B6895B16} Exciter constant related to selfexcited field iKei. Typical value 1. ke {53375318-0A8D-4402-8650-3F870A51BA29} Excitation control system stabilizer gains iKfi gt 0. Typical value 003. kf {BDFC7910-E81F-41c8-BB56-38C14FFE23EB} Coefficient to allow different usage of the model iKf1i gt 0. Typical value 0. kf1 {0BF78AC3-C109-48eb-AA0A-860A3D4B4DC7} Coefficient to allow different usage of the model iKf2i gt 0. Typical value 1. kf2 {7BF6D8A5-46CD-4844-A76F-A578365F6F75} Coefficient to allow different usage of the modelspeed coefficient iKsi gt 0. Typical value 0. ks {F0525376-BE7F-4cea-A127-C799F84E4011} Voltage regulator time constant iTai gt 0. Typical value 002. ta {CD0AA950-9C88-4360-A0AD-83B7D3447AD2} Voltage regulator time constant iTbi gt 0. Typical value 0. tb {FADEADE2-2D36-4891-8A12-DA20A15169A6} Voltage regulator time constant iTiisubcsubi gt 0. Typical value 0. tc {5943ABA1-201C-4a92-94CD-B1CAAC02F914} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 08. te {789A404B-5DED-4b99-B90F-0BD43DECA5AE} Excitation control system stabilizer time constant iTfi gt 0. Typical value 1. tf {E1AC404B-76EC-489e-B3CC-4B0D12E0159E} Maximum voltage regulator output iViisubamaxsubi gt 0. Typical value 145. vamax {6E8F250A-6DD0-40e4-ABD4-05587BE7A46F} Minimum voltage regulator output iViisubaminsubi lt 0. Typical value 145. vamin {3FCC8597-5A3B-484f-BA9E-195684AED978} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVe1i gt 0. Typical value 418. ve1 {5990C173-89BC-42d4-AE0F-594FABBBD315} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVe2i gt 0. Typical value 314. ve2 {F4F6A8F1-8291-4a3d-9A0C-7E110072178C} Maximum voltage regulator outputs iVrmaxi gt 0. Typical value 603. vrmax {9871BDC8-9344-4a6a-AD9A-A2D0BFA157D1} Minimum voltage regulator outputs iVrmini lt 0. Typical value 543. vrmin {E5D21BA0-CD87-4204-A896-54B339E7B67D} Voltage regulator gain iKai gt 0. Typical value 400. ka {ACAA089F-1C67-4d5a-9CD3-E880D47094F5} Second stage regulator gain iKbi gt 0. Exciter field current controller gain. Typical value 25. kb {CCDF1CF6-E857-4195-8372-17806EEDB350} Second stage regulator gain iKb1i. It is exciter field current controller gain used as alternative to iKbi to represent a variant of the ExcAC2A model. Typical value 25. kb1 {A25DC229-BD9A-4df3-B082-EC3CCF1C53C0} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 028. kc {E1213B0A-871F-47bc-9A99-696C7B92AE7C} Demagnetizing factor a function of exciter alternator reactances iKdi gt 0. Typical value 035. kd {8E6000C6-2817-4a72-BC0F-F59C8DF365C0} Exciter constant related to selfexcited field iKei. Typical value 1. ke {8CE743CF-85C7-48c8-B251-A0391076E970} Excitation control system stabilizer gains iKfi gt 0. Typical value 003. kf {DB07700F-9DDD-4419-985A-E144CDED402F} Exciter field current feedback gain iKhi gt 0. Typical value 1. kh {90E213B6-4E4D-4381-BE7C-1DD75B1363D5} Exciter field current limiter gain iKli. Typical value 10. kl {D91822A3-D99C-4253-93E4-C48CEEF7483D} Coefficient to allow different usage of the model iKl1i. Typical value 1. kl1 {70CEE85A-A641-4061-8ED4-D33335C10B80} Coefficient to allow different usage of the modelspeed coefficient iKsi gt 0. Typical value 0. ks {6B0EB6D6-ED98-4bee-BAD6-2BAD76A856F2} Voltage regulator time constant iTai gt 0. Typical value 002. ta {4B59FFDC-F416-4e4c-84B8-31116DE62E64} Voltage regulator time constant iTbi gt 0. Typical value 0. tb {9EC97F7D-9BE0-491a-BC07-C0DC2D1137F7} Voltage regulator time constant iTci gt 0. Typical value 0. tc {824C8D42-0D7A-468d-B5CC-F7877EDD5985} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 06. te {7EAD0734-3A90-4e3b-9ED8-ADFD341A0DDC} Excitation control system stabilizer time constant iTfi gt 0. Typical value 1. tf {DA313FF0-4B2C-4774-B932-D9D516B29D14} Maximum voltage regulator output iVamaxi gt 0. Typical value 8. vamax {CA058C3C-9EF2-49df-9615-7DA0A0601159} Minimum voltage regulator output iVamini lt 0. Typical value 8. vamin {B7DD036A-20CD-4ac0-83EA-5360671AF242} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub1subi gt 0. Typical value 44. ve1 {EB54B1DF-C0EB-411d-845D-2254C4B0D239} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub2subi gt 0. Typical value 33. ve2 {7CD070A4-3CD7-473b-97B0-A1FE156287CD} Exciter field current limit reference iVfemaxi gt 0. Typical value 44. vfemax {858136D1-E5FF-438e-97F6-E5490B2F71A6} Maximum exciter field current iVlri gt 0. Typical value 44. vlr {EA7735C2-52B8-4d26-A6A0-739722E2808C} Maximum voltage regulator outputs iVrmaxi gt 0. Typical value 105. vrmax {D0814F1D-6821-4a87-A4FA-E1A26089A315} Minimum voltage regulator outputs iVrmini lt 0. Typical value 95. vrmin {7A23162C-7ABA-44ab-95D9-157109870AAA} Value of iEfd iat which feedback gain changes iEfdni gt 0. Typical value 236. efdn {A3042DF9-602E-45a3-B059-65CEB8D39C96} Voltage regulator gain iKai gt 0. Typical value 4562. ka {E13E7FD0-39A5-4290-A813-00AAF02DEE9A} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 0104. kc {B96EE6F8-2701-4059-8A66-567BD7CBEDD3} Demagnetizing factor a function of exciter alternator reactances iKdi gt 0. Typical value 0499. kd {65649D1D-7116-490e-B2B2-0C7E4430FDE7} Exciter constant related to selfexcited field iKei. Typical value 1. ke {32964DCC-A519-4cf2-B7C9-D01D1B142818} Excitation control system stabilizer gains iKfi gt 0. Typical value 0143. kf {607CA28C-EC63-4b6a-A246-DD5C6D271192} Coefficient to allow different usage of the model iKf1i. Typical value 1. kf1 {BF519598-F373-4b71-B724-97178F895E67} Coefficient to allow different usage of the model iKf2i. Typical value 0. kf2 {75D53490-5289-481d-BD1A-AEC922BB4EBA} Gain used in the minimum field voltage limiter loop iKlvi. Typical value 0194. klv {3FA58A14-69AE-4f51-BFBF-21ADE948741F} Excitation control system stabilizer gain iKni gt 0. Typical value 005. kn {ED447391-A052-4c9f-8E78-6AA296D9AA00} Constant associated with regulator and alternator field power supply iKri gt 0. Typical value 377. kr {20C6FA20-10EF-4522-AED1-2E69076D2263} Coefficient to allow different usage of the modelspeed coefficient iKsi. Typical value 0. ks {DBB8106E-28AD-403f-9FD5-7DB0E5960F69} Voltage regulator time constant iTai gt 0. Typical value 0013. ta {5E288AC9-EC5F-4231-A134-A17167B76401} Voltage regulator time constant iTbi gt 0. Typical value 0. tb {0ABCE488-9509-47af-80D2-FED3E44EEA64} Voltage regulator time constant iTci gt 0. Typical value 0. tc {FC537C5C-7FF9-4924-929C-500556AC74AF} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 117. te {02C1ECB0-024B-4193-A523-A9953DC7D26F} Excitation control system stabilizer time constant iTfi gt 0. Typical value 1. tf {96720F36-9A67-4193-BAF3-D1B54696DB07} Maximum voltage regulator output iVamaxi gt 0. Typical value 1. vamax {2F4A90AA-39CF-43c3-88BA-BD3E984B60B6} Minimum voltage regulator output iVamini lt 0. Typical value 095. vamin {0BE2AFD7-734A-4a7d-ACE5-369A1C600961} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub1subi gt 0. Typical value 6.24. ve1 {D09A6721-BE9B-4f17-9DA9-65A9B3882A26} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub2subi gt 0. Typical value 468. ve2 {85335AC3-6D85-42a8-8AD3-211AE48513EF} Minimum exciter voltage output iVemini lt 0. Typical value 0. vemin {835D4207-DF7E-4b1e-B5A5-8E1B0B9921B1} Exciter field current limit reference iVfemaxi gt 0. Typical value 16. vfemax {0631A423-7215-42bd-9A41-0B2746EF9342} Field voltage used in the minimum field voltage limiter loop iVlvi. Typical value 079. vlv {C87B456E-4EBE-4b52-8AE0-C3E8880DCDEC} Voltage regulator gain iKai gt 0. Typical value 200. ka {ECFBEEA9-2D13-4307-8344-9E923FC6B1BF} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 0. kc {53634C52-E09C-41c2-B5B0-96DAE7202C36} Voltage regulator time constant iTai gt 0. Typical value 0015. ta {C6D9F1B8-61B3-4f70-846D-A046DF98EAED} Voltage regulator time constant iTbi gt 0. Typical value 10. tb {8BAA4F93-ED66-4648-8C7F-907948E2EA89} Voltage regulator time constant iTci gt 0. Typical value 1. tc {EC2AD6AE-7DDA-4388-8BFB-2880B3D2FA96} Maximum voltage regulator input limit iVimaxi gt 0. Typical value 10. vimax {579D6B75-ED06-41c0-8E7E-FEC595A45FDA} Minimum voltage regulator input limit iVimini lt 0. Typical value 10. vimin {B0C8E5EB-A424-4db1-AF01-009893DCC060} Maximum voltage regulator output iVrmaxi gt 0. Typical value 564. vrmax {EA6EE52B-F5DA-46f9-BAD1-BE972B273F75} Minimum voltage regulator output iVrmini lt 0. Typical value 453. vrmin {0860327B-4B57-48a5-9706-74094AFD5A25} Exciter voltage at which exciter saturation is defined iEfd1i gt 0. Typical value 56. efd1 {F08F3F8D-8662-45f4-AD1A-BEB7FEE3179D} Exciter voltage at which exciter saturation is defined iEfd2i gt 0. Typical value 42. efd2 {41A01F37-F323-4c67-9A92-30CE2FB348DB} Voltage regulator gain iKai gt 0. Typical value 400. ka {03228A76-BE94-4f26-B860-00C9E398C26D} Exciter constant related to selfexcited field iKei. Typical value 1. ke {451BE1C1-5B7C-46bc-9B68-DB5DC0C6D308} Excitation control system stabilizer gains iKfi gt 0. Typical value 003. kf {D2E4943C-0F89-4ec0-ABEA-F49597BA2BAE} Coefficient to allow different usage of the modelspeed coefficient iKsi. Typical value 0. ks {1E0D65A1-456B-4110-90F8-7C3790B29AAC} Voltage regulator time constant iTai gt 0. Typical value 002. ta {6B4E1E5A-E204-4cbf-B022-74BFDDD77626} Voltage regulator time constant iTbi gt 0. Typical value 0. tb {BC626702-7E36-4215-B5C1-1E7286874A62} Voltage regulator time constant iTci gt 0. Typical value 0. tc {D30ADC15-2E4D-4600-8D3E-937640013580} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 08. te {045D132D-6B82-41b6-9DEC-6DF3EC8956A8} Excitation control system stabilizer time constant iTf1i gt 0. Typical value 1. tf1 {860557C1-701D-4813-AFF8-B185E9BA931E} Excitation control system stabilizer time constant iTf2i gt 0. Typical value 08. tf2 {C41E6E85-D3BD-4292-BA31-B7183A786171} Excitation control system stabilizer time constant iTf3i gt 0. Typical value 0. tf3 {69E3D450-B233-46a6-9DBC-6A0683AEA478} Maximum voltage regulator output iVrmaxi gt 0. Typical value 73. vrmax {BEE0BE8F-A922-45b7-994D-25B52FF0CC3E} Minimum voltage regulator output iVrmini lt 0. Typical value 73. vrmin {28AF5082-2A16-44c7-B4F8-4FD082A59077} Voltage regulator gain iKai gt 0. Typical value 536. ka {A7731403-E017-4e7c-955F-A41E1A3DD9DC} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 0173. kc {9A9A7358-9DE1-46a2-B9E2-CE6D8469940D} Demagnetizing factor a function of exciter alternator reactances iKdi gt 0. Typical value 191. kd {CAEBEC6D-8FFF-4cee-99F9-1FB3BFC0F2ED} Exciter constant related to selfexcited field iKei. Typical value 16. ke {EB2EEAD0-A0AB-4ae6-9613-5D7E1B006685} Exciter field current limiter gain iKhi gt 0. Typical value 92. kh {FAEBB3F9-B56D-4aa8-B90E-534BE9C83391} Coefficient to allow different usage of the modelspeed coefficient iKsi. Typical value 0. ks {F831AE51-35B5-4a57-B59A-AC24ACE6DD63} Voltage regulator time constant iTai gt 0. Typical value 0086. ta {153515CD-B93B-43e4-BBF8-DCD57F6D4702} Voltage regulator time constant iTbi gt 0. Typical value 9. tb {642A2FDD-AC40-4349-9CC0-9358AAC57F8F} Voltage regulator time constant iTci gt 0. Typical value 3. tc {38A4158E-D871-4820-B539-634A7E974B94} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 1. te {8A3583C1-6CB1-4879-B732-36F3D17C8909} Exciter field current limiter time constant iThi gt 0. Typical value 008. th {1B667AFC-445F-44d4-969E-6D4C5D7075EE} Exciter field current limiter time constant iTji gt 0. Typical value 002. tj {7E6F9C8D-FD8A-4a6a-8194-C8421C5918EB} Voltage regulator time constant iTki gt 0. Typical value 018. tk {2779039C-0E11-4e07-A8A3-D52DDD878408} Maximum voltage regulator output iVamaxi gt 0. Typical value 75. vamax {FB7C2669-B608-4714-9AA5-6BEBD07786CB} Minimum voltage regulator output iVamini lt 0. Typical value 75. vamin {5F12009F-878A-461d-9557-7A7A608C3508} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub1subi gt 0. Typical value 74. ve1 {451C3C9E-6587-4302-8BF6-C8EC6458E094} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub2subi gt 0. Typical value 555. ve2 {816B5F46-3C4A-4c92-A43E-AD2F45E0635E} Exciter field current limit reference iVfelimi gt 0. Typical value 19. vfelim {0320EBBC-4157-41d8-B89B-74BE683D46F2} Maximum field current limiter signal reference iVhmaxi gt 0. Typical value 75. vhmax {67852D08-8666-4240-9B4D-80A822A8A507} Maximum voltage regulator output iVrmaxi gt 0. Typical value 44. vrmax {5C6320A9-77D7-44cc-B650-35E630F60C3A} Minimum voltage regulator output iVrmini lt 0. Typical value 36. vrmin {855503CC-0084-43fc-BD7A-BEF5A1700877} Voltage regulator gain iKai gt 0. Typical value 1. ka {AE2ADAD7-7C8D-4f20-AB70-C392F926C227} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 055. kc {10206005-EF47-4c2c-8B62-7C6FD521FFDA} Demagnetizing factor a function of exciter alternator reactances iKdi gt 0. Typical value 11. kd {28762860-6566-4c3a-AFD8-E600DDA0515F} Voltage regulator derivative gain iKdri gt 0. Typical value 10. kdr {900226F4-DE57-4f89-9954-9F2C176AC3BE} Exciter constant related to selfexcited field iKei. Typical value 1. ke {A4BC5E7C-FDF3-4bc1-85C7-9AF892FDC9B1} Voltage regulator integral gain iKiri gt 0. Typical value 5. kir {0FFC2183-22F8-4c58-A2C7-BF153EBB4669} Voltage regulator proportional gain iKpri gt 0 if ExcAC8B.kir 0. Typical value 80. kpr {6FFFB667-93A7-4df4-8AA5-1DB65D798B41} Coefficient to allow different usage of the modelspeed coefficient iKsi. Typical value 0. ks {0A3127D2-0C55-41db-A133-3C5EBF81A664} Voltage regulator time constant iTai gt 0. Typical value 0. ta {E819812F-A5E6-4d95-A17F-29F972239DCE} Lag time constant iTdri gt 0 if ExcAC8B.kdr gt 0. Typical value 01. tdr {5A5ECA69-94C4-4fd3-BF6B-228A68CC1420} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 12. te {4D9CF1B6-3B1F-4031-9661-20AD0F34332C} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub1subi gt 0. Typical value 65. ve1 {23243B6C-50EC-4fe6-AD64-A11C8EFE4A71} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub2subi gt 0. Typical value 9. ve2 {433C5A4B-817C-4e41-B123-D3B97C18B144} Minimum exciter voltage output iVemini lt 0. Typical value 0. vemin {8B86C726-9B1C-4878-A257-3F129F2701FC} Exciter field current limit reference iVfemaxi. Typical value 6. vfemax {97731F46-EFBE-4dc9-9143-4D0230C84986} Input signal maximum iVimaxi gt ExcAC8B.vimin. Typical value 35. vimax {F6AC54D3-E713-44ed-8D74-FF89FD84E4E6} Input signal minimum iVimini lt ExcAC8B.vimax. Typical value 10. vimin {5AE9EC54-9B83-4f18-BABA-3EB0C9028A62} PID maximum controller output iVpidmaxi gt ExcAC8B.vpidmin. Typical value 35. vpidmax {4E7A9EE1-57C4-48d7-9ED4-625DFD57413F} PID minimum controller output iVpidmini lt ExcAC8B.vpidmax. Typical value 10. vpidmin {7E28E92B-0369-4b37-9AEE-9CDBD2BC4E0D} Maximum voltage regulator output iVrmaxi gt 0. Typical value 35. vrmax {EE2188FA-EAFF-41c4-AB97-D9495752DE17} Minimum voltage regulator output iVrmini lt 0. Typical value 0. vrmin {69AFAABC-EE92-4e5e-9D45-48B61C9CAFFF} Minimum exciter current iIiisubFMNsubi. Typical value 52. ifmn {B2E05510-728E-47ff-BF08-6A64DBC713EA} Maximum exciter current iIiisubFMXsubi. Typical value 65. ifmx {B6032A3B-F568-4d25-9105-D7E159A835E5} Time constant iTiisub1subi gt 0. Typical value 20. t1 {7AE76CEF-0A13-45aa-A7A1-188D27D96E77} Time constant iTiisub2subi gt 0. Typical value 005. t2 {6CAFD655-B601-44af-89C1-0D8F1744EB00} Time constant iTiisub3subi gt 0. Typical value 16. t3 {27123279-7F75-41c1-BEA4-C6CDB5ED4489} Exciter time constant iTiisubBsubi gt 0. Typical value 004. tb {F8F7A5A5-C4DA-4208-B39F-A21351271BC1} Minimum AVR output iViisubRMNsubi. Typical value 52. vrmn {BCFF5C1E-9657-4715-851E-1978FDE307E0} Maximum AVR output iViisubRMXsubi. Typical value 65. vrmx {88942468-4BC0-4630-AB38-6F422297F6EE} Field voltage value 1 iEiisub1subi. Typical value 4.18. e1 {F0968B7A-CDE1-462f-9959-1A54BA4D46D0} Field voltage value 2 iEiisub2subi. Typical value 314. e2 {8149A099-621B-46cc-9044-99CA9D4D1D6E} AVR time constant iTiisubAsubi gt 0. Typical value 02. ta {B93768F2-3606-4934-BCDE-1A5B57C16192} AVR time constant iTiisubBsubi gt 0. Typical value 0. tb {224188FF-8FE9-4cc5-8A86-071C5ACBCD83} Exciter time constant iTiisubEsubi gt 0. Typical value 1. te {7CEAE241-2D1A-4508-AED1-F633A7C9F13D} Rate feedback time constant iTiisubFsubi gt 0. Typical value 1. tf {A30411E6-FF3B-4b06-97F9-CB37B7EF4C7D} Minimum AVR output iViisubRMNsubi. Typical value 6. vrmn {A289B08B-EEBD-441a-A78E-A80B872B9153} Maximum AVR output iViisubRMXsubi. Typical value 7. vrmx {E8550DDA-8354-4cf2-BED4-17CE3F1EDDB0} Field voltage value 1 iEiisub1subi. Typical value 418. e1 {61336F78-5B7B-4a2c-A542-BCF4FC5492ED} Field voltage value 2 iEiisub2subi. Typical value 314. e2 {6B0F93FE-3358-41ad-9C6F-DA6AB6A58362} AVR time constant iTiisubAsubi gt 0. Typical value 002. ta {A9B9C919-3A9F-4195-A822-5A45B9671E31} AVR time constant iTiisubBsubi gt 0. Typical value 0. tb {216DD169-CC2F-42a8-BC06-C39F3688D43B} Exciter time constant iTiisubEsubi gt 0. Typical value 1. te {E0707DDC-80EB-4163-8536-2D54F92D564E} Rate feedback time constant iTiisubF1subi gt 0. Typical value 1. tf1 {CD886EFF-83FC-4a14-AF12-1A3CF42EDAA9} Rate feedback time constant iTiisubF2subi gt 0. Typical value 1. tf2 {49DAB02A-2869-4e0c-B19F-F028A64D8761} Minimum AVR output iViisubRMNsubi. Typical value 6. vrmn {1FD120B2-9B1C-457a-B006-9B8580615946} Maximum AVR output iViisubRMXsubi. Typical value 7. vrmx {2DA5EE99-2CE5-49c9-BDDB-C032352B024C} Field voltage value 1 iEiisub1subi. Typical value 418. e1 {72BC9698-F45C-47b6-92E2-6602DFC95DD7} Field voltage value 2 iEiisub2subi. Typical value 314. e2 {9680892C-9DF4-4937-A2AF-931C06E69307} AVR time constant iTiisub1subi gt 0. Typical value 20. t1 {651B7916-2965-45c2-A45A-BF18E1031819} AVR time constant iTiisub2subi gt 0. Typical value 16. t2 {3FDCEBF6-27FE-46f1-8855-64ED04BDB427} AVR time constant iTiisub3subi gt 0. Typical value 066. t3 {7B9DA2EB-E0B6-45ab-A3D7-8C63B53FF519} AVR time constant iTiisub4subi gt 0. Typical value 007. t4 {7BD82A7B-8D4B-42eb-BBCF-20BCA49BA2BA} Exciter time constant iTiisubEsubi gt 0. Typical value 1. te {F1DA06DD-ABC7-40b0-BB8A-BF0499ED1911} Minimum AVR output iViisubRMNsubi. Typical value 75. vrmn {45A16AAB-0A9C-4541-BA35-E8842317C814} Maximum AVR output iViisubRMXsubi. Typical value 75. vrmx {A584648E-30C2-4222-8C60-AC89B820024E} AVR time constant iTiisub1subi gt 0. Typical value 48. t1 {59DD589B-F9E5-4750-8C5D-E74221CBB10B} Exciter current feedback time constant iTiisub1IFsubi gt 0. Typical value 60. t1if {31F029AD-BDA3-4743-8FEE-51C71B4547B2} AVR time constant iTiisub2subi gt 0. Typical value 15. t2 {2B018B3B-E937-4004-96D4-2C7060595CDE} AVR time constant iTiisub3subi gt 0. Typical value 0. t3 {38432108-372A-4e4e-993A-8CDD288EDF11} AVR time constant iTiisub4subi gt 0. Typical value 0. t4 {D9BBDDD6-1F2D-4a3c-8CAA-9DBDD4435730} Exciter current feedback time constant iTiisubIFsubi gt 0. Typical value 0. tif {90E8F3CA-8502-47c1-8001-AE5CA6D4E7F9} Minimum exciter output iViisubFMNsubi. Typical value 0. vfmn {E9C91C31-1B3B-4901-8CCF-16AE526BD84B} Maximum exciter output iViisubFMXsubi. Typical value 5. vfmx {5671C45F-B1ED-4400-BE00-2BCDF639191F} Minimum AVR output iViisubRMNsubi. Typical value 0. vrmn {8587DF68-50AD-457f-8C8F-0E077E853219} Maximum AVR output iViisubRMXsubi. Typical value 5. vrmx {029D4739-1000-4c40-A7C0-09640211675C} Gain iKai. ka {EBC15845-8713-47f1-AD4E-C17E60958F64} Effective output resistance iRexi. iRexi represents the effective output resistance seen by the excitation system. rex {6AFA7BBE-0963-416c-8F44-D6A207AB1A6C} Time constant iTai gt 0. ta {2C8B57D6-36B8-4c1b-87BD-D24E736A060A} Lead coefficient iAiisub1subi. Typical value 05. a1 {196174DD-4376-4150-8F4A-4368B56689D5} Lag coefficient iAiisub2subi. Typical value 05. a2 {FA22708D-C3EE-45a2-93D9-91141AF23031} Lead coefficient iAiisub3subi. Typical value 05. a3 {2FAC3642-93C6-4413-8398-C079BC90B038} Lag coefficient iAiisub4subi. Typical value 05. a4 {AFDAA8C5-E3DC-420d-988E-2EFC6D7D5D36} Lead coefficient iAiisub5subi. Typical value 05. a5 {ED5A3254-D62E-4992-BEC9-755DF6A78E12} Lag coefficient iAiisub6subi. Typical value 05. a6 {7DC32CE4-9972-4dc5-8DE1-5DE9BA9FE662} Gain iKiisub1subi. Typical value 1. k1 {4A6DD00D-64C8-494f-8D5A-5B2F62787C5D} Gain iKiisub3subi. Typical value 3. k3 {9CB43529-C4F6-470a-A664-E4FB91AEC080} Gain iKiisub5subi. Typical value 1. k5 {9ADE7B33-9FAD-4e9b-A36B-B86449ACCCD0} Lead time constant iTiisub1subi gt 0. Typical value 005. t1 {43083702-C3C1-4677-BA7C-CCD6A4BC9EC4} Lag time constant iTiisub2subi gt 0. Typical value 01. t2 {3F2C4181-F0B0-468d-ACFA-D9300FDE2E43} Lead time constant iTiisub3subi gt 0. Typical value 01. t3 {154137D3-A722-40e2-BFD0-C3E02AD81C79} Lag time constant iTiisub4subi gt 0. Typical value 01. t4 {CB67E69D-B186-444a-A354-0A61C78BDABD} Lead time constant iTiisub5subi gt 0. Typical value 01. t5 {194D05E2-5C64-4ad4-9D1F-7C3253157A8D} Lag time constant iTiisub6subi gt 0. Typical value 01. t6 {527EE729-CEC3-4bd3-9060-9F38689C8939} Leadlag maximum limit iVmax1i gt ExcAVR7.vmin1. Typical value 5. vmax1 {D504839B-89AE-4aa9-B9EF-2330E0E8C47E} Leadlag maximum limit iVmax3i gt ExcAVR7.vmin3. Typical value 5. vmax3 {6D8971E0-CAC4-42f3-BCC9-21C2D0920B9E} Leadlag maximum limit iVmax5i gt ExcAVR7.vmin5. Typical value 5. vmax5 {5D4CF79B-C420-43e6-8169-561C272B92EF} Leadlag minimum limit iVmin1i lt ExcAVR7.vmax1. Typical value 5. vmin1 {6590DD33-A1E9-470c-917F-8CE98671D135} Leadlag minimum limit iVmin3i lt ExcAVR7.vmax3. Typical value 5. vmin3 {32C653FE-DE5F-43e6-994E-B269E48680AB} Leadlag minimum limit iVmin5i lt ExcAVR7.vmax5. Typical value 2. vmin5 {88126C3E-316A-47ae-8695-D6409D993DF5} Maximum open circuit exciter voltage iEfdmaxi gt ExcBBC.efdmin. Typical value 5. efdmax {9F81FD3E-073B-4fc6-B597-D204BFE9CC71} Minimum open circuit exciter voltage iEfdmini lt ExcBBC.efdmax. Typical value 5. efdmin {E4A16661-A353-491e-A262-00817AF8A499} Steady state gain iKi not 0. Typical value 300. k {1F130B2E-C2CA-4758-9072-000D8A972125} Controller time constant iT1i gt 0. Typical value 6. t1 {90A1697C-9CF0-47f0-A9F9-AA8CD92588C1} Controller time constant iT2i gt 0. Typical value 1. t2 {F85E3E82-9BC6-440f-A427-BFC1CF45A2B3} Leadlag time constant iT3i gt 0. If 0 block is bypassed. Typical value 005. t3 {F383DE01-0A73-418d-AC0D-D4EE4C0A121D} Leadlag time constant iT4i gt 0. If 0 block is bypassed. Typical value 001. t4 {B43932C1-CF21-4614-B36F-F9A1E216BA16} Maximum control element output iVrmaxi gt ExcBBC.vrmin. Typical value 5. vrmax {50E27DDA-9C9A-4960-AF68-94DF8F274E5F} Minimum control element output iVrmini lt ExcBBC.vrmax. Typical value 5. vrmin {275A0816-F302-42e8-977B-7FF9476BFD66} Effective excitation transformer reactance iXei gt 0. iXei models the regulation of the transformerrectifier unit. Typical value 005. xe {A2A1F16A-DBA5-4ba5-83A7-D4D71E5F5446} Exciter output maximum limit iEfdmaxi gt ExcCZ.efdmin. efdmax {EB41FA00-3E29-4a90-8A05-231D04B744E8} Exciter output minimum limit iEfdmini lt ExcCZ.efdmax. efdmin {CC9F5385-763B-4173-BB1B-FAFE42AC419D} Regulator gain iKai. ka {760C25A4-4A6E-45c8-9BAE-E50DF38FAA9C} Exciter constant related to selfexcited field iKei. ke {9125399D-FB15-4ec6-8871-FD2DC8A83CD2} Regulator proportional gain iKpi. kp {A335F6F8-CD40-4e96-AABB-ED690A6D9EE5} Regulator time constant iTai gt 0. ta {A4F99E86-EA26-45d1-AB2F-244CD5C02053} Regulator integral time constant iTci gt 0. tc {6741D922-B5C3-4886-9F09-4BFAE6B2355E} Exciter time constant integration rate associated with exciter control iTei gt 0. te {42D29AF6-A917-4e00-B021-803E179A99C5} Voltage regulator maximum limit iVrmaxi gt ExcCZ.vrmin. vrmax {BAD659A4-7D75-4f7d-BA8D-01DFE315604E} Voltage regulator minimum limit iVrmini lt ExcCZ.vrmax. vrmin {5E3F9034-9E8F-485e-A498-0049FEEB8803} Exciter voltage at which exciter saturation is defined iEfdiisub1subi gt 0. Typical value 31. efd1 {DF840D65-1F12-4b17-B146-9F100B9CD916} Exciter voltage at which exciter saturation is defined iEfdiisub2subi gt 0. Typical value 23. efd2 {D83C1CDB-1157-4161-97BE-7742654C8FFD} Maximum voltage exciter output limiter iEfdmaxi gt ExcDC1A.efdmin. Typical value 99. efdmax {61BD7FD2-0EE0-4af8-961A-EA51D0B346E7} Minimum voltage exciter output limiter iEfdmini lt ExcDC1A.edfmax. Typical value 99. efdmin {3DBD90DD-D2A4-4518-AEFF-7548D36B198E} Voltage regulator gain iKai gt 0. Typical value 46. ka {9509127B-2876-4710-9888-EDFD807A70FA} Exciter constant related to selfexcited field iKei. Typical value 0. ke {21EED69E-A3FC-404e-A639-785EED726346} Excitation control system stabilizer gain iKfi gt 0. Typical value 01. kf {A08DC504-8361-4e94-B831-C3E145AEB8E6} Coefficient to allow different usage of the modelspeed coefficient iKsi. Typical value 0. ks {86B5E9E1-9A78-4202-AE38-019AF7A232A9} Voltage regulator time constant iTai gt 0. Typical value 006. ta {9D86E198-2BEA-4bef-AEEF-F76EFF2CA4CB} Voltage regulator time constant iTbi gt 0. Typical value 0. tb {46B6BF64-195E-4273-9366-A6777C7DE37B} Voltage regulator time constant iTci gt 0. Typical value 0. tc {76BBF27B-C3BF-41ce-93CA-8EB2C54040CE} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 046. te {68423BE2-5E8E-42dc-BEF8-27AD298DE9E3} Excitation control system stabilizer time constant iTfi gt 0. Typical value 1. tf {77AAB9FA-E624-4014-B29A-4BA3A6B5F3E3} Maximum voltage regulator output iVrmaxi gt ExcDC1A.vrmin. Typical value 1. vrmax {8DB84FA2-3224-4e24-821E-BE3C8CB84A03} Minimum voltage regulator output iVrmini lt 0 and lt ExcDC1A.vrmax. Typical value 09. vrmin {3D7D1F82-F8C9-4f51-88A5-0B966FFC9BF0} Exciter voltage at which exciter saturation is defined iEfdiisub1subi gt 0. Typical value 305. efd1 {D54B4BB7-E73F-4b62-BE60-336F6EE389DE} Exciter voltage at which exciter saturation is defined iEfdiisub2subi gt 0. Typical value 229. efd2 {4D68505E-8C1F-4605-BC89-62066F53390E} Voltage regulator gain iKai gt 0. Typical value 300. ka {BEC8EA04-832F-496f-BF27-0466E1E49518} Exciter constant related to selfexcited field iKei. If iKei is entered as zero the model calculates an effective value of iKei such that the initial condition value of iVri is zero. The zero value of iKei is not changed. If iKei is entered as nonzero its value is used directly without change. Typical value 1. ke {D9F42883-4AC5-4ed2-9AA0-CF161C164F27} Excitation control system stabilizer gain iKfi gt 0. Typical value 01. kf {3DF80536-8C42-4700-B72C-BCD925C660DD} Coefficient to allow different usage of the modelspeed coefficient iKsi. Typical value 0. ks {DCA9D6C9-32D2-4215-83DE-E3F7A471D29F} Voltage regulator time constant iTai gt 0. Typical value 001. ta {09C25A19-6B41-4bd2-94C9-A1F1F17898E3} Voltage regulator time constant iTbi gt 0. Typical value 0. tb {994D7AE3-3AA2-451d-BBCC-8B20294F55FD} Voltage regulator time constant iTci gt 0. Typical value 0. tc {02CAD757-4456-45b6-BE3C-843FF2395842} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 133. te {3944CB75-6F6F-45a9-A739-CA9759F75037} Excitation control system stabilizer time constant iTfi gt 0. Typical value 0675. tf {165C91F7-A642-44bd-BDDF-412C37A532BB} Excitation control system stabilizer time constant iTf1i gt 0. Typical value 0. tf1 {8B984ACA-F3A6-4724-A430-5697AB3EA828} Maximum voltage regulator output iVrmaxi gt ExcDC2A.vrmin. Typical value 495. vrmax {B8A724CB-E640-46ee-85E2-EEA809086A32} Minimum voltage regulator output iVrmini lt 0 and lt ExcDC2A.vrmax. Typical value 49. vrmin {15F76A7F-59C8-42c4-9DAB-0D96AEC3936A} Exciter voltage at which exciter saturation is defined iEfdiisub1subi gt 0. Typical value 26. efd1 {D5676F58-83D1-4091-B934-854BD2CA3C47} Exciter voltage at which exciter saturation is defined iEfdiisub2subi gt 0. Typical value 345. efd2 {6BF4B03E-D9E2-453c-BE5D-4D91960F92C1} Maximum voltage exciter output limiter iEfdmaxi gt ExcDC3A.efdmin. Typical value 99. efdmax {498DB7CD-9032-4008-ADF1-F2574D076BDE} Minimum voltage exciter output limiter iEfdmini lt ExcDC3A.efdmax. Typical value 99. efdmin {DD698FDA-DCEB-43ef-A000-6CCB1F0DF250} Exciter constant related to selfexcited field iKei. Typical value 1. ke {78499E44-C695-45a5-B738-D9A4D8844548} Deadband iKri. Typical value 0. kr {148979D4-0B77-42c4-9BAA-56075D3A2757} Coefficient to allow different usage of the modelspeed coefficient iKsi. Typical value 0. ks {705605E6-1E16-4517-ADD9-80037B2E6620} Fast raiselower contact setting iKvi gt 0. Typical value 005. kv {A653E9A1-AF68-45dc-9E00-458445317A53} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 183. te {0DE9A386-04CE-4b52-8BC6-4131FFA31E45} Rheostat travel time iTrhi gt 0. Typical value 20. trh {85AE9738-7E7E-4766-9AF0-660A6684FD26} Maximum voltage regulator output iVrmaxi gt 0. Typical value 5. vrmax {3B33D6E7-C29A-4c80-87D6-C5E98BFE6D73} Minimum voltage regulator output iVrmini lt 0. Typical value 0. vrmin {352E2AD3-83BD-4a71-845F-7098FC11F276} Voltage regulator gain iKai gt 0. Typical value 300. ka {309F4A01-7334-4338-ACBE-FC12385008A4} Exciter constant related to selfexcited field iKei. Typical value 1. ke {62BC2CBD-2354-41f3-A8DA-0FD8FD23B70B} Excitation control system stabilizer gain iKfi gt 0. Typical value 01. kf {80AB00D2-F3AD-447b-8A0A-D3FD94D6789C} Potential circuit gain coefficient iKii gt 0. Typical value 483. ki {BD06810C-D2A1-4606-A0D7-367E1EAD3395} Potential circuit gain coefficient iKpi gt 0. Typical value 437. kp {08D978EC-2BE0-456d-8C3F-97F82853D433} Voltage regulator time constant iTai gt 0. Typical value 001. ta {310CB6C7-79B4-4eaf-A95E-02E5E36401C6} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 183. te {AE3B830F-EEF4-4f8e-90AA-8C809F79D2C9} Excitation control system stabilizer time constant iTfi gt 0. Typical value 0675. tf {1F94B88E-18DA-4b08-BB7C-42739AFD0D1C} Available exciter voltage limiter iVb1maxi gt 0. Typical value 1163. vb1max {0C95D484-6CE9-459c-97B8-EA0999B67EA1} Available exciter voltage limiter iVbmaxi gt 0. Typical value 1163. vbmax {0F23089F-5703-4833-B551-F4C107B8C6F0} Maximum voltage regulator output iVrmaxi gt ExcDC3A1.vrmin. Typical value 5. vrmax {3170F84A-9B4D-41e7-9FB3-32046D34168B} Minimum voltage regulator output iVrmini lt 0 and lt ExcDC3A1.vrmax. Typical value 0. vrmin {1CEEED34-DDB2-4274-B861-F379107AC52D} Controller follow up deadband iDpnfi. Typical value 0. dpnf {8DA7F27D-8DC1-499e-A513-DBCFF0890060} Maximum open circuit excitation voltage iEfmaxi gt ExcELIN1.efmin. Typical value 5. efmax {774E92D6-C600-4466-8DD0-49AEF1B7DB6A} Minimum open circuit excitation voltage iEfmini lt ExcELIN1.efmax. Typical value 5. efmin {1473307C-E535-4d62-AE34-BA06F3C297B7} Stabilizer gain 1 iKs1i. Typical value 0. ks1 {BABB3E98-9806-4b01-A489-2BAE2F6AD136} Stabilizer gain 2 iKs2i. Typical value 0. ks2 {70AAE9B2-0BE6-48f9-8FF5-22AF486BC9FC} Stabilizer limit output ismaxi. Typical value 01. smax {F054A7E6-98D8-43ea-A078-6426905BEB67} Current transducer time constant iTfii gt 0. Typical value 0. tfi {8D350F6E-3F82-40c5-96BD-DD9A6517052E} Controller reset time constant iTnui gt 0. Typical value 2. tnu {794F6994-594A-4bcc-B6F8-4E407A605E31} Stabilizer phase lag time constant iTs1i gt 0. Typical value 1. ts1 {82337C41-79CF-41f8-A0D5-D02DDAF9C3DC} Stabilizer filter time constant iTs2i gt 0. Typical value 1. ts2 {9CA2D61A-1543-4718-93F8-D28B6117D56F} Stabilizer parameters iTswi gt 0. Typical value 3. tsw {16AEF105-37E0-4336-93B1-38E7440E4E5F} Current controller gain iVpii. Typical value 1245. vpi {8D95EEA3-BA68-4e3f-A24B-70DC4324CF07} Controller follow up gain iVpnfi. Typical value 2. vpnf {6EA8457D-5E55-4721-AF8F-1B8FC6047406} Voltage controller proportional gain iVpui. Typical value 345. vpu {9AE6BCD9-9C64-4d4a-AD0D-B049360639A8} Excitation transformer effective reactance iXei gt 0. iXei represents the regulation of the transformerrectifier unit. Typical value 006. xe {0C969D61-FACF-4955-BF20-6C03123BA122} Gain iEfdbasi. Typical value 01. efdbas {2F21471A-EC42-4867-B11E-875DC711E705} Limiter iIiisubefmaxsubi gt ExcELIN2.iefmin. Typical value 1. iefmax {C87B64FC-4A25-4fdd-BBA7-B83C8B821481} Minimum open circuit excitation voltage iIiisubefmax2subi. Typical value 5. iefmax2 {038C1B2D-0FD7-4b5a-97EA-39F850C20DE4} Limiter iIiisubefminsubi lt ExcELIN2.iefmax. Typical value 1. iefmin {3D43519F-E015-4e79-BC8C-878E36821501} Voltage regulator input gain iK1i. Typical value 0. k1 {ECBDDE37-48FD-41bf-872E-709BB56CBC09} Voltage regulator input limit iK1eci. Typical value 2. k1ec {17BD4F54-11D1-430c-9D68-CA52FA2DA4AC} Gain iK2i. Typical value 5. k2 {0BFB6D4F-FC1F-4162-9F15-50CD38CE72DC} Gain iK3i. Typical value 01. k3 {8748E875-F144-4b9d-931D-38B64E2FFFB4} Gain iK4i. Typical value 0. k4 {7D76F6E1-2BE5-4248-8761-1D3D8C267986} Voltage controller derivative gain iKd1i. Typical value 345. kd1 {584155BF-C74A-46ea-BDFE-E3398CDC9818} Gain iKe2i. Typical value 01. ke2 {526BB79F-1051-4df0-8DC5-6A33E71AD86D} Gain iKetbi. Typical value 006. ketb {647255F7-20F2-4285-A5E4-5C8634E54BF5} Controller follow up gain iPID1maxi. Typical value 2. pid1max {F253771A-A2A6-4c43-A365-D29B8E2DA2ED} Exciter saturation function value at the corresponding exciter voltage iVeiisub1subi back of commutating reactance iSeVeiisub1subiii gt 0. Typical value 0. seve1 {F6296057-FE7D-4eee-9300-D6AA66715CE1} Exciter saturation function value at the corresponding exciter voltage iVeiisub2subi back of commutating reactance iSeVeiisub2subiii gt 0. Typical value 1. seve2 {FCBCE510-E759-4711-B2AA-D6C9395CFDA1} Voltage controller derivative washout time constant iTb1i gt 0. Typical value 1245. tb1 {F89AE461-A01B-4b91-A917-D2444D85FD6B} Time constant iTei gt 0. Typical value 0. te {53643157-4D99-4d0b-9F16-A89D1E9F33B5} Time Constant iTiisube2subi gt 0. Typical value 1. te2 {5E827928-1848-40fc-B725-3A9E6C4A43BD} Controller follow up deadband iTi1i. Typical value 0. ti1 {066AB817-A741-41f7-89D9-144CAC48D20F} Time constant iTiisubi3subi gt 0. Typical value 3. ti3 {A165BDBA-BD55-4db1-8F0C-FDD0F9CF7C8F} Time constant iTiisubi4subi gt 0. Typical value 0. ti4 {D7156E6A-F2BA-441d-A15F-A78EE075DCA5} Time constant iTiisubr4subi gt 0. Typical value 1. tr4 {913CA1E6-2AD9-4592-BCC0-96215D96A04C} Limiter iUpmaxi gt ExcELIN2.upmin. Typical value 3. upmax {E5BC43CE-77C2-4e89-86B6-259830DB9D6F} Limiter iUpmini lt ExcELIN2.upmax. Typical value 0. upmin {D9F15DCB-3132-48b6-AE14-7C826FDCDAE4} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub1subi gt 0. Typical value 3. ve1 {E7512511-C071-4cdf-805F-8675785FFC3C} Exciter alternator output voltages back of commutating reactance at which saturation is defined iVeiisub2subi gt 0. Typical value 0. ve2 {98DE2F91-766B-4439-8A12-CA3C607B68D7} Excitation transformer effective reactance iXpi. Typical value 1. xp {3109B1D6-F6C5-41f8-B850-AE86524F08EE} Major loop PI tag gain factor iAei. Typical value 3. ae {BC83E18F-8696-46ab-AD0D-214C5408CCC5} Minor loop PI tag gain factor iAii. Typical value 22. ai {7331960F-40B3-4b07-BD38-822DFBB4D615} AVR constant iAtri. Typical value 219. atr {5AB2421B-3BB8-4329-B61B-DB8BCDE50A84} Field voltage control signal upper limit on AVR base iEmaxi gt ExcHU.emin. Typical value 0996. emax {BF3D01CF-6DF9-48a5-B394-0E929BC0AB3C} Field voltage control signal lower limit on AVR base iEmini lt ExcHU.emax. Typical value 0866. emin {E82E172A-9B05-4b7b-AF24-63B5827AD210} Major loop PI tag output signal upper limit iImaxi gt ExcHU.imin. Typical value 219. imax {50EB6DCF-C9CD-4914-A094-EE436B4CF66E} Major loop PI tag output signal lower limit iImini lt ExcHU.imax. Typical value 01. imin {F1D01FB7-E392-4e38-8C36-5AB486BAA2CD} Major loop PI tag integration time constant iTei gt 0. Typical value 0154. te {C920CCDB-C188-488f-8790-E4BCAFB35086} Minor loop PI control tag integration time constant iTii gt 0. Typical value 001333. ti {2DB6BEBD-74C9-4c4a-A69A-D749D23E2F64} Filter time constant iTri gt 0. If a voltage compensator is used in conjunction with this excitation system model iTr ishould be set to 0. Typical value 001. tr {F6185168-7343-4599-9604-74DCA438EC8D} Voltage regulator gain iKiisubAsubi gt 0. Typical value 400. ka {422F3744-4BB7-4279-9813-238F008AA6B6} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 02. kc {ADF175C9-0B78-4198-AC11-A61527C32D8C} Demagnetizing factor a function of exciter alternator reactances iKiisubDsubi gt 0. Typical value 038. kd {89A199F4-1563-4311-A0C0-2225481E572B} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 1. ke {801AA38F-5121-4451-874B-85921A47CCBC} Excitation control system stabilizer gains iKiisubFsubi gt 0. Typical value 003. kf {9F683D12-4F2E-49c1-8338-75CB67113480} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 002. ta {6CA20ECC-DDAA-44e5-B577-51A9EEAF8658} Voltage regulator time constant iTiisubBsubi gt 0. Typical value 0. tb {E2F44D64-E0D0-4a72-9F18-D0115CA2BDE8} Voltage regulator time constant iTiisubCsubi gt 0. Typical value 0. tc {10EDA76F-18B2-493e-9D48-76AFF514CFAF} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 08. te {DBC3C0BE-5012-414f-9B64-C20DB7056D86} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 1. tf {1857FDC3-641A-40e5-867F-919BEF7F32DE} Maximum voltage regulator output iViisubAMAXsubi gt 0. Typical value 145. vamax {F835D8D9-3026-4b74-85A3-4D729D719D55} Minimum voltage regulator output iViisubAMINsubi lt 0. Typical value 145. vamin {2991ABA6-E532-436e-BA2E-14C4CC17F9E3} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE1subi gt 0. Typical value 418. ve1 {967C0B25-6A55-4e27-B4D4-6405847CC680} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE2subi gt 0. Typical value 314. ve2 {AAB76517-7499-4e01-9B51-F6E9D57FCD56} Maximum voltage regulator outputs iViisubRMAXsubi gt 0. Typical value 603. vrmax {13EF1600-1749-4605-9945-F3D79DBAA0F2} Minimum voltage regulator outputs iViisubRMINsubi lt 0. Typical value 543. vrmin {A1499EF8-A8C9-4e5e-BB4C-60CF118920A0} Voltage regulator gain iKiisubAsubi gt 0. Typical value 400. ka {2EDB427D-57E7-4e1e-9048-7B1B536E481F} Second stage regulator gain iKiisubBsubi gt 0. Typical value 25. kb {4C73167B-A51B-4864-873E-E4C706F2B2FD} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 028. kc {E68C1671-C804-402d-9E2C-E346CA7A5378} Demagnetizing factor a function of exciter alternator reactances iKiisubDsubi gt 0. Typical value 035. kd {4A2F459F-D1C5-4bb9-BED3-5E6D15CD4FAC} Exciter constant related to selfexcited field iKiisubEsubi gt 0. Typical value 1. ke {D154DC6A-6969-46ba-BE29-1579BDADF866} Excitation control system stabilizer gains iKiisubFsubi gt 0. Typical value 003. kf {DE92DC78-8990-41bb-9D7B-6A1FA9704D0A} Exciter field current feedback gain iKiisubHsubi gt 0. Typical value 1. kh {40883B6C-96C0-4f3a-89CD-26548BB301AA} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 002. ta {F077885D-32E4-4480-AADC-E11F8CE0286E} Voltage regulator time constant iTiisubBsubi gt 0. Typical value 0. tb {BF33A5C3-7CD8-444e-B506-E0BA1070FEA1} Voltage regulator time constant iTiisubCsubi gt 0. Typical value 0. tc {9F098821-F066-48dc-AF8D-8EEAD3D5090D} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 06. te {154F04ED-1246-45f3-B0F7-D36125F3E2E6} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 1. tf {DE67A466-8AED-4b4d-928A-20113D538548} Maximum voltage regulator output iViisubAMAXsubi gt 0. Typical value 8. vamax {99E14896-6F9F-4518-B9A4-D204AE39A15F} Minimum voltage regulator output iViisubAMINsubi lt 0. Typical value 8. vamin {237F427A-6BF9-485b-81A1-2780DF676B7D} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE1subi gt 0. Typical value 44. ve1 {9DA21252-EF9B-419c-9FC1-AA90CA08684C} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE2subi gt 0. Typical value 33. ve2 {EF09F7B9-7772-4b96-B62E-3502B3D78ABD} Exciter field current limit reference iViisubFEMAXsubi gt 0. Typical value 44. vfemax {3C860302-3698-49d3-AD1F-5EDF16F5EA76} Maximum voltage regulator outputs iViisubRMAXsubi gt 0. Typical value 105. vrmax {8C6974E9-342B-49e9-ABE8-0859D97E9F79} Minimum voltage regulator outputs iViisubRMINsubi lt 0. Typical value 95. vrmin {53B974C7-AF78-4cee-9923-FBCB8DEC8B4E} Value of iEfd iat which feedback gain changes iEiisubFDNsubi gt 0. Typical value 236. efdn {864D9154-B21E-4a25-803D-D3C0B11CA22E} Voltage regulator gain iKiisubAsubi gt 0. Typical value 4562. ka {0F09588A-2B6D-42d2-8F74-3D9C9F9E2DFB} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 0104. kc {C777575A-38BB-4bf3-8D57-6E1E19605F63} Demagnetizing factor a function of exciter alternator reactances iKiisubDsubi gt 0. Typical value 0499. kd {69F8D527-E190-4d33-BC11-3F0F32E5800B} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 1. ke {904780F8-4B44-4280-81FE-D2F06366238B} Excitation control system stabilizer gains iKiisubFsubi gt 0. Typical value 0143. kf {BE0A49FE-F1FB-4f4c-9DB7-9EF4F4BFDD68} Excitation control system stabilizer gain iKiisubNsubi gt 0. Typical value 005. kn {E62B02A0-3D26-4d31-B014-52CF8A6AA801} Constant associated with regulator and alternator field power supply iKiisubRsubi gt 0. Typical value 377. kr {294108EE-3FE8-4422-B067-0C0632E9CA2C} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 0013. ta {6C44479B-D961-480d-9BA3-B72474A3F504} Voltage regulator time constant iTiisubBsubi gt 0. Typical value 0. tb {F92DF8C8-73FC-4805-8FD3-85887C40BD73} Voltage regulator time constant iTiisubCsubi gt 0. Typical value 0. tc {360E7C25-8D5A-4ea6-BE04-A8716C84D971} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 117. te {868CB845-BE97-44c6-9FDD-1E82BBAF6D59} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 1. tf {C5699D2E-1512-435f-A9B4-CFF2FB1E331F} Maximum voltage regulator output iViisubAMAXsubi gt 0. Typical value 1. vamax {1632BA35-0E9A-4981-9472-459D6A8B8820} Minimum voltage regulator output iViisubAMINsubi lt 0. Typical value 095. vamin {336961B2-4063-49fd-B0C9-0A1A85FB59F0} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE1subi gt 0. Typical value 624. ve1 {AB093CA9-F86B-407c-8185-8F189C3F59C1} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE2subi gt 0. Typical value 468. ve2 {94842F29-3DE3-4757-B4CA-F80C66CBD78F} Minimum exciter voltage output iViisubEMINsubi lt 0. Typical value 0. vemin {41BD01F0-65F5-4941-B475-B57816110BB9} Exciter field current limit reference iViisubFEMAXsubi gt 0. Typical value 16. vfemax {26E18DDB-ECC8-4144-B75A-6FEFB5EDF5DA} Voltage regulator gain iKiisubAsubi gt 0. Typical value 200. ka {9AB26A1E-52C8-4393-9C86-13451850938A} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 0. kc {72677163-64C6-4fc7-BC4E-79BD50DBCBE4} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 0015. ta {4E53AB2E-DD96-47f5-A69A-ABB80AB323FA} Voltage regulator time constant iTiisubBsubi gt 0. Typical value 10. tb {B22D2038-5472-4e5a-9B48-8A1E9AB9E001} Voltage regulator time constant iTiisubCsubi gt 0. Typical value 1. tc {973A6F6F-D83F-4bc6-A26C-82FC4AB05503} Maximum voltage regulator input limit iViisubIMAXsubi gt 0. Typical value 10. vimax {36DB172A-A77F-47b8-958E-F265EA56732F} Minimum voltage regulator input limit iViisubIMINsubi lt 0. Typical value 10. vimin {C61F0260-BDDC-4693-B6AF-6E1D3690A9D4} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 564. vrmax {AB4B512D-CAE1-48f3-A269-72829A73F949} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 453. vrmin {3EE0C72D-BEDA-4af9-9894-592D01C4ECF7} Exciter voltage at which exciter saturation is defined iEiisubFD1subi gt 0. Typical value 56. efd1 {2B4A383D-8271-4e5b-A24E-05637698A45C} Exciter voltage at which exciter saturation is defined iEiisubFD2subi gt 0. Typical value 42. efd2 {ADCA5CA8-3A6E-4238-B289-A06FF1C821B2} Voltage regulator gain iKiisubAsubi gt 0. Typical value 400. ka {A8961E8E-AAE9-42db-93BB-EEE2CD983C50} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 1. ke {9F699065-33E5-4a5f-90EC-87CF4F628A78} Excitation control system stabilizer gains iKiisubFsubi gt 0. Typical value 003. kf {DC2E9E76-F2A4-442e-A667-19CAB1E030F9} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 002. ta {A943B68C-2020-44ea-9C86-6EA70F69DC34} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 08. te {AA064651-8A19-4434-A193-164E7D345A93} Excitation control system stabilizer time constant iTiisubF1subi gt 0. Typical value 1. tf1 {76CD8473-50F8-4338-B03A-480300BAAEF5} Excitation control system stabilizer time constant iTiisubF2subi gt 0. Typical value 1. tf2 {C7A1A86E-E15A-4a00-B8E9-1A9313042784} Excitation control system stabilizer time constant iTiisubF3subi gt 0. Typical value 1. tf3 {552065B1-F131-4549-91D4-7D76958389BA} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 73. vrmax {B1D2A1BF-6D2A-4fe7-ABEE-F26033355816} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 73. vrmin {60DCF610-2D43-415c-ADF3-E1AA1CA569F1} Voltage regulator gain iKiisubAsubi gt 0. Typical value 536. ka {FE78FC51-23B9-4df8-8614-512B1299EE6D} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 0173. kc {23EDD8E0-2455-47cb-B36C-7EB67F2E4635} Demagnetizing factor a function of exciter alternator reactances iKiisubDsubi gt 0. Typical value 191. kd {333DF1C4-8EB3-45fd-956A-70A076B099B5} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 16. ke {C1D1EF1C-F937-4798-83CE-B483F50EB76E} Exciter field current limiter gain iKiisubHsubi gt 0. Typical value 92. kh {C7875C48-1FBE-4d83-8A62-C5FDE342DBD7} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 0086. ta {8B90697C-75D8-453e-A971-67A14487F2F3} Voltage regulator time constant iTiisubBsubi gt 0. Typical value 9. tb {5CCA364B-1C85-498c-90A2-58472E7CA12E} Voltage regulator time constant iTiisubCsubi gt 0. Typical value 3. tc {EAD3C0C3-CEDC-4c23-AE4F-A00F5868D0E1} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 1. te {F555AF9A-CB0E-41e7-8430-DFCDCA58A072} Exciter field current limiter time constant iTiisubHsubi gt 0. Typical value 008. th {AC33F7B8-4102-4722-A49B-4CD3CFE944C3} Exciter field current limiter time constant iTiisubJsubi gt 0. Typical value 002. tj {75B5A038-7801-4e7d-B08E-EF9DCD7E916D} Voltage regulator time constant iTiisubKsubi gt 0. Typical value 018. tk {6678A090-4326-4e44-950E-FEEDBCABF49B} Maximum voltage regulator output iViisubAMAXsubi gt 0. Typical value 75. vamax {25C89DD8-4CDF-42a3-8419-F4AC2927A4B0} Minimum voltage regulator output VsubAMINsub lt 0. Typical value 75. vamin {8F2B92CA-C682-451c-82A9-BA1DF142FB0C} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE1subi gt 0. Typical value 74. ve1 {814FF27D-8BEF-45d7-984E-769F1E947C4D} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE2subi gt 0. Typical value 555. ve2 {054376B1-9EEF-4042-BB73-0570FBC4FA41} Exciter field current limit reference iViisubFELIMsubi gt 0. Typical value 19. vfelim {7D0D4187-3818-4640-A983-82B292E7DF6C} Maximum field current limiter signal reference iViisubHMAXsubi gt 0. Typical value 75. vhmax {FEB707E7-3359-4e2b-9F80-D6F3F15DBF34} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 44. vrmax {E277A280-2EB7-4dcd-9964-E26FD79A88C2} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 36. vrmin {732F3742-A6D2-4184-89E3-3FC6A3F522D2} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 018. kc {5C544B08-73B4-4cac-894C-8B4D7A9387EF} Demagnetizing factor a function of exciter alternator reactances iKiisubDsubi gt 0. Typical value 002. kd {73BB310A-BA6B-48b9-AD58-F34CD179C2D0} Voltage regulator derivative gain iKiisubDRsubi gt 0. Typical value 0. kdr {85A8C730-0B18-4e36-9ADC-BE178F6EB83E} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 1. ke {F170FAA1-4646-40b5-AD48-62822291B736} Excitation control system stabilizer gain iKiisubF1subi gt 0. Typical value 0212. kf1 {682E62AD-F51A-4d03-8F0E-5BC8B6A5208E} Excitation control system stabilizer gain iKiisubF2subi gt 0. Typical value 0. kf2 {78BC81DB-2697-49ff-B38C-173D84A7B0C2} Excitation control system stabilizer gain iKiisubF3subi gt 0. Typical value 0. kf3 {7034D99F-AF65-4408-9C18-9E45CC4D639E} Voltage regulator integral gain iKiisubIAsubi gt 0. Typical value 5969. kia {9C2C1ECC-C260-4f76-88C6-12CE3F5B054E} Voltage regulator integral gain iKiisubIRsubi gt 0. Typical value 424. kir {3154DF6C-2586-4a39-B2DB-E28C520ED324} Exciter field voltage lower limit parameter iKiisubLsubi. Typical value 10. kl {A63F07A4-63CD-44da-B7FD-64875FCFCE74} Potential circuit gain coefficient iKiisubPsubi gt 0. Typical value 496. kp {A42C8F39-693F-4bb2-969A-04B22C025FE2} Voltage regulator proportional gain iKiisubPAsubi gt 0 if ExcIEEEAC7B.kia 0. Typical value 6536. kpa {4C8A8C7D-BAE1-493d-82D9-44A8FC4A1492} Voltage regulator proportional gain iKiisubPRsubi gt 0 if ExcIEEEAC7B.kir 0. Typical value 424. kpr {E79A01EC-5419-46ec-9881-C1733E6E24BE} Lag time constant iTiisubDRsubi gt 0. Typical value 0. tdr {7B5029EB-1E46-4449-BD86-112D074A39AA} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 11. te {4B420A48-2C4F-43bc-AA94-797FE88CC673} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 1. tf {90BB088D-FB10-4d1d-B05F-2065D9935B70} Maximum voltage regulator output iViisubAMAXsubi gt 0. Typical value 1. vamax {CC77DD4A-7097-445c-9933-42244ACC4D90} Minimum voltage regulator output iViisubAMINsubi lt 0. Typical value 095. vamin {1936CDCD-FDC8-4303-BDB8-3D328307EF0F} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE1subi gt 0. Typical value 63. ve1 {ADF31389-E063-43e4-9BD3-E0D8CF274971} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE2subi gt 0. Typical value 302. ve2 {C053EDA8-2777-499d-80D3-45B86B9017B7} Minimum exciter voltage output iViisubEMINsubi lt 0. Typical value 0. vemin {79FD3ACF-8E38-40a7-A649-037ED7C43F4D} Exciter field current limit reference iViisubFEMAXsubi. Typical value 69. vfemax {55C20CD3-AEF6-4e48-AEC4-66767BFC3616} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 579. vrmax {1A99906E-05B7-4737-90DC-F03DD11C6596} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 579. vrmin {8153D7D2-77A0-4bb4-96C9-8E02AFA8F568} Voltage regulator gain iKiisubAsubi gt 0. Typical value 1. ka {CAA94157-6749-427e-B6AF-B57A6D332CF5} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 055. kc {3749DD3D-805A-411c-B79B-77EFB1B4ACCD} Demagnetizing factor a function of exciter alternator reactances iKiisubDsubi gt 0. Typical value 11. kd {A4A2918E-C37B-4145-8E30-BC6B7A15C4B3} Voltage regulator derivative gain iKiisubDRsubi gt 0. Typical value 10. kdr {6A82A570-1589-4b3a-A5A2-8567B3DE0E94} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 1. ke {D4ADF936-A070-43ff-BEF6-2282664134B2} Voltage regulator integral gain iKiisubIRsubi gt 0. Typical value 5. kir {A61FB404-CC01-4438-BA0E-9BE20F5321A2} Voltage regulator proportional gain iKiisubPRsubi gt 0 if ExcIEEEAC8B.kir 0. Typical value 80. kpr {0DBFB2BE-9C8B-4bea-B1C5-5AD06E7388DF} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 0. ta {6D74D921-B4E8-4006-99F5-FEB3C8EDAB2C} Lag time constant iTiisubDRsubi gt 0. Typical value 01. tdr {D90ACBA1-D501-4dcd-A475-50BF19B60C27} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 12. te {EF6D73D3-92EC-4a03-A027-490136D2846E} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE1subi gt 0. Typical value 65. ve1 {02542131-1EF9-4bf9-B481-13FA5C609353} Exciter alternator output voltages back of commutating reactance at which saturation is defined iViisubE2subi gt 0. Typical value 9. ve2 {47C123B5-0DD0-4fe8-8289-31BFFA7C643A} Minimum exciter voltage output iViisubEMINsubi lt 0. Typical value 0. vemin {DA1381CA-D93E-448d-8698-152232181C07} Exciter field current limit reference iViisubFEMAXsubi. Typical value 6. vfemax {FA742534-A49C-4dfa-BF6E-587200C494FD} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 35. vrmax {57AD8D66-84EF-4602-8927-8C1124C6F4AF} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 0. vrmin {77018ED0-3248-4015-88E5-2A30B0A75C80} Exciter voltage at which exciter saturation is defined iEiisubFD1subi gt 0. Typical value 31. efd1 {5C21A9EA-0EE0-49fc-9C22-929904EC936A} Exciter voltage at which exciter saturation is defined iEiisubFD2subi gt 0. Typical value 23. efd2 {2FEBAD6C-6AFC-44a6-8E3D-A73589953659} Voltage regulator gain iKiisubAsubi gt 0. Typical value 46. ka {C5CA11EE-15C2-43e3-B786-95FE21086610} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 0. ke {8624D37D-27AE-402d-BC38-C33617C1B4C4} Excitation control system stabilizer gain iKiisubFsubi gt 0. Typical value 0.1. kf {B70D69E2-D568-4b3a-B746-DC1E0445548B} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 006. ta {AF3D37DD-DF2D-486a-8824-AD01FCEDC421} Voltage regulator time constant iTiisubBsubi gt 0. Typical value 0. tb {A2723F9D-DDD9-4d2d-B677-2BEB27AB84CD} Voltage regulator time constant iTiisubCsubi gt 0. Typical value 0. tc {ADEE2D2A-A2AA-4464-BBC3-AB84DC679B64} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 046. te {52CFCC80-DB47-4de3-A488-FF52B72B8C26} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 1. tf {0A4924CE-5629-414b-A863-64657774F76A} Maximum voltage regulator output iViisubRMAXsubi gt ExcIEEEDC1A.vrmin. Typical value 1. vrmax {CF546840-AC64-4f68-9F57-B1F230694524} Minimum voltage regulator output iViisubRMINsubi lt 0 and lt ExcIEEEDC1A.vrmax. Typical value 09. vrmin {9AD95853-3063-4a47-9339-8E1D98ED4854} Exciter voltage at which exciter saturation is defined iEiisubFD1subi gt 0. Typical value 305. efd1 {50EF9DEB-5DAC-420d-B896-C8BEBFB06A33} Exciter voltage at which exciter saturation is defined iEiisubFD2subi gt 0. Typical value 229. efd2 {BD4B9F65-626E-4182-BC47-8854AE5F86EE} iexclimi. IEEE standard is ambiguous about lower limit on exciter output. Typical value 999 which means that there is no limit applied. exclim {AE32601D-3E52-4ba7-ADCA-D05656320C2B} Voltage regulator gain iKiisubAsubi gt 0. Typical value 300. ka {8B0DBBB2-9EE6-490f-8C42-D63F09AD84E9} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 1. ke {460167B8-C685-4891-8865-77F49AC62D96} Excitation control system stabilizer gain iKiisubFsubi gt 0. Typical value 01. kf {CDF296C2-84C5-41f9-85F6-23316E1DA0A4} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 001. ta {1A461A8D-FE30-49ce-A520-4796C0D30A72} Voltage regulator time constant iTiisubBsubi gt 0. Typical value 0. tb {42E6440E-A6CE-46df-90EF-F30E3406CCAB} Voltage regulator time constant iTiisubCsubi gt 0. Typical value 0. tc {AE5D5AC2-C1F7-431b-96B0-108A679BE624} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 133. te {B917F45C-1C6C-4b66-BB8D-A5BD6DE06511} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 0675. tf {398ABC46-2153-49c3-8A05-F8DC393FBD4D} Maximum voltage regulator output iViisubRMAXsubigt ExcIEEEDC2A.vrmin. Typical value 495. vrmax {49E39611-DF26-4038-809C-A7D73182E5BD} Minimum voltage regulator output iViisubRMINsubi lt 0 and lt ExcIEEEDC2A.vrmax. Typical value 49. vrmin {D6B734BF-53A0-48c3-BEAE-FE61528C3047} Exciter voltage at which exciter saturation is defined iEiisubFD1subi gt 0. Typical value 3375. efd1 {A477E4ED-AFDB-404d-A7B7-1B3246698C9A} Exciter voltage at which exciter saturation is defined iEiisubFD2subi gt 0. Typical value 315. efd2 {DEE62C44-4D77-4723-B494-C38F2859115B} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 005. ke {F33B7DB6-45EC-498c-93E3-055904655711} Fast raiselower contact setting iKiisubVsubi gt 0. Typical value 005. kv {36D76F22-8191-4d6e-8482-739E31FC97FB} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 05. te {E4F92E42-7A71-426f-AB1B-742E1E204EC7} Rheostat travel time iTiisubRHsubi gt 0. Typical value 20. trh {2157905F-0029-4ab8-9E2B-1DF1FC803588} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 1. vrmax {9156F438-7F70-485e-8946-562C988C5E48} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 0. vrmin {6E620177-604E-4cc3-A3E1-4BC724583146} Exciter voltage at which exciter saturation is defined iEiisubFD1subi gt 0. Typical value 175. efd1 {5DBC11EF-4BDC-4908-80E2-9DB2EA524F5B} Exciter voltage at which exciter saturation is defined iEiisubFD2subi gt 0. Typical value 233. efd2 {255AFE50-BEA0-4c6f-AA93-E5F174CEB6F2} Voltage regulator gain iKiisubAsubi gt 0. Typical value 1. ka {C0D0F453-7CD0-440d-B1BF-CFEAE1E09F0B} Regulator derivative gain iKiisubDsubi gt 0. Typical value 20. kd {5BBC5653-C9A0-4ffb-836E-DCE63C56096E} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 1. ke {C5A9E8D6-0397-4986-9A42-0901C42B34B3} Excitation control system stabilizer gain iKiisubFsubi gt 0. Typical value 0. kf {E2C3F1D4-ED5E-459c-A884-51C354FD925B} Regulator integral gain iKiisubIsubi gt 0. Typical value 20. ki {017F2994-D707-4e44-BC0F-3D967EBD47B9} Regulator proportional gain iKiisubPsubi gt 0. Typical value 20. kp {47916C6F-0313-4568-AF12-1E8C20DA022B} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 02. ta {785CE06A-EAC9-4192-9BFA-C0C65986E070} Regulator derivative filter time constant iTiisubDsubi gt 0 if ExcIEEEDC4B.kd gt 0. Typical value 001. td {C6E2EB88-5D76-4e65-A674-254292E91122} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 08. te {A3A70E4F-FCCC-404a-B4F7-CE62E226AFBA} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 1. tf {7BEFB382-83B9-4b72-8AEB-2447E9F5E309} Minimum exciter voltage output iViisubEMINsubi lt 0. Typical value 0. vemin {30D3D922-B230-41c9-BB55-090BE2E6C946} Maximum voltage regulator output iViisubRMAXsubi gt ExcIEEEDC4B.vrmin. Typical value 27. vrmax {B880B106-22CE-450f-B15D-714FA99A7CA3} Minimum voltage regulator output iViisubRMINsubi lt 0 and lt ExcIEEEDC4B.vrmax. Typical value 09. vrmin {5B5EE845-5C6E-438b-A6EE-05AF93F777C5} Exciter output current limit reference iIiisubLRsubiii. Typical value 0. ilr {8C61C4E8-65B7-4dfc-A824-01DE7F42C371} Voltage regulator gain iKiisubAsubi gt 0. Typical value 190. ka {C3392C55-2E2B-46c7-A5A7-5216DEFD6882} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 008. kc {6A214F26-0A35-4e0b-B848-C7EE521DE0DD} Excitation control system stabilizer gains iKiisubFsubi gt 0. Typical value 0. kf {79BE416F-6BF1-4a12-9DAC-B64E820E6D73} Exciter output current limiter gain iKiisubLRsubi. Typical value 0. klr {79702DB8-84F0-447b-AB4E-72DE9A3DCFCE} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 0. ta {9E1D4656-32FB-4950-8A23-98D22367A2A3} Voltage regulator time constant iTiisubBsubi gt 0. Typical value 10. tb {8ACCD110-4BDF-44dc-BEB8-3E3FF740CAF2} Voltage regulator time constant iTiisubB1subi gt 0. Typical value 0. tb1 {6E628FDE-3E25-4d8a-ADB9-FEA799D5AEE8} Voltage regulator time constant iTiisubCsubi gt 0. Typical value 1. tc {4FFB39D6-E51A-41cc-A5CB-F534187934F8} Voltage regulator time constant iTiisubC1subi gt 0. Typical value 0. tc1 {93C55100-BD33-4560-9072-BBC9C6FB94FB} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 1. tf {D5D96655-D2D2-4384-A011-96E4EF572612} Selector of the connection of the UEL input iUELini. Typical value ignoreUELsignal. uelin {F343504B-E6F3-427f-A565-30F740733A98} Maximum voltage regulator output iViisubAMAXsubi gt 0. Typical value 145. vamax {F7E74221-6201-4f6c-9EC1-FBD2971F9B03} Minimum voltage regulator output iViisubAMINsubi lt 0. Typical value 145. vamin {1662A19F-3E32-4bcd-B130-C6241BEF9DA0} Maximum voltage regulator input limit iViisubIMAXsubi gt 0. Typical value 999. vimax {7776AE1D-072D-4644-8CB9-E391B7A69C42} Minimum voltage regulator input limit iViisubIMINsubi lt 0. Typical value 999. vimin {68B11135-8D65-4741-8E64-F8AC034E3781} Maximum voltage regulator outputs iViisubRMAXsubi gt 0. Typical value 78. vrmax {C0EF2A02-0DE1-43d6-AF16-59F60666CFE3} Minimum voltage regulator outputs iViisubRMINsubi lt 0. Typical value 67. vrmin {C4C188F6-DC6F-4719-8F19-30CA3FC6DDC2} Maximum field voltage iEiisubFDMaxsubi gt 0. Typical value 99. efdmax {92ED82AD-8685-4b6f-A1CC-8A2C7C3471CA} Voltage regulator gain iKiisubAsubi gt 0. Typical value 120. ka {ABFC48CB-23E8-4029-8AD1-515533A1D1E8} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 182. kc {7DBA1AD4-9659-4feb-A527-2BEC12676699} Exciter constant related to selfexcited field iKiisubEsubi. Typical value 1. ke {F1E795D2-5F05-4ca4-9A1F-953D5697A3B1} Excitation control system stabilizer gains iKiisubFsubi gt 0. Typical value 005. kf {44290411-EAD7-41d2-87F3-2BB40B82AAD0} Potential circuit gain coefficient iKiisubIsubi gt 0. Typical value 8. ki {7AD803D3-A15F-480d-A313-E836B79F6054} Potential circuit gain coefficient iKiisubPsubi gt 0. Typical value 488. kp {88C78104-4F94-4ace-A434-5E802E783FCD} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 015. ta {26B29524-EA7B-498e-89D3-1DE17E911015} Exciter time constant integration rate associated with exciter control iTiisubEsubi gt 0. Typical value 05. te {B7CDFA17-4298-4fa8-9576-86AE3418C639} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 1. tf {80FC0FA1-DE57-45f4-A9F5-7DC411CE8D97} Maximum voltage regulator outputs iViisubRMAXsubi gt 0. Typical value 1. vrmax {48B7A69B-E09C-4226-B011-8BA4BACD7B7E} Minimum voltage regulator outputs iViisubRMINsubi lt 0. Typical value 0. vrmin {F970BD16-8974-47d8-B89C-74F29C233410} Voltage regulator gain iKiisubAsubi gt 0. This is parameter iKi in the IEEE standard. Typical value 200. ka {A3C087B1-791E-4d06-B035-FFFD372C4D25} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 02. kc {320366EC-3C73-4ac2-85A4-455C018D0453} Feedback gain constant of the inner loop field regulator iKiisubGsubi gt 0. Typical value 1. kg {28145DB2-8F90-4bee-8902-988E21F0103F} Potential circuit gain coefficient iKiisubIsubi gt 0. Typical value 0. ki {B5053791-953F-4710-8D97-38ED9D8765AA} Forward gain constant of the inner loop field regulator iKiisubMsubi gt 0. Typical value 793. km {55344280-D8F0-44a8-912E-8D78BBDBAC7B} Potential circuit gain coefficient iKiisubPsubi gt 0. Typical value 615. kp {8C83DCAE-8746-482b-B978-061BD95E4F2E} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 0. ta {82922C99-28EF-4cb8-9A27-1483A2642ADA} Voltage regulator time constant iTiisubBsubi gt 0. Typical value 10. tb {B5C43A75-77B8-4ef9-A794-1609C29378CC} Voltage regulator time constant iTiisubCsubi gt 0. Typical value 1. tc {9F574F64-792F-412b-ACD9-1A5C2212B8C8} Potential circuit phase angle ithetapi. Typical value 0. thetap {DD50E55D-558D-4ff8-8DC4-943484691AE6} Forward time constant of inner loop field regulator iTiisubMsubi gt 0. Typical value 04. tm {E0507F84-1A36-45b5-ABD2-BBFF182F9478} Maximum excitation voltage iViisubBMaxsubi gt 0. Typical value 69. vbmax {C383680D-D827-4db4-8EDC-0A7E355748A6} Maximum inner loop feedback voltage iViisubGMaxsubi gt 0. Typical value 58. vgmax {45E564F9-292B-423d-A7FF-5CC9A276B442} Maximum voltage regulator input limit iViisubIMAXsubi gt 0. Typical value 02. vimax {C23B5DA8-299C-4ef6-956A-2C0BD0FF1445} Minimum voltage regulator input limit iViisubIMINsubi lt 0. Typical value 02. vimin {FEC4346A-EB5C-4efc-9249-9B33B8E7947C} Maximum inner loop output iViisubMMaxsubi gt 0. Typical value 1. vmmax {6799E6BA-C4A9-44bf-AFFE-8417D6147187} Minimum inner loop output iViisubMMinsubi lt 0. Typical value 0. vmmin {CF18AAEE-1A4A-4951-89BC-DC6F3367331E} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 10. vrmax {29B99855-2D0C-42ce-8074-34940F19C1B5} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 10. vrmin {FD78D994-92A4-469f-851F-03C6EBA26A34} Reactance associated with potential source iXiisubLsubi gt 0. Typical value 0081. xl {E331EB82-1416-40a6-931A-A0A18E21F60C} Rectifier loading factor proportional to commutating reactance iKiisubCsubi gt 0. Typical value 0113. kc {CC02EDA1-161E-4915-AFD7-13CFD389C679} Feedback gain constant of the inner loop field regulator iKiisubGsubi gt 0. Typical value 0. kg {174459A8-2467-4d69-8883-AEC34E57F92E} Potential circuit gain coefficient iKiisubIsubi gt 0. Typical value 0. ki {6F4228CF-9DE4-41a5-B8F1-EE416D5E9831} Voltage regulator integral gain output iKiisubIMsubi. Typical value 0. kim {575C835A-8951-432e-8961-C9EE226548F9} Voltage regulator integral gain iKiisubIRsubi. Typical value 1075. kir {05D5287A-45EE-43a3-9AEB-2BE05891A6B1} Potential circuit gain coefficient iKiisubPsubi gt 0. Typical value 93. kp {06CE480A-82FC-4335-B729-C82049B536EC} Voltage regulator proportional gain output iKiisubPMsubi. Typical value 1. kpm {EF32C59F-C1C0-414f-B8A7-1C3F668BC770} Voltage regulator proportional gain iKiisubPRsubi. Typical value 1075. kpr {207D6C86-7591-4ec8-BD8D-8945B8F6A969} Voltage regulator time constant iTiisubAsubi gt 0. Typical value 002. ta {181FE944-E90A-481d-9E6B-07DBCE3BAA12} Potential circuit phase angle ithetapi. Typical value 0. thetap {2E44DFF3-234F-4674-9605-1950FEFBD8B0} Maximum excitation voltage iViisubBMaxsubi gt 0. Typical value 1163. vbmax {FD530BF0-5D2C-4b6b-B433-05157E17E634} Maximum inner loop output iViisubMMaxsubi gt ExcIEEEST4B.vmmin. Typical value 99. vmmax {F537585B-51A8-4bb1-AB3A-3E86C3EE0E56} Minimum inner loop output iViisubMMinsubi lt ExcIEEEST4B.vmmax. Typical value 99. vmmin {47D7013B-638E-479c-B0A8-5D4DE1A8931E} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 1. vrmax {D7A47E4E-5196-422e-8C89-0303D0C3F075} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 087. vrmin {F2C0F2D2-96FF-493d-AC5C-17B203C5FE4A} Reactance associated with potential source iXiisubLsubi gt 0. Typical value 0124. xl {B97E568B-A3AE-4d5e-BC45-80FC583F4FBF} Rectifier regulation factor iKiisubCsubi gt 0. Typical value 0004. kc {509279AB-F531-483d-B285-2580410FC297} Regulator gain iKiisubRsubi gt 0. Typical value 200. kr {AFB5267A-5A05-4151-B5A6-B4EB1B90D72D} Firing circuit time constant iT1i gt 0. Typical value 0004. t1 {A64D6107-BE0F-4ecc-B143-4FD95D614B6A} Regulator lag time constant iTiisubB1subi gt 0. Typical value 6. tb1 {7A70B43C-E1BB-43d3-B604-8A2DF5A2291E} Regulator lag time constant iTiisubB2subi gt 0. Typical value 001. tb2 {8C2E0609-F8F1-4008-A312-68C7B77E791D} Regulator lead time constant iTiisubC1subi gt 0. Typical value 08. tc1 {C40EF6B0-E52C-4c38-8340-EA19FCA30B98} Regulator lead time constant iTiisubC2subi gt 0. Typical value 008. tc2 {CB2BECE7-0213-4f75-84F3-F2E7B5EE4CAE} OEL lag time constant iTiisubOB1subi gt 0. Typical value 2. tob1 {270A1478-6631-464f-8035-9FCC45F0C0F1} OEL lag time constant iTiisubOB2subi gt 0. Typical value 008. tob2 {AF0A05D8-3FC4-4368-B511-9FC33C358486} OEL lead time constant iTiisubOC1subi gt 0. Typical value 01. toc1 {E6FE7F29-6533-4d44-8358-083D8044311A} OEL lead time constant iTiisubOC2subi gt 0. Typical value 008. toc2 {F37C04C6-9EBE-4704-B1C3-78A832B9CA3A} UEL lag time constant iTiisubUB1subi gt 0. Typical value 10. tub1 {62EC4650-349E-45a2-B6A2-A30853DF5D2B} UEL lag time constant iTiisubUB2subi gt 0. Typical value 005. tub2 {1BFC4B8E-A1D8-40dc-8C91-AAC19E758D3E} UEL lead time constant iTiisubUC1subi gt 0. Typical value 2. tuc1 {67A12FB3-AFB7-4410-926F-FA9ABA8818E2} UEL lead time constant iTiisubUC2subi gt 0. Typical value 01. tuc2 {7C14C219-3BB5-473c-8EB6-D9F785FEA035} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 5. vrmax {BCCEC06F-77FB-404f-ADAC-C7CD0044F084} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 4. vrmin {FE8E96AC-F9F7-4439-A2F7-EB1E9ACCE574} Exciter output current limit reference iIiisubLRsubi gt 0. Typical value 4164. ilr {6DD69C6A-D8BC-4408-B8FF-0A69C7C5515D} Exciter output current limit adjustment iKiisubCIsubi gt 0. Typical value 10577. kci {82513056-D3D9-40f9-AE07-BA004F6275B8} Precontrol gain constant of the inner loop field regulator iKiisubFFsubi. Typical value 1. kff {2C19E93F-AE86-490f-9E16-09D964499864} Feedback gain constant of the inner loop field regulator iKiisubGsubi gt 0. Typical value 1. kg {69084BCC-F707-42bf-9056-C152A46F75A5} Voltage regulator integral gain iKiisubIAsubi gt 0. Typical value 45094. kia {B1759B97-C455-4ea6-8074-53A2D7045A1C} Exciter output current limiter gain iKiisubLRsubi gt 0. Typical value 1733. klr {AF352265-457A-413e-B8B7-2127DB0D3943} Forward gain constant of the inner loop field regulator iKiisubMsubi. Typical value 1. km {5068F9C7-5A5F-4d46-94CB-FA4D282B1030} Voltage regulator proportional gain uKuusubPAsubu gt 0. Typical value 18038. kpa {BB5DEF62-10B9-4372-AA2B-E147FF68EDF9} OEL input selector iOELini. Typical value noOELinput. oelin {14735B3B-98B1-4b26-BA49-F6CDF3AAB896} Feedback time constant of inner loop field voltage regulator iTiisubGsubi gt 0. Typical value 002. tg {2DD24D01-74E4-408b-B0FE-05DE3F1700F0} Maximum voltage regulator output VisubAMAXsubi gt 0. Typical value 481. vamax {641AF6B9-0C4E-4c43-89FF-74110288F4A6} Minimum voltage regulator output iViisubAMINsubi lt 0. Typical value 385. vamin {41484B28-927C-4003-A2AF-D7C2CA792F01} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 481. vrmax {35F4955E-5EAE-4da8-B6CA-8781F6256766} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 385. vrmin {ABF693C2-6818-4101-B15B-EC0E95E0DC6E} Highvalue gate feedback gain iKiisubHsubi gt 0. Typical value 1. kh {43BBB77E-26A1-4e2d-AEAE-B2F01F28ED3A} Voltage regulator integral gain iKiisubIAsubi gt 0. Typical value 1. kia {ACF9C97C-5D50-4b81-8B26-CF1DD7AA99B6} Lowvalue gate feedback gain iKiisubLsubi gt 0. Typical value 1. kl {F00C0507-801C-4346-BC88-E47C43486F13} Voltage regulator proportional gain iKiisubPAsubi gt 0. Typical value 40. kpa {6BE8FA89-08B1-4fc5-8D60-D33ED957D03C} OEL input selector iOELini. Typical value noOELinput. oelin {90AE62BA-B286-4c1d-BD88-B61080B16E79} Regulator lag time constant iTiisubBsubi gt 0. Typical value 1. tb {6CE3CCDC-54EC-4524-A0B8-AA531D2B17ED} Regulator lead time constant iTiisubCsubi gt 0. Typical value 1. tc {9605D374-AD1C-4e16-86B0-931F43978343} Excitation control system stabilizer time constant iTiisubFsubi gt 0. Typical value 1. tf {A4BCD34E-FEAD-4b60-978C-F63BB4B10A72} Feedback time constant of inner loop field voltage regulator iTiisubGsubi gt 0. Typical value 1. tg {55F1E500-AC63-4eeb-A40B-38836513342F} Feedback time constant iTiisubIAsubi gt 0. Typical value 3. tia {609916C6-3026-44c1-ADBC-0E9D6DDDE3AC} UEL input selector iUELini. Typical value noUELinput. uelin {C3050131-90A7-4129-A13A-D7FBC7AA02A7} Maximum voltage reference signal iViisubMAXsubi gt 0 and gt ExcIEEEST7B.vmin. Typical value 11. vmax {5FDFEECE-FE0F-483f-9383-72FA6A71199F} Minimum voltage reference signal iViisubMINsubi gt 0 and lt ExcIEEEST7B.vmax. Typical value 09. vmin {9C0D10A0-3BBC-4214-9C3E-4887B91D0B7C} Maximum voltage regulator output iViisubRMAXsubi gt 0. Typical value 5. vrmax {C995909E-5AB0-4bec-9C39-F326A5BCDB72} Minimum voltage regulator output iViisubRMINsubi lt 0. Typical value 45. vrmin {6E245220-20CD-4fec-ADF3-93653A6BFCCD} Voltage regulator gain iKai gt 0. Typical value 210. ka {8F0BB6FD-7F47-4352-A2E3-F9D7D94004B5} Excitation control system stabilizer gain iKfi gt 0. Typical value 001. kf {1D74BC2F-93B0-45c9-BEFE-BC2FB6BDBD48} irci irfdi iRi gt 0. 0 means exciter has negative current capabilitygt 0 means exciter does not have negative current capability. Typical value 5. r {F337910E-26D5-4a91-8B95-BF3FB984C9CD} Voltage regulator time constant iTai gt 0. Typical value 002. ta {2E0C4647-5E1A-4c08-AA8B-32E7E2579014} Excitation control system stabilizer time constant iTf1i gt 0. Typical value 10. tf1 {298EB9FE-88B8-44d7-B574-1972B587A48B} Excitation control system stabilizer time constant iTf2i gt 0. Typical value 01. tf2 {1CA15C51-4950-475d-B24B-CB2AC313CEDF} Time constant iTri gt 0. Typical value 002. tr {4BC6768A-77FC-4409-AB50-00E475D61073} Maximum voltage regulator ouput iVrmaxi gt ExcNI.vrmin. Typical value 50. vrmax {4DEDBBDE-77D5-47c8-9E4A-2864E98248E7} Minimum voltage regulator ouput iVrmini lt ExcNI.vrmax. Typical value 20. vrmin {1508A7D6-CFE0-491f-85DB-4C882088968A} Saturation parameter iEiisub1subi. e1 {E942AFAA-EE17-4eb7-A454-2F62F7B5A64D} Saturation parameter iEiisub2subi. e2 {2F5E5EBF-4370-4b2d-9DCE-8700FF72D24F} Gain iKiisubAsubi. ka {B9515878-C715-40f4-8904-9EDC3B2389ED} Gain iKiisubCsubi. kc {19B9D3FC-3C8B-42f6-8D56-75943C6851CB} Gain iKiisubDsubi. kd {4733AE75-F9E7-491e-BB20-11B783CBBDAC} Gain iKiisubEsubi. ke {637244DC-2AF8-43fc-804A-7FD020011C58} Gain iKiisubFsubi. kf {3639B35D-63E8-4e68-B0BD-74C8CCA72BA3} Saturation parameter iSiisubEsubiiEiisub1subiii. see1 {4021D622-E204-4acb-B0EB-4D7F1B64C62C} Saturation parameter iSiisubEsubiiEiisub2subiii. see2 {793E79BE-3ABE-4fff-B270-B401C9F0F5BE} Time constant iTiisub1subi gt 0. t1 {6D595B12-BC8E-4395-A927-ACBE45D03353} Time constant iTiisub2subi gt 0. t2 {72861C34-AE7A-48f6-AF56-A92AE34FA2D6} Time constant iTiisub3subi gt 0. t3 {F36BFBBF-AFE7-44b8-B224-D3FB5AB1B72A} Time constant iTiisub4subi gt 0. t4 {7087D1E9-1C15-426b-A575-4C5175032E7D} Time constant iTiisub5subi gt 0. t5 {55A9101D-331B-4f60-AF95-8F368C15D9F2} Time constant iTiisub6subi gt 0. t6 {D904B8D3-5CEC-436a-AF9B-3E411DBA3DE8} Time constant iTiisubEsubi gt 0. te {CE14CA81-717C-4f49-B370-B5AFFC4BE8A2} Time constant iTiisubFsubi gt 0. tf {AB6022D7-C2E2-409e-BAC3-B713D1AE1D1E} Limiter iViisubRMAXsubi gt ExcOEX3T.vrmin. vrmax {7BD6BE27-E10A-46e3-9011-447DEBF3D4BE} Limiter iViisubRMINsubi lt ExcOEX3T.vrmax. vrmin {F50045B9-586F-4c1b-9608-4081B886208F} Field voltage value 1 iEiisub1subi. Typical value 0. e1 {EEBE48FA-7B93-48c7-8735-F9025B42D5F5} Field voltage value 2 iEiisub2subi. Typical value 0. e2 {75A8D86C-649D-4786-BC27-0C32CF71AB14} Exciter maximum limit iEiisubfdmaxsubi gt ExcPIC.efdmin. Typical value 8. efdmax {391DD3B5-FBF9-4e8a-8280-396D524557E9} Exciter minimum limit iEiisubfdminsubi lt ExcPIC.efdmax. Typical value 087. efdmin {74EFB20A-4C9C-4c01-93A7-55AF0CD86421} PI controller gain iKiisubasubi. Typical value 315. ka {5BCA2DE1-420A-4899-A08B-91EEB6CB10AD} Exciter regulation factor iKiisubcsubi. Typical value 008. kc {28B3377C-BB8F-42e5-8EB2-7CF4EA397DBE} Exciter constant iKiisubesubi. Typical value 0. ke {902997F3-CF1A-4ad7-8DEE-81FBAB289096} Rate feedback gain iKiisubfsubi. Typical value 0. kf {5AD2CCEE-FFBB-4980-BEAE-79B39C438B58} Current source gain iKiisubisubi. Typical value 0. ki {B552DBF0-7962-4d25-A542-F2F625204F01} Potential source gain iKiisubpsubi. Typical value 65. kp {60EB104E-1D4E-4ecf-8C9B-FC77F7FDBBE6} Saturation factor at iEiisub1subi iSeiisub1subi. Typical value 0. se1 {A25CA093-89FD-441d-9E20-8C6B30D1F130} Saturation factor at iEiisub2subi iSeiisub2subi. Typical value 0. se2 {BDED94F4-7FD6-4c4d-83E7-004EC29D35E9} PI controller time constant iTiisuba1subi gt 0. Typical value 1. ta1 {E9E8CF95-70E3-4d1e-9A9F-8F59BAB44A01} Voltage regulator time constant iTiisuba2subi gt 0. Typical value 001. ta2 {E949BFE4-381D-431b-A551-93403A1CEA5A} Lead time constant iTiisuba3subi gt 0. Typical value 0. ta3 {DDDC8D0A-13F1-4635-A7D2-FE6C5FD0E7C8} Lag time constant iTiisuba4subi gt 0. Typical value 0. ta4 {5ABF11DE-2E44-4e27-9C3B-A55D44C5FDC1} Exciter time constant iTiisubesubi gt 0. Typical value 0. te {2B9F001B-0151-4325-AFAA-26A5423ABBD4} Rate feedback time constant iTiisubf1subi gt 0. Typical value 0. tf1 {7B375F84-7678-4c63-B71D-6C887C7EF0A1} Rate feedback lag time constant iTiisubf2subi gt 0. Typical value 0. tf2 {F0267C4F-9C65-4307-951B-14F2A9655B2D} PI maximum limit iViisubr1subi. Typical value 1. vr1 {AF3CC231-831C-4486-A7D6-4D4CDBB7A6D1} PI minimum limit iViisubr2subi. Typical value 087. vr2 {6713D0C3-F0EE-43e5-8DE7-35054F6274E4} Voltage regulator maximum limit iViisubrmaxsubi gt ExcPIC.vrmin. Typical value 1. vrmax {C4D26504-6125-47f1-98EF-1A40D7B21A72} Voltage regulator minimum limit iViisubrminsubi lt ExcPIC.vrmax. Typical value 087. vrmin {B7C19D24-A986-497f-B51A-D77109151D11} Field voltage value 1 iEiisub1subi. Typical value 3. e1 {164FF977-2FF6-41c6-AE1F-88734F72D57B} Field voltage value 2 iEiisub2subi. Typical value 4. e2 {AE085DFD-AD00-4a0f-9551-537093FB3EE3} Rate feedback signal flag ifbfi. Typical value fieldCurrent. fbf {DFED37F0-9874-4241-8F51-0802853DB747} Limit type flag iFlimfi. Typical value 0. flimf {A0A350C6-93E9-4a81-8410-C769F3920346} Rectifier regulation factor iKci. Typical value 005. kc {38A6941F-0125-4738-B058-C90C350BA0D5} Exciter regulation factor iKdi. Typical value 2. kd {EE04C4BB-5D20-437d-8846-95E2C3E49D12} Exciter field proportional constant iKei. Typical value 1. ke {A6B53E41-5B64-4438-ADE0-54F2BFE82011} Field voltage feedback gain iKefdi. Typical value 0. kefd {BAA1CA90-5E07-49e8-BD09-0DD6DFA58648} Rate feedback gain iKfi gt 0. Typical value 005. kf {21FF995A-7948-43e1-9791-213E20697284} Field voltage controller feedback gain iKhi. Typical value 0. kh {8C0B2D0A-6B2E-438a-9C63-158D4928DBCD} Field current regulator integral gain iKiii. Typical value 0. kii {1128DAA8-399E-47d3-89C3-DEE9BE045E85} Field current regulator proportional gain iKipi. Typical value 1. kip {5C6427A7-6EBA-45e6-A728-B61462497777} Coefficient to allow different usage of the modelspeed coefficient iKsi. Typical value 0. ks {3B54A7AA-444D-4633-AA33-8B2B32D74C9B} Voltage regulator integral gain iKvii. Typical value 0. kvi {5E62EC4C-EF68-4f28-9087-2C2CAEA2472F} Voltage regulator proportional gain iKvpi. Typical value 2800. kvp {13D6632B-6C89-430d-8827-EB2B6E555D3C} VHz limiter gain iKvphzi. Typical value 0. kvphz {FE9FAAE0-6E2B-495c-89A9-E2BA75036112} Pickup speed of VHz limiter iNvphzi. Typical value 0. nvphz {59F067BD-FABE-4f37-8F09-AF177DFB6D1A} Saturation factor at iEiisub1subii iiSeiisub1subi. Typical value 00001. se1 {C6DF5A98-35BC-475d-BF75-14EAA742BEFA} Saturation factor at iEiisub2subi iSeiisub2subi. Typical value 0001. se2 {AB4E5708-8F13-492c-98D0-ECD404A26A5B} Voltage regulator time constant iTai gt 0. If 0 block is bypassed. Typical value 001. ta {1823BC8A-E677-4e6f-A2DD-E1D6AB82BC6D} Lag time constant iTb1i gt 0. If 0 block is bypassed. Typical value 0. tb1 {0D2DC130-91E3-4862-AB8A-0B65AFF5879D} Lag time constant iTb2i gt 0. If 0 block is bypassed. Typical value 0. tb2 {3CBCFBD6-90F5-459a-AC76-54D3AC35B22A} Lead time constant iTc1i gt 0. Typical value 0. tc1 {E2E39AA3-28B6-4e85-B8BD-B9B671508B85} Lead time constant iTc2i gt 0. Typical value 0. tc2 {BE1EB996-C2DE-49c4-AC97-9C58C1BE917A} Exciter field time constant iTei gt 0. Typical value 12. te {3F2A693A-EA97-4152-8DE8-5C65813DD02B} Rate feedback time constant iTfi gt 0. If 0 the feedback path is not used. Typical value 1. tf {A1A80139-7398-453a-8285-88B57F0022AD} Feedback lead time constant iTf1i gt 0. Typical value 0. tf1 {8CC07373-DC27-4753-BFF5-497DB67CEC25} Feedback lag time constant iTf2i gt 0. If 0 block is bypassed. Typical value 0. tf2 {F9FD5508-79C1-46e1-98B0-61F677DE1764} Field current bridge time constant iTpi gt 0. Typical value 0. tp {521F84AC-7F9F-406d-BBD9-7232D826D809} Maximum compounding voltage iVcmaxi. Typical value 0. vcmax {337CB21C-BCBA-4a33-A646-D85C88358ACA} Maximum exciter field current iVfmaxi gt ExcREXS.vfmin. Typical value 47. vfmax {7247F5BE-EC4E-4c8e-9479-49FA0613BE8D} Minimum exciter field current iVfmini lt ExcREXS.vfmax. Typical value 20. vfmin {E7686DA5-5AE6-4d15-AC40-D5409F72AAB9} Voltage regulator input limit iVimaxi. Typical value 01. vimax {B83961F7-E22F-4aa2-A454-42F7445F7ECF} Maximum controller output Virmaxi gt ExcREXS.vrmin. Typical value 47. vrmax {837348BB-9823-4a46-930D-12039A3F019C} Minimum controller output iVrmini lt ExcREXS.vrmax. Typical value 20. vrmin {33A42831-C76D-45c5-BAD5-C1DE3EBEF120} Exciter compounding reactance iXci. Typical value 0. xc {A79AD54D-A5C2-4903-A5B6-72D42C039209} Integrator limiter iLSATi. Typical value 573. lsat {FC2ED949-867C-4492-A30C-E22DE3F3159F} Setpoint iLUSi. Typical value 012. lus {12DFCF3E-BF50-4476-88E8-DEAF0B00DD9F} Voltage input time constant iMESUi gt 0. Typical value 002. mesu {D228BCF3-F8F4-4771-9D6F-9D8AE6093515} Input time constant iT4Mi gt 0. Typical value 5. t4m {356724A3-E0AA-4491-B323-416289AD1D4F} Lead lag time constant iTCi gt 0. Typical value 002. tc {FCC25BEF-45D5-4172-97CE-45B8979B9F09} Lead lag time constant iTEi gt 0. Typical value 022. te {FA18CA67-BB00-4454-BA75-FC50E96C5C2A} Exciter time constant iTFi gt 0. Typical value 001. tf {028B3D45-810E-48ff-BB3E-BAAF81AD4FE3} Maximum voltage reference limit iUCMAXi gt ExcRQB.ucmin. Typical value 11. ucmax {2527D779-DC89-465d-BAD8-711D4643F64B} Minimum voltage reference limit iUCMINi lt ExcRQB.ucmax. Typical value 09. ucmin {C5E3235C-8A06-4837-8625-6FEE9A8946E2} Maximum field voltage output iEmaxi gt ExcSCRX.emin. Typical value 5. emax {BA58E757-E10E-426a-B0FE-337EF03939CA} Minimum field voltage output iEmini lt ExcSCRX.emax. Typical value 0. emin {6498CE49-AF8F-4aa1-8256-5B79825B452C} Gain iKi gt 0. Typical value 200. k {8AC0E9A7-A057-464e-A78C-6C7983DB937B} Denominator time constant of laglead block iTbi gt 0. Typical value 10. tb {41A5AFD5-E1ED-4f9e-B941-EFB7298F69A8} Time constant of gain block iTei gt 0. Typical value 002. te {719F3A53-D2A7-4c1c-8BC4-38D6579D9D79} Field voltage clipping maximum limit iEfdmaxi gt ExcSEXS.efdmin. Typical value 5. efdmax {F0C86E0F-FC43-4f59-867B-86B521DA22F6} Field voltage clipping minimum limit iEfdmini lt ExcSEXS.efdmax. Typical value 5. efdmin {5E05184B-B1A2-4f70-BF11-66A183E695EB} Maximum field voltage output iEmaxi gt ExcSEXS.emin. Typical value 5. emax {F051BD88-056E-4f60-97EB-872E15E43C53} Minimum field voltage output iEmini lt ExcSEXS.emax. Typical value 5. emin {DBAD3D75-804B-45f8-A507-EA534D2CACD5} Gain iKi gt 0. Typical value 100. k {4F0E6B81-FF7D-4b6b-92FA-52250C6BF3E7} PI controller gain iKci gt 0 if ExcSEXS.tc gt 0. Typical value 008. kc {E3473C5E-7B22-4574-B4F2-853C914A509E} Denominator time constant of laglead block iTbi gt 0. Typical value 10. tb {C5064A87-9B38-4a3c-BFF2-B13AB2109838} PI controller phase lead time constant iTci gt 0. Typical value 0. tc {261F868D-1638-4d43-BFA0-EA83D3E486C0} Time constant of gain block iTei gt 0. Typical value 005. te {FE66CAC3-FB7E-4687-AAD1-479896B7D6ED} Field voltage clipping upper level limit iEfdmaxi gt ExcSK.efdmin. efdmax {0FD6F6E4-E898-412c-A4F6-EE30DF924E8B} Field voltage clipping lower level limit iEfdmini lt ExcSK.efdmax. efdmin {2D429937-73F6-4628-9C56-21D506052E14} Maximum field voltage output iEmaxi gt ExcSK.emin. Typical value 20. emax {B0EEAFBE-2487-4a16-98BB-6A3C34D76506} Minimum field voltage output iEmini lt ExcSK.emax. Typical value 20. emin {8D70C21C-B2B5-4f1b-B601-57CEC3318BE0} Gain iKi. Typical value 1. k {BD843955-8E54-47a7-938A-65CF5F0CB4FC} Parameter of underexcitation limit iK1i. Typical value 01364. k1 {68FD4614-5741-4551-A64F-3668F8C7E3AC} Parameter of underexcitation limit iK2i. Typical value 03861. k2 {BE8C96ED-F4CA-4ea2-B895-17463F9F87AC} PI controller gain iKci. Typical value 70. kc {561EBBD2-7150-4b48-BAA0-FD28EF893735} Rectifier regulation factor iKcei. Typical value 0. kce {3284DFD6-7744-420e-86A1-9DB5C7852572} Exciter internal reactance iKdi. Typical value 0. kd {5962CD3D-E872-421e-B352-559B29A58F33} P controller gain iKgobi. Typical value 10. kgob {3C6EB743-962C-45ab-BAF1-CA0CAB78F7BC} PI controller gain iKpi. Typical value 1. kp {73AA33B0-E129-40de-8030-ED22FBCBAA92} PI controller gain of integral component iKqii. Typical value 0. kqi {711A9A2D-86D4-46ed-8E07-D20B84FE7DB1} Rate of rise of the reactive power iKqobi. kqob {FCB1D27A-E4A2-47ff-85F5-C23C414DA3E1} PI controller gain iKqpi. Typical value 0. kqp {7D3732D4-96CE-40d2-95EF-6DB819CDB0BE} Deadband of reactive power inqi. Determines the range of sensitivity. Typical value 0001. nq {AD6C219A-305A-4b1b-9879-A8860E0E21BD} Desired value setpoint of reactive power manual setting iQzi. qz {B38B207C-40F5-4827-9F32-3C70C7E8C6E6} Apparent power of the unit iSbasei gt 0. Unit MVA. Typical value 259. sbase {D15ECA3E-3FD1-4584-B2CC-B70884FCDA83} PI controller phase lead time constant iTci gt 0. Typical value 8. tc {690E4CEE-5ADB-4f44-AAC6-56E6811094C2} Time constant of gain block iTei gt 0. Typical value 01. te {7AA1CAD6-AB5F-4943-B253-8024981A7108} PI controller phase lead time constant iTii gt 0. Typical value 2. ti {55A63105-579E-4e85-B7E4-B1E0857B256D} Time constant iTpi gt 0. Typical value 01. tp {1EAE01E6-7A2C-479a-9C23-DA86213629EF} Voltage transducer time constant iTri gt 0. Typical value 001. tr {DB62C59D-8F81-40e1-B20E-E831D5349336} Maximum error iUImaxi gt ExcSK.uimin. Typical value 10. uimax {DE76216E-210B-4730-B70B-451037833DEB} Minimum error iUImini lt ExcSK.uimax. Typical value 10. uimin {AB4D34F7-5072-473b-8E5B-3E36BA53D1C8} Maximum controller output iURmaxi gt ExcSK.urmin. Typical value 10. urmax {31276876-9B91-42c6-B212-5E1B6BE41BCA} Minimum controller output iURmini lt ExcSK.urmax. Typical value 10. urmin {B1B5F001-6874-4d63-89AC-19327190DA78} Maximum terminal voltage input iVtmaxi gt ExcSK.vtmin. Determines the range of voltage deadband. Typical value 105. vtmax {831EC9A6-2EB2-4887-9213-E1F4F75E4C6C} Minimum terminal voltage input iVtmini lt ExcSK.vtmax. Determines the range of voltage deadband. Typical value 095. vtmin {54C4FD15-0EBB-44d3-8231-5C175B2AADBA} Maximum output iYpi. Typical value 1. yp {4CC00DA4-48FD-41c1-832E-DC6C5B06DF4A} Exciter output current limit reference iIlri. Typical value 0. ilr {299F6CC8-4242-415a-8A66-833D42D155D2} Voltage regulator gain iKai gt 0. Typical value 190. ka {5FA43B7E-B066-4055-A993-22EA69BAA575} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 005. kc {C1147AE5-D510-4a61-83E7-12E213058FDA} Excitation control system stabilizer gains iKfi gt 0. Typical value 0. kf {1B2022B8-C962-4d71-9DDF-84813986A02D} Exciter output current limiter gain iKlri. Typical value 0. klr {55D4825C-335E-41bb-8319-724D8040D2D9} Voltage regulator time constant iTai gt 0. Typical value 002. ta {0B71598C-A8A9-49c0-9070-F94B972FA257} Voltage regulator time constant iTbi gt 0. Typical value 10. tb {A91EB8DD-E9B2-49bb-BC30-5C731961AFEC} Voltage regulator time constant iTb1i gt 0. Typical value 0. tb1 {D35EF4E2-771E-495c-892C-E7EF82F9E810} Voltage regulator time constant iTci gt 0. Typical value 1. tc {F95F8649-9727-4216-B449-8B1C806A00A9} Voltage regulator time constant iTc1i gt 0. Typical value 0. tc1 {644B50E3-A954-43c3-8DCC-CFBD85C3C4E2} Excitation control system stabilizer time constant iTfi gt 0. Typical value 1. tf {297716A1-9281-428e-9DC6-339BB15B7164} Maximum voltage regulator output iVamaxi gt 0. Typical value 999. vamax {9694EE51-19FE-4718-84F8-C80AE21B80D7} Minimum voltage regulator output iVamini lt 0. Typical value 999. vamin {9FBA70E4-BCC1-453e-A3AC-0C35CF7BB9A7} Maximum voltage regulator input limit iVimaxi gt 0. Typical value 999. vimax {BE5AA2C9-CA37-41d1-8BEF-2FC80DAE61FC} Minimum voltage regulator input limit iVimini lt 0. Typical value 999. vimin {06AEEF13-B378-4774-8E8C-A93AB84A6811} Maximum voltage regulator outputs iVrmaxi gt 0 . Typical value 78. vrmax {90BD86F1-4D12-4603-AF05-AEAA91C05F0E} Minimum voltage regulator outputs iVrmini lt 0. Typical value 67. vrmin {E850252E-D5F4-4ab1-A704-7BC626749A0B} Excitation xfmr effective reactance iXei. Typical value 004. xe {C4CA66BD-BB69-42f0-AE49-98B713DB04C0} Maximum field voltage iEfdmaxi gt 0. Typical value 99. efdmax {04FB7F7D-E5C2-4732-B7D7-000573F50691} Voltage regulator gain iKai gt 0. Typical value 120. ka {99A6327C-145D-4aa4-B3CB-18DD357B99D0} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 182. kc {7D5095FE-5B08-4c42-BD59-C0AE5265A315} Exciter constant related to selfexcited field iKei. Typical value 1. ke {334F712E-05EF-4919-A6C1-5558E80D59BD} Excitation control system stabilizer gains ikfi gt 0. Typical value 005. kf {40CB6E18-9774-49bc-B1AA-A3F7A585155E} Potential circuit gain coefficient iKiisubisubi gt 0. Typical value 8. ki {F5EBC6C9-F6EB-4bcf-B60F-5CAA5BD5FA0A} Potential circuit gain coefficient iKiisubpsubi gt 0. Typical value 488. kp {438AA8E0-EC2A-4335-A741-8F099D607516} Voltage regulator time constant iTai gt 0. Typical value 015. ta {E4574F75-ABB8-46e5-BA32-AFB2A0EF8AEC} Voltage regulator time constant iTbi gt 0. Typical value 0. tb {F083AE64-1099-4367-9F63-17026ACEC1C9} Voltage regulator time constant iTci gt 0. Typical value 0. tc {7E2421E3-C609-4fcf-B228-BCE66EC6F370} Exciter time constant integration rate associated with exciter control iTei gt 0. Typical value 05. te {2FF502DB-FC0D-4fac-B790-C8B2743FE5E7} Excitation control system stabilizer time constant iTfi gt 0. Typical value 07. tf {394F4FFC-7825-4681-B651-3326632EEF09} Maximum voltage regulator outputs iVrmaxi gt 0. Typical value 1. vrmax {10DE218B-1E0C-43bb-8834-4E1153698116} Minimum voltage regulator outputs iVrmini lt 0. Typical value 1. vrmin {7B1AEA0E-E3D0-4f18-8F81-DFF7DF4CFBA9} Maximum AVR output iEfdmaxi gt 0. Typical value 69. efdmax {B49CC0D1-FF73-4ede-BA5D-2DD5DDEC017E} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 11. kc {759F8FC1-9C06-4000-B69C-92FEFA3DDD62} Feedback gain constant of the inner loop field regulator iKgi gt 0. Typical value 1. kg {C962B310-42A4-4dee-B320-59C167AFEB20} Potential circuit gain coefficient iKiisubisubi gt 0. Typical value 483. ki {EB7FD237-72F1-4807-BCFB-94A3A09D05B7} AVR gain iKji gt 0. Typical value 200. kj {2E8AD6FA-9042-47c9-B00D-325156CD6AE1} Forward gain constant of the inner loop field regulator iKmi gt 0. Typical value 704. km {0D6CDDEA-0034-4de5-AD0B-F4B58970262D} Potential source gain iKiisubpsubi gt 0. Typical value 437. kp {31D10031-B358-47c1-96D0-9D4D7C67AD71} Coefficient to allow different usage of the modelspeed coefficient iKsi. Typical value 0. ks {112D9E88-EF72-4d1c-85B1-A544F84CAF93} Coefficient to allow different usage of the modelspeed coefficient iKs1i. Typical value 0. ks1 {C4A5C191-9F4A-4535-9579-04D479582852} Voltage regulator time constant iTbi gt 0. Typical value 667. tb {3A50E6F6-3D29-4201-B6DB-C63623D018BB} Voltage regulator time constant iTci gt 0. Typical value 1. tc {0E068C63-6C9B-41a1-AF39-BB489330DC3D} Potential circuit phase angle ithetaiisubpsubi. Typical value 20. thetap {95EDEBF4-177D-410e-9BAD-297391272654} Forward time constant of inner loop field regulator iTmi gt 0. Typical value 1. tm {F207B687-878E-4557-85DF-8254522CB6EB} Maximum excitation voltage iVbmaxi gt 0. Typical value 863. vbmax {806CEC8A-3D3B-4db2-B231-FF5CB5460B43} Maximum inner loop feedback voltage iVgmaxi gt 0. Typical value 653. vgmax {C7F51423-E9FB-4dc2-875D-A6EBCEE837FE} Maximum voltage regulator input limit iVimaxi gt 0. Typical value 02. vimax {0B040704-DE08-4fd0-82B0-F6581783A2BD} Minimum voltage regulator input limit iVimini lt 0. Typical value 02. vimin {9BC9955E-E99F-4553-9757-085DE4195D79} Maximum voltage regulator output iVrmaxi gt 0. Typical value 1. vrmax {6F1CDD75-B4DE-499f-A087-2068F39F2797} Minimum voltage regulator output iVrmini lt 0. Typical value 1. vrmin {0A385D67-19AA-4727-8F12-2C0943FB5733} Reactance associated with potential source iXli gt 0. Typical value 009. xl {A84048A2-51DD-4bf5-8FF0-41F0BBA7ECF3} Rectifier loading factor proportional to commutating reactance iKci gt 0. Typical value 0113. kc {6EDEFCBA-079E-4290-854D-CDF8DB25FE4C} Feedback gain constant of the inner loop field regulator iKgi gt 0. Typical value 0. kg {14A18922-E6B8-409f-861B-F794FB4A98AD} Potential circuit gain coefficient iKii gt 0. Typical value 0. ki {D2007931-E17A-4553-A7FD-CAC7E75A0014} Voltage regulator integral gain output iKimi. Typical value 0. kim {4A7B2A9D-6E61-45f0-84C3-99F7E6328846} Voltage regulator integral gain iKiri. Typical value 1075. kir {E0AD83C8-3786-431a-A705-2E9653CA6CB9} Potential circuit gain coefficient iKpi gt 0. Typical value 93. kp {7B352853-2448-486c-9924-E37B59371786} Voltage regulator proportional gain output iKpmi. Typical value 1. kpm {13AAB946-F17E-4fbf-9A11-CD1811931F25} Voltage regulator proportional gain iKpri. Typical value 1075. kpr {E7B37141-1F44-4f27-803C-812CFD52473E} Voltage regulator time constant iTai gt 0. Typical value 002. ta {4EBCE4F0-94D6-4f08-B2E7-F6369BFDC94F} Potential circuit phase angle ithetaiisubpsubi. Typical value 0. thetap {7FD0BF6C-F14E-431c-ADC2-05A61971660F} Maximum excitation voltage iVbmaxi gt 0. Typical value 1163. vbmax {4E09E42B-F894-4f5d-BE2D-D6E1AB8D3AE7} Maximum inner loop feedback voltage iVgmaxi gt 0. Typical value 58. vgmax {FB46EB5E-7D7F-451d-B5B6-22A5554D225E} Maximum inner loop output iVmmaxi gt ExcST4B.vmmin. Typical value 99. vmmax {E94E8EBE-D461-4f60-9238-A0EAA59D8AE3} Minimum inner loop output iVmmini lt ExcST4B.vmmax. Typical value 99. vmmin {D145E2BF-D2C8-4ca7-BF37-F3D3F297A10E} Maximum voltage regulator output iVrmaxi gt 0. Typical value 1. vrmax {E7742CB5-2678-4bc7-82C4-B2E91C3E65A5} Minimum voltage regulator output iVrmini lt 0. Typical value 087. vrmin {00E16C89-365B-4353-B025-D9C196BFC28D} Reactance associated with potential source iXli gt 0. Typical value 0124. xl {47EC3F39-C11A-44c7-A2BF-FC7A201AC00D} Exciter output current limit reference iIlri gt 0. Typical value 4164. ilr {FCA8A10C-DBAD-4049-B59E-F187762F1A65} Exciter output current limit adjustment iKcli gt 0. Typical value 10577. kcl {3A03D787-8FC6-4517-8C9E-3F88D4BA4916} Precontrol gain constant of the inner loop field regulator iKffi. Typical value 1. kff {3A3B956C-CA37-4a16-B43C-D4DCCE5098AB} Feedback gain constant of the inner loop field regulator iKgi gt 0. Typical value 1. kg {E5BA9747-D3A5-480e-8B33-2537D34D3BB3} Voltage regulator integral gain iKiai gt 0. Typical value 45094. kia {478B94F9-DE07-4bd3-922D-AF36B9CEEBF3} Exciter output current limit adjustment iKcli gt 0. Typical value 1733. klr {8C470550-6C26-4c95-887D-97C43A96F782} Forward gain constant of the inner loop field regulator iKmi. Typical value 1. km {C253D207-1AB9-4e5b-A328-470BCC10BE64} Voltage regulator proportional gain iKpai gt 0. Typical value 18038. kpa {604F5148-D7EE-4b63-9F25-EC486268D709} Voltage regulator derivative gain iKvdi. Typical value 0. kvd {A44EC6DA-DCAD-492c-ADF9-BBBAF462B5CF} OEL input selector iOELini. Typical value noOELinput corresponds to iOELini 0 on diagram. oelin {BC9CF815-45CE-47c3-B93E-60A221E7347B} Feedback time constant of inner loop field voltage regulator iTgi gt 0. Typical value 002. tg {EDC9DD41-AAB5-44ad-9270-B02302733648} Rectifier firing time constant iTsi gt 0. Typical value 0. ts {D5C32325-C614-45c1-9CEA-BEA8BD26A1F8} Voltage regulator derivative gain iTvdi gt 0. Typical value 0. tvd {A4BF77C2-C3E0-4953-882B-C195B6215241} Maximum voltage regulator output iVamaxi gt 0. Typical value 481. vamax {C1C060E9-F615-404e-8C90-3839006F23D1} Minimum voltage regulator output iVamini lt 0. Typical value 385. vamin {D8D69CA0-4560-454c-86AD-186598946A99} Maximum voltage regulator input limit iVimaxi gt ExcST6B.vimin. Typical value 10. vimax {9911F24C-D092-46c4-916A-BB94D6C159DB} Minimum voltage regulator input limit iVimini lt ExcST6B.vimax. Typical value 10. vimin {E76D3012-490C-4cf4-8ACB-30708748B417} Maximum voltage regulator output iVrmaxi gt 0. Typical value 481. vrmax {264FE55C-A470-450e-830D-409B9D222CFC} Minimum voltage regulator output iVrmini lt 0. Typical value 385. vrmin {9D2C0854-E7FD-4a26-AEF6-F2F9EDBEA19E} Excitation source reactance iXci. Typical value 005. xc {CFE95EFB-D6A9-4460-A7BB-9F16B7A60E8D} Highvalue gate feedback gain iKhi gt 0. Typical value 1. kh {70132C02-89DD-4f18-9B11-50094001F527} Voltage regulator integral gain iKiai gt 0. Typical value 1. kia {2632802D-0AC4-4221-858A-B3521F14A671} Lowvalue gate feedback gain iKli gt 0. Typical value 1. kl {4440B121-48D5-4f2a-91B3-720A655A30D4} Voltage regulator proportional gain iKpai gt 0. Typical value 40. kpa {C26A669A-D7BA-4113-A91F-37634F96916D} OEL input selector iOELini. Typical value noOELinput. oelin {55897842-91B8-4c4a-A38E-A88FB78B11FF} Regulator lag time constant iTbi gt 0. Typical value 1. tb {8BB6C432-DA6F-4daa-B7F3-678A02D9506D} Regulator lead time constant iTci gt 0. Typical value 1. tc {E341A921-3731-4bad-9E4C-022AB18CE5AA} Excitation control system stabilizer time constant iTfi gt 0. Typical value 1. tf {265813C0-D043-40be-9342-679FAB10BB01} Feedback time constant of inner loop field voltage regulator iTgi gt 0. Typical value 1. tg {DB87FE62-391C-4c72-82F6-446933866664} Feedback time constant iTiai gt 0. Typical value 3. tia {FB558E6B-74F6-4bb2-9DF0-8A453A4D24C2} Rectifier firing time constant iTsi gt 0. Typical value 0. ts {95E5DCB2-CE79-470f-AAA6-871EA7220C07} UEL input selector iUELini. Typical value noUELinput. uelin {CC627920-D4D5-4fd6-A639-11C670C7E6F2} Maximum voltage reference signal iVmaxi gt 0 and gt ExcST7B.vmin. Typical value 11. vmax {21F6CF25-E060-48c9-99F8-04D529E13492} Minimum voltage reference signal iVmini gt 0 and lt ExcST7B.vmax. Typical value 09. vmin {FB2ADFC3-91ED-49cd-97B3-CB0F47BCC7FE} Maximum voltage regulator output iVrmaxi gt 0. Typical value 5. vrmax {EE9E1285-0A4B-4d4d-B499-BDAB8948BA20} Minimum voltage regulator output iVrmini lt 0. Typical value 45. vrmin {E3868033-D2EC-4050-BA79-4C0614B10136} Discontinuous excitation control model associated with this excitation system model. DiscontinuousExcitationControlDynamics {A3CB1790-95C9-404f-AA0A-91B8334A0AD4}.ClientEnd Overexcitation limiter model associated with this excitation system model. OverexcitationLimiterDynamics {A6EC8E29-6996-4dba-B736-0ACEAFBAD928}.ClientEnd Power factor or VAr controller type 1 model associated with this excitation system model. PFVArControllerType1Dynamics {A9638A5A-FA55-428d-8A6E-7CD1F44F4703}.ClientEnd Power factor or VAr controller type 2 model associated with this excitation system model. PFVArControllerType2Dynamics {5FBF52C8-0201-4d22-996D-1457516FB808}.ClientEnd Power system stabilizer model associated with this excitation system model. PowerSystemStabilizerDynamics {EC18A533-5643-4fe6-87AE-2182DD4C9F1F}.ClientEnd Synchronous machine model with which this excitation system model is associated. SynchronousMachineDynamics {C7679E92-5BAF-4548-868A-CE939B02A5E8}.SupplierEnd Undrexcitation limiter model associated with this excitation system model. UnderexcitationLimiterDynamics {280D64B5-2696-4d89-8390-C68A8F827258}.ClientEnd Voltage compensator model associated with this excitation system model. VoltageCompensatorDynamics {261F59A6-26BA-4cfc-9309-36D92F002250}.ClientEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {5206A5D1-9E7E-4283-B6EF-7F3C51885F61}.ClientEnd ExpectedEnergyValues {1952C58A-4A15-483e-A741-9C389499CAAB}.SupplierEnd ExpectedEnergy {1952C58A-4A15-483e-A741-9C389499CAAB}.ClientEnd RegisteredResource {29590DFD-E80A-489e-9558-7515799A9C17}.ClientEnd extensionsItem {F3F93A94-3B64-40c9-8285-0A1EE26EADEF} Power Frequency Bias. This is the change in power injection divided by the change in frequency and negated. A positive value of the power frequency bias provides additional power injection upon a drop in frequency. governorSCD {01E4CD87-A49A-4ae9-BFB1-C80033BBD38C} Maximum initial symmetrical shortcircuit currents Ik max in A Ik SkSQRT3 Un. Used for short circuit data exchange according to IEC 60909. maxInitialSymShCCurrent {A9F4F42E-246F-4da4-AE34-14AE148CF3BF} Maximum active power of the injection. maxP {C915FB34-81C2-4752-9F7A-23941C7E985F} Maximum reactive power limit. It is used for modelling of infeed for load flow exchange and not for short circuit modelling. maxQ {7AE475FE-0F78-42e3-81B1-8C8744B9062F} Minimum initial symmetrical shortcircuit currents Ik min in A Ik SkSQRT3 Un. Used for short circuit data exchange according to IEC 60909. minInitialSymShCCurrent {CEA5D0C1-40FF-4bc9-9887-7E2C67B4A121} Minimum active power of the injection. minP {EC098689-7996-4822-A83C-ED6ADCE4CF9B} Minimum reactive power limit. It is used for modelling of infeed for load flow exchange and not for short circuit modelling. minQ {B2CF8876-6398-4362-B2B8-7BC11A81F53E} Active power injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for steady state solutions. p {AA86E221-E69B-41af-BB7C-A899574AC007} Reactive power injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for steady state solutions. q {747953B0-23CB-4f85-B09F-C9828637BB1C} Voltage factor in pu which was used to calculate shortcircuit current Ik and power Sk. Used only if short circuit calculations are done according to superposition method. voltageFactor {F0AAD163-7313-4376-9CED-46F863F38E66} Kind of FACTS device. kind {C566FB1F-C93C-4dc5-A309-8A9528B43B55} EnergyPriceCurve {38EA7E7F-BA90-431d-816C-66C5286F4757}.ClientEnd Flowgate {DFEE65EA-08ED-41f3-910F-446DC7C3B26D}.ClientEnd Pnodes {A43D8B73-D014-475b-8461-B03EC8169BB8}.SupplierEnd Quantity typically MWs Seller owns all rights being offered MWs over time on same Point of Receipt Point of Delivery or Resource. baseEnergy {0637C1BB-0D22-4afa-8210-FD0ECB0ABCCA} Reason for breaker failure. breakerFailureReason {C4A89781-F158-49af-A637-8B7841514B3E} Classification of failure. failureClassification {01072E4A-F4DF-4aac-ADE1-0C655E70D4F5} How the asset failure was isolated from the system. failureIsolationMethod {F7A2DC7A-E078-4763-B73A-8ABF2A1527C5} What asset failed to be able to do. failureMode {BB740CCA-3762-4f42-AB1A-8F9CBD6C51A9} Reason for transformer failure. transformerFailureReason {F9271E6F-C0A5-4d64-A94F-5E282FB75976} All types of fault cause. FaultCauseTypes {76F2310A-9AC3-4fb7-87A4-E24B2A669076}.SupplierEnd Equipment carrying this fault. FaultyEquipment {6B3EA616-0934-425c-A898-1D84DADF5261}.SupplierEnd Location {7F84E357-68DD-4257-BD11-EE226FADA1E6}.SupplierEnd Outage associated with this fault. Outage {B23C14B3-6E9C-4b0c-82C5-781ED12E4406}.ClientEnd Fault impedance. Its usage is described by kind. impedance {4DFBDAF9-B528-44d1-A3D3-8CBABD131499} The kind of phase fault. kind {D4AF3A43-0D83-418f-997A-3957B4A762CC} The phases participating in the fault. The fault connections into these phases are further specified by the type of fault. phases {18AAE005-424C-4b89-941E-5D72E4C2075B} ConfigurationEvent {B79138C2-DB7B-43a8-A72B-77D615EB381B}.ClientEnd All faults with this cause type. Faults {76F2310A-9AC3-4fb7-87A4-E24B2A669076}.ClientEnd The resistance of the fault between phases and ground. rGround {DA3016FC-3A48-4d38-B3B3-A21BBF1832FE} The resistance of the fault between phases. rLineToLine {463CA558-541A-42b2-88C0-8E6C80D5471B} The reactance of the fault between phases and ground. xGround {6AC55EA4-E390-491d-AC2A-EF69D162C48A} The reactance of the fault between phases. xLineToLine {36EA383A-71DE-4ead-B46C-66F973DDC08B} Kind of reset mechanisim of this fault indicator. resetKind {E6FE4887-07EB-4b13-97EF-02A0BE271014} The secondary substations that are normally energized from the feeder. Used for naming purposes. Should be consistent with the other associations for energizing terminal specification and the feeder energization specification. NamingSecondarySubstation {D06442E1-D688-4393-8B71-E08E4CA4685F}.SupplierEnd The substations that are normally energized by the feeder. NormalEnergizedSubstation {11C09449-0F39-4372-A153-258CD2A57196}.SupplierEnd The substation that nominally energizes the feeder. Also used for naming purposes. NormalEnergizingSubstation {D83ED2BA-7B91-4a91-81C0-A7CF3669C450}.SupplierEnd The normal head terminal or terminals of the feeder. NormalHeadTerminal {C1A181B0-A25E-4eca-9A0E-394B6E20BB6C}.SupplierEnd Crew {2F2C04F1-3A57-404e-87F0-356183FF8B57}.SupplierEnd FieldDispatchStep {2B5021A8-7C38-4df1-ABED-A71EC82BC277}.SupplierEnd PlannedOutage {37072B50-0229-4a00-A050-8976613B5259}.SupplierEnd UnplannedOutage {D82C3366-0534-4013-898A-7202071B4EF5}.SupplierEnd FieldDispatchHistory {2B5021A8-7C38-4df1-ABED-A71EC82BC277}.ClientEnd The status of one or more crews dispatched to perform field work at one or more work sites dispatchStatus {AE292504-F155-4d8c-8F8E-371BDFDF9A65} All safety documents issued to this supervisor. IssuedSafetyDocuments {9928D926-C37A-4b01-9B70-087C54DA13DA}.SupplierEnd All safety documents released by this supervisor. ReleasedSafetyDocuments {D76F467F-64BC-408a-BE7C-AEA257C59F88}.SupplierEnd The asset to which this financial information relates. Asset {1B0E0E88-6371-4ed9-AD31-7E0799CB9AD6}.SupplierEnd The actual purchase cost of this particular asset. actualPurchaseCost {04BD44E7-FD1C-4292-A8F8-8DADE6AAA622} Value of asset as of valueDateTime. financialValue {D7044F6F-4037-4595-9910-1C2923148DDB} The quantity of the asset if per unit length for example conductor. quantity {BDFF234B-770A-449a-A2C3-4ACD1948F296} AuxillaryValues {6B36C00F-62F3-49c3-998C-F5EDD88A0CA8}.SupplierEnd Unit multiplier of this quantity. multiplier {9A517FCA-1C10-4df0-B2B5-EEC4F2BC2611} Unit of this quantity. unit {99793087-EF72-4fe3-834B-7C2F56A6E5C2} Point {DA5D6A56-1992-4d38-994D-E118A3CDC921}.SupplierEnd TimeSeries {090E7580-E214-4627-9E02-CE3051F6B408}.ClientEnd CongestionRevenueRight {C6E4CA42-E336-4a8a-828E-6AF9E8F25458}.ClientEnd ConstraintResults {18E34024-C496-433d-B129-256CA4377357}.SupplierEnd ContractDistributionFactor {3A09997D-D60D-46df-B010-018CC9A81D1B}.SupplierEnd FTRs {DFEE65EA-08ED-41f3-910F-446DC7C3B26D}.SupplierEnd FlowgateRelief {FAA03841-9BD5-44ff-94D8-81234341632C}.SupplierEnd FlowgateValue {3482FAE4-117E-4132-A682-1E1D2291A577}.SupplierEnd From_SubControlArea {1041B4DE-551C-4099-85BD-E8EBC12523E1}.SupplierEnd GeneratingUnitDynamicValues {88A0B4C3-D5DA-43c8-AF9F-4CD15D7E9B66}.ClientEnd GenericConstraints {DE1D7657-F706-42fa-AB0A-26D34549C4A7}.ClientEnd HostControlArea {AF155808-E637-4950-B9F3-2EAB07EDB824}.ClientEnd InterTie {001E125A-BECE-4e28-A128-A8ADBBEFE8D0}.SupplierEnd InterTieResults {E8AB91AD-788A-4426-BCAB-5F8132B26BE5}.SupplierEnd MktLine {8B57B818-A6B3-4836-BC0E-617E9ABEB67D}.SupplierEnd MktPowerTransformer {E865ED1B-5944-445e-BD28-D928C5FF6389}.SupplierEnd MktTerminal {E72576E6-C983-42fd-AED5-7EBD0160B933}.ClientEnd RegisteredInterTie {B4B4DF5E-5FDD-4ed9-B4E9-ADE4754D4D34}.SupplierEnd SecurityConstraints {D96B3C19-134E-4b97-96C3-34675C1BB168}.SupplierEnd To_SubControlArea {84D89B72-DEA9-4433-B8A9-4EEC604AA936}.SupplierEnd TranmissionRightEntitlement {4577596A-E96F-49da-9220-E1987860787A}.SupplierEnd TransmissionCapacity {8921D733-BE8B-4a9f-BB12-03E6AB71B1AB}.SupplierEnd ViolationLimits {60BE8E0E-9F8A-4813-93AA-E5DC48BEF7A5}.ClientEnd The direction of the flowgate export or import direction {CBEB429F-27C3-4d36-9CED-C02CF4B44D95} Export MW rating exportMWRating {DA6511CE-1D9A-4fcb-A9EB-6315CF80812D} Import MW rating importMWRating {F6392594-E1B4-4aad-90D6-F3EBA308A3AB} FlowgateValue {D6A42AC2-2960-4436-89AF-97FB2C39460D}.SupplierEnd Flowgate {FAA03841-9BD5-44ff-94D8-81234341632C}.ClientEnd Flowgate {3482FAE4-117E-4132-A682-1E1D2291A577}.ClientEnd FlowgatePartner {D6A42AC2-2960-4436-89AF-97FB2C39460D}.ClientEnd Specifies the direction of energy flow in the flowgate flowDirectionFlag {FF6FE5B4-EE2D-4ad7-90F6-4021A1747035} RegisteredResource {F7D2A98A-9DDF-4461-8515-85812EF2DDD4}.ClientEnd The interval for which the forecast is valid. For example a forecast issued now for tomorrow might be valid for the next 2 hours. validFor {A058F840-FDF7-42d9-A803-B4EFD6E20F40} RegisteredResource {6E79A630-6C5D-4ba3-86D5-0BE5A92B7A38}.ClientEnd A fuel allocation schedule shall have a fossil fuel. FuelAllocationSchedules {C8620C74-1F29-40d6-AB8F-9050A6FB2AE7}.SupplierEnd A thermal generating unit may have one or more fossil fuels. ThermalGeneratingUnit {2839ECA7-4BCD-4b58-8243-16046DF6DFBA}.SupplierEnd The type of fossil fuel such as coal oil or gas. fossilFuelType {072D15FA-975B-445a-BEB8-8BA657B0814B} The cost in terms of heat value for the given type of fuel. fuelCost {60B46C0B-BC3D-4dca-8D2A-90266147C1AA} The cost of fuel used for economic dispatching which includes fuel cost transportation cost and incremental maintenance cost. fuelDispatchCost {E40606FD-C5CF-4d3c-A354-048090DAB96C} The efficiency factor for the fuel per unit in terms of the effective energy absorbed. fuelEffFactor {D86EC3C3-5700-4eef-B610-F18175761B7D} Handling and processing cost associated with this fuel. fuelHandlingCost {3E6E4D4B-58BB-4e20-A1BC-20009FE4767D} Relative amount of the given type of fuel when multiple fuels are being consumed. fuelMixture {BF007CFE-6AB1-4639-8D2F-929145E6AA51} The fuels fraction of pollution credit per unit of heat content. fuelSulfur {1DAFF39E-7664-4ddf-85DA-D342BA88A14B} The active power output level of the unit at which the given type of fuel is switched on. This fuel e.g. oil is sometimes used to supplement the base fuel e.g. coal at high active power output levels. highBreakpointP {8B2493B1-E76B-42ef-BE9D-BB05890FBC30} The active power output level of the unit at which the given type of fuel is switched off. This fuel e.g. oil is sometimes used to stabilize the base fuel e.g. coal at low active power output levels. lowBreakpointP {629EC404-D9B1-4bbc-8619-DEF90D6C21F9} Off nominal frequency effect on auxiliary real power. Per unit active power variation versus per unit frequency variation. auxPowerVersusFrequency {5AA8792F-D4FE-49c5-8FC4-173BC334C94B} Off nominal voltage effect on auxiliary real power. Per unit active power variation versus per unit voltage variation. auxPowerVersusVoltage {F61BB20D-2F93-444f-8DFB-8233EB9C8F5B} The control mode of the boiler. boilerControlMode {8E2CCCAF-2DF1-4f2e-8AD3-FB3995E3EA5F} Pressure error deadband. controlPED {8E342210-75CA-46d2-B4A9-5D3007C44D0D} Feedwater time constant ratio. feedWaterTC {217477B3-505F-43c0-8BE9-835027B1587D} Fuel demand limit. fuelDemandLimit {033739E2-3B1F-4077-AD9B-8F1E06ED4EC9} Fuel delay. fuelSupplyDelay {87C42A46-7134-48f1-BCBE-2D802A25AF59} Fuel supply time constant. fuelSupplyTC {0D256B64-7FC9-42aa-B744-00B089C176A1} Mechanical power sensor lag. mechPowerSensorLag {EC99F758-1FC3-480d-8B5C-302FCDA76A36} Throttle pressure setpoint. throttlePressureSP {0128B0B3-F0DD-4cde-8ADD-03C5CE48298D} Frame {EDD89720-4773-45ee-9FB3-8DFFCD2B09AA}.ClientEnd Model frame type of the model frame. ModelFrameType {48C2079D-ACDD-4f43-B91E-201B0B6EEBFB}.SupplierEnd multiplier {72725AEC-C5F4-458b-9558-EF3378A97B34} unit {1400EF48-1ADD-4118-B82C-00E133BEEDD5} Frequency on the AC side. frequency {051B7664-65BB-43d9-8CE0-21A90A2FB4BB} The maximum active power on the DC side at which the frequency converter should operate. maxP {48B1699E-00F5-49b0-BF5D-E2ECD93C664E} The maximum voltage on the DC side at which the frequency converter should operate. maxU {CA02BD7C-C525-4cef-A3FC-AC647F7ABF8B} The minimum active power on the DC side at which the frequency converter should operate. minP {C6727346-BC0E-41f0-9159-C5BC431A4C8A} The minimum voltage on the DC side at which the frequency converter should operate. minU {2E9BA9EF-2B21-46e0-8620-E44A01575A0D} A fuel allocation schedule shall have a fossil fuel. FossilFuel {C8620C74-1F29-40d6-AB8F-9050A6FB2AE7}.ClientEnd A thermal generating unit may have one or more fuel allocation schedules. ThermalGeneratingUnit {B6363E4A-4FC1-40b5-AE09-A51CCFB2B37E}.SupplierEnd The type of fuel which also indicates the corresponding measurement unit. fuelType {A6B03E09-B052-4539-A181-DD2D8A8CC0DD} RegisteredGenerator {D73658B4-E454-4c33-84E3-F4704B76D7FD}.SupplierEnd GasPrice {0E1E2A5F-A268-439c-AD0C-58D72BC2233F}.ClientEnd OilPrice {4309159F-3756-4294-B5A1-E8863F5CEA5B}.ClientEnd RTO {D369B12F-39AD-45d8-B6C9-CDD43DE3458A}.ClientEnd RegisteredGenerator {2A9F12A2-E1BC-468f-B9A6-8FD550AE1D66}.SupplierEnd FuelRegion {0E1E2A5F-A268-439c-AD0C-58D72BC2233F}.SupplierEnd Input to the gate. GateInputPin {0D3AAA53-9731-464c-8DA3-7F929B5C355E}.ClientEnd PinGate {71584FA4-43BB-4d8b-84DF-B578C3B8580C}.SupplierEnd For the ProtectiveAction to be activated the condition for communication needs to be met true. ProtectiveActionCom {D34B99BA-6D10-4f96-88B9-7AD3024A8166}.ClientEnd ProtectiveActionEnabled {1A878962-D12D-4598-ADE4-4D8B2DDE6CA7}.ClientEnd RemedialActionScheme {F4AEF34E-199A-4f15-B975-FF0B28FD8751}.SupplierEnd StageTrigger {5AED1733-5EAF-4438-9A42-E9656E4508DA}.ClientEnd StageTriggerArmed {EB996EFA-4676-43b1-8D6E-DCBC54112791}.ClientEnd StageTriggerCom {5CBC56EA-4603-4ba3-93A1-162E6A7AC535}.ClientEnd TriggerCondition {1E9CF642-F79D-453e-840A-CCAA1AB4A74D}.ClientEnd The logical operation of the gate. kind {9B264C0E-5D19-425e-B695-360A5EF8601D} Gate {0D3AAA53-9731-464c-8DA3-7F929B5C355E}.SupplierEnd The compare operation. aDLogicKind {D0BB4BF2-E3B8-4a44-B804-B04F666C8E16} The duration the compare condition need to be present before given a true. Default is 0 seconds. duration {5B4C1B5B-24C8-4e5f-87C8-15D5CE202B18} The threshold percentage that should be used for compare with the percentage change between input value and threshold value. thresholdPercentage {8DD81831-4791-4f0e-A5EA-42C8D98D4045} AggregatedPnode {909A546B-EA82-4f60-8B44-1E47722DB03E}.ClientEnd DistributionFactorSet {A0057A86-6FBB-46b3-A9AE-B72D9CDACC6F}.ClientEnd IndividualPnode {1A518B75-8859-4a3f-AB51-3C3CD3B54E95}.ClientEnd Standard synchronous machine out of which current flow is being compensated for. SynchronousMachineDynamics {E86FBA0E-B146-4508-95E0-F005CB0E4DF5}.SupplierEnd The standard IEEE type 2 voltage compensator of this compensation. VcompIEEEType2 {85A30109-1473-4ba8-A00B-DA4D28CE2463}.SupplierEnd font color0f0f0fResistive component of compensation of generator associated with this IEEE type 2 voltage compensator for current flow out of another generator iRciji.font rcij {CED75700-A90E-4ca0-A51D-C6E70B233738} font color0f0f0fReactive component of compensation of generator associated with this IEEE type 2 voltage compensator for current flow out of another generator iXciji.font xcij {65AD49AF-DB66-4f21-B2B1-0A8FC21708D6} A generating unit may have one or more cost curves depending upon fuel mixture and fuel cost. GeneratingUnit {7B33215F-75EA-4926-9F28-841CBF3A0F5E}.SupplierEnd A generating unit may have an operating schedule indicating the planned operation of the unit. GeneratingUnit {F1D837F0-09B0-4009-810F-62E6AF45ECC4}.SupplierEnd GeneralClearingResults {839D164D-CDF7-48fd-9700-7D80076D1DB7}.SupplierEnd GeneralClearing {839D164D-CDF7-48fd-9700-7D80076D1DB7}.ClientEnd SubControlArea {52EA9C29-FB61-4524-A03E-85E09C194BB4}.ClientEnd Load PredictionForecast MW by Time Period 5 10 15 loadForecast {D8FD0335-8760-41c8-8192-7F4D379C4FDD} BidSet {DBBF1D0E-B376-4e47-A369-EB0EB0F211C5}.SupplierEnd NotificationTimeCurve {9A5F74CD-56FF-45e1-8BC8-5AD82D6C11B0}.SupplierEnd RampRateCurve {B75E5730-E5F1-4d60-BAEF-5B89FAB09454}.SupplierEnd RegisteredGenerator {C4BA4125-803E-42c1-9C0B-2D5179DA8B57}.ClientEnd SecurityConstraints {EF812433-5985-4f7f-AEE9-C31F08021E9B}.SupplierEnd StartUpCostCurve {2C224C9B-54C9-40f5-8796-E455294849C7}.ClientEnd StartUpTimeCurve {70D9DB41-202E-44ce-B18A-F7269093B950}.ClientEnd Maximum Dn ramp rate in MWmin lowerRampRate {33B8C18F-EB58-4bc5-9C5A-5EE230B92A4B} Power rating available for unit under emergency conditions greater than or equal to maximum economic limit. maxEmergencyMW {3A9CB9D6-B603-436f-B3E5-4935F3E6BDCB} Minimum power rating for unit under emergency conditions which is less than or equal to the economic minimum. minEmergencyMW {0D1E4459-4AB5-4836-B2F4-53B46E31E631} Maximum Up ramp rate in MWmin raiseRampRate {47C13D89-9469-4f29-8FCD-12BBFFE627D8} Resource startup ramp rate MWminute startUpRampRate {8ED10432-6C3F-48f0-B07B-3221E606FB01} ControlArea specifications for this generating unit. ControlAreaGeneratingUnit {682C859C-B9CD-4dde-A959-EB89678BBBD6}.ClientEnd A generating unit may have one or more cost curves depending upon fuel mixture and fuel cost. GenUnitOpCostCurves {7B33215F-75EA-4926-9F28-841CBF3A0F5E}.ClientEnd A generating unit may have an operating schedule indicating the planned operation of the unit. GenUnitOpSchedule {F1D837F0-09B0-4009-810F-62E6AF45ECC4}.ClientEnd A generating unit may have a gross active power to net active power curve describing the losses and auxiliary power requirements of the unit. GrossToNetActivePowerCurves {5A8B2A9D-6CA6-40c5-A362-38519E574F17}.ClientEnd A synchronous machine may operate as a generator and as such becomes a member of a generating unit. RotatingMachine {075455B4-8BAD-4ff0-BF82-B9A27A62A8D2}.SupplierEnd The planned unused capacity spinning reserve which can be used to support emergency load. allocSpinResP {1F5D4B4A-6801-4fc6-8936-04DBB4998742} The planned unused capacity which can be used to support automatic control overruns. autoCntrlMarginP {6718295E-BD0D-4e85-BEB1-3E29975096DE} For dispatchable units this value represents the economic active power basepoint for units that are not dispatchable this value represents the fixed generation value. The value shall be between the operating low and high limits. baseP {61BED29F-6FAD-4dd3-8E38-670E386E9752} Unit control error deadband. When a units desired active power change is less than this deadband then no control pulses will be sent to the unit. controlDeadband {EEBA5F2E-D53D-4d7d-A31C-89958F27B90D} Pulse high limit which is the largest control pulse that the unit can respond to. controlPulseHigh {59777C02-3FD3-4e8b-994C-9ECE05887964} Pulse low limit which is the smallest control pulse that the unit can respond to. controlPulseLow {4F598483-A0C2-4430-8772-3B7E2CE57351} Unit response rate which specifies the active power change for a control pulse of one second in the most responsive loading level of the unit. controlResponseRate {D33CB2D7-6634-43b7-98E0-BC00E9C47873} The efficiency of the unit in converting mechanical energy from the prime mover into electrical energy. efficiency {9C05FAE6-5DC5-4e7f-AC3E-BF89EC1E5D26} The unit control mode. genControlMode {26EC8389-AA1E-4af2-86B8-A5180CC6994B} The source of controls for a generating unit. Defines the control status of the generating unit. genControlSource {7D2A94D5-4ACC-412f-818C-FEA312773FEC} Governor motor position limit. governorMPL {B27D599B-17FC-49b9-8E5B-9C3362843FAF} Governor Speed Changer Droop. This is the change in generator power output divided by the change in frequency normalized by the nominal power of the generator and the nominal frequency and expressed in percent and negated. A positive value of speed change droop provides additional generator output upon a drop in frequency. governorSCD {96994FFA-E19B-4945-A813-0EFF4E608B65} High limit for secondary AGC control. highControlLimit {5170760A-4045-4543-92EC-D055F8D9F82B} Default initial active power which is used to store a powerflow result for the initial active power for this unit in this network configuration. initialP {CC9FC613-AC81-4626-87D4-F4AF0ED17767} Low limit for secondary AGC control. lowControlLimit {3E6466C6-E3A6-4e4d-8355-A07F9B742A65} The normal maximum rate the generating unit active power output can be lowered by control actions. lowerRampRate {DF0E3A44-4CA4-46b6-AC47-5336E7F98FE4} Maximum high economic active power limit that should not exceed the maximum operating active power limit. maxEconomicP {62CC5B01-6098-4901-B00D-F5455C940661} This is the maximum operating active power limit the dispatcher can enter for this unit. maxOperatingP {90C37DAB-392D-4ee6-9648-9B77F316F1BD} Maximum allowable spinning reserve. Spinning reserve will never be considered greater than this value regardless of the current operating point. maximumAllowableSpinningReserve {2D6E3559-8BC0-4d16-94DF-2A84AAEA3170} Low economic active power limit that shall be greater than or equal to the minimum operating active power limit. minEconomicP {E2AA7DB8-B51C-4a60-87DF-84BF0CA0E294} This is the minimum operating active power limit the dispatcher can enter for this unit. minOperatingP {5F668F34-E61A-467a-893F-E7E46A3BCE82} Minimum time interval between unit shutdown and startup. minimumOffTime {3A5AB7E8-8785-4df2-905B-0EC62CDB55BC} Detail level of the generator model data. modelDetail {181DA738-39E3-49f5-8AEB-2EF181A9CBFA} The nominal power of the generating unit. Used to give precise meaning to percentage based attributes such as the governor speed change droop governorSCD attribute.The attribute shall be a positive value equal to or less than RotatingMachine.ratedS. nominalP {B11EF073-DEE6-49eb-BFCB-F354BD7764CA} The normal maximum rate the generating unit active power output can be raised by control actions. raiseRampRate {74265370-26DF-4cc7-924A-E7F236BA6259} The units gross rated maximum capacity book value.The attribute shall be a positive value. ratedGrossMaxP {0778CB94-7024-438a-A36A-4B8890E49C72} The gross rated minimum generation level which the unit can safely operate at while delivering power to the transmission grid.The attribute shall be a positive value. ratedGrossMinP {2CB7C074-A213-4539-8C0C-954E59FD158D} The net rated maximum capacity determined by subtracting the auxiliary power used to operate the internal plant machinery from the rated gross maximum capacity.The attribute shall be a positive value. ratedNetMaxP {08CAD54F-B098-4615-968F-A42A0DB56AC5} The initial startup cost incurred for each start of the GeneratingUnit. startupCost {59C81DCB-E449-4f74-9832-7314FC2842A9} Time it takes to get the unit online from the time that the prime mover mechanical power is applied. startupTime {7B3E6342-0BE6-47f5-BE64-25B61DFA8B3A} The efficiency of the unit in converting the fuel into electrical energy. totalEfficiency {086F12C2-E050-4c15-B92A-9003226BCD9E} The variable cost component of production per unit of ActivePower. variableCost {48530DFC-135F-41ec-AB43-9A8B74E49F2B} Flowgate {88A0B4C3-D5DA-43c8-AF9F-4CD15D7E9B66}.SupplierEnd MktGeneratingUnit {068663E7-88C7-413e-9ACC-BB0E7776514E}.SupplierEnd ProvidedBy {824933A0-9111-4506-81AD-C90C98EB9B66}.ClientEnd Maximum real power limit. maxP {CEDE215E-3C0F-4ab4-A78E-B22F0D13026F} Maximum reactive power limit. maxQ {0991B405-A98B-4f18-8367-998F2378C290} Minimum real power generated. minP {17EA8B2A-24D3-4fff-BB41-78B155E40156} Minimum reactive power generated. minQ {1AA72317-0104-4dd5-9A00-677D98C78088} Directaxis subtransient resistance. rDirectSubtrans {C067DDB7-FED9-4a24-9A24-3544A27A32B6} Directaxis synchronous resistance. rDirectSync {216CBBD8-2C5E-4443-B086-EF40563E4AE7} Directaxis transient resistance. rDirectTrans {E0EE9B44-CAD8-4239-9309-1BF0945DB3E4} Quadratureaxis subtransient resistance. rQuadSubtrans {D69BF9DD-80AC-49e6-BC8F-817DD0ADB25D} Quadratureaxis synchronous resistance. rQuadSync {EA6C67B1-9E4E-4c32-B179-F88495B5D53D} Quadratureaxis transient resistance. rQuadTrans {5C38980E-CFE1-4599-8B78-9AE138F14741} Directaxis subtransient reactance. xDirectSubtrans {C885051F-1AC6-42be-9B19-56E9D719BC66} Directaxis synchronous reactance. xDirectSync {A1006CC7-77E9-40b2-9DE5-7E242D3B92CD} Directaxis transient reactance. xDirectTrans {4FE0A5E4-9832-40b3-B337-1008BF42E0F9} Quadratureaxis subtransient reactance. xQuadSubtrans {2664207C-EA94-4c0f-B473-078B65D601A8} Quadratureaxis synchronous reactance. xQuadSync {FCD2ED71-FFA4-4af7-A023-829D28D479FA} Quadratureaxis transient reactance. xQuadTrans {6B7F7A1E-C890-4792-8E16-1763DB18707A} PowerSystemResource {7F56BF7C-C7AA-432b-8454-59AE37E0C7F8}.SupplierEnd Flowgate {DE1D7657-F706-42fa-AB0A-26D34549C4A7}.SupplierEnd TransmissionCapacity {384C3E51-C664-4bf5-A75C-E0697CE38B7D}.SupplierEnd All subgeographical regions within this geographical region. Regions {023E20DF-DF02-4ffb-A047-E5BBDB18AB59}.SupplierEnd Kind of geospheric analog. kind {E8705F4C-3A5E-47fa-85D3-E7AB9C469376} Speed governor deadband in PU speed idbi. In the majority of applications it is recommended that this value be set to zero. Typical value 0. db {1F2F9638-E2C0-4ad9-A56E-17407C762BD7} Speed sensitivity coefficient iDmi. iDmi can represent either the variation of the engine power with the shaft speed or the variation of maximum power capability with shaft speed. If it is positive it describes the falling slope of the engine speed verses power characteristic as speed increases. A slightly falling characteristic is typical for reciprocating engines and some aeroderivative turbines. If it is negative the engine power is assumed to be unaffected by the shaft speed but the maximum permissible fuel flow is taken to fall with falling shaft speed. This is characteristic of singleshaft industrial turbines due to exhaust temperature limits. Typical value 0. dm {71820DA6-2706-4458-88A0-20F956E13AD4} Acceleration limiter gain iKai. Typical value 10. ka {DCA687A7-C276-4bc6-A92B-9480E9B0D82E} Governor derivative gain iKdgovi. Typical value 0. kdgov {C0C8A3D9-B473-4e5a-894C-A4C3E33B42B9} Governor integral gain iKigovi. Typical value 2. kigov {24B5987E-823E-4bd2-804A-719E059BD939} Load limiter integral gain for PI controller iKiloadi. Typical value 067. kiload {975F88A9-80D8-4bc0-B275-1F4A2DAE0729} Power controller reset gain iKimwi. The default value of 001 corresponds to a reset time of 100 s. A value of 0001 corresponds to a relatively slowacting load controller. Typical value 001. kimw {E5A95F4A-2C34-44de-A1AC-2B6C76EAC3B6} Governor proportional gain iKpgovi. Typical value 10. kpgov {95AFE270-83FE-4893-9E66-BB171BD64952} Load limiter proportional gain for PI controller iKploadi. Typical value 2. kpload {BFFC2751-105D-40b9-9516-1F5D84ED58B2} Turbine gain iKturbi gt 0. Typical value 15. kturb {3001C9F9-9263-4059-9722-1CAEE3EE5598} Load limiter reference value iLdrefi. Typical value 1. ldref {F71C2E67-F670-4459-903B-FC4C7A83A994} Maximum value for speed error signal imaxerri gt GovCT1.minerr. Typical value 005. maxerr {19F506B9-F125-412e-9BE4-83C600F0BE1E} Minimum value for speed error signal iminerri lt GovCT1.maxerr. Typical value 005. minerr {435E2931-1B95-4476-A660-E0AC517EEDDE} Base for power values iMWbasei gt 0. Unit MW. mwbase {11C3B1FC-99D3-4f1f-9091-93732BDF5621} Permanent droop iRi. Typical value 004. r {2A8FF93B-DBE4-4a02-983E-3957E8132B9A} Maximum rate of load limit decrease iRdowni. Typical value 99. rdown {ADD1DE1E-D3B6-4e09-8459-37AEBEE092BC} Feedback signal for droop iRselecti. Typical value electricalPower. rselect {62A176EF-DA19-41ee-B7DC-02C52FE22B0E} Maximum rate of load limit increase iRupi. Typical value 99. rup {988EB45B-4BD2-4eca-83F5-79F3E645CAF8} Acceleration limiter time constant iTai gt 0. Typical value 01. ta {EFBE3FF7-A860-41f4-8C1D-FC066E8D3ED1} Actuator time constant iTacti gt 0. Typical value 05. tact {B65C3493-923E-4ac2-9811-98079D855150} Turbine lag time constant iTbi gt 0. Typical value 05. tb {F56DAE19-35E3-4d26-8F54-E57BDCF213E2} Turbine lead time constant iTci gt 0. Typical value 0. tc {273F4064-EFB4-4dc9-BB32-F6C316B76A4A} Governor derivative controller time constant iTdgovi gt 0. Typical value 1. tdgov {AADB6002-51D6-440a-926B-8958FD04F9DC} Transport time delay for diesel engine used in representing diesel engines where there is a small but measurable transport delay between a change in fuel flow setting and the development of torque iTengi gt 0. iTengi should be zero in all but special cases where this transport delay is of particular concern. Typical value 0. teng {3C48B77E-EEC9-4bb5-AE7C-8FBF40B2EA42} Loadlimiter time constant iTfloadi gt 0. Typical value 3. tfload {8DDF6345-31C1-4309-AEC1-A6349D16E0CF} Electrical power transducer time constant iTpeleci gt 0. Typical value 1. tpelec {D145F158-DBD0-4961-BAAF-095E1E36EAD1} Temperature detection lead time constant iTsai gt 0. Typical value 4. tsa {C9A3081E-ED67-4df3-9999-64AC59151732} Temperature detection lag time constant iTsbi gt 0. Typical value 5. tsb {D435F302-D53E-4833-AE46-88ABDD6A8DA0} Maximum valve position limit iVmaxi gt GovCT1.vmin. Typical value 1. vmax {08DAC325-81F5-41c4-AFCE-6CBA6F705FE0} Minimum valve position limit iVmini lt GovCT1.vmax. Typical value 015. vmin {053C5410-E2C4-4708-B724-23E65A8D8496} No load fuel flow iWfnli. Typical value 02. wfnl {8741996D-7CF1-49f7-B0B5-D351F23F98AB} Speed governor deadband in PU speed idbi. In the majority of applications it is recommended that this value be set to zero. Typical value 0. db {B1E307A2-31D8-41e5-A45C-113ACC08CCDB} Speed sensitivity coefficient iDmi. iDmi can represent either the variation of the engine power with the shaft speed or the variation of maximum power capability with shaft speed. If it is positive it describes the falling slope of the engine speed verses power characteristic as speed increases. A slightly falling characteristic is typical for reciprocating engines and some aeroderivative turbines. If it is negative the engine power is assumed to be unaffected by the shaft speed but the maximum permissible fuel flow is taken to fall with falling shaft speed. This is characteristic of singleshaft industrial turbines due to exhaust temperature limits. Typical value 0. dm {6B4551A2-A769-42e7-8766-248F419EEF70} Frequency threshold 1 iFlim1i. Unit Hz. Typical value 59. flim1 {9EC8978A-2C3D-47c8-A2C8-690593D0CD70} Frequency threshold 10 iFlim10i. Unit Hz. Typical value 0. flim10 {DAB43067-9223-4ff1-BE29-D9D70D0B0597} Frequency threshold 2 iFlim2i. Unit Hz. Typical value 0. flim2 {E1FEB400-CC03-416e-A834-AAB59A889F5F} Frequency threshold 3 iFlim3i. Unit Hz. Typical value 0. flim3 {01592279-2A42-4153-9EBC-44913C81AC67} Frequency threshold 4 iFlim4i. Unit Hz. Typical value 0. flim4 {1D53C016-BB44-4c49-8FAD-AA936A09A713} Frequency threshold 5 iFlim5i. Unit Hz. Typical value 0. flim5 {7492E59F-5841-428e-B9FB-A459E80AF91A} Frequency threshold 6 iFlim6i. Unit Hz. Typical value 0. flim6 {80D49807-0A34-4232-9738-F1EFEBA5CE97} Frequency threshold 7 iFlim7i. Unit Hz. Typical value 0. flim7 {B314EA22-F268-4a9f-9EF8-47C80C4ED7EC} Frequency threshold 8 iFlim8i. Unit Hz. Typical value 0. flim8 {6DFBEDFF-068D-4578-82A1-57BE09AED551} Frequency threshold 9 iFlim9i. Unit Hz. Typical value 0. flim9 {0122E53A-E52D-499c-8C61-9977CA711C4F} Acceleration limiter gain iKai. Typical value 10. ka {AD9A5421-FF79-4fa3-9955-AF2114F8D3FB} Governor derivative gain iKdgovi. Typical value 0. kdgov {7D85D163-296C-4d4d-A5BF-59795E29B47D} Governor integral gain iKigovi. Typical value 045. kigov {E72CBF33-4107-4ec5-8BFA-2EB4DF0F8BE8} Load limiter integral gain for PI controller iKiloadi. Typical value 1. kiload {8357AAD1-E716-4487-BB97-3FDC2A770121} Power controller reset gain iKimwi. The default value of 001 corresponds to a reset time of 100 seconds. A value of 0001 corresponds to a relatively slowacting load controller. Typical value 0. kimw {1536B628-C3F8-494d-970C-BA2B7741EF1F} Governor proportional gain iKpgovi. Typical value 4. kpgov {4767D01C-B187-4245-A8B3-FCBDB01AB18F} Load limiter proportional gain for PI controller iKploadi. Typical value 1. kpload {BC9B5A0B-9BDE-4c57-9A65-0AA92ED678E5} Turbine gain iKturbi. Typical value 19168. kturb {4C092125-5E94-4d92-9ED4-62921AE1C83C} Load limiter reference value iLdrefi. Typical value 1. ldref {0F8DF7C4-E603-49d7-8229-B05D5565184D} Maximum value for speed error signal iMaxerri gt GovCT2.minerr. Typical value 1. maxerr {4C434ABB-DBA9-4114-B0FC-9627D66F066A} Minimum value for speed error signal iMinerri lt GovCT2.maxerr. Typical value 1. minerr {BD083295-6042-4340-A3AF-04C25ED8F176} Base for power values iMWbasei gt 0. Unit MW. mwbase {F051FF75-F04D-480d-9B65-AD23AE499091} Power limit 1 iPlim1i. Typical value 08325. plim1 {A38E7D08-E899-48f2-A79E-D25E4AB2131B} Power limit 10 iPlim10i. Typical value 0. plim10 {35DA60BF-1F6B-403c-BD5E-B63A9B59A3DA} Power limit 2 Plim2. Typical value 0. plim2 {E992D293-2BA9-455e-9A47-69DDFF4458A2} Power limit 3 iPlim3i. Typical value 0. plim3 {35AD4466-34EC-4571-95F6-A679262412A3} Power limit 4 iPlim4i. Typical value 0. plim4 {5B430703-A5E1-4e68-BE21-C3B2F40D006D} Power limit 5 iPlim5i. Typical value 0. plim5 {334820BF-B1E4-45af-82BC-9D1C40EB29A5} Power limit 6 iPlim6i. Typical value 0. plim6 {1E611B2E-9A22-4ee0-A606-CA0DE642CDF2} Power limit 7 iPlim7i. Typical value 0. plim7 {31352583-9FAD-40ef-BCE4-0646396BCFC6} Power limit 8 iPlim8i. Typical value 0. plim8 {96E8FA08-BFF0-462e-85F3-6D6AC902A505} Power Limit 9 iPlim9i. Typical value 0. plim9 {0031888A-ADA3-4f90-9FA3-69804C4A86F9} Ramp rate for frequencydependent power limit iPratei. Typical value 0017. prate {5DD4D166-0F8C-48d2-A66E-2A1263822872} Permanent droop iRi. Typical value 005. r {09C63393-129B-4dd2-984E-94D4FF8B563A} Maximum rate of load limit decrease iRdowni. Typical value 99. rdown {AB9EBE18-2954-4f49-ABD2-11D68B74A973} Feedback signal for droop iRselecti. Typical value electricalPower. rselect {D519C9BE-855D-4d33-892C-183D266FDA05} Maximum rate of load limit increase iRupi. Typical value 99. rup {C734EE8E-AE90-404a-BC6E-B5275CE82B36} Acceleration limiter time constant iTai gt 0. Typical value 1. ta {74C0E921-4534-45b6-98EF-AAE5B53E5FF3} Actuator time constant iTacti gt 0. Typical value 04. tact {9AF4BDC5-93F2-455f-99F4-F9CDDC6C136C} Turbine lag time constant iTbi gt 0. Typical value 01. tb {5B057734-D6FD-4698-A1C5-F969BD02EFB0} Turbine lead time constant iTci gt 0. Typical value 0. tc {E5507C19-4FF6-410c-A640-19BA6441CBFF} Governor derivative controller time constant iTdgovi gt 0. Typical value 1. tdgov {4267DFD1-9F8A-4dba-A530-06EDA7DC791D} Transport time delay for diesel engine used in representing diesel engines where there is a small but measurable transport delay between a change in fuel flow setting and the development of torque iTengi gt 0. iTengi should be zero in all but special cases where this transport delay is of particular concern. Typical value 0. teng {25FB30F3-44F4-40e0-BBCC-AF73DADE2832} Load limiter time constant iTfloadi gt 0. Typical value 3. tfload {2B6E9280-2A13-407f-9D93-4B1E045DECF5} Electrical power transducer time constant iTpeleci gt 0. Typical value 25. tpelec {CAEFFCE4-FF92-4948-9850-E11E1B785BFF} Temperature detection lead time constant iTsai gt 0. Typical value 0. tsa {979B4DCF-410D-45a2-B976-BC216F73B2C2} Temperature detection lag time constant iTsbi gt 0. Typical value 50. tsb {1B8F3848-D518-4507-91CF-441A19EC5554} Maximum valve position limit iVmaxi gt GovCT2.vmin. Typical value 1. vmax {E8441676-D766-49e6-818B-763B8DD05D90} Minimum valve position limit iVmini lt GovCT2.vmax. Typical value 0175. vmin {A3779824-E52A-4a57-84DA-4B2DF5C17799} No load fuel flow iWfnli. Typical value 0187. wfnl {153EDD62-68F3-4993-A1C6-88813E54B88D} Ambient temperature load limit iLoad Limiti. Typical value 1. at {56FAD993-8736-4e20-B890-058FB038BC31} Turbine damping factor iDturbi. Typical value 018. dturb {3EA5895C-9257-4379-8A3D-B6F997A85810} Temperature limiter gain iKti. Typical value 3. kt {769624AF-9464-4126-9445-7B9E64F56A10} Base for power values iMWbasei gt 0. Unit MW. mwbase {1CA3D859-BBFE-45e8-B9F8-E8DB4FA52E78} Permanent droop iRi gt0. Typical value 004. r {71F37AE5-473B-4e4c-BEB6-DADE188F583F} Governor mechanism time constant iT1i gt 0. iT1i represents the natural valve positioning time constant of the governor for small disturbances as seen when rate limiting is not in effect. Typical value 05. t1 {AC4D3D92-6624-4861-8751-0D6C798BD44C} Turbine power time constant iT2i gt 0. iT2i represents delay due to internal energy storage of the gas turbine engine. iT2i can be used to give a rough approximation to the delay associated with acceleration of the compressor spool of a multishaft engine or with the compressibility of gas in the plenum of a free power turbine of an aeroderivative unit for example. Typical value 05. t2 {2828896F-6D2F-4873-8C74-0D69399F0552} Turbine exhaust temperature time constant iT3i gt 0. Typical value 3. t3 {2C012AF8-935F-4628-8EF8-40CA7763E8E9} Maximum turbine power PU of MWbase iVmaxi gt GovGAST.vmin. Typical value 1. vmax {EFD4A194-6B9C-413a-A97E-1D4524BBB93F} Minimum turbine power PU of MWbase iVmini lt GovGAST.vmax. Typical value 0. vmin {2EAF6D4A-826E-4fee-9BA1-08A0044DEB3B} Intentional deadband width idb1i. Unit Hz. Typical value 0. db1 {3DE6895A-EEE5-4b31-B9F8-B46965B026C7} Unintentional deadband idb2i. Unit MW. Typical value 0. db2 {C35915F9-E1F0-46b0-BF58-5A2A4D38D7F7} Intentional db hysteresis iepsi. Unit Hz. Typical value 0. eps {DCBCC604-699C-44b9-AA14-A480603898D9} Fuel flow at zero power output iFidlei. Typical value 018. fidle {71DDABC1-4D62-4087-B6B1-5E50CE4AC2A5} Nonlinear gain point 1 PU gv iGv1i. Typical value 0. gv1 {E06CDA93-A254-422c-8E84-E1D24AE53C96} Nonlinear gain point 2PU gv iGv2i. Typical value 0. gv2 {AAF2388C-B687-4e0f-943C-ED61922177EC} Nonlinear gain point 3 PU gv iGv3i. Typical value 0. gv3 {691F02EA-F4D5-43b1-8E52-7CB56FDF1441} Nonlinear gain point 4 PU gv iGv4i. Typical value 0. gv4 {9F9110FD-A2B4-4f84-9492-949875A9C7C1} Nonlinear gain point 5 PU gv iGv5i. Typical value 0. gv5 {F004ADAA-B76F-43c8-B1C7-3623192556DE} Nonlinear gain point 6 PU gv iGv6i. Typical value 0. gv6 {6123327F-ACBA-42da-A65A-86BE9A7F0B26} Governor gain iKai. Typical value 0. ka {AE7517F8-0BA9-451f-B3E9-CFE01BF8785E} Temperature limiter gain iKti. Typical value 3. kt {39606C19-0167-4bd5-9B4C-4AF7D94AED9C} Ambient temperature load limit iLmaxi. iLmaxi is the turbine power output corresponding to the limiting exhaust gas temperature. Typical value 1. lmax {09EB2B8F-9D85-4d12-A12A-F34F85663093} Valve position change allowed at fast rate iLoadinci. Typical value 005. loadinc {84B7E018-DCEE-4b68-8160-C26A1BBBD881} Base for power values iMWbasei gt 0. Unit MW. mwbase {9119B06D-2FDA-475a-A446-027940C1C607} Nonlinear gain point 1 PU power iPgv1i. Typical value 0. pgv1 {A3ABADB7-436B-41ec-A468-B3B2D73954F3} Nonlinear gain point 2 PU power iPgv2i. Typical value 0. pgv2 {BA10A591-0F3A-4154-A413-D0301879FD1F} Nonlinear gain point 3 PU power iPgv3i. Typical value 0. pgv3 {0265C2FC-4392-4c68-9950-EEB13F703BA5} Nonlinear gain point 4 PU power iPgv4i. Typical value 0. pgv4 {CC11422C-C01E-4b25-A8A1-C4636539773B} Nonlinear gain point 5 PU power iPgv5i. Typical value 0. pgv5 {A0433ABD-6C39-4614-A77C-9C2E45DD6988} Nonlinear gain point 6 PU power iPgv6i. Typical value 0. pgv6 {B6886018-FC42-497a-937C-88410225FD97} Permanent droop iRi gt0. Typical value 004. r {7B4E7DBF-073F-4b72-A864-77E23AAE6FF5} Governor mechanism time constant iT1i gt 0. iT1i represents the natural valve positioning time constant of the governor for small disturbances as seen when rate limiting is not in effect. Typical value 05. t1 {E9696364-A2B8-4f03-959D-75A993C64A5A} Turbine power time constant iT2i gt 0. iT2i represents delay due to internal energy storage of the gas turbine engine. iT2i can be used to give a rough approximation to the delay associated with acceleration of the compressor spool of a multishaft engine or with the compressibility of gas in the plenum of the free power turbine of an aeroderivative unit for example. Typical value 05. t2 {64540ACB-5451-44bf-8CDD-F596C4BEAC1F} Turbine exhaust temperature time constant iT3i gt 0. iT3i represents delay in the exhaust temperature and load limiting system. Typical value 3. t3 {5EABA132-95FD-4b43-8826-63E65FAF762D} Governor lead time constant iT4i gt 0. Typical value 0. t4 {D81791D7-28ED-46ce-8021-A3BA70519221} Governor lag time constant iT5i gt 0. If 0 entire gain and leadlag block is bypassed. Typical value 0. t5 {27AAE52A-2F86-4769-834E-813B6C64DBDB} Valve position averaging time constant iTltri gt 0. Typical value 10. tltr {4ED80D64-8C8B-447f-ADA1-6F7CF120C18D} Maximum turbine power PU of MWbase iVmaxi gt GovGAST1.vmin. Typical value 1. vmax {14CA128C-AC3C-4bc1-93BD-8DEA1CA13AAB} Minimum turbine power PU of MWbase iVmini lt GovGAST1.vmax. Typical value 0. vmin {9A64CA9D-3112-449b-B6B4-CAFE72E1AD4D} Exhaust temperature parameter iAf1i. Unit PU temperature. Based on temperature in degrees C. af1 {45D1CDB3-9790-4435-B51F-958417705B7D} Coefficient equal to 051speed iAf2i. af2 {FE4D3144-88D8-4b0d-974C-D8A40367AAB6} iBf1i. iBf1i iEi1 iWi where iEi speed sensitivity coefficient is 055 to 065 x iTri. Unit PU temperature. Based on temperature in degrees C. bf1 {B92A787E-BD67-4e86-9481-88322F441A90} Turbine torque coefficient Ksubhhvsub depends on heating value of fuel stream in combustion chamber iBf2i. bf2 {5A58EC44-4260-407d-8A0A-65062F325410} Coefficient defining fuel flow where power output is 0 iCf2i. Synchronous but no output. Typically 023 x Ksubhhvsub 23 fuel flow. cf2 {189FE130-752A-47d1-A143-C0AEA8CBEC8A} Combustion reaction time delay iEcri gt 0. ecr {C8CC2888-0234-4a6b-9454-E718EC9C5FCE} Turbine and exhaust delay iEtdi gt 0. etd {C6549C57-903E-42a4-A5EC-AA10F1F22E5B} Ratio of fuel adjustment iK3i. k3 {DD0B6D8A-ECB4-42af-8B4A-26F0E6FDCB4E} Gain of radiation shield iK4i. k4 {B184C87E-486E-4431-95EC-A02F85A6A247} Gain of radiation shield iK5i. k5 {442B9151-C66C-42ba-BDE0-7078CAC6074F} Minimum fuel flow iK6i. k6 {9AED82B1-77AF-48cf-A9AA-46A5A7BF2AF7} Fuel system feedback iKfi. kf {57CA2EAB-F0AC-4bd2-8E3C-F519267628E1} Base for power values iMWbasei gt 0. Unit MW. mwbase {D51C0958-8DCB-4518-AD30-9E18CCBF805F} Fuel control time constant iTi gt 0. t {7CA936B5-234A-4a03-B4A6-F6D9E40DDED4} Radiation shield time constant iT3i gt 0. t3 {00AE3E90-B57E-4915-8CC8-257830299FDF} Thermocouple time constant iT4i gt 0. t4 {F93BA02B-3C3D-430f-BF9A-B44884D13DD2} Temperature control time constant iT5i gt 0. t5 {69EDC641-2E10-4217-9A74-F0246EC3C354} Temperature control iTci. Unit F or C depending on parameters iAf1i and iBf1i. tc {E918F440-CD04-4df9-959F-0C4280F74BA7} Compressor discharge time constant iTcdi gt 0. tcd {58B8978E-E048-426d-8403-1A9CDC382868} Fuel system time constant iTfi gt 0. tf {AB8C99F1-2336-4458-B1C9-9C72699E64EB} Maximum turbine limit iTmaxi gt GovGAST2.tmin. tmax {457E7CFE-99B1-4f6d-A785-3592667767FA} Minimum turbine limit iTmini lt GovGAST2.tmax. tmin {580E6981-A7F4-470d-8CA5-BDE825F2F07F} Rated temperature iTri. Unit C depending on parametersi Af1 iand iBf1i. tr {F60CE303-14F5-466e-BB64-CDEA1639D7D7} Turbine rating iTratei. Unit MW. trate {8E5D6A8E-160A-4cc9-B1D3-8AC674C631ED} Temperature controller integration rate iTti gt 0. tt {90C62C8B-D05E-483e-B262-A2F00497D446} Governor gain 1droop on turbine rating iWi. w {2D07300D-F950-4cf0-9119-B374421AD84E} Governor lead time constant iXi gt 0. x {73139190-89B3-49a6-B40C-9B3E882BF9B5} Governor lag time constant iYi gt 0. y {27A89971-0780-4400-A3FC-C3328DCD458A} Droop ibpi. Typical value 005. bp {32C8F38B-3ED4-49dc-BD87-BDCF5996A1A7} Exhaust temperature variation due to fuel flow increasing from 0 to 1 PU ideltaTci. Typical value 390. dtc {FF0EDAE8-A645-44a6-AF77-D1AB52E65AC6} Minimum fuel flow iKai. Typical value 023. ka {01270F02-562D-43e6-A95F-89F75BF99E7B} Fuel flow maximum negative error value iMNefi. Typical value 005. mnef {41DFFB06-4845-4516-B054-7CFBEAC51ACE} Fuel flow maximum positive error value iMXefi. Typical value 005. mxef {A44E5F29-F284-4a40-A9D6-DCB26261646B} Minimum fuel flow iRCMNi. Typical value 01. rcmn {5ABD4AC2-83A6-4521-96D2-C4564EF32AE3} Maximum fuel flow iRCMXi. Typical value 1. rcmx {071DA61F-581D-4533-9AD4-DD252C7D3657} Fuel control time constant iTaci gt 0. Typical value 01. tac {8E9E716B-22A1-4c7d-90B1-406E16125BF8} Compressor discharge volume time constant iTci gt 0. Typical value 02. tc {EA039A7D-EA1A-4234-8C5E-C1A95873945C} Temperature controller derivative gain iTdi gt 0. Typical value 33. td {306776E9-EBA0-4639-9116-DF141F89D537} Turbine rated exhaust temperature correspondent to Pm1 PU iTfeni. Typical value 540. tfen {436A97FD-C667-4c3e-AFB4-58E04364EACF} Time constant of speed governor iTgi gt 0. Typical value 005. tg {903247BF-FA07-4c14-8C39-8CCBBAF12668} Time constant of radiation shield iTsii gt 0. Typical value 15. tsi {974011B1-12BB-41b7-86D2-0AD1CEC5A4B5} Temperature controller integration rate iTti. Typical value 250. tt {DE04646B-0149-4ef5-BABC-5C6345F61444} Time constant of thermocouple iTtci gt 0. Typical value 25. ttc {C9E318B6-94C6-41b6-8BA0-91C5C0FE7FB2} Time constant of fuel valve positioner iTyi gt 0. Typical value 02. ty {74EE6FF5-3F88-4a6c-8A8A-347833CA98C0} Droop ibiisubpsubi. Typical value 005. bp {B0042327-D84B-4f77-84C5-92D654C95F99} Compressor gain iKtmi. Typical value 0. ktm {BCE95750-8510-4e52-870B-1526020B0C69} Fuel flow maximum negative error value iMNefi. Typical value 005. mnef {2E39EE3B-6FF8-41e7-B5FB-4B90351E9AAF} Fuel flow maximum positive error value iMXefi. Typical value 005. mxef {AF76CEFE-2152-403c-A7F0-64AB057B5575} Minimum valve opening iRYMNi. Typical value 0. rymn {8346DE86-66A8-4655-970D-191A4BA7E31D} Maximum valve opening iRYMXi. Typical value 11. rymx {F6F33950-4461-4023-9632-DF5F22447CD3} Maximum gate opening velocity iTAi gt 0. Typical value 3. ta {08B45EBF-58BE-4521-8D83-E0B0575B901E} Maximum gate closing velocity iTCi gt 0. Typical value 05. tc {E413FBF9-2B72-4503-A885-99D375AA93F0} Fuel control time constant iTcmi gt 0. Typical value 01. tcm {36547794-00BE-489d-AAFA-82D56B82E48B} Compressor discharge volume time constant iTmi gt 0. Typical value 02. tm {97E46F38-5DB0-4d7d-B70F-89DF57E3889F} Time constant of fuel valve positioner iTyi gt 0. Typical value 01. ty {EA8EB802-82AA-4181-980B-5AB56A4A7D36} Exhaust temperature parameter iAf1i. af1 {BAD3FD6B-543F-439f-9916-B601A0F797C7} Coefficient equal to 051speed iAf2i. af2 {8F604F6A-68EC-440f-91F8-1903348F2EED} iBf1i. iBf1i iEi1iwi where iEi speed sensitivity coefficient is 055 to 065 x iTri. bf1 {0DE33289-2AED-4ef1-A029-0FF07549AE7B} Turbine torque coefficient Ksubhhvsub depends on heating value of fuel stream in combustion chamber iBf2i. bf2 {90C76F60-AA06-47bf-A995-F69246EA0A22} Coefficient defining fuel flow where power output is 0 iCf2i. Synchronous but no output. Typically 023 x Ksubhhv sub23 fuel flow. cf2 {9938F6C5-6F70-4a1b-8FF1-783310424DEC} Combustion reaction time delay iEcri gt 0. ecr {E2649AC7-0447-4721-9286-0CD92F82CCDA} Turbine and exhaust delay iEtdi gt 0. etd {2F025F5E-0E6E-46d0-993B-12FD2DAB66E5} Ratio of fuel adjustment iK3i. k3 {1BF22E14-F29C-4c06-BA62-F729E97EC481} Gain of radiation shield iK4i. k4 {062F1807-AE26-43a1-A4EB-CA47829BD673} Gain of radiation shield iK5i. k5 {65F461A9-A23A-45d1-AF07-6636C1A51130} Minimum fuel flow iK6i. k6 {25B6A870-C68F-4285-9372-FF25F758DCAE} Drop governor gain iKdi. kd {3CD8EA5C-A3F3-464d-8F75-C955E8B5D411} iKdroopi gt 0. kdroop {53BE233F-E597-435e-9EE8-32762D5769E2} Fuel system feedback iKfi. kf {18034879-9FB3-4d8d-B4AC-B70FF2FB3DC7} Isochronous Governor Gain iKii. ki {06B18E6E-3F42-45f8-B5AC-CFA014647CB1} PID proportional gain iKpi. kp {DF1A90F2-14A2-4959-BD6B-91F3FDF6721C} Base for power values iMWbasei gt 0. Unit MW. mwbase {AD1058DB-3580-425e-B7B4-E620AF7591E9} Fuel control time constant iTi gt 0. t {4496FC4C-2076-4835-B622-0B5A8D831F1B} Radiation shield time constant iT3i gt 0. t3 {4F3EC56D-F128-4311-9955-FC1FD2B3109A} Thermocouple time constant iT4i gt 0. t4 {BF2AFDA2-E1A3-4d2a-BD38-29DE53C2B114} Temperature control time constant iT5i gt 0. t5 {65E05FB4-5E10-4954-AB84-0D5158770FC3} Temperature control iTci. tc {8989E83E-350D-412e-ABFF-98F4620A653A} Compressor discharge time constant iTcdi gt 0. tcd {7AD2404F-9868-475e-AABD-B43E58786C38} Power transducer time constant iTdi gt 0. td {1794CD83-3D07-4080-8914-B555130719A7} Fuel system time constant iTfi gt 0. tf {68DE0768-EB04-4763-AC7A-F51498FE937D} Maximum Turbine limit iTmaxi gt GovGASTWD.tmin. tmax {A2026E04-2E46-4d23-80A9-26CB247809C0} Minimum turbine limit iTmini lt GovGASTWD.tmax. tmin {A222E8D5-F51E-4667-947A-E3692AF0E7E7} Rated temperature iTri. tr {B2CC37AB-1ED9-4fb3-82E1-13EB499510E7} Turbine rating iTratei. Unit MW. trate {775688D9-771C-42f5-ADFB-94FBF83CC532} Temperature controller integration rate iTti gt 0. tt {F80ED7EC-E304-4138-962C-26E978B77294} Turbine gain iAti gt 0. Typical value 12. at {B7667ACF-A3F2-46b5-9D3E-063C9B9449E8} Turbine damping factor iDturbi gt 0. Typical value 05. dturb {755F807F-32CC-441a-BC36-9ED655CCED76} Maximum gate opening iGmaxi gt 0 and gt GovHydro.gmin. Typical value 1. gmax {9446DBF8-C9AF-401c-B824-104D8ABBCBD7} Minimum gate opening iGmini gt 0 and lt GovHydro1.gmax. Typical value 0. gmin {10A3351A-C604-4fba-8CC0-969F1AED05FB} Turbine nominal head ihdami. Typical value 1. hdam {F36E6359-6BDC-4bf8-9AE2-FFA83D3305DD} Base for power values iMWbasei gt 0. Unit MW. mwbase {53C775F6-5EDB-47f7-B289-3D4CDA27036F} Noload flow at nominal head iqnli gt 0. Typical value 008. qnl {E92E8ECF-2FB1-4bb7-A8FC-E72000068EFE} Permanent droop iRi gt 0. Typical value 004. rperm {9BE9B3D7-3418-4731-92B2-F7C837C1D5D6} Temporary droop iri gt GovHydro1.rperm. Typical value 03. rtemp {6AC646D5-1AA8-4094-82A5-8C3E51C76DC1} Filter time constant iTfi gt 0. Typical value 005. tf {34CD9FC9-5BEC-4716-8C51-42A2248E4AB1} Gate servo time constant iTgi gt 0. Typical value 05. tg {C2E7046C-F87E-463c-B8DC-0A1659464824} Washout time constant iTri gt 0. Typical value 5. tr {8ED7DB99-BFE1-4f4d-A514-A485B51FF796} Water inertia time constant iTwi gt 0. Typical value 1. tw {29D38CF8-2E1A-4871-893C-5EA177EA05B5} Turbine numerator multiplier iAturbi. Typical value 1. aturb {62ED2FCB-050A-4e79-8966-FB7F2EF07CE4} Turbine denominator multiplier iBturbi gt 0. Typical value 05. bturb {E3809028-3CEF-4107-B272-07CC7A261105} Intentional deadband width idb1i. Unit Hz. Typical value 0. db1 {97534C85-AB6A-478a-A705-11AA3D60F5DB} Unintentional deadband idb2i. Unit MW. Typical value 0. db2 {D73EA3B4-D639-4809-A28A-735E1C1A0A4B} Intentional db hysteresis iepsi. Unit Hz. Typical value 0. eps {08085396-4033-40fd-B33E-F796827E2E4B} Nonlinear gain point 1 PU gv iGv1i. Typical value 0. gv1 {D3C8856D-381E-43b3-9B97-941BFB32FAD1} Nonlinear gain point 2 PU gv iGv2i. Typical value 0. gv2 {FEE091BA-B020-44ba-92CE-A314506CDCA2} Nonlinear gain point 3 PU gv iGv3i. Typical value 0. gv3 {75B8E10D-9DD0-4383-A0B5-300A0F5A3A07} Nonlinear gain point 4 PU gv iGv4i. Typical value 0. gv4 {31549E35-2F8C-4b9c-BFE0-1DFEE682032B} Nonlinear gain point 5 PU gv iGv5i. Typical value 0. gv5 {0024B25D-7AC0-46b4-B23A-4DC1FB04BE4C} Nonlinear gain point 6 PU gv iGv6i. Typical value 0. gv6 {A0DB7792-3596-494a-80E2-1EFAAB7FD568} Turbine gain iKturbi. Typical value 1. kturb {3330DA77-7708-4432-9A6F-5EC54310927F} Base for power values iMWbasei gt 0. Unit MW. mwbase {48698C3C-1FA7-460c-A379-CF2EB7D917D0} Nonlinear gain point 1 PU power iPgv1i. Typical value 0. pgv1 {2BAF50B1-0FA4-4674-B69A-D86F14281837} Nonlinear gain point 2 PU power iPgv2i. Typical value 0. pgv2 {CF48DDB5-A67F-4177-8C17-ED362029D415} Nonlinear gain point 3 PU power iPgv3i. Typical value 0. pgv3 {01657288-FA03-41ed-844A-83823B0E3C49} Nonlinear gain point 4 PU power Pigv4i. Typical value 0. pgv4 {ED6B6B42-6E64-4e26-9DC2-22EE254F24EF} Nonlinear gain point 5 PU power iPgv5i. Typical value 0. pgv5 {D683E5C6-B0C7-4c8c-9C06-C47A0CE0DB00} Nonlinear gain point 6 PU power iPgv6i. Typical value 0. pgv6 {02D61038-D9FF-4c91-BFC2-B8755C2B721D} Maximum gate opening iPmaxi gt GovHydro2.pmin. Typical value 1. pmax {6666A8BF-FB6A-4bfc-B1DF-123C568D7716} Minimum gate opening iPmini lt GovHydro2.pmax. Typical value 0. pmin {3D67CB36-E987-433a-AF14-4F1E28F4A135} Permanent droop iRpermi. Typical value 005. rperm {83E10A7C-DA3B-4977-96C3-640BCE7FACA1} Temporary droop iRtempi. Typical value 05. rtemp {39355991-8503-4302-B260-7A55BA48EA7D} Gate servo time constant iTgi gt 0. Typical value 05. tg {5F198946-1F0F-4528-B747-673816A2E56B} Pilot servo valve time constant iTpi gt 0. Typical value 003. tp {A2425B1F-6D60-4ed1-A7ED-9E3691D1CEC5} Dashpot time constant iTri gt 0. Typical value 12. tr {C58AF2A0-34CB-455d-8B59-82DEE72271AF} Water inertia time constant iTwi gt 0. Typical value 2. tw {525B78BC-5FA6-4c31-B85D-40CB3C3B620D} Turbine gain iAti gt0. Typical value 12. at {078ABE56-A03D-4bf1-BC79-934A31C45EB1} Intentional deadband width idb1i. Unit Hz. Typical value 0. db1 {98032353-4C78-4352-BB64-03EA33BA297A} Unintentional deadband idb2i. Unit MW. Typical value 0. db2 {2484B0A2-1159-486e-98BC-C0BC6871B967} Turbine damping factor iDturbi. Typical value 02. dturb {263A9D47-66FC-4559-A0B3-BE630F7109B4} Intentional db hysteresis iepsi. Unit Hz. Typical value 0. eps {CF04C226-EE15-493b-B870-68E05326BC62} Nonlinear gain point 1 PU gv iGv1i. Typical value 0. gv1 {BB8E4881-00EC-4c53-91F3-8F22C088347B} Nonlinear gain point 2 PU gv iGv2i. Typical value 0. gv2 {48F3A651-16FB-470b-ACF8-4312FEBFC83A} Nonlinear gain point 3 PU gv iGv3i. Typical value 0. gv3 {E438F419-E218-4113-9DE5-5F5FC9EB950F} Nonlinear gain point 4 PU gv iGv4i. Typical value 0. gv4 {55A2ACE0-CBD5-4523-AEC1-95078DBC1BC7} Nonlinear gain point 5 PU gv iGv5i. Typical value 0. gv5 {F5FCBBB1-7B15-4a04-AB56-78F31CF394ED} Nonlinear gain point 6 PU gv iGv6i. Typical value 0. gv6 {99EE7DB4-67C3-4b6f-A430-D99A4F2C5B7D} Turbine nominal head iH0i. Typical value 1. h0 {34DB767C-6620-4e95-94E3-C3AB43E47C5E} Derivative gain iK1i. Typical value 001. k1 {4DAB5BC2-FE3A-495c-B64B-810989A16C14} Double derivative gain if iCflagi 1 iK2i. Typical value 25. k2 {6086AE56-2AC4-409a-ABF2-09DE9CFAC17C} Gate servo gain iKgi. Typical value 2. kg {E8D446BB-3ECF-467c-AF0F-3F22114FB419} Integral gain iKii. Typical value 05. ki {0EE19D78-66C0-432c-9A25-30591A2F9311} Base for power values iMWbasei gt 0. Unit MW. mwbase {F34A20D8-56F8-45fb-9DF9-5E4D8A5AB5ED} Nonlinear gain point 1 PU power iPgv1i. Typical value 0. pgv1 {4CD72DD2-E947-4873-BD51-648B82313081} Nonlinear gain point 2 PU power iPgv2i. Typical value 0. pgv2 {26FC0D05-52EA-43b0-953C-4D9F92AA8B1B} Nonlinear gain point 3 PU power iPgv3i. Typical value 0. pgv3 {A6A541E5-FAE5-49d3-9473-AA62A8611DB6} Nonlinear gain point 4 PU power iPgv4i. Typical value 0. pgv4 {020EB4AF-98C1-4f85-B532-D243A377023A} Nonlinear gain point 5 PU power iPgv5i. Typical value 0. pgv5 {25B07835-84A0-4b04-8364-6DE54BA04A20} Nonlinear gain point 6 PU power iPgv6i. Typical value 0. pgv6 {6EAC63C1-275C-4286-90FC-7DB7C2C329CD} Maximum gate opening PU of MWbase iPmaxi gt GovHydro3.pmin. Typical value 1. pmax {2A4A956F-07C7-4ab3-B635-F2EDC06CB2F0} Minimum gate opening PU of iMWbasei iPmini lt GovHydro3.pmax. Typical value 0. pmin {90539CF5-62A2-45d0-B41D-CA226600D555} Noload turbine flow at nominal head iQnli. Typical value 008. qnl {14A2DBDF-10AD-4295-ACB5-0151A8C82C68} Steadystate droop PU for electrical power feedback iReleci. Typical value 005. relec {C1D58766-8E27-4e1d-8E7E-AE92D0E48A0E} Steadystate droop PU for governor output feedback iRgatei. Typical value 0. rgate {9C264F67-E29E-42cf-A965-73C7069703C3} Input filter time constant iTdi gt 0. Typical value 005. td {593E6877-BBCB-4a33-BADC-A012025A0AB6} Washout time constant iTfi gt 0. Typical value 01. tf {C7DEAEDA-0761-4eb9-BEE0-45386C066B5F} Gate servo time constant iTpi gt 0. Typical value 005. tp {4D992F59-3F30-4ab2-B5D7-8AD276C00A48} Power feedback time constant iTti gt 0. Typical value 02. tt {C3E77CF6-BE70-4f5f-868F-3E1047EC8A63} Water inertia time constant iTwi gt 0. If 0 block is bypassed. Typical value 1. tw {0ACC8A01-70B3-4b20-ADD9-64C961799471} Turbine gain iAti. Typical value 12. at {8507C6F2-29F7-4a95-972A-012FA0064FF5} Kaplan blade servo point 0 iBgv0i 0 for simple 0 for FrancisPelton. Typical value for Kaplan 0. bgv0 {B470D9B7-3FB0-4b9a-9B85-B241C58FC596} Kaplan blade servo point 1 iBgv1i 0 for simple 0 for FrancisPelton. Typical value for Kaplan 0. bgv1 {F067D149-09D0-4516-B7C4-2E28C86BDA40} Kaplan blade servo point 2 iBgv2i 0 for simple 0 for FrancisPelton. Typical value for Kaplan 01. bgv2 {3A8C5ACC-5FC7-4448-902C-F919B366B72E} Kaplan blade servo point 3 iBgv3i 0 for simple 0 for FrancisPelton. Typical value for Kaplan 0667. bgv3 {1FDD0FE4-F933-4ba3-8E7D-8DDDD11152AA} Kaplan blade servo point 4 iBgv4i 0 for simple 0 for FrancisPelton. Typical value for Kaplan 09. bgv4 {F0301C42-6FC0-4ad2-B2E1-DCDC77E8240A} Kaplan blade servo point 5 iBgv5i 0 for simple 0 for FrancisPelton. Typical value for Kaplan 1. bgv5 {1593114D-AFB3-40fc-BD32-78C98035B012} Intentional deadband width idb1i. Unit Hz. Typical value 0. db1 {7F3A2379-5A30-4ba2-A417-57684A69C36C} Unintentional deadband idb2i. Unit MW. Typical value 0. db2 {E567E7BB-3D9F-4031-B786-3C6A84196ECC} Turbine damping factor iDturbi. Unit delta P PU of iMWbasei delta speed PU. Typical value for simple 05 FrancisPelton 11 Kaplan 11. dturb {03E6CE59-FDB0-4ba0-A1EE-E529D6FF39E8} Intentional db hysteresis iepsi. Unit Hz. Typical value 0. eps {621898DB-B575-4abf-B834-D6E1321429D0} Maximum gate opening PU of iMWbasei iGmaxi gt GovHydro4.gmin. Typical value 1. gmax {80817639-2699-4b57-9E44-52E2307DE031} Minimum gate opening PU of iMWbasei iGmini lt GovHydro4.gmax. Typical value 0. gmin {4E09A8F5-7A95-4acd-AA1D-21E898CACFBB} Nonlinear gain point 0 PU gv iGv0i 0 for simple. Typical for FrancisPelton 01 Kaplan 01. gv0 {5D8E826B-D20B-4243-9C33-891B2EA5B257} Nonlinear gain point 1 PU gv iGv1i 0 for simple gt GovHydro4.gv0 for FrancisPelton and Kaplan. Typical value for FrancisPelton 04 Kaplan 04. gv1 {438C9730-67B5-4d3b-BC2A-D321B66DA1B2} Nonlinear gain point 2 PU gv iGv2i 0 for simple gt GovHydro4.gv1 for FrancisPelton and Kaplan. Typical value for FrancisPelton 05 Kaplan 05. gv2 {730712FE-0761-486e-8533-86816BBEE72D} Nonlinear gain point 3 PU gv iGv3i 0 for simple gt GovHydro4.gv2 for FrancisPelton and Kaplan. Typical value for FrancisPelton 07 Kaplan 07. gv3 {AE20C7D2-84EA-4cb3-87DB-99DCDE0CF5B7} Nonlinear gain point 4 PU gv iGv4i 0 for simple gt GovHydro4.gv3 for FrancisPelton and Kaplan. Typical value for FrancisPelton 08 Kaplan 08. gv4 {A4D2BE8E-5554-416e-B948-00F0D78B8342} Nonlinear gain point 5 PU gv iGv5i 0 for simple lt 1 and gt GovHydro4.gv4 for FrancisPelton and Kaplan. Typical value for FrancisPelton 09 Kaplan 09. gv5 {EAA3C490-A3FE-4e4d-A0EA-ADE1F55B7176} Head available at dam ihdami. Typical value 1. hdam {127AC479-9F31-484f-9AE7-09EE022A5210} The kind of model being represented simple FrancisPelton or Kaplan. model {D17882F1-3D71-45a3-A849-0F01A91FB22E} Base for power values iMWbasei gt 0. Unit MW. mwbase {F78B90E0-1062-472d-96B4-5B3A1C3A3468} Nonlinear gain point 0 PU power iPgv0i 0 for simple. Typical value 0. pgv0 {DF7D151D-7EB8-4050-B696-73224C1233FE} Nonlinear gain point 1 PU power iPgv1i 0 for simple.Typical value for FrancisPelton 042 Kaplan 035. pgv1 {6F7596D9-D3E7-4059-9FCA-8193421EA31D} Nonlinear gain point 2 PU power iPgv2i 0 for simple.Typical value for FrancisPelton 056 Kaplan 0468. pgv2 {0FAF88E7-45D0-4482-8DE9-81C41F115D5C} Nonlinear gain point 3 PU power iPgv3i 0 for simple.Typical value for FrancisPelton 08 Kaplan 0796. pgv3 {DB67820C-2709-4d28-B825-2448ED18C208} Nonlinear gain point 4 PU power iPgv4i 0 for simple.Typical value for FrancisPelton 09 Kaplan 0917. pgv4 {1B925978-241D-481b-8E59-161244D6FE9C} Nonlinear gain point 5 PU power iPgv5i 0 for simple. Typical value for FrancisPelton 097 Kaplan 099. pgv5 {1575ED37-1AA6-4a7b-A2C6-101C347450E6} Noload flow at nominal head iQnli.Typical value for simple 008 FrancisPelton 0 Kaplan 0. qnl {34949B92-60D3-4fe8-AC41-CF66479AA56E} Permanent droop iRpermi gt 0. Typical value 005. rperm {A173BC61-79B9-4ad0-A9C4-06183A399010} Temporary droop iRtempi gt 0. Typical value 03. rtemp {17BCD83F-00A5-4731-B99F-0CD1B03A7E7F} Blade servo time constant iTbladei gt 0. Typical value 100. tblade {EA5F20AA-C5FB-429a-A3CA-3EEA464D5209} Gate servo time constant iTgi gt 0. Typical value 05. tg {1C5BA69C-215E-4fd2-B1C3-EB0789E70050} Pilot servo time constant iTpi gt 0. Typical value 01. tp {315FE273-0A7A-4189-9DE9-750E50777BD9} Dashpot time constant iTri gt 0. Typical value 5. tr {FD6AF508-00EB-4a96-8B38-93E0E89B3BF9} Water inertia time constant iTwi gt 0. Typical value 1. tw {71259C52-1385-4cac-9CB4-070A6AF0EAB5} Turbine numerator multiplier iAturbi see parameter detail 3. Typical value 1. aturb {742DF58E-5CEF-457f-8D8A-B691DA3E7CAB} Turbine denominator multiplier iBturbi see parameter detail 3. Typical value 05. bturb {46357550-189B-4010-A68B-D8952C5CA389} Intentional deadband width idb1i. Unit Hz. Typical value 0. db1 {F26F2059-7050-4dc1-A947-15B1C7FDEEBD} Unintentional deadband idb2i. Unit MW. Typical value 0. db2 {33BAB8AB-301D-43ab-9671-69EA9B323DF9} Intentional db hysteresis iepsi. Unit Hz. Typical value 0. eps {0DDABA81-FF0A-4fb0-AC55-8C7A3FCBDAB8} Maximum gate opening iGmaxi gt GovHydroDD.gmin. Typical value 0. gmax {8D3A60C8-C643-4c01-A4EF-138885E431CE} Minimum gate opening iGmini lt GovHydroDD.gmax. Typical value 0. gmin {0B5537D8-F08B-45d4-81B3-B07B47A897CB} Nonlinear gain point 1 PU gv iGv1i. Typical value 0. gv1 {A77EFA00-5ECA-4ecf-9BEE-8B1B18AB6D66} Nonlinear gain point 2 PU gv iGv2i. Typical value 0. gv2 {94304CDB-20CC-4eeb-BD9F-00964B4D6440} Nonlinear gain point 3 PU gv iGv3i. Typical value 0. gv3 {DD52A994-2B69-4d26-B80A-8F911DECB125} Nonlinear gain point 4 PU gv iGv4i. Typical value 0. gv4 {21CA9AC2-A119-4922-9D8C-E5CE77C8B9FF} Nonlinear gain point 5 PU gv iGv5i. Typical value 0. gv5 {B278D8BE-6696-4d77-948D-A967B79EFBE0} Nonlinear gain point 6 PU gv iGv6i. Typical value 0. gv6 {18868044-EF4E-409f-81F5-AC745D4C22EB} Single derivative gain iK1i. Typical value 36. k1 {E90A046D-F554-41ab-988B-09312E35C984} Double derivative gain iK2i. Typical value 02. k2 {A25A162A-B728-4973-9735-F60DD78BE066} Gate servo gain iKgi. Typical value 3. kg {A717271A-3A89-48c6-9AD1-FB8F0783FDE1} Integral gain iKii. Typical value 1. ki {3F379118-5D8F-409b-B107-F0C1AA48405E} Base for power values iMWbasei gt0. Unit MW. mwbase {7E84DB32-5477-4292-9EF5-D79F373AD29E} Nonlinear gain point 1 PU power iPgv1i. Typical value 0. pgv1 {FA1D0554-6159-46b2-9A1E-4E93F30FA875} Nonlinear gain point 2 PU power iPgv2i. Typical value 0. pgv2 {3E4BC076-FED6-4724-B7F1-423DC0E8DB19} Nonlinear gain point 3 PU power iPgv3i. Typical value 0. pgv3 {B304A009-0CBF-473d-B841-B32FAD1BFAB3} Nonlinear gain point 4 PU power iPgv4i. Typical value 0. pgv4 {F3C92CFE-570F-4f77-9DE9-F1DBEB5E7591} Nonlinear gain point 5 PU power iPgv5i. Typical value 0. pgv5 {F14B6E86-74F3-4a76-8AD1-DF22F5D180BD} Nonlinear gain point 6 PU power iPgv6i. Typical value 0. pgv6 {16FC5B3B-E320-4595-BD7F-AD1B13A10912} Maximum gate opening PU of iMWbasei iPmaxi gt GovHydroDD.pmin. Typical value 1. pmax {28C0FE72-4D95-43b5-96A5-54E4F950542A} Minimum gate opening PU of iMWbasei iPmini gt GovHydroDD.pmax. Typical value 0. pmin {21E787D0-EE26-4c1e-A519-45645C9BD889} Steady state droop iRi. Typical value 005. r {53DB3212-BC20-4539-95BB-092E8C6F7C2B} Input filter time constant iTdi gt 0. If 0 block is bypassed. Typical value 0. td {6931EDFA-1F35-40c3-8B19-CBEA6B8691EF} Washout time constant iTfi gt 0. Typical value 01. tf {39290CE3-6480-4280-9FDF-F64C23288B3E} Gate servo time constant iTpi gt 0. If 0 block is bypassed. Typical value 035. tp {2F0EF951-62E3-46c3-99CA-7925DB7307ED} Power feedback time constant iTti gt 0. If 0 block is bypassed. Typical value 002. tt {4438E251-2C80-4882-BABC-4EBB5E12EF6D} Turbine time constant iTturbi gt 0. See parameter detail 3. Typical value 08. tturb {6181F368-C827-45bf-8116-53E23B813EBA} Opening section iSiisubEFFsubi at the maximum efficiency iAmi. Typical value 07. am {CDD58297-5216-4d32-8F40-434C6C439295} Area of the surge tank iAiisubV0subi. Unit msup2sup. Typical value 30. av0 {A33B7E93-CC68-4ffe-830D-AD91C896CFFA} Area of the compensation tank iAiisubV1subi. Unit msup2sup. Typical value 700. av1 {63098FB2-5381-4f82-A5B0-81F4E75AABE9} Droop iBpi. Typical value 005. bp {6C2F9039-A507-40f6-9F93-6B4CB4A9433D} Intentional deadband width iDB1i. Unit Hz. Typical value 0. db1 {67AF015D-266C-4842-8997-B56495A6C12D} Maximum efficiency iEtaMaxi. Typical value 105. etamax {8C502ADB-F1C2-4f24-832A-16000AE62DF4} Governor control flag iCflagi. Typical value mechanicHydrolicTachoAccelerator. governorControl {82B8D404-5ADD-480e-B503-D4243F4A57BB} Head of compensation chamber water level with respect to the level of penstock iHiisub1subi. Unit km. Typical value 0004. h1 {5BCFE1A1-41AD-47ca-A0C0-B0805A74F7D0} Head of surge tank water level with respect to the level of penstock iHiisub2subi. Unit km. Typical value 0040. h2 {36C26250-BA01-4bf6-BF80-3A4A7A4EADAE} Rated hydraulic head iHiisubnsubi. Unit km. Typical value 0250. hn {A44E4508-5DD9-4c7a-B30E-E4890B44DEE5} Penstock loss coefficient due to friction iKci. Typical value 0025. kc {B0194F3B-D136-41e8-B56A-B489613A4E01} Water tunnel and surge chamber loss coefficient due to friction iKgi. Typical value 0025. kg {1CA60ACA-C1ED-4da4-A3CB-D985FC2FFE74} Washout gain iKti. Typical value 025. kt {7EBD2E09-1B36-40f1-AD52-6B315E477B7D} Noload turbine flow at nominal head iQc0i. Typical value 01. qc0 {FF1F840D-A377-461b-89EE-B4E0A17A8B03} Rated flow iQiisubnsubi. Unit msup3sups. Typical value 250. qn {9160A05A-A4F0-45ef-B8B0-877061CD1AE9} Derivative gain iTai gt 0. Typical value 3. ta {2BE28249-109B-4376-A07D-48989E4EA2FD} Washout time constant iTdi gt 0. Typical value 6. td {2DD22B3C-E4D8-456a-B433-D56A697F5CB3} Gate servo time constant iTsi gt 0. Typical value 05. ts {BC545CFB-AE7F-4330-A4A0-65C804071946} Water inertia time constant iTwnci gt 0. Typical value 1. twnc {AC7A1124-2F84-458f-B6FC-F6A1B68E550F} Water tunnel and surge chamber inertia time constant iTwngi gt 0. Typical value 3. twng {14A49FBB-F163-4e82-8659-29483CCA0670} Derivative feedback gain iTxi gt 0. Typical value 1. tx {54E7ABD7-762E-4fcf-AF24-D70C1CD37C2F} Maximum gate opening iValvMaxi gt GovHydroFrancis.valvmin. Typical value 11. valvmax {AC4668F4-C3F4-4894-B6FD-49833BBB1E64} Minimum gate opening iValvMini lt GovHydroFrancis.valvmax. Typical value 0. valvmin {7CF42B23-33C4-4b7b-AACA-D4E41B4EBC3B} Head of upper water level with respect to the level of penstock iZsfci. Unit km. Typical value 0025. zsfc {F6047EA4-365D-4b6d-A4B1-DFA864AAA713} Governor gain iKi. k {0C98F22E-4C87-4e9d-A331-D9CECC2076D8} Base for power values iMWbasei gt 0. Unit MW. mwbase {EABE1337-3C6D-4bda-AE52-4BE263C548F0} Gate maximum iPmaxi gt GovHydroIEEE0.pmin. pmax {BDD1A88C-93DB-4e7f-A4E0-8A19338333B9} Gate minimum iPmini lt GovHydroIEEE.pmax. pmin {B67D4FAF-C46E-4fb6-B956-F1348378BD1C} Governor lag time constant iT1i gt 0. Typical value 025. t1 {C2EE48B3-FE0E-4677-9F12-728C2CCEB38A} Governor lead time constant iT2i gt 0. Typical value 0. t2 {521A3E0D-2616-4433-BE64-913378974122} Gate actuator time constant iT3i gt 0. Typical value 01. t3 {64474B0C-A6DC-458d-B808-2E08FE207EF7} Water starting time iT4i gt 0. t4 {ECAE8F95-0A47-4454-BECF-D6E41D67E305} Turbine numerator multiplier iAturbi. Typical value 1. aturb {16160504-A508-40d7-BCCE-CE33FC6E2B56} Turbine denominator multiplier iBturbi gt 0. Typical value 05. bturb {D752432F-BBE9-4780-B0A2-A995EFFEB72D} Nonlinear gain point 1 PU gv iGv1i. Typical value 0. gv1 {F63CD920-C121-496e-88BA-CA5AC02192B4} Nonlinear gain point 2 PU gv iGv2i. Typical value 0. gv2 {4FBEA10C-88E1-4c59-97A5-9BADCC30B096} Nonlinear gain point 3 PU gv iGv3i. Typical value 0. gv3 {1866D0CA-87CE-48af-ACAD-3CA491A175C3} Nonlinear gain point 4 PU gv iGv4i. Typical value 0. gv4 {61F3F8D7-3C7C-4a3d-8458-6C6011EDFF2C} Nonlinear gain point 5 PU gv iGv5i. Typical value 0. gv5 {2390C7A9-A7D2-476f-9C9F-0AD28541B21C} Nonlinear gain point 6 PU gv iGv6i. Typical value 0. gv6 {D4FF4666-5B17-439c-954E-EDDD294CDA46} Turbine gain iKturbi. Typical value 1. kturb {77B93020-3F48-4c9e-A774-D6BFE6AFCCAC} Base for power values iMWbasei gt 0. Unit MW. mwbase {44C5C73C-0AB4-40f1-9F7A-FE5302C723C2} Nonlinear gain point 1 PU power iPgv1i. Typical value 0. pgv1 {E7E87A7F-DC7E-4f38-B8F3-3375D35257FC} Nonlinear gain point 2 PU power iPgv2i. Typical value 0. pgv2 {17C6FF41-FFA8-407b-8814-9E5CDCB3E1BE} Nonlinear gain point 3 PU power iPgv3i. Typical value 0. pgv3 {91B3B43A-1177-408a-9D6C-C634DEF5EAF6} Nonlinear gain point 4 PU power iPgv4i. Typical value 0. pgv4 {882EC2DD-001A-420e-8391-8367277AC3F8} Nonlinear gain point 5 PU power iPgv5i. Typical value 0. pgv5 {639267D9-A5BA-472c-A36D-3EF97AAC2613} Nonlinear gain point 6 PU power iPgv6i. Typical value 0. pgv6 {D5A833C3-F4B9-4573-9381-DC03E502FBD4} Maximum gate opening iPmaxi gt GovHydroIEEE2.pmin. Typical value 1. pmax {D1CAFBCA-9330-4839-91DF-AFDB88017678} Minimum gate opening iPmini ltGovHydroIEEE2.pmax. Typical value 0. pmin {E25A4956-E306-410f-BA73-6F15ADECB877} Permanent droop iRpermi. Typical value 005. rperm {81F58BDC-9674-48ae-B0FE-E350F658E7DB} Temporary droop iRtempi. Typical value 05. rtemp {2D6BBE42-78AB-421d-A47B-C57247CEC49C} Gate servo time constant iTgi gt 0. Typical value 05. tg {14DED583-6BF8-4ee5-862E-A9A487DC2DBB} Pilot servo valve time constant iTpi gt 0. Typical value 003. tp {60E17F40-2444-4aca-B5B2-AF400E1FE8D6} Dashpot time constant iTri gt 0. Typical value 12. tr {9131D573-1974-476e-A568-3A7B10BD5282} Water inertia time constant iTwi gt 0. Typical value 2. tw {BAACA66F-EFFE-4fcf-A4D7-17B12CC36D36} Turbine numerator multiplier iAturbi see parameter detail 3. Typical value 1. aturb {A615AF4E-FEC4-4a58-BEB9-367C21380B9C} Turbine denominator multiplier iBturbi see parameter detail 3. Typical value 05. bturb {305E0037-79D2-4072-8B33-417B7A9AE85F} Intentional deadband width idb1i. Unit Hz. Typical value 0. db1 {F5D3F30B-B09A-42df-ACD9-FA51C40401CB} Unintentional deadband idb2i. Unit MW. Typical value 0. db2 {1E661077-4598-47c6-95F1-F4F51E2A9BEC} Intentional db hysteresis iepsi. Unit Hz. Typical value 0. eps {394D8886-5129-4cc2-BCBB-BED57E4A46E4} Nonlinear gain point 1 PU gv iGv1i. Typical value 0. gv1 {48F144E3-D53C-4900-9D4D-8E8386AFEC20} Nonlinear gain point 2 PU gv iGv2i. Typical value 0. gv2 {64D7C701-4121-44e8-BF5D-7A8A3ADD56E8} Nonlinear gain point 3 PU gv iGv3i. Typical value 0. gv3 {488E2C53-75C6-485a-AE23-3BABD359FF75} Nonlinear gain point 4 PU gv iGv4i. Typical value 0. gv4 {DCD778C1-9395-43da-BD58-6AC7248F844D} Nonlinear gain point 5 PU gv iGv5i. Typical value 0. gv5 {46E280BF-A3F2-44db-8266-004297A7DC73} Nonlinear gain point 6 PU gv iGv6i. Typical value 0. gv6 {B7C4539F-EEC2-4d51-BF1D-DD5B70F3D3BE} Derivative gain iKdi. Typical value 111. kd {0AC54FA8-2D92-4c63-8C5B-B6A836772EB1} Gate servo gain iKgi. Typical value 25. kg {B8ACA60C-1A2E-4641-A01B-24B3071DE0CE} Integral gain iKii. Typical value 036. ki {35EA3654-61F8-4201-93CD-BBE3BEBE91B2} Proportional gain iKpi. Typical value 01. kp {41C75A1B-D28D-47eb-8ED1-6C43683F7DAD} Base for power values iMWbasei gt 0. Unit MW. mwbase {2BDA3F51-E500-4d92-8B9A-748E56A96008} Nonlinear gain point 1 PU power iPgv1i. Typical value 0. pgv1 {F591C394-5348-44d8-9E9D-B3B104849B33} Nonlinear gain point 2 PU power iPgv2i. Typical value 0. pgv2 {C0270DB3-14BF-4e8c-A100-4086CDBA6A83} Nonlinear gain point 3 PU power iPgv3i. Typical value 0. pgv3 {7D9B3CAA-B416-4707-856C-8DD047D57B0B} Nonlinear gain point 4 PU power iPgv4i. Typical value 0. pgv4 {28FC71C1-927E-49d4-B408-2100A121BF9A} Nonlinear gain point 5 PU power iPgv5i. Typical value 0. pgv5 {5B0277C1-F92A-46f9-9CAD-90CBF4D1E2F8} Nonlinear gain point 6 PU power iPgv6i. Typical value 0. pgv6 {A2B3EAAE-FFBB-4144-B9C6-64EBC1342BBE} Maximum gate opening PU of MWbase iPmaxi gt GovHydroPID.pmin. Typical value 1. pmax {602962F1-A2C4-40fa-9C42-F99638B56C35} Minimum gate opening PU of MWbase iPmini lt GovHydroPID.pmax. Typical value 0. pmin {0900038F-AFCE-4fb5-9370-D2E3976C9658} Steady state droop iRi. Typical value 005. r {FCDC9A31-F6F3-4656-BD40-07900815888B} Input filter time constant iTdi gt 0. If 0 block is bypassed. Typical value 0. td {33B4696B-D0BA-4288-B534-368A8602E155} Washout time constant iTfi gt 0. Typical value 01. tf {0F5FFB1C-F808-436f-868D-C93C0AFAC4BB} Gate servo time constant iTpi gt 0. If 0 block is bypassed. Typical value 035. tp {6734CBC0-118E-40b9-8173-6C1BD5293EE2} Power feedback time constant iTti gt 0. If 0 block is bypassed. Typical value 002. tt {F5150390-6D98-442e-A271-A9E9EDA3D44F} Turbine time constant iTturbi gt 0. See Parameter detail 3. Typical value 08. tturb {902C49B0-A17E-4a16-983B-8F50B2ED7E71} Factor multiplying iTwi iAtwi. Typical value 0. atw {E85C5E35-5F88-47cd-B421-D55156046A44} Turbine damping factor iDi. Unit delta P delta speed. Typical value 0. d {8F5B12F0-DEC8-4710-9C4A-CF32A668224D} Gate opening at speed no load iG0i. Typical value 0. g0 {DFA88B53-923A-4701-ABA6-98DE8AFFA96E} Intermediate gate opening iG1i. Typical value 0. g1 {C74498BC-04F0-4a98-B178-D5C3316816F6} Intermediate gate opening iG2i. Typical value 0. g2 {9D4C505D-0E6A-4417-8896-80C6AC6DE8E6} Maximum gate opening iGmaxi gt GovHydroPID2.gmin. Typical value 0. gmax {25FCEB84-D6FA-4e50-8F78-3E4C087DA2CE} Minimum gate opening iGmini gt GovHydroPID2.gmax. Typical value 0. gmin {C638F1C1-57F1-498a-91CE-56CAA8F479A9} Derivative gain iKdi. Typical value 0. kd {EDDDE006-3AD1-47e5-B855-4E8D842C79B7} Proportional gain iKpi. Typical value 0. kp {A5C16343-07B0-41eb-A707-D9A504DF8D12} Base for power values iMWbasei gt0. Unit MW. mwbase {FE7F559C-B2D0-465d-BFD6-769F3E0211C3} Power at gate opening iG1i iP1i. Typical value 0. p1 {042F3249-6DDD-45ef-AE9E-980A4491DB56} Power at gate opening G2 iP2i. Typical value 0. p2 {96879763-74D4-4de8-813A-78255403DD56} Power at full opened gate iP3i. Typical value 0. p3 {959FD35A-DCDD-41d6-885C-5EAC52C46A62} Permanent drop iRpermi. Typical value 0. rperm {EBE6A524-8A1B-41cd-863B-BC88F43CBFBE} Controller time constant iTai gt 0. Typical value 0. ta {61632889-472A-4ef6-B2FA-D8EE7244B7BB} Gate servo time constant iTbi gt 0. tb {096EFB3F-52B3-4058-B977-C9219A5853E7} Speed detector time constant iTregi gt 0. Typical value 0. treg {9FEF6BAE-D400-4cce-898B-DDDF520CC671} Water inertia time constant iTwi gt 0. Typical value 0. tw {956D8A87-4895-4242-BB57-ABAB839FBAC7} Area of the surge tank iAiisubV0subi. Unit msup2sup. Typical value 30. av0 {2F20AFE2-FBC0-44ce-BF77-D998719D17A2} Area of the compensation tank iAiisubV1subi. Unit msup2sup. Typical value 700. av1 {2D371EC1-51E6-404c-BEC1-77A780F72510} Droop ibpi. Typical value 005. bp {DD70C425-193B-4f92-B028-A12AFB7DB27C} Intentional deadband width iDB1i. Unit Hz. Typical value 0. db1 {B7E183DE-8BDE-45d4-8A25-8494AAE0A455} Intentional deadband width of valve opening error iDB2i. Unit Hz. Typical value 001. db2 {B66E1AF1-69FC-40a0-88E2-74688EE03FB8} Head of compensation chamber water level with respect to the level of penstock iHiisub1subi. Unit km. Typical value 0004. h1 {A377687D-8B26-4763-8A47-711E82F90682} Head of surge tank water level with respect to the level of penstock iHiisub2subi. Unit km. Typical value 0040. h2 {1627FCC3-0850-498b-B4AC-CF9964A6E502} Rated hydraulic head iHiisubnsubi. Unit km. Typical value 0250. hn {4498B638-C25C-4ec1-9DD9-2CBBB5018AEB} Penstock loss coefficient due to friction iKci. Typical value 0025. kc {77E94867-E358-4e63-A3D6-579D12956FF4} Water tunnel and surge chamber loss coefficient due to friction iKgi. Typical value 0025. kg {87732474-836A-4593-845F-A57C2C4634F9} Noload turbine flow at nominal head iQc0i. Typical value 005. qc0 {1C546174-B511-4831-A680-3BE4BA42D308} Rated flow iQiisubnsubi. Unit msup3sups. Typical value 250. qn {DF90C1F5-CD28-44f8-B2D6-6FBD043F2D52} Derivative gain accelerometer time constant iTai gt 0. Typical value 3. ta {970E95EF-72A9-4773-8802-184E8FD45A6C} Gate servo time constant iTsi gt 0. Typical value 015. ts {7A57AC08-D35A-4875-8430-185F56385CB1} Servomotor integrator time constant iTvi gt 0. Typical value 03. tv {F9C3A679-8AE8-4b2b-9152-0D884937D745} Water inertia time constant iTwnci gt 0. Typical value 1. twnc {728E5D63-2341-43e2-A646-CDB5BF1A2A3A} Water tunnel and surge chamber inertia time constant iTwngi gt 0. Typical value 3. twng {878D05D6-AB48-440c-AEB6-6975519E07B6} Electronic integrator time constant iTxi gt 0. Typical value 05. tx {99714F28-2A9D-425f-B569-9FB01313B3EC} Maximum gate opening iValvMaxi gt GovHydroPelton.valvmin. Typical value 11. valvmax {A481FBBF-800B-425e-A3BA-39A68696209D} Minimum gate opening iValvMini lt GovHydroPelton.valvmax. Typical value 0. valvmin {1DBDEB21-7152-40fe-A850-1A7498C1C310} Maximum servomotor valve opening velocity iVavi. Typical value 01. vav {CE8C0735-87A8-49f1-A5BF-9E6AE80E68D0} Maximum servomotor valve closing velocity iVcvi. Typical value 01. vcv {B923AB16-1662-49b2-BB20-155B839F7470} Head of upper water level with respect to the level of penstock iZsfci. Unit km. Typical value 0025. zsfc {1B29880E-20FC-4d30-A1D0-92C67AC5A6F1} Turbine gain iAti. Typical value 12. at {0E9985D1-534B-448c-9C1B-228630BF4E38} Intentional deadband width idb1i. Unit Hz. Typical value 0. db1 {5FB28864-B480-4761-AC5C-FC9105551A8B} Unintentional deadband idb2i. Unit MW. Typical value 0. db2 {EB1E0DD7-BE69-4319-BAB7-ED823A27FBB9} Turbine damping factor iDturbi. Typical value 02. dturb {8266D47E-6B2C-44e2-826E-32FFFC21F734} Intentional db hysteresis iepsi. Unit Hz. Typical value 0. eps {37046D34-6DEB-465a-B139-1F3E1D076C03} Maximum governor output iGmaxi gt GovHydroR.gmin. Typical value 105. gmax {8A41CBC0-AB0D-4961-8EB4-6AEDEA80A556} Minimum governor output iGmini lt GovHydroR.gmax. Typical value 005. gmin {E4D1B26B-5928-4058-BC8C-8199EECEB47C} Nonlinear gain point 1 PU gv iGv1i. Typical value 0. gv1 {4E2CE730-28E8-4b84-925D-0EAA28888ABA} Nonlinear gain point 2 PU gv iGv2i. Typical value 0. gv2 {F8D4C82E-C4C2-4c69-B4D7-88ED67A1A0C8} Nonlinear gain point 3 PU gv iGv3i. Typical value 0. gv3 {1E2A1AB1-0794-4334-85D5-925352C72E8D} Nonlinear gain point 4 PU gv iGv4i. Typical value 0. gv4 {CEDE59C7-AE9A-4cae-9138-B949B9785CC1} Nonlinear gain point 5 PU gv iGv5i. Typical value 0. gv5 {B5576BF4-D9F9-43ef-85A7-F34F76DFDAE5} Nonlinear gain point 6 PU gv iGv6i. Typical value 0. gv6 {75DD60CD-B8BC-419d-9FE1-994C381FB28D} Turbine nominal head iH0i. Typical value 1. h0 {4F45C6E9-616B-4743-9B0C-6876D1E9F82D} Gate servo gain iKgi. Typical value 2. kg {580CB40B-63C6-4887-AA8C-C85CF002C194} Integral gain iKii. Typical value 05. ki {162371C6-8C21-42a3-845E-FD4A170CDBC5} Base for power values iMWbasei gt 0. Unit MW. mwbase {0A892D73-D119-44a0-A803-A2698869527F} Nonlinear gain point 1 PU power iPgv1i. Typical value 0. pgv1 {E0545B0A-0FFD-4453-AED2-F64A92ECD272} Nonlinear gain point 2 PU power iPgv2i. Typical value 0. pgv2 {E00557F7-4AB0-42fb-8B50-C8E017DA8B46} Nonlinear gain point 3 PU power iPgv3i. Typical value 0. pgv3 {1CAFBC3B-07BB-4a4f-B9E4-8926A95DBC6D} Nonlinear gain point 4 PU power iPgv4i. Typical value 0. pgv4 {FDCC0FA8-54CB-4924-AA3F-179BFEF59DD8} Nonlinear gain point 5 PU power iPgv5i. Typical value 0. pgv5 {66504A0A-EA8F-4324-96E1-1F2C12D9C010} Nonlinear gain point 6 PU power iPgv6i. Typical value 0. pgv6 {B90932E3-AFF8-493f-991E-F1843C925C02} Maximum gate opening PU of iMWbasei iPmaxi gt GovHydroR.pmin. Typical value 1. pmax {8EC63699-2FE3-4266-B523-56C94559CE05} Minimum gate opening PU of iMWbasei iPmini lt GovHydroR.pmax. Typical value 0. pmin {9617CE68-08F4-4c9e-8FE8-9B3A5AA4CE1E} Noload turbine flow at nominal head iQnli. Typical value 008. qnl {0272C6F1-EC6B-416a-BF08-319565D9844A} Steadystate droop iRi. Typical value 005. r {B5F21912-8537-4442-9EA7-C45B72A466ED} Lead time constant 1 iT1i gt 0. Typical value 15. t1 {9E7F522B-AD1A-49e8-AF96-7B6CDEB6E3E4} Lag time constant 1 iT2i gt 0. Typical value 01. t2 {38922249-DA0A-473a-BA63-60D8D49B580B} Lead time constant 2 iT3i gt 0. Typical value 15. t3 {0AC56C2D-5D7C-40b3-A6AB-18A3E91F63A0} Lag time constant 2 iT4i gt 0. Typical value 01. t4 {5077F2AE-4AFE-4ec7-B463-3C14542202C6} Lead time constant 3 iT5i gt 0. Typical value 0. t5 {F1288D02-630F-4075-BB67-2A353A304804} Lag time constant 3 iT6i gt 0. Typical value 005. t6 {6C4CC16E-11B3-499c-9504-26A87FB0B215} Lead time constant 4 iT7i gt 0. Typical value 0. t7 {15E0C07D-885D-4f51-BC05-46726D2D381E} Lag time constant 4 iT8i gt 0. Typical value 005. t8 {7E2B8BB3-7911-4d47-BB71-AF4739C2C031} Input filter time constant iTdi gt 0. Typical value 005. td {9E4B88B2-2284-4cc5-8CBD-9B5C54C29FD9} Gate servo time constant iTpi gt 0. Typical value 005. tp {C55C485A-F0CA-4d21-AE5A-13C6F3FB8B43} Power feedback time constant iTti gt 0. Typical value 0. tt {5631C3CD-114F-4950-99F2-131BD87E6268} Water inertia time constant iTwi gt 0. Typical value 1. tw {363D660D-331E-4ba8-9E6F-7D8D3D809F3E} Speed deadband idbi. db {849E983B-D5DE-4f0b-A7F5-DC3C8B94A1FE} Value to allow the integral controller to advance beyond the gate limits iDicni. dicn {AE31A0FF-07F7-4afd-ACDA-0F43B55FCF4F} Value to allow the pilot valve controller to advance beyond the gate limits iDpvi. dpv {45C9B199-CD8D-4406-9EBE-BAF277E4A5BD} Turbine damping factor iDturbi. Unit delta P PU of iMWbasei delta speed PU. dturb {3D1FD0CB-274D-4ac7-8C02-74871B687668} Flowgate 1 iFl1i. Flow value for gate position point 1 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. fl1 {9BDB8DCC-58BC-4c29-BF70-AF981D0B0F8A} Flowgate 2 iFl2i. Flow value for gate position point 2 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. fl2 {C992A913-F55B-4dc0-BEE9-53A854BFB9B2} Flowgate 3 iFl3i. Flow value for gate position point 3 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. fl3 {109E4766-868D-45bd-AD37-6AF5D1EBA46C} Flowgate 4 iFl4i. Flow value for gate position point 4 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. fl4 {7EBDECEA-6D5F-4a64-9066-3B1FA5665F3E} Flowgate 5 iFl5i. Flow value for gate position point 5 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. fl5 {5760844D-73C0-4a88-8CA1-00E51F83F368} Flow P1 iFp1i. Turbine flow value for point 1 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp1 {1916E846-ED5F-4813-BA63-8C3EFDFE76B5} Flow P10 iFp10i. Turbine flow value for point 10 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp10 {4EA2E0CD-8F91-4aac-BECF-170592984B28} Flow P2 iFp2i. Turbine flow value for point 2 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp2 {7E25342F-C381-4549-8E29-7298D378987F} Flow P3 iFp3i. Turbine flow value for point 3 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp3 {78D35C8A-4CE5-4c92-A35D-AB0CFB535856} Flow P4 iFp4i. Turbine flow value for point 4 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp4 {21066FBB-3F5E-492c-86D7-A9046294A620} Flow P5 iFp5i. Turbine flow value for point 5 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp5 {7DED80F8-F034-49c5-8687-FC3838D5885E} Flow P6 iFp6i. Turbine flow value for point 6 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp6 {344C9FCA-23FE-4e7f-A035-07A5CD93B8DA} Flow P7 iFp7i. Turbine flow value for point 7 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp7 {B99854AF-E5A3-41a0-91F0-1EDE86523725} Flow P8 iFp8i. Turbine flow value for point 8 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp8 {2B40A8AB-32F3-41b5-A657-FDBDAB8A14E3} Flow P9 iFp9i. Turbine flow value for point 9 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. fp9 {BD244D13-5805-4f39-A0D4-6AB400B42DFA} Maximum gate position iGmaxi gt GovHydroWEH.gmin. gmax {46B0E2D5-707A-4605-B164-F105314D5F1B} Minimum gate position iGmini lt GovHydroWEH.gmax. gmin {24665CC3-493E-48aa-9214-6ACA9765CD9B} Maximum gate closing rate iGtmxcli. gtmxcl {34423799-3E6A-447d-ACCA-A5AC39DF6432} Maximum gate opening rate iGtmxopi. gtmxop {1EEDF8E6-3068-4887-9EC8-C2EA214B87E0} Gate 1 iGv1i. Gate Position value for point 1 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. gv1 {A9C5A0A5-4720-4d99-A7A7-2D26F00D79E0} Gate 2 iGv2i. Gate Position value for point 2 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. gv2 {EEC48490-894C-4250-B1C4-72F856BE5A36} Gate 3 iGv3i. Gate Position value for point 3 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. gv3 {0CB4F774-A53F-4eb4-88FA-A50756044440} Gate 4 iGv4i. Gate Position value for point 4 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. gv4 {E5EE3181-0144-42de-9355-F5431928AE8C} Gate 5 iGv5i. Gate Position value for point 5 for lookup table representing water flow through the turbine as a function of gate position to produce steady state flow. gv5 {F04970BE-5332-4023-9D01-3CF0F2A64EEE} Derivative controller derivative gain iKdi. kd {437820AA-EB84-43e3-9F14-CD29F17E5357} Derivative controller Integral gain iKii. ki {186CD31C-11C2-4600-9C52-C73868C11E8C} Derivative control gain iKpi. kp {6C38D8F7-4D15-4269-88C5-8BB7D8B7B534} Base for power values iMWbasei gt 0. Unit MW. mwbase {E9D4FB05-AC60-4ec0-97F7-D0F12CD79F7C} Pmss flow P1 iPmss1i. Mechanical power output for turbine flow point 1 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss1 {7D878D2D-2290-494e-ABE1-2E30138DBADA} Pmss flow P10 iPmss10i. Mechanical power output for turbine flow point 10 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss10 {D1502FC1-74AE-4abe-9D8B-3A91C9B34B75} Pmss flow P2 iPmss2i. Mechanical power output for turbine flow point 2 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss2 {93ADB708-1FCF-46a7-A1FE-84B92459F065} Pmss flow P3 iPmss3i. Mechanical power output for turbine flow point 3 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss3 {CEC08DD4-FC8C-4e17-9617-C88CF79F807C} Pmss flow P4 iPmss4i. Mechanical power output for turbine flow point 4 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss4 {375B46F3-DFA0-48be-8747-B26DED2033EB} Pmss flow P5 iPmss5i. Mechanical power output for turbine flow point 5 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss5 {569E9FF0-4F73-4459-BC27-4C496AD9EA29} Pmss flow P6 iPmss6i. Mechanical power output for turbine flow point 6 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss6 {7515B1CA-A07C-4ee5-8977-871CAAF88680} Pmss flow P7 iPmss7i. Mechanical power output for turbine flow point 7 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss7 {C7FE804F-AB3E-41fd-B89C-259FED97771C} Pmss flow P8 iPmss8i. Mechanical power output for turbine flow point 8 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss8 {0021E92F-92DC-4c3b-8AF2-459A6CD9859C} Pmss flow P9 iPmss9i. Mechanical power output for turbine flow point 9 for lookup table representing PU mechanical power on machine MVA rating as a function of turbine flow. pmss9 {9F0CD115-B416-4c42-AC39-07560AE20E0D} Derivative controller time constant iTdi gt 0. Limits the derivative characteristic beyond a breakdown frequency to avoid amplification of highfrequency noise. td {CA60CB57-5545-44b2-A97E-B31C19C35908} Distributive valve time lag time constant iTdvi gt 0. tdv {163C915E-AF38-4e64-9D52-5BF5424C6118} Value to allow the distribution valve controller to advance beyond the gate movement rate limit iTgi gt 0. tg {E9402819-AB88-4baa-BD6E-2B688C06C3BE} Pilot valve time lag time constant iTpi gt 0. tp {36419228-318B-4c64-AB00-A75F021B45EF} Electrical power droop time constant iTpei gt 0. tpe {F37EFAD1-2A67-4c5f-B7CC-7658CC10C1E2} Water inertia time constant iTwi gt 0. tw {60C51DC4-0C85-4c88-B9FB-8535481239A0} Turbine damping factor iDi. Unit delta P delta speed. d {1CDFD103-979A-45f2-AC53-B6EBABF1658E} Gate opening limit maximum iGatmaxi gt GovHydroWPID.gatmin. gatmax {CBC8CAC7-BBD5-46ea-AA63-9BBA95339CA9} Gate opening limit minimum iGatmini lt GovHydroWPID.gatmax. gatmin {59E5BEF5-54B4-4300-948D-E434DDC29D67} Gate position 1 iGv1i. gv1 {54D1F02F-B3AE-4c97-92AC-E3ECB097EE4E} Gate position 2 iGv2i. gv2 {4BF85918-D50B-4ded-A4A7-7D751F42AF41} Gate position 3 iGv3i 10. gv3 {088C7FD4-A64F-4679-9308-F019240AB520} Derivative gain iKdi. Typical value 111. kd {7DD3DF14-A636-486c-93BF-2CDE421C351A} Reset gain iKii. Typical value 036. ki {80A87F57-E0A0-4355-8369-5F25F473B715} Proportional gain iKpi. Typical value 01. kp {DC7ECAB0-32B9-4f6b-96CD-21A7737B8AE3} Base for power values iMWbasei gt 0. Unit MW. mwbase {F0BFC978-6685-4754-8C7B-33DAC29144ED} Output at iGv1i PU of iMWbasei iPgv1i. pgv1 {6499A090-412B-4d38-B39E-65354DA61FFC} Output at iGv2i PU of iMWbasei iPgv2i. pgv2 {B5555EA0-F1DA-4444-91EF-A708739B01BB} Output at iGv3i PU of iMWbasei iPgv3i. pgv3 {C1C12E4E-54B8-4819-9EA7-3700A2F6D4F4} Maximum power output iPmaxi gt GovHydroWPID.pmin. pmax {C5161F34-C44E-4101-B7C7-AC4EC8AF73D4} Minimum power output iPmini lt GovHydroWPID.pmax. pmin {C0683772-32A1-48e0-831F-580D802FA100} Permanent drop iRegi. reg {943CF738-EE1C-47da-A25F-0C2EEC63695D} Controller time constant iTai gt 0. Typical value 0. ta {4B54F2C1-ACDC-4a1b-BD6B-44F3B1BE10C6} Gate servo time constant iTbi gt 0. Typical value 0. tb {0F0841FD-29F4-4349-ABE3-4371D74439DB} Speed detector time constant iTregi gt 0. treg {2FE7836B-00FF-46e9-BF83-1AD62994F770} Water inertia time constant iTwi gt 0. Typical value 0. tw {61278E8C-3A6F-4b21-A728-6920DD784BCD} Maximum gate opening velocity iVelmaxi gt GovHydroWPID.velmin. Unit PU s. Typical value 0. velmax {8099C25E-58FC-47d6-A4E5-9B275BAA8990} Maximum gate closing velocity iVelmini lt GovHydroWPID.velmax. Unit PU s. Typical value 0. velmin {966F8F0A-F65F-483f-B4A6-0DD4E3D4B61B} Turbine damping coefficient iDti. Unit delta P delta speed. Typical value 0. dt {2E52C3FD-AFC7-45df-979E-816627C3BD3B} Base for power values iMWbasei gt 0. Unit MW. mwbase {2DEDF38C-4F35-4a09-A72B-1E682C971FEF} Permanent droop iRi. Typical value 005. r {DEF748BA-6B2D-41bf-B4AB-684779F9E07C} Steam bowl time constant iT1i gt 0. Typical value 05. t1 {4A1A56EA-CC0F-45de-A8C0-5B84F599EBBF} Numerator time constant of iT2iiT3i block iT2i gt 0. Typical value 3. t2 {70493A6B-C94A-4b89-9561-AC0392054D36} Reheater time constant iT3i gt 0. Typical value 10. t3 {343FBD73-1436-4911-9FDA-B150560357FD} Maximum valve position PU of imwcapi iVmaxi gt GovSteam0.vmin. Typical value 1. vmax {6699F1C1-E261-4ac0-AA90-240DCE9EDDB5} Minimum valve position PU of imwcapi iVmini lt GovSteam0.vmax. Typical value 0. vmin {DC8803D9-2717-41cc-B675-7CDBDF480BF3} Intentional deadband width idb1i. Unit Hz. Typical value 0. db1 {A77CBD3D-9EF5-4960-983F-4BF3E49C5B9A} Unintentional deadband idb2i. Unit MW. Typical value 0. db2 {585062E0-7AF5-49a4-9109-11EA6036AB5F} Intentional db hysteresis iepsi. Unit Hz. Typical value 0. eps {11565F1A-7262-4d99-9D36-85008D67B2E2} Nonlinear gain valve position point 1 iGV1i. Typical value 0. gv1 {D31498E8-812A-4616-BF02-E62F0267A6E7} Nonlinear gain valve position point 2 iGV2i. Typical value 04. gv2 {9911B00A-D603-484a-BDE5-543F20B0A5A8} Nonlinear gain valve position point 3 iGV3i. Typical value 05. gv3 {FAC8C6BF-EAF3-4b9c-AF63-EC0441E6994A} Nonlinear gain valve position point 4 iGV4i. Typical value 06. gv4 {6AC94045-31C6-4865-BF63-B9A9ACD16490} Nonlinear gain valve position point 5 iGV5i. Typical value 1. gv5 {3B50B532-5A5C-4889-AB87-B31155DB184F} Nonlinear gain valve position point 6 iGV6i. Typical value 0. gv6 {2F114B0F-A915-4b0b-97B3-D9EAB684BDF3} Governor gain reciprocal of droop iKi gt 0. Typical value 25. k {EB46DBE2-3AED-40c4-A6A6-975580FB1882} Base for power values iMWbasei gt 0. Unit MW. mwbase {11EA8F80-CAD5-44e3-8893-3FBF11D33D5F} Nonlinear gain power value point 1 iPgv1i. Typical value 0. pgv1 {188F2130-8802-45f5-91AA-2A9514AC388D} Nonlinear gain power value point 2 iPgv2i. Typical value 075. pgv2 {7D77B573-07F0-47f7-BFFF-4F13EE82DA25} Nonlinear gain power value point 3 iPgv3i. Typical value 091. pgv3 {DDF38B36-369E-4d46-9D55-C9F87C94F24C} Nonlinear gain power value point 4 iPgv4i. Typical value 098. pgv4 {3EF3FE5E-3655-4c03-9F17-38BB5B02D04A} Nonlinear gain power value point 5 iPgv5i. Typical value 1. pgv5 {7D9CEFCA-A8B6-4bce-BD69-F7CAA3B08F5E} Nonlinear gain power value point 6 iPgv6i. Typical value 0. pgv6 {3D47DC91-D57C-4556-A31F-96B696DE66F1} Maximum valve opening iPmaxi gt GovSteam1.pmin. Typical value 1. pmax {7C1F64A8-147F-4e18-95F0-3F0BABF82895} Minimum valve opening iPmini gt 0 and lt GovSteam1.pmax. Typical value 0. pmin {C43C4789-9603-48d4-8BCB-72AE473AB8A1} Governor lag time constant iT1i gt 0. Typical value 0. t1 {84219FED-6A24-4520-ADEA-42E38B6E5465} Governor lead time constant iT2i gt 0. Typical value 0. t2 {CB1CBB4D-B666-4352-A131-5FA0663EACEF} Valve positioner time constant iT3 igt 0. Typical value 01. t3 {B05D1EC4-887A-4d17-9F0D-AF50BCA30EE5} Inlet pipingsteam bowl time constant iT4i gt 0. Typical value 03. t4 {06C29E01-3EBE-4768-AFB8-EAD717A5BE02} Time constant of second boiler pass iT5i gt 0. Typical value 5. t5 {E5405C9F-90A0-4002-8DF6-994A5AB4678F} Time constant of third boiler pass iT6i gt 0. Typical value 05. t6 {0B28BBC7-8677-4352-871C-C629D45FA46D} Time constant of fourth boiler pass iT7i gt 0. Typical value 0. t7 {79D2E4BF-C691-4c14-9039-653FC5A12749} Frequency deadband iDBFi. Typical value 0. dbf {4ECCC0CA-82AA-4b5c-836B-0E47BE551C38} Fuel flow maximum negative error value iMNiisubEFsubi. Typical value 1. mnef {AFD2584D-F92C-42a8-947A-428E8CE2E897} Fuel flow maximum positive error value iMXiisubEFsubi. Typical value 1. mxef {4E4A36B6-988F-4c44-A020-6165A778B92A} Maximum fuel flow iPiisubMAXsubi gt GovSteam2.pmin. Typical value 1. pmax {285C7FC5-344F-4625-AE73-9DB41F052ECD} Minimum fuel flow iPiisubMINsubi lt GovSteam2.pmax. Typical value 0. pmin {881CB33A-F1B3-4373-8E54-DDABCBF500E6} Governor lag time constant iTiisub1subi gt 0. Typical value 045. t1 {35B345F9-6E69-4ad2-8F13-6A1029B16261} Governor lead time constant iTiisub2subi gt 0. Typical value 0. t2 {5B194B27-05BF-4e75-8DD3-2D801159E3A5} Frequency deadband ifiisubcutsubi gt 0. Typical value 0002. fcut {0E18FB6D-C7CF-4b3d-8979-F10B6ED20238} Gain iK2i. Typical value 075. k2 {D6246395-FC43-4751-A620-E9AFCE848947} Gain iK3i. Typical value 05. k3 {752C1268-60AE-4c49-9D23-775FFFEA156B} Gain iKdi. Typical value 10. kd {5251AB39-0329-46a3-AFF1-A029EFF6CF94} Gain iKgi. Typical value 10. kg {A43E1339-FEE8-4462-8DF2-9D3D49165DB5} Gain iKlsi gt 0. Typical value 01. kls {30DFF15C-37AA-4700-A237-29BF65295E8B} Gain iKpi. Typical value 10. kp {2B8EBC64-4CC4-43ad-9A0F-B96F89FB39CA} Gain iKsi. Typical value 210. ks {A7302803-04A9-4430-8E57-97AB9A240F03} High power limit iPmaxi gt GovSteamBB.pmin. Typical value 10. pmax {F7EBD23C-4A5A-4941-8D0D-AF35EEBE3AB9} Low power limit iPmini lt GovSteamBB.pmax. Typical value 0. pmin {92C0B557-9F74-41cb-819A-EAD19DD6BDFE} Time constant iT1i. Typical value 005. t1 {06D55A71-AF1B-46ac-BF85-3C64F21A808A} Time constant iT4i. Typical value 015. t4 {23F09386-B96A-4807-9E42-35EBCD7355B5} Time constant iT5i. Typical value 120. t5 {D1164155-DB71-4d65-B3ED-B9DED1577924} Time constant iT6i. Typical value 075. t6 {1E8F11DC-A2F0-4144-915D-408A7F982624} Time constant iTdi gt 0. Typical value 10. td {0E0D3B71-1315-4fcb-8B30-B3CF976B8AFD} Time constant iTni gt 0. Typical value 10. tn {4212F57B-6F71-4352-8793-EE325DFC21B4} HP damping factor iDhpi. Typical value 0. dhp {CAA4CE58-A372-4921-B2C8-4A02D2858FC2} LP damping factor iDlpi. Typical value 0. dlp {F2553540-1BBF-4ba2-9BAB-5A46146D77C8} Fraction of HP power ahead of reheater iFhpi. Typical value 03. fhp {F243C240-3FE8-4c29-BB34-B8741BF6D940} Fraction of LP power ahead of reheater iFlpi. Typical value 07. flp {2D0CC21A-3B88-4712-A698-A93DE78DCCC9} Base for power values iMWbasei gt 0. Unit MW. mwbase {7D26F55F-866C-4dc1-9929-4475EF721953} Maximum HP value position iPmaxhpi. Typical value 1. pmaxhp {0215266A-9E00-4294-B267-67FB9D77D6FD} Maximum LP value position iPmaxlpi. Typical value 1. pmaxlp {5C39A692-9C54-4c8c-8E60-A0953782C737} HP governor droop iRhpi gt 0. Typical value 005. rhp {A1DB6375-5D37-4daa-877D-E25951792479} LP governor droop iRlpi gt 0. Typical value 005. rlp {E93DE78A-2C59-418d-9776-509B889795D6} HP governor time constant iT1hpi gt 0. Typical value 01. t1hp {3D952D69-270E-4d49-88FD-8FA58FA272ED} LP governor time constant iT1lpi gt 0. Typical value 01. t1lp {C89637BB-AA65-403b-A87E-9EFEFB6FB8EE} HP turbine time constant iT3hpi gt 0. Typical value 01. t3hp {B189CEEA-2CA7-4e67-8F67-0B367BDDCD7D} LP turbine time constant iT3lpi gt 0. Typical value 01. t3lp {08AA57C2-525A-4c3b-99FE-F6DECFBF63A2} HP turbine time constant iT4hpi gt 0. Typical value 01. t4hp {7C37A7BF-EBA3-471b-928B-2239F4485D94} LP turbine time constant iT4lpi gt 0. Typical value 01. t4lp {20C82B5A-F5C2-4019-8669-321C7A5F1B5E} HP reheater time constant iT5hpi gt 0. Typical value 10. t5hp {B1789202-591E-47af-8790-F6E94CB23471} LP reheater time constant iT5lpi gt 0. Typical value 10. t5lp {BDC9972B-0E8D-40ef-AD59-E2FC50B8CA3F} Intercept valves rate closing limit iCici. Typical value 22. cic {1CE2C5C6-F833-4b5f-B445-84FBCFD7361D} Intercept valves rate opening limit iCioi. Typical value 0123. cio {568A9507-36A3-421b-9640-2A9CA7E27E5D} Deadband of the frequency corrector idb1i. Typical value 0. db1 {3C28927B-00E6-4258-B92E-D97480764999} Deadband of the speed governor idb2i. Typical value 00004. db2 {E4E274A4-6302-48b5-9E76-FFE916C9B1A2} Maximum control valve position iHhpmaxi. Typical value 1. hhpmax {A1183CB7-248E-49b3-9CBE-174DAA2AA360} Gain of the power controller iKei. Typical value 065. ke {9C484EA6-BDD5-4168-8BF8-316D4B3BB6D1} Gain of the frequency corrector iKfcori. Typical value 20. kfcor {F44827D7-5A62-4e6a-B51B-889200EE9BAC} Fraction of total turbine output generated by HP part iKhpi. Typical value 0277. khp {DCD58561-BCFA-4811-AB0A-696EC2C80130} Fraction of total turbine output generated by HP part iKlpi. Typical value 0723. klp {90CB447C-DD10-4264-A94F-7295BFD6BAC6} Gain of the speed governor iKwcori. Typical value 20. komegacor {DFA76021-D5A7-4ef8-99C2-57EE96E5C8B1} Base for power values iMWbasei gt 0. Unit MW. mwbase {F36677CC-53A8-4a82-8071-5D477609BFCD} Maximal active power of the turbine iPmaxi. Typical value 1. pmax {141D9FB3-AE5A-453b-90FC-7666AEFB9923} Maximum low pressure limit iPrhmaxi. Typical value 14. prhmax {E4A8F98D-D571-48be-86EA-AA4DA473C260} Intercept valves transfer limit iSimxi. Typical value 0425. simx {110F9C82-647B-433d-A6D0-F20BE969A8FD} Boiler time constant iTbi gt 0. Typical value 100. tb {6939BF5E-1A7B-49c3-BCAE-B256D5305802} Derivative time constant of the power controller iTdpi gt 0. Typical value 0. tdp {81B7D62E-D2DB-41c9-A79E-163FB2210FF4} Electro hydraulic transducer iTeni gt 0. Typical value 01. ten {19813DEF-9416-4ffa-804B-D47E5FF2C4CC} Frequency transducer time constant iTfi gt 0. Typical value 0. tf {CDDB592D-5B31-49d5-BA52-5374D479B1BE} Time constant of the power controller iTfpi gt 0. Typical value 0. tfp {B5F3AA62-2076-4637-8306-B36724D11885} High pressure HP time constant of the turbine iThpi gt 0. Typical value 031. thp {57975343-40A0-46bb-A43C-13E600304884} Integral time constant of the power controller iTipi gt 0. Typical value 2. tip {0F8A085F-B368-436d-9D92-343E88AF2219} Low pressure LP time constant of the turbine iTlpi gt 0. Typical value 045. tlp {29B893EA-A77B-43ea-8A20-6D6320408868} Power transducer time constant iTpi gt 0. Typical value 007. tp {BCC75C87-06BE-4533-AA66-7FFC57721184} Reheater time constant of the turbine iTrhi gt 0. Typical value 8. trh {35B57951-2DF1-4ebe-9382-5BEAACC7C1A4} Control valves servo time constant iTvhpi gt 0. Typical value 01. tvhp {C4AD7C67-5135-4472-B036-22EB2964F783} Intercept valves servo time constant iTvipi gt 0. Typical value 015. tvip {E0C2F944-FE5B-48af-A4C2-FEC518B2AB55} Speed transducer time constant iTwi gt 0. Typical value 002. tw {7899000C-51A1-4038-8E92-908FEB0D86C0} Upper limit for frequency correction iWfmaxi gt GovSteamEU.wfmin. Typical value 005. wfmax {5E5EA0F9-E4E3-4c29-915D-D2D38D6D0424} Lower limit for frequency correction iWfmini lt GovSteamEU.wfmax. Typical value 005. wfmin {4206D95B-5A8C-42ee-B955-02C4C77EFD69} Emergency speed control lower limit iwmax1i. Typical value 1025. wmax1 {451E7E3F-6990-43b5-AF43-78CFC5A711B6} Emergency speed control upper limit iwmax2i. Typical value 105. wmax2 {A329D28C-1432-4fbe-A428-E947CC5F4448} Upper limit for the speed governor iWwmaxi gt GovSteamEU.wwmin. Typical value 01. wwmax {2BDA9EEB-A0A5-42a0-A6E3-132EFA209F17} Lower limit for the speed governor frequency correction iWwmini lt GovSteamEU.wwmax. Typical value 1. wwmin {FDD5FF45-AB58-4636-814A-F587E30F1EA8} iDti. dt {1078B67F-81D7-43e3-AC0C-095EB6FE9E0D} Fraction of the turbine power developed by turbine sections not involved in fast valving iKi. k {5D8BF3BB-513A-425b-99E1-296E80E4BB77} Alternate base used instead of machine base in equipment model if necessary iMWbasei gt 0. Unit MW. mwbase {775BD8D4-7E30-4e5c-83C8-37E6EC02069C} iRi. r {FE49FC81-A61A-49f5-B89B-7B3DC35958E8} Governor time constant iT1i gt 0. t1 {E72B25DB-96F9-4ce4-9A5A-478DD9F8CF48} Reheater time constant iT3i gt 0. t3 {CFF9C104-AF8A-4a1b-9235-8498396F3C58} Time after initial time for valve to close iTai gt 0. ta {CA28640A-98C2-45f5-9FB4-3CA075811C95} Time after initial time for valve to begin opening iTbi gt 0. tb {A4905A52-147D-425f-8D70-0BD93B908647} Time after initial time for valve to become fully open iTci gt 0. tc {03ED1261-377F-4cdf-BF52-3C02546B2E7B} Time constant with which power falls off after intercept valve closure iTti gt 0. tt {C31BA8DF-B822-49a7-BBE7-3317B0A9A159} iVmaxi gt GovSteamFV2.vmin. vmax {CF82BE67-DCDF-421e-BC3B-0B97CD064051} iVmini lt GovSteamFV2.vmax. vmin {FA92EA93-7BE4-427e-98A4-CFDDF7128C54} Nonlinear gain valve position point 1 iGV1i. Typical value 0. gv1 {E874B1DF-E7F2-4dd2-84F9-13E25FCE9FE1} Nonlinear gain valve position point 2 iGV2i. Typical value 04. gv2 {D6ACEA3F-7510-495a-89B0-D9EC37898E57} Nonlinear gain valve position point 3 iGV3i. Typical value 05. gv3 {72054D4A-B578-4339-BF19-A0D87AC68CC6} Nonlinear gain valve position point 4 iGV4i. Typical value 06. gv4 {429CB562-E8AB-434d-9F06-0531A5FB8EC2} Nonlinear gain valve position point 5 iGV5i. Typical value 1. gv5 {CADA4FA7-24F0-4006-8FCA-C0DFA7B528AF} Nonlinear gain valve position point 6 iGV6i. Typical value 0. gv6 {EB422568-E0EB-46e3-A82E-CE28ED9AA6D5} Governor gain reciprocal of droop iKi. Typical value 20. k {D812C52D-7AB5-4275-AA2B-72BFBEC2935C} Fraction of turbine power developed after first boiler pass iK1i. Typical value 02. k1 {50077BE8-96B4-4ace-996C-F03786379A92} Fraction of turbine power developed after second boiler pass iK2i. Typical value 02. k2 {A7687637-D622-492f-A7FE-78F185BB94F3} Fraction of hp turbine power developed after crossover or third boiler pass iK3i. Typical value 06. k3 {82C3CBE7-853A-4dbb-9BCF-8B6FC6DDE68C} Base for power values iMWbasei gt 0. Unit MW. mwbase {5D07D037-9E57-48ec-B14E-EA6B6DB4B0D9} Nonlinear gain power value point 1 iPgv1i. Typical value 0. pgv1 {4B6A30E2-D5EB-4364-9D05-5985E67AD5EF} Nonlinear gain power value point 2 iPgv2i. Typical value 075. pgv2 {39CE6A04-677D-46ce-A4B3-46A3CC5B3703} Nonlinear gain power value point 3 iPgv3i. Typical value 091. pgv3 {169C7971-2422-4a63-95B9-861B6395671B} Nonlinear gain power value point 4 iPgv4i. Typical value 098. pgv4 {A48F5B0F-293F-443b-84F9-3808641B4A47} Nonlinear gain power value point 5 iPgv5i. Typical value 1. pgv5 {B63726CA-1E67-412f-A0C2-CCB460851FD6} Nonlinear gain power value point 6 iPgv6i. Typical value 0. pgv6 {F9940DA2-49DB-4808-9791-1E3354DE3B0C} Maximum valve opening PU of iMWbasei iPmaxi gt GovSteamFV3.pmin. Typical value 1. pmax {83CDC484-448A-41e9-9B76-1387BA086210} Minimum valve opening PU of iMWbasei iPmini lt GovSteamFV3.pmax. Typical value 0. pmin {5067B69C-1F2E-4ae7-B34D-82E10D593270} Max. pressure in reheater iPrmaxi. Typical value 1. prmax {08A80961-533E-4c2d-9922-B957DC12B461} Governor lead time constant iT1i gt 0. Typical value 0. t1 {96858B4F-3184-49fe-A309-14C0C5292B1A} Governor lag time constant iT2i gt 0. Typical value 0. t2 {69C796D4-A0AF-4327-B185-59635C60C453} Valve positioner time constant iT3i gt 0. Typical value 0. t3 {E218667B-0751-41ab-B15A-793C48132DC1} Inlet pipingsteam bowl time constant iT4i gt 0. Typical value 02. t4 {20359039-EB27-41fc-A1C6-00DF036CFE3A} Time constant of second boiler pass i.e. reheater iT5i gt 0 if fast valving is used otherwise gt 0. Typical value 05. t5 {FEEC774C-00BF-47c5-BB64-66AA92CB02DA} Time constant of crossover or third boiler pass iT6i gt 0. Typical value 10. t6 {0C07F8A3-EC87-44e3-802B-E29F6E7A0CF4} Time to close intercept valve IV iTai gt 0. Typical value 097. ta {19FF9DAA-9677-4971-BD65-451BFDC95350} Time until IV starts to reopen iTbi gt 0. Typical value 098. tb {31CD944F-4727-4535-889B-8ED2187C1D7F} Time until IV is fully open iTci gt 0. Typical value 099. tc {65A3FED2-6AFD-45ec-822F-07E55F257F30} Minimum value of pressure regulator output iCpsmni. Typical value 1. cpsmn {E9DBD13F-85FF-4f9d-9CC2-CBF8D30537F2} Maximum value of pressure regulator output iCpsmxi. Typical value 1. cpsmx {E2C0F331-1B3D-411a-B83C-A907C3286AFA} Minimum value of regulator setpoint iCrmni. Typical value 0. crmn {34ECA262-63E9-4632-8FFB-FA2D44612B6D} Maximum value of regulator setpoint iCrmxi. Typical value 12. crmx {49ED4396-A7C2-45f0-A3DE-4E1BCF2F36AF} Derivative gain of pressure regulator iKdci. Typical value 1. kdc {C946421B-13FD-4d63-BE11-411FAA7A1488} Frequency bias reciprocal of droop iKf1i. Typical value 20. kf1 {508C2858-C010-49b6-A75C-AFC7AA3BBAE8} Frequency control reciprocal of droop iKf3i. Typical value 20. kf3 {B1997DED-9F95-41ac-9AC5-820C23706CC0} Fraction of total turbine output generated by HP part iKhpi. Typical value 035. khp {850AE4D1-F8FE-4d1c-B2E7-214EB3E7D533} Integral gain of pressure regulator iKici. Typical value 00033. kic {11BEE5A6-7EC1-475b-B096-71A00DD5B0DC} Integral gain of pressure feedback regulator iKipi. Typical value 05. kip {5638FE78-5181-4a8a-8C8B-44EEE90EE355} Integral gain of electrohydraulic regulator iKiti. Typical value 004. kit {36D398CE-4730-4956-88E2-D1EAAD1DCE48} First gain coefficient of intercept valves characteristic iKmp1i. Typical value 05. kmp1 {A3F3162A-036E-421b-AD4D-A8B7A1629142} Second gain coefficient of intercept valves characteristic iKmp2i. Typical value 35. kmp2 {4B7EF22B-BF12-460b-9661-4F05ABC35877} Proportional gain of pressure regulator iKpci. Typical value 05. kpc {F60F8893-378A-47da-8EA0-EAF3FAD00195} Proportional gain of pressure feedback regulator iKppi. Typical value 1. kpp {D7AA6144-3E0C-4292-8213-0C08C3620A12} Proportional gain of electrohydraulic regulator iKpti. Typical value 03. kpt {1E78FDA6-6D86-46a7-A6F8-88B14D05EDAC} Maximum variation of fuel flow iKrci. Typical value 005. krc {AB7B7099-8460-428e-AFCB-CA16A9874F0B} Pressure loss due to flow friction in the boiler tubes iKshi. Typical value 008. ksh {7544C5BC-B364-4ea0-A283-32E3560EEA64} Maximum negative power error iLpii. Typical value 015. lpi {BD96AA9C-4159-4c5e-BB47-AD342BFDD719} Maximum positive power error iLpsi. Typical value 003. lps {3C8A33C3-274B-4d1d-8D5D-AAB04C4DB84A} Lower limit for frequency correction iMNiisubEFsubi. Typical value 005. mnef {285955C5-D035-42a8-966C-3AFD99799AA8} Upper limit for frequency correction iMXiisubEFsubi. Typical value 005. mxef {801A2891-39DA-433a-B3F3-A06D2E96A234} First value of pressure set point static characteristic iPr1i. Typical value 02. pr1 {CD5E7783-3DE0-4520-88AE-C2610005E1BA} Second value of pressure set point static characteristic corresponding to iPs0i 10 PU iPr2i. Typical value 075. pr2 {0A7E701E-3922-4e2a-8C1F-C74A2FE11E13} Minimum value of pressure set point static characteristic iPsmni. Typical value 1. psmn {A7DF91CF-A30F-43d6-8B79-565A2F75D427} Minimum value of integral regulator iRsmimni. Typical value 0. rsmimn {8B05B27E-532F-414c-B2F8-60AEF76DC6E5} Maximum value of integral regulator iRsmimxi. Typical value 11. rsmimx {86384E60-6DED-4a13-B081-87A85572597D} Minimum value of integral regulator iRvgmni. Typical value 0. rvgmn {CFFE55BB-0A0C-423a-BFD8-68A65FBCAA5D} Maximum value of integral regulator iRvgmxi. Typical value 12. rvgmx {026BE588-F74B-4015-8F31-646BE73272A8} Minimum valve opening iSrmni. Typical value 0. srmn {BDD9B27C-E19C-40a2-B9A3-40C178F96C3A} Maximum valve opening iSrmxi. Typical value 11. srmx {6A4B6465-FFFC-4cc9-9A19-0D739D468207} Intercept valves characteristic discontinuity point iSrsmpi. Typical value 043. srsmp {6DA38905-8256-404b-A444-04C9EE89644E} Control valves rate opening time iTai gt 0. Typical value 08. ta {5E168E27-CF72-411e-BEE5-E17364F8E223} Intercept valves rate opening time iTami gt 0. Typical value 08. tam {B7BEFDB3-EC75-4c1d-A5CD-5ABF52976BE3} Control valves rate closing time iTci gt 0. Typical value 05. tc {21F03085-6C79-4dad-9C3F-E8F964F79C7D} Intercept valves rate closing time iTcmi gt 0. Typical value 05. tcm {D34C3D25-D4CC-42c6-8F48-4812BA6C67E2} Derivative time constant of pressure regulator iTdci gt 0. Typical value 90. tdc {92244DA9-318A-408b-AE5C-433CBE35824A} Time constant of fuel regulation iTf1i gt 0. Typical value 10. tf1 {DD5F9B1D-032F-4d31-A0DF-437758280B81} Time constant of steam chest iTf2i gt 0. Typical value 10. tf2 {4F79E063-4AA6-4983-9E6E-295EF7A60FB1} High pressure HP time constant of the turbine iThpi gt 0. Typical value 015. thp {10FD21BA-CD02-446b-8E93-593B94D77B67} Low pressure LP time constant of the turbine iTmpi gt 0. Typical value 04. tmp {396BC671-A807-4b26-B7A3-91C37689C5AE} Reheater time constant of the turbine iTrhi gt 0. Typical value 10. trh {21F92AA8-3819-4808-8972-F78A329F7A44} Boiler time constant iTvi gt 0. Typical value 60. tv {5BB2D156-1D6A-4a63-A31D-C707296AAC5A} Control valves servo time constant iTyi gt 0. Typical value 01. ty {16218B62-D2B3-45a6-9FC1-B0BED9126075} Coefficient of linearized equations of turbine Stodola formulation iYi. Typical value 013. y {2ADF361B-A0F5-46d4-B6BA-A90C2B2B965F} Minimum control valve position iYhpmni. Typical value 0. yhpmn {8925B517-7D03-4a5f-A11C-6AEE121FD1C4} Maximum control valve position iYhpmxi. Typical value 11. yhpmx {AD266096-6044-474c-9B43-B09B41FDB5C2} Minimum intercept valve position iYmpmni. Typical value 0. ympmn {8F8B125A-EA23-4807-8A7F-571B0D75E79B} Maximum intercept valve position iYmpmxi. Typical value 11. ympmx {8F18ED11-7811-4dc3-BA55-B3519E8F6FBD} Governor gain reciprocal of droop iKi gt 0. Typical value 25. k {3B0BA29C-E505-4c31-AC6D-22153D6A2344} Base for power values iMWbasei gt 0i. iUnit MW. mwbase {D7E35874-9E7E-401b-8C00-EFF8CE6D581B} Maximum valve opening iPmaxi gt GovSteamIEEE1.pmin. Typical value 1. pmax {C0A21ABD-B86F-4be6-843A-6418DBDFBA74} Minimum valve opening iPmini gt 0 and lt GovSteamIEEE1.pmax. Typical value 0. pmin {E07CF9E0-312E-4170-B843-E218030E028A} Governor lag time constant iT1i gt 0. Typical value 0. t1 {A43E3910-A206-47ce-90EF-4EDDCEAD2B97} Governor lead time constant iT2i gt 0. Typical value 0. t2 {7B8DF74C-AF7D-4355-BC96-3E03C80DC2C2} Valve positioner time constant iT3i gt 0. Typical value 01. t3 {528BF1FA-2DE1-49af-9EFE-992F44D064BA} Inlet pipingsteam bowl time constant iT4i gt 0. Typical value 03. t4 {D42E87AF-7FB9-4f45-8951-C2672F43892A} Time constant of second boiler pass iT5i gt 0. Typical value 5. t5 {C87552A6-806A-4e71-8690-82F8580A2D8D} Time constant of third boiler pass iT6i gt 0. Typical value 05. t6 {B6FEADDA-2652-401b-BCAC-3EC97560751D} Time constant of fourth boiler pass iT7i gt 0. Typical value 0. t7 {034804D5-AB66-4855-9002-4CDF1ACC780C} One PU regulation iK1i. k1 {03926971-3F21-4914-927A-AF05CD061C02} Fraction iK2i. k2 {9FD36089-0DEA-4e95-BCFD-634C00DA8598} Fraction iK3i. k3 {67B9B9D6-D9DC-48d6-90F5-045C8CBDF2BC} Base for power values iMWbasei gt 0. Unit MW. mwbase {C613BB7A-3323-4635-B664-C4E30D182893} Upper power limit iPmaxi gt GovSteamSGO.pmin. pmax {43756471-2CE6-410b-B4B7-A4711385608C} Lower power limit iPmini gt 0 and lt GovSteamSGO.pmax. pmin {4C92810B-55D6-4f56-B1FD-381DF7F8F6E7} Controller lag iT1i gt 0. t1 {9DD652EA-4807-4313-8A33-F94BA5596DF0} Controller lead compensation iT2i gt 0. t2 {C1793777-CC94-4269-98CF-7D2904A63C2A} Governor lag iT3i gt 0. t3 {0D4E6BB8-A356-4073-9D8C-2B6164ECEC24} Delay due to steam inlet volumes associated with steam chest and inlet piping iT4i gt 0. t4 {5C4F8354-CA49-4224-AB28-1A759E350DC7} Reheater delay including hot and cold leads iT5i gt 0. t5 {F33128D7-055F-4bbd-A4A3-9116F3C417D0} Delay due to IPLP turbine crossover pipes and LP end hoods iT6i gt 0. t6 {CA8EC5EB-322E-418b-BB3B-B256740CD309} A generating unit may have a gross active power to net active power curve describing the losses and auxiliary power requirements of the unit. GeneratingUnit {5A8B2A9D-6CA6-40c5-A362-38519E574F17}.SupplierEnd Action taken with this ground. GroundAction {66B211AA-2CA9-43e6-9304-6C6E078FC904}.ClientEnd The line segment that this ground action will affect. This is the only way to access relationship to clamp in case the ground needs to be placed along the line segment. AlongACLineSegment {1E3F8223-0B92-4d7f-B4A8-4D976F915A99}.SupplierEnd Ground on which this action is taken. Ground {66B211AA-2CA9-43e6-9304-6C6E078FC904}.SupplierEnd Equipment being grounded with this operation. In case of placing a ground anywhere along a line segment you must use the clamp to get the distance from one terminal so use the explicit relation with line segment. In all other cases including placing the ground at a line segment terminal reference to one or more conducting equipment is sufficient. GroundedEquipment {E49D8003-4EDF-4e58-A61C-0A5F1C6165E1}.SupplierEnd Switching action to perform. kind {66457754-0A36-4354-B043-81FCC23B4478} Reactance of device. x {EAF81570-74C7-49bb-B7CD-DDC0F14E9A27} Qregulator {7AC340E9-74FE-45f9-8424-0F67D74E0B6A}.SupplierEnd VDCOL {14C2B235-371D-4ebf-BFF8-1E462660C3D0}.SupplierEnd functionKind {3F937634-1749-4f11-A2D1-B3D391549380} Status of this hazard. status {FCC8BE04-7ADD-48f6-8612-BA3EA0E20610} Risk score with which this health score is associated. AssetRiskScore {35D3A10F-8986-4cb3-84BA-68730CC19A28}.SupplierEnd A thermal generating unit may have a heat input curve. ThermalGeneratingUnit {0F7AF31F-7DEC-4822-9117-8C921A5EADD4}.SupplierEnd Power output auxiliary power multiplier adjustment factor. auxPowerMult {C363F167-DCA3-444f-A356-B2EC5EC6BFE3} Power output auxiliary power offset adjustment factor. auxPowerOffset {EBDBFAC3-F5B4-417e-9DCE-FD4332A94039} Heat input efficiency multiplier adjustment factor. heatInputEff {A9882A3A-810D-44e6-BC69-3AD2A316B429} Heat input offset adjustment factor. heatInputOffset {93844E51-F4F7-47ab-91CA-B268630921DA} multiplier {5DEF0F44-4B0F-4c43-8A24-A09D1CF5FFD6} unit {F95A9930-5D29-48ea-B9E4-F822F6F83BE4} A thermal generating unit may have a heat rate curve. ThermalGeneratingUnit {E732F28C-0BF4-4edf-8CAB-14E807036F6F}.SupplierEnd A combustion turbine may have a heat recovery boiler for making steam. CombustionTurbines {C08435B8-5EEA-4a1c-84DE-0253F3F7AC68}.SupplierEnd AdjacentCASet {8E4B9C0F-0498-44a7-BFE9-8CB6884935B0}.SupplierEnd BidSelfSched {A54AFE0A-D986-4114-B72E-9243C90ABC98}.SupplierEnd CnodeDistributionFactor {334067AA-47A1-45ec-86D0-469477F304C9}.SupplierEnd A ControlAreaCompany controls a ControlArea. Controls {1AFC6FC5-1F2B-45c1-92ED-34FE03FF7500}.SupplierEnd Flowgate {AF155808-E637-4950-B9F3-2EAB07EDB824}.SupplierEnd LossClearingResults {AD728487-11BF-4cf9-8208-EB973AA30251}.SupplierEnd RTO {61BC778B-58EC-4247-B85A-DA7F2D069EB9}.ClientEnd RegisteredResource {4F7E336A-F935-41ea-B46D-CA4A8FBC907C}.SupplierEnd The interchange area may operate as a control area SubControlAreas {FBEF4124-D3C2-4585-A504-3D5551015F14}.SupplierEnd SysLoadDistribuFactor {451D980C-3785-4de0-AC06-5515EF2C589B}.SupplierEnd TransferInterface {916AF086-1537-4361-A735-CFC6D28337F9}.SupplierEnd The areas present control mode CF constant frequency or CTL constant tieline or TLB tieline bias or OFF off control areaControlMode {98508A61-49E6-4434-A8AA-2EE605E1E720} The present power system frequency set point for automatic generation control freqSetPoint {680B241E-AF4C-450e-817A-01CF7FEFDFFE} multiplier {D6A39BEF-98E8-41ea-B1C7-A5A740DB7F72} unit {2E277D44-14DA-4343-85AC-FFBF01D847F8} A hydro generating unit has an efficiency curve. HydroGeneratingUnit {8EFF4A51-FC21-4aa8-936F-C5CD96AED3B5}.SupplierEnd A hydro generating unit has an efficiency curve. HydroGeneratingEfficiencyCurves {8EFF4A51-FC21-4aa8-936F-C5CD96AED3B5}.ClientEnd The hydro generating unit belongs to a hydro power plant. HydroPowerPlant {DF7B4AA7-A2FE-443d-80DA-3E081B767D96}.ClientEnd A hydro generating unit has a penstock loss curve. PenstockLossCurve {7ACC0340-79B7-4e30-B609-66235FA04D5D}.ClientEnd A hydro generating unit has a tailbay loss curve. TailbayLossCurve {F9B9CD62-2EEB-4f1a-969B-6EE451A47D3F}.ClientEnd The height water drops from the reservoir midpoint to the turbine. dropHeight {B502B280-7E7E-4b6b-891B-61CB4DD59A36} Energy conversion capability for generating. energyConversionCapability {FD24D707-A27D-4ff0-AD05-342786B12544} The equivalent cost of water that drives the hydro turbine. hydroUnitWaterCost {8EA91FB4-19DF-4575-8188-A14EA84B2E96} Type of turbine. turbineType {5C107CE1-BFC7-49b0-877E-A3F16C08008B} Generators are supplied water from or pumps discharge water to an upstream reservoir. GenSourcePumpDischargeReservoir {00B2E13E-C0A8-4011-8062-D47DDF498C70}.SupplierEnd The hydro generating unit belongs to a hydro power plant. HydroGeneratingUnits {DF7B4AA7-A2FE-443d-80DA-3E081B767D96}.SupplierEnd The hydro pump may be a member of a pumped storage plant or a pump for distributing water. HydroPumps {97B133E1-465B-463d-A8D6-CD977E575F10}.SupplierEnd Generators discharge water to or pumps are supplied water from a downstream reservoir. Reservoir {2C3E96AE-B573-4669-98A0-A1B15E5B69A2}.SupplierEnd Water travel delay from tailbay to next downstream hydro power station. dischargeTravelDelay {7E41C303-46EA-49e5-811F-391B6D32DB9C} The hydro plants generating rating active power for rated head conditions.The attribute shall be a positive value. genRatedP {28D52CE4-E00F-48b9-B17D-8C2589281C71} The type of hydro power plant water storage. hydroPlantStorageType {19631246-ED56-44ae-A636-6C1B4DACDDF0} Total plant discharge capacity. plantDischargeCapacity {7BCFA6C6-1EA0-4c6a-9FC4-5E4DF0B64AFF} The plants rated gross head.The attribute shall be a positive value. plantRatedHead {656435AA-37ED-4a01-970D-4292DAABEDD4} The hydro plants pumping rating active power for rated head conditions.The attribute shall be a positive value. pumpRatedP {7C1B9181-2FEF-4d65-9411-DFDD7CEFD2C5} The level at which the surge tank spills. surgeTankCrestLevel {2AE16ADA-2ECF-4899-ACBB-FCF6C9807C2C} The hydro pump may be a member of a pumped storage plant or a pump for distributing water. HydroPowerPlant {97B133E1-465B-463d-A8D6-CD977E575F10}.ClientEnd The hydro pump has a pumping schedule over time indicating when pumping is to occur. HydroPumpOpSchedule {FBD22BD2-FDFF-4973-A3EF-F30E7E51A36C}.ClientEnd The synchronous machine drives the turbine which moves the water from a low elevation to a higher elevation. The direction of machine rotation for pumping may or may not be the same as for generating. RotatingMachine {B7907DA2-3474-44e7-8BA4-9B2DB3D1D425}.ClientEnd The pumping discharge under maximum head conditions usually at full gate. pumpDischAtMaxHead {9D90170B-3F8F-40a9-B12F-1096B584C7C6} The pumping discharge under minimum head conditions usually at full gate. pumpDischAtMinHead {18BF0612-CF16-449c-B10E-E37CDEAF6D5E} The pumping power under maximum head conditions usually at full gate. pumpPowerAtMaxHead {D1FB01DB-20BE-4ba6-BB53-397352A73FE1} The pumping power under minimum head conditions usually at full gate. pumpPowerAtMinHead {A663A382-B65C-4b74-999D-234661878F20} The hydro pump has a pumping schedule over time indicating when pumping is to occur. HydroPump {FBD22BD2-FDFF-4973-A3EF-F30E7E51A36C}.SupplierEnd Gate upper limit. gateUpperLimit {F8DFE559-ADA7-4947-8207-604FEEF7807A} Maximum efficiency active power at maximum head conditions. maxHeadMaxP {9DDEDD01-FED7-4702-8C77-2F953107A7FD} Maximum efficiency active power at minimum head conditions. minHeadMaxP {E761D565-2AAC-41f6-9D30-3DFFFF11EBEA} Rated speed in number of revolutions. The attribute shall be a positive value. speedRating {A1F6B52E-13C8-4422-B314-31C7450BC0FB} Speed regulation. speedRegulation {D59C0A8B-F4E3-432b-9809-157934B00C0F} Transient droop time constant. transientDroopTime {B57DCA5C-64B9-43ba-94AB-E03D5848E150} Transient regulation. transientRegulation {36E50ED7-D493-41e7-83F7-944A9FCC05A7} Rated turbine active power. The attribute shall be a positive value. turbineRating {A3FA8BFD-6022-45e5-8FED-09082CF033FC} Type of turbine. turbineType {F57E682E-9BC6-41ce-8566-C0CC08E30A48} Water starting time. waterStartingTime {A405790B-074F-441d-B7CD-AE5818D76533} Kind of hydrospheric analog. kind {01D4ACA7-1A34-4942-A956-09C303B9DF9E} Bilateral table agreement that includes the informational message. TASE2BilateralTable {D286EEBB-4C7C-449f-8621-C35CE7904696}.SupplierEnd Indicates if the Point is global scoped e.g. VCC or accessible only to the Bilateral table peer e.g. ICC. scope {8ED16BF5-7CC8-4e3b-8FE1-11C8455AF042} Provides information regarding the access privileges allowed to the ICCP Point. accessPriviledge {F0A85B7D-074A-412d-8E63-4FDB313F5FA9} Specifies the type of ICCP quality that will be conveyed as part of the ICCP Point. pointQuality {82B1178E-ED69-4116-8D6B-8FEAD66C9BC2} Indicates the ICCP Point type that is to be conveyed.A CIM AccumlatorValue shall be mapped to an ICCP real.A CIM AnalogValue shall be mapped to an ICCP real.A CIM DiscreteValue shall be mapped to either an ICCP real state stateSupplemental or either protection event type.A CIM StringMeasurementValue does not have a standardized mapping. pointType {F2BADF24-7697-4aa5-866E-C58D0F4CD4E7} Indicates if the Point is global scoped e.g. VCC or accessible only to the Bilateral table peer e.g. ICC. scope {C5080713-CF50-4d85-9B8B-8BB69C33C65F} Specifies the expected security mechanism per IEC 623514 to be utilized. applicationSecurityRequirement {637A7E23-1FF3-410b-A39B-5F676EDDE97B} Edition of IEC standard. standardEdition {585CC50D-21F9-440d-ABE6-2D3D0704FBC4} IEC standard number. standardNumber {0C85B647-C34F-470e-B7D6-25AEA75D63E6} Edition of IEEE standard. standardEdition {FD546E83-49E5-4d47-B13D-08A13B74DB6E} IEEE standard number. standardNumber {72D3AE93-F639-43e0-B530-A65D534C57D9} Bilateral ICCP point for the measurement or control. BilateralToIOPoint {D2E53A93-0C08-4243-8A32-01EF61C12DBB}.SupplierEnd Local merasurement value source for an ICCP point. IOPointSource {F40144F0-7CF5-4813-9870-55D84B003374}.ClientEnd ICCP point for a local measurement value source. IOPoint {F40144F0-7CF5-4813-9870-55D84B003374}.SupplierEnd IP address type. addressType {83E31300-ECA0-4c28-8A25-D0B0C19F6ED6} Edition of ISO standard. standardEdition {C2FB345E-2A1C-4b48-9EA2-BEF5D3C70E7A} ISO standard number. standardNumber {3EF36699-DC51-44c9-81A1-09C19A488257} Certificate to be bound for use for Application layer mutual authentication. UpperLayerPublicX509Certificate {5562C131-015C-4469-BB74-1B33BA1A81D9}.ClientEnd CSCtype1 {339D9BE1-B6FE-4ebd-B884-707C77DA6C91}.SupplierEnd Delay {F80046F2-833E-473c-81F7-F2217DD56589}.ClientEnd VDCOL {D9D8D23C-3E4B-4af0-B456-954687DFA9E6}.ClientEnd The diagram objects that are associated with the domain object. DiagramObjects {03423B70-34E0-4313-B19B-5FAFFD1F143B}.SupplierEnd Dataset containing the data objects. InstanceSet {8740E742-45B5-4b82-8058-EFA19A56A689}.SupplierEnd All names of this identified object. Names {203C47E2-30FB-4c8f-ABEA-1661621CC0A7}.ClientEnd The single CIM data object in the appropriate dataset context. PropertiesCIMDataObject {F527D24E-59B1-4748-B31A-660841060493}.ClientEnd Data objects registered. TargetingCIMDataObject {950EB9DD-F3F6-405e-81C4-3D00B3ABD338}.ClientEnd CSCtype1 {2F9E4B3A-A9A7-43b4-8FAD-55865942D1B6}.SupplierEnd multiplier {92990EDC-2F54-42c3-8F99-B78E953C4A09} unit {B16F7D93-D30C-49a4-8E27-369431523B0A} A control area can have one or more net inadvertent interchange accounts SubControlArea {3CB78F17-FFCF-48bc-835B-C78BF0FB4994}.SupplierEnd All notifications for a customer related to the status change of this incident. CustomerNotifications {F292A647-3328-43e1-AA6F-08A42730AF41}.SupplierEnd All hazards associated with this incident. IncidentHazard {68AE0E00-0724-4e70-981A-2F27766EAF3E}.SupplierEnd Location of this incident. Location {92317947-BF8F-4e74-A2A0-4C97EDA82DD0}.SupplierEnd Outage for this incident. Outage {91D33A1C-B14C-40a2-8C56-19764D00E571}.SupplierEnd Operator who owns this incident. Owner {C2056AB7-C6BB-48a9-9AC4-CC384465DB27}.SupplierEnd TroubleOrder {3D79F2D5-BE8F-4d59-A6FE-14060E81D5FA}.ClientEnd All trouble tickets reporting this incident. TroubleTickets {604AF98C-C65C-46ec-828D-96FE5F906C35}.ClientEnd UnplannedOutage {F41F931E-15E0-43ea-9BBE-8F6DB650B1D9}.SupplierEnd All works addressing this incident. Works {49B9A841-26C8-423d-94AD-33ADD3293D00}.SupplierEnd Incident associated with this hazard. Incident {68AE0E00-0724-4e70-981A-2F27766EAF3E}.ClientEnd Trouble ticket associated with this hazard. TroubleTicket {F1DCAE08-2CD6-4c12-9B22-D06B9E9DAA02}.ClientEnd IncrementalDataset {4727D339-3136-4719-B7FF-3F8D5D00B334}.SupplierEnd IncrementalDatasetArgDescription {343EFB4F-6622-4258-9EC1-BCB257B0ECB8}.SupplierEnd The incremental dataset used for this argument instance. IncrementalDatasetArg {343EFB4F-6622-4258-9EC1-BCB257B0ECB8}.ClientEnd A thermal generating unit may have an incremental heat rate curve. ThermalGeneratingUnit {44777851-6FBC-4f50-AF92-1EA11CE04CA8}.SupplierEnd CongestionArea {6DB2691B-152F-462d-B727-DE871F8AAB7A}.ClientEnd GenDistributionFactor {1A518B75-8859-4a3f-AB51-3C3CD3B54E95}.SupplierEnd LoadDistributionFactor {3F23D218-E902-4629-B47B-6E2F216E85DF}.SupplierEnd MktConnectivityNode {2B0FBC3E-406E-4d8b-A02A-36C41F9A1D0E}.SupplierEnd PnodeDistributionFactor {24E9F23C-430E-4596-B763-07DB8054801D}.SupplierEnd multiplier {DF6B0AAC-52CD-4c60-8800-409FE83F07D1} unit {7668DEE2-8EA2-47c3-9C02-E4B53F39569C} multiplier {F05ABE27-834D-45c9-AD64-4B7F0EC4DC73} unit {AD33BEF6-443E-4d2c-A32A-9152AEB8D250} A reservoir may have a natural inflow forecast. Reservoir {390FA231-DEA9-4f7c-9E58-9EA15F9F2F0C}.SupplierEnd Kind of analog representing inspection result. kind {223CD58E-7581-423f-9A39-FAC7937B528C} AccordingToSchedules {37ACB8AF-5C2E-4faa-8C9D-87E718507CBD}.ClientEnd Kind of discrete representing inspection result. kind {F24FF102-2B32-41ed-97BD-90FFF1EE7382} The role of a dataset in the context of an operation. DatasetArg {5B31BEB7-2629-4c5a-B015-4D2B871D04D9}.ClientEnd Data objects contained in the dataset. InstanceSetMember {8740E742-45B5-4b82-8058-EFA19A56A689}.ClientEnd ActualDemandResponseEvents may exist that are not part of a cordinated MarketActualEvent associated to a Market. These ActualDemandResponseEvents can have many InstructionClearing Instructions for specified RegisteredResources or Distributed Energy Resource type of AggregateNodes. ActualDemandResponseEvent {7B14AF42-A7C8-4839-AEBA-18F104ABE94C}.ClientEnd Instructions {B51C2A99-4E92-4961-A6C0-F5BB918A2A32}.ClientEnd ResourceDeploymentStatus {23E96A97-D54D-4d70-8585-71267B61B888}.SupplierEnd DopInstruction {21EAE1E5-554D-4e8e-BE91-8FB6E528D842}.SupplierEnd DemandResponseActualEvent {01022165-D079-41fa-B9C3-342CFFA5E537}.ClientEnd DotInstruction {CEC60D6E-B919-43a0-9B3B-92AE42278138}.SupplierEnd Indication that the system is currently operating in a contingency mode. contingencyActive {053E4E87-A262-4b01-85C2-561E03435F2B} dispatchMode {16F39C62-17F5-4ecb-9626-F74D211EDBD1} AggregateNode {917AB6A6-8808-4d28-B5EB-217844E5D8B1}.SupplierEnd InstructionClearing {B51C2A99-4E92-4961-A6C0-F5BB918A2A32}.SupplierEnd RegisteredResource {7B076588-700D-4bbc-80C9-CA48511DE042}.SupplierEnd bindingInstruction {92EF9110-493F-45e2-9DAD-96940A666F62} instruction source for market quality results INS ACT instructionSource {840886A3-DD5B-4c03-A1D3-044812FB88A9} Indicator of either a StartUp or a ShutDown. instructionType {44F83183-5D66-47d1-9ADC-5A120C320B6F} Manually Blocked Indicator YesNo. The instruction has been blocked by an Operator. manuallyBlocked {384324F4-53D6-4332-93F2-EBB059193AFF} updateType {56B266F3-BF55-4817-BF75-EF207B49D688} Unit multiplier of this quantity. multiplier {286F4EA7-EFD2-4fdc-B949-CA5DBE502F0A} Unit of this quantity. unit {FA3EBEDD-32A3-4c7e-AA72-8F6A20C0DE4A} RampRateCurve {1BDCCD9A-FE44-4136-9A38-58893BFCA0AA}.SupplierEnd RegisteredInterTie {E8B2FD01-4BC1-4e68-B739-26E746DDB71F}.SupplierEnd InterTieResults {CD0BFC1C-1DAF-4569-BDDF-9FD9518B3A7E}.SupplierEnd RegisteredInterTie {C1ECE446-41CB-4935-9DD9-BB8E3EA8F832}.ClientEnd The accept status submitted by the responder. Valid values are NONRESPONSE ACCEPT DECLINE PARTIAL. acceptStatus {E9B4D769-DED5-4bbd-8842-9907CFD756F8} Part of the Composite key that downstream app uses to match the instruction passIndicator {1D66B497-93F3-4b21-A024-44DA0D6F6F62} Flowgate {E8AB91AD-788A-4426-BCAB-5F8132B26BE5}.ClientEnd InterTieClearing {CD0BFC1C-1DAF-4569-BDDF-9FD9518B3A7E}.ClientEnd InterchangeSchedule {C18B28C7-505A-47a1-861A-9B8EC4C4FAA8}.ClientEnd InterTie {F470E1A6-33AE-4803-A2CA-A8627C7D6956}.SupplierEnd InterchangeETCData {C18B28C7-505A-47a1-861A-9B8EC4C4FAA8}.SupplierEnd RegisteredInterTie {EB89CB04-1946-4823-B7D2-6E517A703273}.SupplierEnd To indicate a check out type such as adjusted capacity or dispatch capacity. checkOutType {0DE58477-5040-4bfa-9EDB-F556A29E971C} Import or export. directionType {9CA5B0A9-5F61-465f-9507-78F104392696} Energy product type. energyType {3B444EC5-D5A8-466d-BECB-A8679D350E3C} Market type. marketType {5A41A1C6-CA1B-4a6d-81FF-87C5D3CC2AAD} Schedule type. scheduleType {2062604B-81D8-4b65-9021-C65259115BDE} RegisteredResource {6E8D1E08-8516-4936-BA3D-566DD94BE286}.ClientEnd CurrentEmergencySI {BEFB4486-B77B-4cd6-A9AD-9D7F2906C32F}.ClientEnd CurrentScheduledInterchange {25FE6285-FBFC-4387-9CFA-5A909EABEF8D}.ClientEnd Bushings to which the fixed contacts of this interrupter isare attached. Some interrupters have one fixed and one moving contact some have 2 fixed contacts some 2 moving contacts. An interrupter will have relationships with 2 bushings and those relationships may be any combination of the FixedContact and MovingContact associations. Bushings to which the moving contacts of this interrupter isare attached. Some interrupters have one fixed and one moving contact some have 2 fixed contacts some 2 moving contacts. An interrupter will have relationships with 2 bushings and those relationships may be any combination of the FixedContact and MovingContact associations. Bushing {04E4A3E7-BA8B-450c-A235-995CEAB16935}.SupplierEnd {C2A54CC4-02E6-4205-BF7A-A8BAE99CDBAA}.SupplierEnd Breaker mechanism controlling this interrupter. OperatingMechanism {DA02B460-9B93-4dff-AF33-7056DC71BA82}.ClientEnd Interrupting medium. interruptingMedium {203BEC08-AB3F-4e25-8BE4-6B14B92E7006} Interval reading contained in this block. IntervalReadings {0DE6A2FC-3A1D-4025-9791-0BDC1FE70873}.SupplierEnd Meter reading containing this interval block. MeterReading {15942C2F-68E7-46d2-88D4-0C74530EE8E5}.SupplierEnd Pending calculation to apply to interval reading values contained by this block after which the resulting reading type is different than the original because it reflects the conversion result. PendingCalculation {6805BD0C-43D7-4b31-81D9-807FDA537C71}.SupplierEnd Type information for interval reading values contained in this block. ReadingType {5E2DE546-E491-4480-879B-2607C691B257}.SupplierEnd All blocks containing this interval reading. IntervalBlocks {0DE6A2FC-3A1D-4025-9791-0BDC1FE70873}.ClientEnd The point data values that define a curve. TimePoints {73F6489D-7DA0-44ef-8CC9-D8AF413DAC53}.SupplierEnd An IrregularTimePoint belongs to an IrregularIntervalSchedule. IntervalSchedule {73F6489D-7DA0-44ef-8CC9-D8AF413DAC53}.ClientEnd The time is relative to the schedule starting time. time {7F344F9D-2DFC-4f89-9CA5-0AB59385A201} All documents for this issuer. Documents {D3F6B3FF-697C-4b9b-845F-66D92692128D}.SupplierEnd Configuration of joint. configurationKind {D84F2B73-EA32-4eaf-8105-5A5C411E3AB0} Material used to fill the joint. fillKind {75D4C599-4E0E-4ae6-8322-7F99A1D12C96} Action taken with this jumper. JumperAction {A665FDB4-D392-4791-8A37-99C6494742D4}.ClientEnd The line segment that this jumper action will affect. This is the only way to access relationship to clamp in case the jumper needs to connect along the line segment. ACLineSegments {9581D491-DFD1-477b-A1F8-56207CB6A28F}.SupplierEnd Clamp {74BBE709-CFEF-40a9-A120-33F704608576}.ClientEnd Conducting equipment is affected when the jumper action connects one or both ends of a jumper to the conducting equipment. If the jumper action involves placing one or both ends of a jumper anywhere along a line segment you must use the clamp to get the distance from one terminal using the explicit relation with clamp. In the case of placing one or both ends of the jumper at a line segment terminal reference to one or more line segments is sufficient. JumpedEquipments {4D35C940-C8A8-4a53-846A-929278E1DB57}.SupplierEnd Jumper on which this action is taken. Jumper {A665FDB4-D392-4791-8A37-99C6494742D4}.SupplierEnd Switching action to perform. kind {5C8EEC22-6AC5-4ca3-8117-FE471700B406} multiplier {633D88B5-13E1-4dd6-8CBF-61A5DE5E46FE} unit {7150BC2B-A31A-4c34-8BB8-C5FAEC099C84} Test lab which produced this set of lab test results. AssetTestLab {2E1C1072-F34D-447f-A661-8FC9A06E3F6D}.SupplierEnd Specimen on which lab testing done in determining results. Specimen {C2DD4DA1-4B26-4df0-8A58-EA8BE7DC80D4}.SupplierEnd Reason for performing test. reasonForTest {8FB67C6B-F023-4b3d-B021-843DE4BB093E} ErpPersons {A04894E3-14E3-4cfe-B0D3-57701085ACBE}.ClientEnd WorkCostDetail {955B011F-CCEE-4126-A607-513F05388ADE}.SupplierEnd WorkTask {FDB3A56B-46C4-4591-A0EA-AA7F58E3236A}.ClientEnd Total cost for labor. Note that this may not be able to be derived from labor rate and time charged. cost {3873F482-0558-4407-A2DF-271244BE21E9} Time required to perform work. laborDuration {CDC2AF11-6EE9-411c-8A3C-01413EFB0DFF} The labor rate applied for work. laborRate {D8E44A34-BF06-49cf-ADAF-6B45466D31C6} status {E6AEDA33-EC3C-4a08-B05F-54600691B920} Edition of Laborelec standard. standardEdition {F1099835-5A56-449d-B391-E45364A57BF2} Laborelec standard number. standardNumber {D18A07C1-E5F8-4d97-953E-4B0847C37367} AssetContainers {658256E1-9CC7-4618-861D-E2D5F2458763}.SupplierEnd ErpOrganisationRoles {125BFBC7-E66A-4486-A898-CE2D1087BB13}.SupplierEnd ErpPersonRoles {E882A219-E4D5-4259-AD38-2754C0D502A2}.SupplierEnd ErpSiteLevelDatas {86405B23-FBDA-4f53-A547-5BE7134DF39C}.SupplierEnd All location grants this land property has. LocationGrants {C759CAEB-F5C3-465e-97E7-310578A2EE42}.SupplierEnd The spatail description of a piece of property. Locations {ACFA3E19-34F0-4388-A1A3-CF9E27854574}.SupplierEnd All rights of way this land property has. RightOfWays {EB5019C4-5ACE-4ae3-BA94-0695131D9A29}.ClientEnd Demographics around the site. demographicKind {6CE69ADE-D00D-4c72-A88D-B83ACFE99914} Kind of land property categorised according to its main functional use from the utilitys perspective. kind {19EC9B8D-AEEA-4f46-BE1B-240FD53D9781} status {527490A6-7D55-44b3-8B46-A187C91F0209} multiplier {7E3DD904-59E9-4a23-8877-756089992413} unit {3D6E3075-6B8A-44df-9D89-B4713FE7BDAC} A reservoir may have a level versus volume relationship. Reservoir {1CA34C6F-D018-451a-B9BA-91A089FCA0F8}.SupplierEnd Likelihood that strike fell within errorEllipse. errorEllipseConfidence {612A2FC7-6BED-4589-9006-6F974398B2FF} Length of major semiaxis longest radius of the error ellipse. errorEllipseMajorSemiAxis {B21AA3B7-F1CE-4b83-BDA0-79AF0B9B9466} Length of minor semiaxis shortest radius of the error ellipse. errorEllipseMinorSemiAxis {B51075A5-F832-4ae4-A64F-D284B630B623} The orientation of the major semi axis in degrees from True North. errorEllipseOrientation {C59923E9-97B3-4034-9115-48EE9BF34DBC} Peak current of strike. peakAmplitude {CCD211E7-E954-44fa-80E2-37C50425C968} Procedures {B58288B5-634A-4da2-AF81-FC8EE0EB0F45}.ClientEnd The equipment for which this limit dependency model is organized under. Equipment {CEF63A20-BB9F-4d20-85B7-C4EF0AB5624F}.SupplierEnd The operational limits to which this limit dependency model applies. OperationalLimit {930C423F-F107-4857-A500-C7D5C97E88CB}.ClientEnd SourceOperationalLimit {312BBC54-9F5A-4000-8A02-754DB702EB90}.SupplierEnd The associated source limit is scaled by this value to compute the limit of the dependency model. limitScalingPercent {A5FE7CA4-6641-485d-A9C6-8E5BE591EA3B} The subgeographical region of the line. Region {BAB73169-D3BE-43c3-A58B-F1B87EAA1239}.ClientEnd Amount for this line item. amount {70BAF500-3C22-48cc-98F0-4ED38C0A4B3E} Totalised monetary value of all errors due to process rounding or truncating that is not reflected in amount. rounding {174ABABE-C74F-4683-BDC3-BF78EAFFC3B4} The line segment of this line fault. ACLineSegment {BBA661BB-92B7-4934-988B-DF65931690EE}.SupplierEnd The length to the place where the fault is located starting from terminal with sequence number 1 of the faulted line segment. lengthFromTerminal1 {39244DFF-5709-4fd8-AE0A-F5BA2C171329} Zero sequence shunt charging susceptance per section. b0PerSection {18D033B2-4A27-4254-8F20-5442D0E163E7} Positive sequence shunt charging susceptance per section. bPerSection {295441F9-63A5-4222-894E-F64C29A24C5E} Zero sequence shunt charging conductance per section. g0PerSection {2D5E2E4F-C07A-4000-BD54-C5FBF7B99D7A} Positive sequence shunt charging conductance per section. gPerSection {DAB7E864-95F0-4325-B595-3997057DD82F} Susceptance per section of the phase if shunt compensator is wye connected. Susceptance per section phase to phase if shunt compensator is delta connected. bPerSection {5E420ADA-58AC-48a1-BE11-10AC64D4F407} Conductance per section for this phase if shunt compensator is wye connected. Conductance per section phase to phase if shunt compensator is delta connected. gPerSection {5FE8AC9E-7752-476f-9F1E-FE43FAA0B288} Aggregate motor dynamic load associated with this aggregate load. LoadMotor {4492B845-85C0-4825-8D06-D03F4BBCDF4A}.ClientEnd Aggregate static load associated with this aggregate load. LoadStatic {4C437CDA-D82C-4512-ADA6-9B94A96DF087}.ClientEnd The SubLoadAreas in the LoadArea. SubLoadAreas {985B4F6F-A487-4691-9470-6EE3C9636DC8}.SupplierEnd AreaLoadBid {66BF4185-41CD-43e2-8659-871C1A781082}.ClientEnd LoadReductionPriceCurve {6CFF5725-EC18-4ea2-A12C-2D2ECE52DD51}.SupplierEnd RampRateCurve {AD8B5072-D22F-4473-AF99-5A6CD5C52809}.SupplierEnd RegisteredLoad {4D1C0118-19FE-4b30-B956-5BEF77F618EE}.ClientEnd Maximum rate that load can be reduced MWminute dropRampRate {F02D2AE9-01E5-4aaf-8514-2AFD109C8F16} load reduction initiation cost loadRedInitiationCost {DFF2667B-6568-4423-9DAF-6A1B088E5353} Minimum MW load below which it may not be reduced. minLoad {3BD81119-B627-46f3-9DD3-AEA9CFD0FAEC} Minimum MW for a load reduction e.g. MW rating of a discrete pump. minLoadReduction {9B453547-9F05-454c-B3BE-E076741D4999} Cost in at the minimum reduced load minLoadReductionCost {6895F631-C303-48ab-B972-323D15EE7B32} Maximum rate load may be restored MWminute pickUpRampRate {6D8F4BDB-469D-44d3-A900-74DB99BC8097} The fixed cost associated with committing a load reduction. shutdownCost {30A20BCC-4547-4ec1-BFE0-27CF0FE3D562} Inertia constant iHi gt 0. Typical value 25. h {51D2BF52-33B6-40d5-99E3-8BA27720D977} AggregatedPnode {1E748A16-16A1-4251-B7F2-5AB41F4B8AB1}.ClientEnd DistributionFactorSet {49BDACA6-0568-4346-BD7A-07BB3DE08C0C}.ClientEnd IndividualPnode {3F23D218-E902-4629-B47B-6E2F216E85DF}.ClientEnd Energy consumer to which this dynamics load model applies. EnergyConsumer {4F34241A-F054-4f5c-8638-560DED3C98B4}.SupplierEnd RegisteredResource {3C97A30C-33B1-4e87-8AAE-BC2568E2F4BD}.ClientEnd RegisteredResource {D80F6DFF-96C2-4687-ABA8-88B11C00DF6E}.SupplierEnd updateType {4319F9CF-E227-4ef7-BF28-34D73D33C75C} Type of generic nonlinear load model. genericNonLinearLoadModelType {0EC63AF7-FC07-4c14-A043-DBB66B7A86FA} Time constant of lag function of active power iTiisubPsubi gt 0. tp {63971A4F-C775-4c11-BD27-ECA0D8DA093E} Time constant of lag function of reactive power iTiisubQsubi gt 0. tq {9B0A9261-37AA-4035-BA52-310ABC78830C} The SubLoadArea where the Loadgroup belongs. SubLoadArea {6910F2B1-E481-496a-91B7-7AAA14F6D47E}.ClientEnd Aggregate load to which this aggregate motor dynamic load belongs. LoadAggregate {4492B845-85C0-4825-8D06-D03F4BBCDF4A}.SupplierEnd Inertia constant iHi gt 0. Typical value 04. h {F0FD1C52-0775-434a-9500-FB4301BC7E34} Transient reactance iLpi. Typical value 015. lp {CFCCAC01-5A98-46bd-8114-530A5D13C6B1} Subtransient reactance iLppi. Typical value 015. lpp {B75DCE7C-EE1B-4f60-909D-64CD5F999CFD} Synchronous reactance iLsi. Typical value 32. ls {A7D4FF09-5F6C-4cf3-8D09-A1ECC0B90A8B} Stator resistance iRai. Typical value 0. ra {2EBF719B-7221-43f6-89D0-2262283F223F} Circuit breaker operating time iTbkri gt 0. Typical value 008. tbkr {F3B08BB9-8193-4eb0-B62C-DFBB9AC72F0E} Transient rotor time constant iTpoi gt 0. Typical value 1. tpo {31ACC981-C4AC-45bd-8CA1-01B3F8B3B1BA} Subtransient rotor time constant iTppoi gt 0. Typical value 002. tppo {FFCCD719-96F8-4d29-88AE-7AC5107217C7} Voltage trip pickup time iTvi gt 0. Typical value 01. tv {8D2E6339-44AA-470f-9644-7978BEDD30BD} Voltage threshold for tripping iVti. Typical value 07. vt {8DB2CEC8-F4C3-486a-82BD-040623B3666F} SchedulingCoordinator {1F7B041F-E74A-417c-95DE-6C226FA9485B}.SupplierEnd Share in percentage of total Market load for the selected time interval. share {3EBCC71D-EDAE-430f-99F2-C938741EC06A} LoadBid {6CFF5725-EC18-4ea2-A12C-2D2ECE52DD51}.ClientEnd The set of loads that have the response characteristics. EnergyConsumer {ABB1EF4C-2A3F-4c47-8D73-B51ADA827E97}.ClientEnd Aggregate load to which this aggregate static load belongs. LoadAggregate {4C437CDA-D82C-4512-ADA6-9B94A96DF087}.SupplierEnd Type of static load model. Typical value constantZ. staticLoadModelType {F78BA2E0-BA77-4658-BF2D-6EE1BEA7A2F1} Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {42F5637B-59FE-4442-AC86-EC1605637C40}.ClientEnd RTO {E6D2764A-B166-47aa-85A1-8B82794864DB}.ClientEnd RegisteredGenerator {2AFCD919-E0B4-402b-9374-D1683A531031}.SupplierEnd All assets at this location. Assets {1547DDC4-B4CB-4406-B642-4E0337FC4594}.ClientEnd All configuration events created for this location. ConfigurationEvents {5A4A6C15-ADB0-446d-8CFE-0DE670D4800F}.SupplierEnd Coordinate system used to describe position points of this location. CoordinateSystem {D9DB79D8-27F1-4071-9C79-F0F1F62B4F18}.SupplierEnd Crew {5396B10B-F4AB-46c8-B558-A0D64090E603}.SupplierEnd Crews {9F98B054-8439-4bd9-8F2E-43422494EFE5}.ClientEnd Kind of environmental location which this location is. EnvironmentalLocationKind {153D33F0-C3EC-4cda-8188-6776F6BD789B}.ClientEnd Monitoring station located at this location. EnvironmentalMonitoringStation {17713B5C-F047-400e-ADE7-5B55F485CA85}.ClientEnd Fault {7F84E357-68DD-4257-BD11-EE226FADA1E6}.ClientEnd All asset hazards at this location. Hazards {A7C698DB-6096-423a-918E-5D26CD309E44}.ClientEnd Incident at this location. Incident {92317947-BF8F-4e74-A2A0-4C97EDA82DD0}.ClientEnd LandProperties {ACFA3E19-34F0-4388-A1A3-CF9E27854574}.ClientEnd Measurements {F582AAC6-446D-49be-9380-09E21CAA0CCF}.SupplierEnd OutageOrder {5D0E1B69-67C1-469c-B013-AE8901A8B015}.ClientEnd Sequence of position points describing this location expressed in coordinate system Location.CoordinateSystem. PositionPoints {DBF35456-ABE1-4deb-A885-2E48B3D6F8F6}.SupplierEnd All power system resources at this location. PowerSystemResources {9F4B30FA-0A66-4ce4-9A00-413B0DB058C7}.SupplierEnd Routes {BD8B4DA4-D676-478b-B855-5DB85DFFDB26}.ClientEnd SwitchingOrder {4909DE0B-FF1E-4cd5-8339-71D4430BBEF1}.SupplierEnd TroubleOrder {2BE0988C-AEEE-43e6-9FB2-B3C811465CE1}.ClientEnd Electronic address. electronicAddress {27DF32EF-8F8F-437d-8C52-A9AEF3D04CE9} Main address of the location. mainAddress {44CF2281-A210-4c5a-A26A-D802302AA58D} Phone number. phone1 {35C3E445-F094-4720-8C8E-FC83D922CD89} Additional phone number. phone2 {B2B17DA4-F097-4a16-B416-353F451C0A78} Secondary address of the location. For example PO Box address may have different ZIP code than that in the mainAddress. secondaryAddress {A1C7D128-217A-4d61-90BF-7ACFB4216F92} Status of this location. status {716A4DAA-ED9F-42f4-8AD2-C1B6DBB88896} Land property this location grant applies to. LandProperty {C759CAEB-F5C3-465e-97E7-310578A2EE42}.ClientEnd LossClearingResults {9EC3534E-B7AC-4cc1-B1A2-D7CAD11E98DD}.SupplierEnd HostControlArea {AD728487-11BF-4cf9-8208-EB973AA30251}.ClientEnd LossClearing {9EC3534E-B7AC-4cc1-B1A2-D7CAD11E98DD}.ClientEnd RUCZone {28810405-AFDC-42b6-889E-E5634F47D761}.ClientEnd SubControlArea {609C0491-3062-444d-9F49-61791CBD647B}.SupplierEnd An EnergyTransaction may have a LossProfile. EnergyTransaction {0E272DF7-73BF-495c-AEAE-1F184C3A0031}.SupplierEnd Part of the LossProfile for an EnergyTransaction may be a loss for a TransmissionProvider. If so the TransmissionProvider must be one of the participating entities in the EnergyTransaction. HasLoss_ {A0E07F75-BF34-4a53-91DA-8AC7F9199E13}.SupplierEnd MktConnectivityNode {BAB096FD-2D2E-4088-887E-124132BB99A0}.SupplierEnd LMPMFinalFlag {12C50657-2A30-4f30-91A7-F81207258D35} MPMTestResults {8F96A178-A65F-4a2f-9906-0E01C5028264}.SupplierEnd SMPMFinalFlag {C34F8682-0D24-49a2-B6B4-115AC644A903} mitigationOccuredFlag {F4B0EB6A-3B29-4e91-8A3C-6B2FE008D142} MPMTestCategory {F2AACF8A-1162-4769-8B44-79E4491F3254}.ClientEnd MitigatedBidClearing {E48948D6-38C5-4c7b-8933-F5947320697F}.ClientEnd RegisteredResource {606C8F33-4FFF-4ea5-A5B5-CEB460B07A57}.ClientEnd MPMResourceStatus {F2AACF8A-1162-4769-8B44-79E4491F3254}.SupplierEnd MPMTestResults {BE5BB481-4AB2-4a4b-8C64-B3875DA5546C}.SupplierEnd MPMTestThreshold {5D041FF2-6CFE-4b89-B8AC-DF1E41386754}.SupplierEnd Nature of threshold dataM Mitigation thresholdR Reporting threshold purposeFlag {AD384B1A-B6ED-4880-9AE2-B3217FBD9A64} 1 Global Price Test2 Global Conduct Test3 Global Impact Test4 Local Price Test5 Local Conduct Test6 Local Impact Test testIdentifier {EFE3B0F6-6342-4694-A875-850D9384E4C0} The method of performing the market power monitoring. Examples are Normal default thresholds or Alternate thresholds. testMethod {02EFC8E3-3783-4f65-834F-863DB41EBDD5} AggregatedPnode {C0382101-491D-471a-B6BD-412F2E2BEFE1}.ClientEnd MPMClearing {8F96A178-A65F-4a2f-9906-0E01C5028264}.ClientEnd MPMTestCategory {BE5BB481-4AB2-4a4b-8C64-B3875DA5546C}.ClientEnd Used to show the Margin result of the Impact test marginPercent {CB16FFD1-D63F-4ccc-85CB-A24610675CDE} The results of the test. For the Price Impact and Conduct tests typical values are NA Pass Fail Disable or Skip. outcome {9B184A03-B407-4be3-A732-7A3FEBAFB186} AggregatedPnode {3A9890C7-0792-48c5-BE74-53A2FA81C59A}.SupplierEnd MPMTestCategory {5D041FF2-6CFE-4b89-B8AC-DF1E41386754}.ClientEnd RegisteredResource {BEDAF373-FFF3-488c-94D4-242E91A60CFB}.SupplierEnd Market Type DAM RTM marketType {DB981E2A-6A80-485c-A814-D14A1B513C40} Price Threshold in percent {0750D9AA-DBCC-4749-ABE7-1D613A27DF3B} Price Threshold in MW price {A6610301-EBD1-40c1-8FAF-82505741C767} MeteredSubSystem {A5BC78A9-02B6-4693-833B-5988046C9A07}.SupplierEnd RTO {42061DAA-FC2A-4510-A0B6-81F8DDD07587}.SupplierEnd Charge for Emission Costs Start Up Costs or Minimum Load Costs. costRecovery {9A176D4F-6DFB-416f-97B3-80B920630ECC} MSS Load Following may select Net vs. Gross settlement. Net Settlement requires the net Demand settled at the MSS LAP and Net Supply needs to settle at the equivalent to the weighted average price of the MSS generation. Gross load will be settled at the System LAP and the Gross supply will be settled at the LMP. MSS Aggregation that elects gross settlement shall have to identify if its resources are Load Following or not. grossSettlement {8D3502CE-C109-4679-A24D-EEF5A8C262C2} Provides an indication if losses are to be ignored for this zone. Also refered to as Exclude Marginal Losses. ignoreLosses {DB2547D7-7FA4-485d-B341-F560E31635E0} Provides an indication if marginal losses are to be ignored for this zone. ignoreMarginalLosses {E4B1E2B6-C61C-4233-82B4-19C63EE950D3} Indication that this particular MSSA participates in the Load Following function. loadFollowing {C5E15E5D-E3DC-4f5b-BAE9-9195BDEF79A0} Indicates that RUC will be procured by the ISO or self provided. rucProcurement {5BDF1B45-574F-4bfd-ABF8-C870D2C7DE2A} MeteredSubSystem {92A84479-AD05-4df5-BE48-E000CB70D4B3}.ClientEnd Provides an indication if losses are to be ignored for this metered subsystem zone. ignoreLosses {6DC4E554-BE3F-4d2d-8336-B1E48773AC3B} Metered SubSystem MSS Load Following may select Net vs. Gross settlement. Net Settlement requires the net Demand settled at the Metered SubSustem MSS Load Aggregation Point LAP and Net Supply needs to settle at the equivalent to the weighted average price of the MSS generation. Gross load will be settled at the System LAP and the Gross supply will be settled at the LMP. MSS Aggregation that elects gross settlement shall have to identify if its resources are Load Following or not. rucGrossSettlement {CC1E3B2B-0887-4b24-B5EC-A75900C98C3A} SecurityConstraintLimit {B2755079-F601-4879-9341-AAF0FDCD8B1B}.ClientEnd multiplier {0E5F2BFD-8703-49fc-B826-41CE003DBC98} unit {5C9C7A55-729A-4981-8F1D-AD83C2E569B2} Change in the disturbance storm time Dst index. The size of a geomagnetic storm is classified as moderate 50 nT gtminimum of Dst gt 100 nT intense 100 nT gt minimum Dst gt 250 nT or superstorm minimum of Dst lt 250 nT. changeDst {38E67047-21E7-4d3b-9B27-BC2E8D3E02BC} Kind of breaker maintenance performed by this maintenance work task. breakerMaintenanceKind {DE40F27B-05CC-40c6-85DF-50C0C31BF814} Kind of transformer maintenance performed by this maintenance work task. transformerMaintenanceKind {8189DD2E-E93E-43c1-A39E-22D4FE9E3759} A MajorChargeGroup can have 0n ChargeType. A ChargeType can associate to 0n MajorChargeGroup. ChargeType {90202EBC-584B-4461-94E0-1F697B9901DA}.SupplierEnd MarketInvoice {BE562C52-127A-4564-95DF-779C969CA8C0}.ClientEnd MktScheduledEvent {890B707F-43E2-4bb0-BE45-1359D597DA95}.SupplierEnd Settlement {66C30E2D-CB35-48aa-A9C2-A0E325DA6FD5}.SupplierEnd All asset models by this manufacturer. ProductAssetModels {4B21049D-BA80-4bd7-A107-BD54730986AA}.ClientEnd MarketFactors {DC280149-D350-4b9a-9EB9-28F20E183E1D}.ClientEnd MarketProducts {8A7E15E4-F0D3-453a-9ECB-CC6F62725DA9}.ClientEnd MarketRun {622410B9-A129-42a5-B23C-DD8F7914108C}.ClientEnd Market run triggered by this actual event. For example the DA market run is triggered by the actual open bid submission event and terminated by the actual execution and completion of the DA market run captured by the runState of the MarketRun. MarketRun {930F69B6-9BC4-4791-8097-015E9B6F277C}.SupplierEnd Planned event executed by this actual event. PlannedMarketEvent {6F2C5CBA-31FA-4fbf-93FC-0732720881FC}.SupplierEnd Event status e.g. active canceled expired etc. eventStatus {3D1A1CBE-18BB-4913-8A8C-7491E7340418} MarketProductClearing {193E6A14-52CA-4269-A05F-CC3FCD23A162}.ClientEnd AceTariffType {17256E85-4394-4e3a-95AC-8ECE9214CA71}.ClientEnd AttributeInstanceComponent {56078672-F984-4496-A0EE-E53993207A8C}.SupplierEnd DateAndOrTime {F49F44BE-047D-4792-8B5B-A3AA670AA0A1}.ClientEnd Domain {65A175B6-9924-45f6-8876-8254B2486786}.SupplierEnd MarketDocument {6E6D96F5-F1A5-4401-9DDB-9AA7004318AC}.ClientEnd MarketParticipant {15329A77-AC86-4d04-9E5A-63C6BAA901A8}.ClientEnd Period {07DDBEDE-D21C-439d-AAF4-F347D1B02B1E}.SupplierEnd Process {02A672D8-0CED-4250-99DC-0E425C62E548}.ClientEnd Reason {B1D45B36-F3A6-4f96-A2D1-0E8AD7CFBBF6}.ClientEnd SelfMarketDocument {6E6D96F5-F1A5-4401-9DDB-9AA7004318AC}.SupplierEnd TimeSeries {8685CC5C-5A4F-4b05-AC0B-AE70B37260A5}.ClientEnd TimeSeries {D819A727-1DB3-424c-9D73-1E1D3668972A}.ClientEnd Market {DC280149-D350-4b9a-9EB9-28F20E183E1D}.SupplierEnd MktActivityRecord {3B634A0B-A62D-4bc1-906D-A2B67BA6B989}.SupplierEnd MajorChargeGroup {BE562C52-127A-4564-95DF-779C969CA8C0}.SupplierEnd MarketInvoiceLineItems {2EDD1DEF-974C-4208-BC3A-F7F232F27A8F}.ClientEnd Total amount due on this invoice based on line items and applicable adjustments. amount {99DA6952-B9CB-41b8-B784-71C34EDD61D3} Kind of media by which the CustomerBillingInfo was delivered. billMediaKind {46E55177-239C-4c51-B01D-E87ECE8D107D} Kind of invoice default is sales. kind {05167FF5-1A6F-4a9f-9E90-E0EDD5DB4275} ComponentMarketInvoiceLineItems {AF978BE6-BF2F-453f-B08B-F421B78F3243}.ClientEnd ContainerMarketInvoiceLineItem {AF978BE6-BF2F-453f-B08B-F421B78F3243}.SupplierEnd MarketInvoice {2EDD1DEF-974C-4208-BC3A-F7F232F27A8F}.SupplierEnd Settlement {C0177491-5DB7-458c-8967-3D68B4E446EA}.SupplierEnd Bill period for the line item. billPeriod {175EE50A-E411-479d-8D1E-4D9DA9C05A0A} Kind of line item. kind {A1EAFC5B-AAA3-4196-B064-C04CC86BB340} MarketLedgerEntries {FAE450BD-F214-4f34-BF8C-489DA9D4DC4D}.SupplierEnd MarketLedger {FAE450BD-F214-4f34-BF8C-489DA9D4DC4D}.ClientEnd Settlement {DE87169A-1AAE-49ed-BD84-5D34B06D5FC7}.SupplierEnd Kind of account for this entry. accountKind {016366EB-4F3E-47f9-9F2C-24F421349F52} The amount of the debit or credit for this account. amount {FB60A19F-D7A2-47f7-872A-2C93035A44AB} Status of ledger entry. status {BB1F100D-4CC3-4b1c-889C-4DAD6FF96E08} RegisteredResource {E489A51C-813C-4dd4-B929-320AFC501DEA}.SupplierEnd TimeSeries {DFA9145B-F296-4711-93A0-08DAEC6641D6}.SupplierEnd Bid {4483FC15-4087-4afd-8766-1D708647568D}.ClientEnd MarketDocument {15329A77-AC86-4d04-9E5A-63C6BAA901A8}.SupplierEnd MarketPerson {DB33BF98-91AD-4809-B83F-315F5A277246}.SupplierEnd MarketRole {24379B20-BB0D-49b6-B4BD-3ECE8DE8C8B5}.ClientEnd RegisteredResource {7EC28792-B0B8-4baa-9CE0-B5896FAAB9BA}.ClientEnd SchedulingCoordinator {B7A4F593-994A-4de3-804C-823ABC09CB5B}.ClientEnd TimeSeries {1ACE2F82-31E4-482b-B2EF-A568B3991A86}.ClientEnd MarketParticipant {DB33BF98-91AD-4809-B83F-315F5A277246}.ClientEnd MarketSkills {79C287DE-B210-4dca-BF3B-74038B8B585E}.SupplierEnd Alternate Electronic address. electronicAddressAlternate {2F95FC92-1F17-4a4f-A828-84B683869325} Primary Electronic address. electronicAddressPrimary {3D19FB72-8B61-4b47-B44F-7A715A83EA88} Landline phone number. landlinePhone {A5FCC193-5CD7-4cf8-9C5B-7AAD808AF5A4} Mobile phone number. mobilePhone {9DAA0C00-8AB6-4239-9DAC-5DC8AAEDDDE9} status {160B9787-B5FD-4a17-99FA-828717A6D7BE} A market plan has a number of markets DA HA RT. PlannedMarket {9939F0DA-F147-4cab-A25A-C40C674AF836}.SupplierEnd BidError {9E7BFD17-29EA-44f9-8314-8B82238242CC}.SupplierEnd BidPriceCap {82238162-E851-4fa8-8103-3D73229CE310}.SupplierEnd CommodityDefinition {2CE15336-9D65-42db-A3CA-4D3E955778DF}.ClientEnd Market {8A7E15E4-F0D3-453a-9ECB-CC6F62725DA9}.SupplierEnd MarketRegionResults {473EB75C-4F19-4d7e-8585-2A0AE52F3F22}.SupplierEnd ProductBids {E7348A42-CD3B-49ba-B555-9BE41638E702}.SupplierEnd Market product associated with reserve requirement must be a reserve or regulation product. ReserveReqs {B135E6CF-CF03-4e34-8A2A-CAB47CB13C0C}.ClientEnd ResourceAwardInstruction {DCAE610D-01F2-4d9d-84E5-FC64B8C205A5}.SupplierEnd Market product type examplesEN EnergyRU Regulation UpRD Regulation DnSR Spinning ReserveNR NonSpinning ReserveRC RUC marketProductType {E612BB3D-5CE6-4f3c-9BD3-914F8447DD06} MarketSkills {7B119A79-FBC3-4255-8D6C-04F192205945}.ClientEnd ExPostMarketRegionResults {801B61F8-BE1E-447c-ACAC-D47A715E668A}.ClientEnd MarketRegionResults {08BD1B28-8AA8-4bc1-859C-C7296DDF32CF}.SupplierEnd ReserveDemandCurve {C2EA5FDF-AB5A-4353-86E1-3AC96CCCA3CC}.SupplierEnd AncillaryServiceClearing {F1B3EB5C-675E-4790-95CC-79C38272C39C}.ClientEnd MarketProduct {473EB75C-4F19-4d7e-8585-2A0AE52F3F22}.ClientEnd MarketRegion {08BD1B28-8AA8-4bc1-859C-C7296DDF32CF}.ClientEnd Locational AS Flags indicating whether the Upper or Lower Bound limit of the AS regional procurment is binding limitFlag {7B959257-3ED0-42b4-8F4F-35DF3356AD5F} The Lumpy FlagYN indicates whether the resource that sets the price is a lumpy generator by hour over the time horizon.Only applicable for the Day Ahead Market lumpyIndicator {4C2E7A9A-AF6D-4f74-BF17-C5BC9DC2EB90} EnergyMarket {1BCDE256-7739-44fd-A327-E54563BBB888}.ClientEnd Global Contingent Operating Reserve Availability Indicator YesNo contingentOperatingResAvail {887AE29E-13A3-4159-A15F-3F50E55B7742} MarketParticipant {24379B20-BB0D-49b6-B4BD-3ECE8DE8C8B5}.SupplierEnd Market {622410B9-A129-42a5-B23C-DD8F7914108C}.SupplierEnd All actual events that trigger this market run. MarketActualEvent {930F69B6-9BC4-4791-8097-015E9B6F277C}.ClientEnd A planned market could have multiple market runs for the reason that a planned market could have a rerun. PlannedMarket {E537509E-3F2D-41ba-881E-85BABB782FC0}.ClientEnd The execution type Day Ahead Intra Day Real Time PreDispatch Real Time Dispatch executionType {3E3E16C8-55F7-460f-A830-E11D697AFED4} The market type Day Ahead Market or Real Time Market. marketType {04726F39-C49C-487c-9D25-12FCC83BB8FD} MajorChargeGroup {890B707F-43E2-4bb0-BE45-1359D597DA95}.ClientEnd Duration of the scheduled event for example the time to ramp between values. duration {4559B6DA-2560-4c14-92EE-29BD1AE23788} status {996FB657-A475-4c2e-A80C-7562396B1AE0} MarketPerson {79C287DE-B210-4dca-BF3B-74038B8B585E}.ClientEnd MarketQualificationRequirements {7B119A79-FBC3-4255-8D6C-04F192205945}.SupplierEnd Interval between the certification and its expiry. certificationPeriod {9C2E6F5E-18DD-4b73-822E-099F7BDE1744} MarketStatementLineItem {E7BE2BCE-CD84-4967-861E-5AFCA116CB56}.ClientEnd ComponentMarketStatementLineItem {00ADC084-731A-4011-BD96-3B38CDF055F7}.ClientEnd ContainerMarketStatementLineItem {00ADC084-731A-4011-BD96-3B38CDF055F7}.SupplierEnd MarketStatement {E7BE2BCE-CD84-4967-861E-5AFCA116CB56}.SupplierEnd MktUserAttribute {EA6E81CB-9BBB-4a78-A1D6-B66BC9D9B2B7}.SupplierEnd PassThroughBill {C9289981-55CD-40d3-9FB2-9C66EC3AEB17}.ClientEnd A Marketer holds title to an EnergyProduct. HoldsTitleTo_EnergyProducts {45B2E11F-1F87-46d0-BEDA-714E73AB2B7B}.ClientEnd A Marketer may resell an EnergyProduct. Resells_EnergyProduct {FFB388F3-6858-48ca-82BF-9BB8CF25DE4B}.ClientEnd multiplier {D40AF86B-C0F4-411f-91D2-A75099897751} unit {6CF35055-FDC7-44dc-B75D-BD9B6175FE11} TypeMaterial {1D24C169-2407-4dc7-9946-2E7695DD3662}.ClientEnd WorkTask {BFEEB8FC-4560-4027-829D-304562ADB795}.ClientEnd Quantity of material used. quantity {6CC6AB98-8734-4afc-9C5B-3C7C4B3DC2A4} Asset {016DD996-A1EA-4bb6-8349-AF38EEDFF7AD}.ClientEnd Calculation method hierarchy which applies to this analog. CalculationMethodHierarchy {F91A2D8A-DA8C-4273-9073-224DE84F0F21}.SupplierEnd Locations {F582AAC6-446D-49be-9380-09E21CAA0CCF}.ClientEnd MeasurementAction {0566ECD1-879E-43fc-AFB0-A8B79BFC4DEE}.ClientEnd MeasurementCalculatorInput {05661ED0-AD2E-4ee0-A3E5-9A25623C86D6}.ClientEnd PinMeasurement {D94A460B-0ABB-4872-900D-CDEEB9374DB3}.ClientEnd The power system resource that contains the measurement. PowerSystemResource {78186A65-461E-4479-9917-94B5C4F2F9F6}.ClientEnd Measurements are specified in types of documents such as procedures. Procedures {FEA58AE6-6428-4541-9097-FEFB35D64AD7}.ClientEnd ProtectiveActionAdjustment {9685ABB8-FD59-47dc-891C-CFC7E0CC0A6F}.SupplierEnd One or more measurements may be associated with a terminal in the network. Terminal {9C2962C4-F1BE-4c1a-9577-DB6E59B8FB49}.SupplierEnd Indicates to which phases the measurement applies and avoids the need to use measurementType to also encode phase information which would explode the types. The phase information in Measurement along with measurementType and phases uniquely defines a Measurement for a device based on normal network phase. Their meaning will not change when the computed energizing phasing is changed due to jumpers or other reasons.If the attribute is missing three phases ABC shall be assumed. phases {752AF06E-692D-4889-820C-2CBDA746E822} The unit multiplier of the measured quantity. unitMultiplier {E6B15F9B-D6F8-412c-B662-FC9D1902C7ED} The unit of measure of the measured quantity. unitSymbol {257F4465-5F67-4dca-91CB-2D2F6F040283} Measurement {0566ECD1-879E-43fc-AFB0-A8B79BFC4DEE}.SupplierEnd Used in the calculation. MeasurementCalculatorInput {F24A2F91-9867-44ee-A6E6-31185DC84FC5}.ClientEnd PinMeasurement {CFBABACD-D1FC-46de-8BA7-DA6F2F4B3CC9}.SupplierEnd Calculation operation executed on the operants. kind {8EC69B84-0006-4d3b-B402-721E72411644} Measurement used as input to a calculation. Measurement {05661ED0-AD2E-4ee0-A3E5-9A25623C86D6}.SupplierEnd MeasurementCalculator {F24A2F91-9867-44ee-A6E6-31185DC84FC5}.SupplierEnd CalculationMethodHierarchy {54A8E767-B481-4e4a-947E-047AC60B5490}.ClientEnd ErpPerson {E047391D-9AD5-4022-964F-3C6152531AE3}.ClientEnd A MeasurementValue has a MeasurementValueQuality associated with it. MeasurementValueQuality {BF14C261-4E21-4d59-89B0-1CAC365A66A1}.ClientEnd A reference to the type of source that updates the MeasurementValue e.g. SCADA CCLink manual etc. User conventions for the names of sources are contained in the introduction to IEC 61970301. MeasurementValueSource {A71FD16F-0766-4c32-AFBC-626DE7028412}.ClientEnd ProcedureDataSet {A0C93754-F2B4-4597-96C0-BDCA60E5BC09}.ClientEnd Link to the physical telemetered point associated with this measurement. RemoteSource {A7C88F72-6063-4225-8BCA-A830CE33CAC0}.SupplierEnd The limit expressed as a percentage of the sensor maximum that errors will not exceed when the sensor is used under reference conditions. sensorAccuracy {6473AC26-9C48-4a1c-9FE5-BA7CE555F4DD} A MeasurementValue has a MeasurementValueQuality associated with it. MeasurementValue {BF14C261-4E21-4d59-89B0-1CAC365A66A1}.SupplierEnd The MeasurementValues updated by the source. MeasurementValues {A71FD16F-0766-4c32-AFBC-626DE7028412}.SupplierEnd Asynchronous machine model with which this mechanical load model is associated. MechanicalLoadDynamics shall have either an association to SynchronousMachineDynamics or to AsynchronousMachineDynamics. AsynchronousMachineDynamics {2E5B6ACA-CE14-4ff7-A95C-1961DD872622}.SupplierEnd Synchronous machine model with which this mechanical load model is associated. MechanicalLoadDynamics shall have either an association to SynchronousMachineDynamics or AsynchronousMachineDyanmics. SynchronousMachineDynamics {2298CEEA-3BC8-4a46-9C31-9B6C0CDB1324}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {16E261AB-0A61-4015-A4AF-C0D1E3AADE99}.ClientEnd Medium with which this asset is filled. Asset {C899B2C5-BB4D-4ce8-A659-85956A304887}.SupplierEnd Specification {E64B800B-A4D4-4190-B7C3-AC53BAA0C1DD}.ClientEnd Kind of this medium. kind {2E93E180-7FA6-4cc1-9D7C-A8A0671D04BF} The volume of the medium specified for this application. Note that the actual volume is a type of measurement associated witht the asset. volumeSpec {C5525725-B4B4-40f5-8001-F5941F5C58D4} Merchant agreement that instantiated this merchant account. MerchantAgreement {6385AC88-456C-4b10-A868-F0F70A08912C}.ClientEnd All transactors this merchant account is registered with. Transactors {4E9EC9E2-B298-41e8-9F52-493E9BBBDAC4}.SupplierEnd All vendor shifts that operate on this merchant account. VendorShifts {28C890D5-DD6C-419b-AC03-0323BBD41D10}.SupplierEnd The current operating balance of this account. currentBalance {7BA81B69-B5F3-493d-A61B-5EB3355C674B} The balance of this account after taking into account any pending debits from VendorShift.merchantDebitAmount and pending credits from BankStatement.merchantCreditAmount or credits see also BankStatement attributes and VendorShift attributes. provisionalBalance {5ACC1A8F-DC23-4e45-98FE-2348EE41DA53} All merchant accounts instantiated as a result of this merchant agreement. MerchantAccounts {6385AC88-456C-4b10-A868-F0F70A08912C}.SupplierEnd All multipliers applied at this meter. MeterMultipliers {7310B281-4A19-4049-8E9E-774367FEA689}.SupplierEnd All meter readings provided by this meter. MeterReadings {AFE4FF06-8B2A-466e-8CA5-C0C940A18F23}.SupplierEnd All work tasks on replacement of this old meter. MeterReplacementWorkTasks {1617E573-158B-4042-8A7B-4A88A56E774C}.ClientEnd All nonreplacement work tasks on this meter. MeterServiceWorkTask {B91474A2-AF62-4326-B24C-CA6F2959ABD1}.ClientEnd All vending transactions on this meter. VendingTransactions {95682AE1-DDB3-4fa2-AC18-655296065A72}.ClientEnd Meter applying this multiplier. Meter {7310B281-4A19-4049-8E9E-774367FEA689}.ClientEnd Kind of multiplier. kind {3952B5E5-304C-4a15-8267-F2C328C765D7} could be deprecated in the future Customer agreement for this meter reading. CustomerAgreement {A14F100A-AE6C-49c4-AD0C-FC8D5004074A}.SupplierEnd All end device events associated with this set of measured values. EndDeviceEvents {DF4C0081-227B-4d2d-A692-33F732385A32}.SupplierEnd All interval blocks contained in this meter reading. IntervalBlocks {15942C2F-68E7-46d2-88D4-0C74530EE8E5}.ClientEnd Meter providing this reading. Meter {AFE4FF06-8B2A-466e-8CA5-C0C940A18F23}.ClientEnd All reading values contained within this meter reading. Readings {50ABD845-4A69-4a91-A0FE-99656D135A6F}.ClientEnd Usage point from which this meter reading set of values has been obtained. UsagePoint {EB5C430A-F69D-402a-9806-69357BFC879C}.SupplierEnd Date and time interval of the data items contained within this meter reading. valuesInterval {9146DBC3-DC7A-4ec3-AFF9-F20F5635E8D8} Meter on which this nonreplacement work task is performed. Meter {B91474A2-AF62-4326-B24C-CA6F2959ABD1}.SupplierEnd Old meter replaced by this work task. OldMeter {1617E573-158B-4042-8A7B-4A88A56E774C}.SupplierEnd Usage point to which this meter service work task applies. UsagePoint {30B864E4-AFB6-47b2-BF72-C36AA03A3F68}.SupplierEnd MSSAggregation {A5BC78A9-02B6-4693-833B-5988046C9A07}.ClientEnd MSSZone {92A84479-AD05-4df5-BE48-E000CB70D4B3}.SupplierEnd All reading types required to be collected by this metrology requirement. ReadingTypes {B5CE221C-AAE6-4ae6-A720-B4E199752DF9}.SupplierEnd All usage points having this metrology requirement. UsagePoints {28F71A07-2CD9-466b-BB76-3CAC30AEEC8F}.SupplierEnd Reason for this metrology requirement being specified. reason {DBB69BD4-7DF4-4382-BCBE-77DCC2FEAF19} multiplier {1ACF207C-AF79-4e5e-B536-DF1C7EDFB417} unit {45CF91A2-F79F-4606-B73D-F3E2D818F46E} DesignLocation {ECAD85F3-E7E4-48d0-B3DF-81B8B5795C03}.ClientEnd WorkCostDetail {D3D92A8C-C7B5-4a95-B1BF-113EA20D2A57}.SupplierEnd WorkTask {AB707969-391C-4b7b-9824-9E98B7029488}.ClientEnd The cost per unit for this misc. item. costPerUnit {35E1E964-0BDA-4d41-9100-16B05FC51411} The quantity of the misc. item being assigned to this location. quantity {E34551CA-BF53-4af9-B734-83F525452144} status {034A2A27-DC0C-4cea-BB44-7316C8AF712D} Bid {41CDA34B-D1DA-4d10-BD9C-9ACD84F95C4F}.SupplierEnd MitigatedBidClearing {CC434B38-6DC2-46e9-A8FF-4CC3583B4114}.SupplierEnd MPMResourceStatus {E48948D6-38C5-4c7b-8933-F5947320697F}.SupplierEnd MitigatedBid {CC434B38-6DC2-46e9-A8FF-4CC3583B4114}.ClientEnd RMRDetermination {5A2FDC45-69C0-48d6-B301-3B257BF71F43}.ClientEnd Bid {BB5D09A6-5901-41e0-9C70-FEA07F4C897A}.ClientEnd EndAFlow {C683E41C-A3EC-4316-BD46-D25F17ED532B}.ClientEnd EndBFlow {977B9C6C-1464-4035-A670-FC92869C7E0B}.ClientEnd MarketFactors {3B634A0B-A62D-4bc1-906D-A2B67BA6B989}.ClientEnd The type of limit the value representsBranch Limit TypesShort TermMedium TermLong TermVoltage LimitsHighLow limitType {9EA49FA7-07EC-4189-A4DD-9BA4C569D8CE} AggregatedPnode {667EE2EC-BAF5-4e35-9AEA-070E69E9AACF}.SupplierEnd CombinedCycleLogicalConfiguration {E85573FF-D877-4da8-AD0E-F1D7EBBB5773}.ClientEnd CnodeDistributionFactor {2E462F8F-23E2-41eb-8C60-ECC38D2C21A2}.ClientEnd IndividualPnode {2B0FBC3E-406E-4d8b-A02A-36C41F9A1D0E}.ClientEnd LossPenaltyFactor {BAB096FD-2D2E-4088-887E-124132BB99A0}.ClientEnd NodeConstraintTerm {E32D476E-22A4-4002-A185-3CB6C77E4005}.ClientEnd RTO {E1B1E7AA-80C6-41cb-8B19-3F793E0E7B53}.ClientEnd RegisteredResource {102246E9-40F9-404f-A841-A49127DDD797}.ClientEnd SysLoadDistribuFactor {C9774777-9F95-427f-B6A2-3AD33980CE68}.ClientEnd ConstraintResults {01D4A0B2-81CC-4497-A052-25EA792CEC6E}.ClientEnd ContingencyConstraintLimit {0906BEF7-3804-4598-9F39-8339F2B0B443}.ClientEnd TransferInterfaceSolutionA {C3F0F2CA-4331-417e-BB6F-AC8830FC9ABF}.ClientEnd TransferInterfaceSolutionB {A997CE1E-D37D-451f-AAE5-0DEBC8D07E52}.ClientEnd ControlAreaSolutionData {72466897-1E7B-4232-8415-B1CF11A7D241}.ClientEnd GeneratingUnitDynamicValues {068663E7-88C7-413e-9ACC-BB0E7776514E}.ClientEnd RegisteredGenerator {1BFB226F-6654-4314-8030-31CF5E037B03}.ClientEnd ResourceVerifiableCosts {19E8F4BC-BA0C-4a8b-8AFC-83E8D5EE0E8D}.ClientEnd Flowgate {8B57B818-A6B3-4836-BC0E-617E9ABEB67D}.ClientEnd TransmissionRightOfWay {30BB45B0-2DB4-4d68-BC65-DFE2DF74D8D1}.SupplierEnd A measurement is made on the B side of a tie point ByTiePoint {405D53E3-14AD-4d07-9D1F-3F3285139237}.ClientEnd DynamicSchedule {10B4C6E2-CE00-43d6-91C5-CA7BF16D48A2}.ClientEnd A measurement is made on the A side of a tie point ForTiePoint {BE3DB3DE-E7FF-4f27-8DC0-5606F98986E5}.ClientEnd Allows Pnode an association to aggregated resources external DC ties or psuedo tie measurements. Pnode {72AD4107-7210-4172-B722-F58EA3179E3E}.ClientEnd ViolationLimit {7B62C3C6-7398-40f5-BDE5-CBD6C32FC0EF}.ClientEnd TimeSeries {CBE02ED5-1004-4fe7-8827-53E8B4BDDE03}.SupplierEnd EndAFlow {6B82670E-C342-4f85-A215-9BB510562254}.ClientEnd EndBFlow {D9B28EF9-4971-4bb7-B90B-5D0EF7D92756}.ClientEnd Flowgate {E865ED1B-5944-445e-BD28-D928C5FF6389}.ClientEnd EndAFlow {5C0AAF99-2DB3-4ce7-8154-9C37E518CB30}.ClientEnd EndBFlow {A6C6B3F9-7B48-423b-99F5-774083959E01}.ClientEnd ShuntCompensatorDynamicData {4C898DD2-7D9D-4138-A8D0-B271310AE638}.ClientEnd SwitchStatus {F865D7AC-3978-4a82-A41D-4131DB7D21B2}.ClientEnd TapChangerDynamicData {FD943330-575B-40e5-BD88-67AED345044F}.ClientEnd Flowgate {E72576E6-C983-42fd-AED5-7EBD0160B933}.SupplierEnd TerminalConstraintTerm {B8192AA1-3321-4d5a-9823-446CC79C90D7}.ClientEnd CombinedCycleConfigurationMember {DF15B386-08F6-4c78-95AD-B7B10FCC1AB9}.ClientEnd AttributeProperty {3FB05567-9270-4fcb-8976-9ADA1813AE21}.ClientEnd BillDeterminant {3D3E108F-27E6-46ff-B50B-1A3A9365B887}.ClientEnd ChargeGroup {7E99E40A-D085-4ca0-9CA9-3E9E0C539B2A}.ClientEnd ChargeType {FA4D0F9A-CFBA-4b39-8AF5-D8EDA0559E55}.ClientEnd MarketStatementLineItem {EA6E81CB-9BBB-4a78-A1D6-B66BC9D9B2B7}.ClientEnd PassThroughBill {8190276C-7601-4378-973C-AE9F4C42620E}.ClientEnd Modeling Authority Sets supplied and maintained by this Modeling Authority. ModelingAuthoritySets {DD1413D0-73ED-4d90-8ADB-E87B483F7D14}.ClientEnd Models of the model frame. ModelSpecification {F71435FC-A6DA-4cce-BB6F-AAE8A1166194}.ClientEnd Modeling Authority suppliying and maintaining the data for the objects in this Modeling Authority Set. ModelingAuthority {DD1413D0-73ED-4d90-8ADB-E87B483F7D14}.SupplierEnd Model frames of the model frame type. ModelFrame {48C2079D-ACDD-4f43-B91E-201B0B6EEBFB}.ClientEnd Arguments of the operation. ModelOperationArg {8FC83F05-9979-46fe-AC90-E3B729F03BDB}.ClientEnd The type of the model operation. ModelOperationDescription {784F27D9-2196-49a7-BAA9-5C220EDE1B7E}.SupplierEnd OperationSequence {625A7E9A-0BA8-4b99-8F27-F85B489D5E7E}.ClientEnd The opeation for the operation argument. ModelOperation {8FC83F05-9979-46fe-AC90-E3B729F03BDB}.SupplierEnd The type of operation for this type of dataset role. Operations referencing the dataset role type should only belong to operations that reference the operation type. ModelOperationDefinition {351BA520-733C-4ff8-89F0-7F56FA528900}.SupplierEnd The instances of operations that conform to this operation type. ModelOperation {784F27D9-2196-49a7-BAA9-5C220EDE1B7E}.ClientEnd The type of dataset roles that can be used for a type of general model operation. OperationDatasetArgDescription {351BA520-733C-4ff8-89F0-7F56FA528900}.ClientEnd ModelOperation {625A7E9A-0BA8-4b99-8F27-F85B489D5E7E}.SupplierEnd The assembly description into which model parts should be included. AssemblyDescription {63DD40D8-8901-4fa0-B3DA-04BEDB15C589}.ClientEnd Model frame of the model part. FrameworkPart {F71435FC-A6DA-4cce-BB6F-AAE8A1166194}.SupplierEnd Modle parts conforming to the model part specification. Model {F5F3F26B-ED67-4cc0-AFDD-6BAB5F794D13}.ClientEnd AssemblyManifest {181112F7-C48F-44b9-B4D1-249851E26CBA}.ClientEnd CompleteModelToBeDeleted {C390164D-CBC2-47e2-8EAE-2EC7A1187A16}.SupplierEnd DataSet {2494ED30-254C-4f13-8F87-6FBEE03C2A4F}.SupplierEnd Model specification of the modelt. ModelSpecification {F5F3F26B-ED67-4cc0-AFDD-6BAB5F794D13}.SupplierEnd multiplier {86CC9B3D-6DFC-4a34-9152-1BD808FBDD41} unit {FA0E49C2-B5F3-4084-948C-2A553D874695} The starting terminal for the calculation of distances along the first branch of the mutual coupling. Normally MutualCoupling would only be used for terminals of AC line segments. The first and second terminals of a mutual coupling should point to different AC line segments. First_Terminal {E0778435-CE76-4d56-9FCA-FF9F04ED4FCA}.SupplierEnd The starting terminal for the calculation of distances along the second branch of the mutual coupling. Second_Terminal {3849B779-18E4-46d5-B987-8359D8A98A12}.SupplierEnd Zero sequence mutual coupling shunt charging susceptance uniformly distributed of the entire line section. b0ch {AC6F5010-FE14-46d4-8356-FAC00C72C23E} Distance to the start of the coupled region from the first lines terminal having sequence number equal to 1. distance11 {24F204CC-E384-4dfe-98B9-D0075DF1DA65} Distance to the end of the coupled region from the first lines terminal with sequence number equal to 1. distance12 {7275F327-1ABD-4a11-B170-904B24B53BDD} Distance to the start of coupled region from the second lines terminal with sequence number equal to 1. distance21 {5BB2F943-1CE7-4997-9E13-BAD43BA321F6} Distance to the end of coupled region from the second lines terminal with sequence number equal to 1. distance22 {40540F6D-3306-4d14-B600-53F9A1392F82} Zero sequence mutual coupling shunt charging conductance uniformly distributed of the entire line section. g0ch {5AC0AF5A-CD75-4dc9-9A70-DE9012477272} Zero sequence branchtobranch mutual impedance coupling resistance. r0 {4F35A9CE-4DB1-4270-BC6C-2E4415752E41} Zero sequence branchtobranch mutual impedance coupling reactance. x0 {D4B922E9-B25A-4821-A84E-AEDFA549F466} Identified object that this name designates. IdentifiedObject {203C47E2-30FB-4c8f-ABEA-1661621CC0A7}.SupplierEnd Type of this name. NameType {2DF559F1-C2F0-43ff-B7E0-654C3E738FDE}.SupplierEnd Authority responsible for managing names of this type. NameTypeAuthority {19684F95-02B1-4b64-B345-ADF4DDB40433}.SupplierEnd All names of this type. Names {2DF559F1-C2F0-43ff-B7E0-654C3E738FDE}.ClientEnd All name types managed by this authority. NameTypes {19684F95-02B1-4b64-B345-ADF4DDB40433}.ClientEnd NetworkFrame {695E7BFC-35D6-4d1d-AAA2-D5F42AA026BB}.SupplierEnd {CA21CE47-5254-4798-BFEE-38C0883A3CC1}.SupplierEnd FrameworkPart {EDD89720-4773-45ee-9FB3-8DFFCD2B09AA}.SupplierEnd NetworkBoundary {695E7BFC-35D6-4d1d-AAA2-D5F42AA026BB}.ClientEnd {CA21CE47-5254-4798-BFEE-38C0883A3CC1}.ClientEnd Operation {33808218-A5AF-495e-8ACC-888EF93D696E}.SupplierEnd Projects that are included in this parent project. ContainedProject {11B9FF97-2A88-467b-A14A-1843624A76BF}.ClientEnd Child {2A18274D-D3FD-4344-8344-B2FDC6DDCA5D}.ClientEnd A specific version of the network model project change. NetworkModelProjectChangeVersion {E749C3AE-A14B-4d74-905B-0BDDBE3992F3}.ClientEnd The details of model changes for this project. The change set should have a new identifier if it changes. ChangeSet {D0FD1813-3105-4ab3-AA49-9C2E1C71624E}.SupplierEnd The persistent network model project change to which this version applies. NetworkModelProjectChange {E749C3AE-A14B-4d74-905B-0BDDBE3992F3}.SupplierEnd The state of this network model project version. NetworkModelProjectState {79467043-AB52-45dc-900F-3947F6B07CC0}.SupplierEnd The project version that will supercede this project version. SupercededBy {84532593-82B1-4531-9C9A-EE2D56ED988A}.SupplierEnd Project version that is being superceded. Supercedes {84532593-82B1-4531-9C9A-EE2D56ED988A}.ClientEnd The parent project of this project. ContainingProject {11B9FF97-2A88-467b-A14A-1843624A76BF}.SupplierEnd NetworkModelProjectDocument {0203E575-3F55-4f26-BFAF-8F659C7E7E80}.SupplierEnd ProjectARelationships {186C7F99-9FCA-41de-8436-41E563322984}.ClientEnd ProjectBRelationships {49452EA4-5410-4415-B1E8-99AC0B96119F}.ClientEnd CurrentState {955D5BF8-C371-455c-9915-2EDD3CA75C50}.SupplierEnd Parent {2A18274D-D3FD-4344-8344-B2FDC6DDCA5D}.SupplierEnd NetworkModelProjectComponent {0203E575-3F55-4f26-BFAF-8F659C7E7E80}.ClientEnd ProjectA {186C7F99-9FCA-41de-8436-41E563322984}.SupplierEnd ProjectB {49452EA4-5410-4415-B1E8-99AC0B96119F}.SupplierEnd ChangeSets {5C7D89EE-E6F6-4bc7-9B55-013A14F63C05}.SupplierEnd DenpendecyDependingStage {66BEEFB3-CC6F-4eb4-B3FF-8D386E2F2D98}.ClientEnd DependencyDependentOnStage {DA34DBEB-9B66-47df-B464-9D7E5EC7EA99}.ClientEnd The change versions that are at this state. NetworkModelProjectChangeVersion {79467043-AB52-45dc-900F-3947F6B07CC0}.ClientEnd Transformer end that current is applied to in this noload test. EnergisedEnd {F3E7A0B0-A48C-4358-8A44-11C4C94ABFB4}.SupplierEnd Voltage applied to the winding end during test. energisedEndVoltage {20FBD71A-ECFC-4665-BC2C-38A1996F3CE7} Exciting current measured from a positivesequence or singlephase excitation test. excitingCurrent {483E5C02-946E-4159-938B-4B1774667A52} Exciting current measured from a zerosequence opencircuit excitation test. excitingCurrentZero {FD31067C-C048-4f4f-923E-EC9F02E7E694} Losses measured from a positivesequence or singlephase excitation test. loss {BC40329E-347C-4bcb-ACF4-879701BBE06A} Losses measured from a zerosequence excitation test. lossZero {613CA323-1A7C-442f-B8DF-39AF71F7A4E1} MktConnectivityNode {E32D476E-22A4-4002-A185-3CB6C77E4005}.SupplierEnd Group of this ConformLoad. LoadGroup {3CAF0C58-293B-4fcd-945A-945312494BFB}.ClientEnd Conform loads assigned to this ConformLoadGroup. EnergyConsumers {3CAF0C58-293B-4fcd-945A-945312494BFB}.SupplierEnd The NonConformLoadSchedules in the NonConformLoadGroup. NonConformLoadSchedules {30607CC5-5FB9-4bd4-8F9D-BD718F651B4E}.SupplierEnd The NonConformLoadGroup where the NonConformLoadSchedule belongs. NonConformLoadGroup {30607CC5-5FB9-4bd4-8F9D-BD718F651B4E}.ClientEnd The projected cost for this item. amount {BC547B43-1F66-4933-AAB5-BD3B7E548B0D} Positive sequence shunt charging susceptance per section. b {2444AD6A-5AE8-4468-ACEB-73E8D4613927} Positive sequence shunt charging conductance per section. g {191632B6-2840-477e-B57D-AB48DC16ADB8} Positive sequence shunt charging susceptance per section. b {6F759E68-6762-48f7-83F8-A68CCBF75008} Zero sequence shunt charging susceptance per section. b0 {5BC99084-351E-4a1d-AEEA-41C16FBE6AA8} Positive sequence shunt charging conductance per section. g {60A2BA6A-2613-4fd4-99D4-72E10BF34045} Zero sequence shunt charging conductance per section. g0 {E58C51D2-C678-4903-ADFB-59CA9EC22209} GeneratingBids {9A5F74CD-56FF-45e1-8BC8-5AD82D6C11B0}.ClientEnd The data object holding preconditions of updates. ObjectReverseModification {22E96F65-7EFC-4331-BA60-BA9C5D984E2E}.ClientEnd The associated data object representing the update. Normally the associaiton is specifed but in the case of a proxy object where the association is removed we might not reference any data object as it would only reference a proxy data object with no associations. ObjectModification {22E96F65-7EFC-4331-BA60-BA9C5D984E2E}.SupplierEnd Kind of analog representing oil fluid test analysis result. kind {F30FD808-456D-4ef1-93B0-DF58F603E429} Kind of discrete representing oil fluid test analysis result. kind {4E3257AD-BED3-4db4-9C0F-E63C7BC8A135} Kind of analog representing oil dissolved gases analysis result. kind {5D615ACB-C887-465a-B339-FB3D202411CB} Kind of analog representing oil metals elements analysis result. kind {DE0264E7-5366-4fbc-A51A-4EFFE5F26CD1} Kind of analog representing oil moisture analysis result. kind {A5E40132-9CBD-4838-B58E-0694B1841409} Kind of analog representing oil PCB analysis result. kind {1038D4BB-1176-4e34-82DB-6628D7ADC79A} Kind of discrete representing oil PCB test analysis result. kind {FCA1D905-CCB3-4c74-BC12-1F2885A376B4} Kind of analog representing oil paper degradation analysis result. kind {4F15F807-15FA-4fdd-B36C-4BB7FC7938D4} Kind of analog representing oil particulate analysis result. kind {31A17357-0261-4295-8328-2E201A2C2FD0} Kind of discrete representing oil particulate analysis result. kind {63B47147-116B-4cc3-99D3-80E3F77FD60E} FuelRegion {4309159F-3756-4294-B5A1-E8863F5CEA5B}.SupplierEnd Location from which oil sample taken. oilSampleTakenFrom {4035942E-3822-481e-9B7A-E717A379390C} Oil sample temperature. oilSampleTemperature {5ED27F1C-8473-406a-8CC5-A014A849FC2C} Source of oil temperature. oilTemperatureSource {63B3B095-DD70-4ec7-849D-424121278112} Type of sample container. sampleContainer {9ECB0B31-A44C-4d90-B30E-068B7789B6C2} All Assignments for this Crew. Assignments {B597E5EE-DEFD-46c2-9B5C-1B4B22EA8086}.SupplierEnd Capabilities {A3C41283-0A33-4ee9-A5AA-105826F2A3B8}.ClientEnd Locations {9F98B054-8439-4bd9-8F2E-43422494EFE5}.SupplierEnd Route {E3EA714F-98DF-4908-8D66-9D4D2D2ECDBE}.SupplierEnd ShiftPatterns {764EE186-E180-4d38-9772-53A73AAE0278}.SupplierEnd Crafts {19D1AD6D-1BA3-400f-BACA-BF16BDB31A48}.ClientEnd CustomerData {08C6C8AA-21F3-4f0e-91C1-B7765CD6D7FA}.ClientEnd ErpCompetency {A11130EF-055F-4b39-8ED5-B1CB36A71F99}.SupplierEnd ErpPersonnel {284A2414-6888-411f-82F7-90FAF8CA2419}.SupplierEnd LaborItems {A04894E3-14E3-4cfe-B0D3-57701085ACBE}.SupplierEnd LandPropertyRoles {ABB493E7-418A-4fe4-B85B-23905A057C94}.SupplierEnd MeasurementValues {E047391D-9AD5-4022-964F-3C6152531AE3}.SupplierEnd OrganisationRoles {694B40C4-6F8C-41a2-9D1E-27B7A4572BBE}.SupplierEnd Skills {9D792EF4-F8E0-42ce-A1BF-B84E9BA01D5F}.SupplierEnd status {85D1041F-EF9D-4161-A285-EEB8EAEDA342} The maximum rms voltage that may be applied across an open contact without breaking down the dielectric properties of the switch in the open position. dielectricStrength {07BB73CC-6FAB-4867-8927-69AAC0C36694} The highest value of current the switch can make at the rated voltage under specified operating conditions without suffering significant deterioration of its performance. makingCapacity {BEB67DB0-4C7F-4415-AE1D-4FE26FE0BD47} The lowest value of current that the switch can make carry and break in uninterrupted duty at the rated voltage under specified operating conditions without suffering significant deterioration of its performance. minimumCurrent {2CF18E57-21C4-4787-8165-7FCE2E42E726} The highest value of current the switch can carry in the closed position at the rated voltage under specified operating conditions without suffering significant deterioration of its performance. withstandCurrent {903743F6-97BC-4bfe-A957-B4CCAD2196FA} Overload rating for 24 hours. dayOverLoadRating {45CAF1A7-AA19-440b-96F6-FFF7F2A8E241} Overload rating for 1 hour. hourOverLoadRating {99C410E9-8AA7-4654-BFF9-5E5983FE1E44} Weight of solid insultation in transformer. solidInsulationWeight {17A5040D-2047-4a64-8D7B-14FE792ADB70} Type of insultation used for transformer windings. windingInsulationKind {DC10AE0D-7691-4b41-AA73-93D4D55D2812} Kind of construction for this transformer. constructionKind {F31C5B99-BA3D-4c01-A540-618EF7A9A998} Weight of core and coils in transformer. coreCoilsWeight {31200834-25CB-4cac-BAC7-CE5BF875DAD8} Core kind of this transformer product. coreKind {8C022234-AB4E-4f1d-B592-448A1F9C484A} Function of this transformer. function {E1D99D79-255D-4598-AB65-61A021740C26} Basic insulation level of neutral. neutralBIL {586E9509-F1A5-4c20-B445-C2A0C378E8DB} Kind of oil preservation system. oilPreservationKind {E6B251F6-B06E-4078-B823-F9DC9F97BEBD} Capabilities {99651776-E1FC-4685-A904-70049BEA9646}.ClientEnd ContractorItems {3123F76B-B55F-4f42-AEB4-96AA9F5254CA}.SupplierEnd Design {83CD7FF8-6559-45a7-AB79-BA79FC3B1C82}.ClientEnd DesignLocationCUs {FCF781BC-040D-407f-A030-D5BB3656B390}.ClientEnd LaborItems {FDB3A56B-46C4-4591-A0EA-AA7F58E3236A}.SupplierEnd MiscCostItems {AB707969-391C-4b7b-9824-9E98B7029488}.SupplierEnd OverheadCost {B41A8F8E-876B-48ea-B6D2-DE732BA34F6E}.SupplierEnd QualificationRequirements {B3426602-AFB3-44a7-9BCB-107ADC91CCAB}.SupplierEnd Usages {AADBFD79-5E2A-47b4-A108-F25824E68687}.SupplierEnd WorkCostDetails {7F10B6C7-082B-4d2d-B95B-E5DF634041D3}.ClientEnd WorkFlowStep {C76E630D-24B2-45f0-8B97-801F51060C44}.ClientEnd WorkLocations {ECA7D24D-E18E-412d-BD83-31B1B68A4448}.ClientEnd Transformer end that current is applied to in this opencircuit test. EnergisedEnd {71BB3848-4B63-4fd1-9254-66CEBBF18C94}.SupplierEnd Transformer end measured for induced voltage and angle in this opencircuit test. OpenEnd {AC00E333-4A04-486e-AA1A-D3D83FB22682}.SupplierEnd Voltage applied to the winding end during test. energisedEndVoltage {61C79A42-CF37-45d8-BD20-3C3E9DFF5F5A} Voltage measured at the opencircuited end with the energised end set to rated voltage and all other ends open. openEndVoltage {7B8EF14F-49BF-482d-8D73-A2C345AE7693} Phase shift measured at the open end with the energised end set to rated voltage and all other ends open. phaseShift {950DE312-6E35-45e0-B7A6-16CABB15AE0D} Interrupter controlled by this mechanism. InterrupterUnit {DA02B460-9B93-4dff-AF33-7056DC71BA82}.SupplierEnd Close current nominal. closeAmps {D85DBA0C-1D24-4ed4-9DE9-F12A9EA6D7DE} Close voltage in volts DC. closeVoltage {3A230AB7-1714-40e6-94C2-C7CB4B860F51} Kind of breaker operating mechanism. mechanismKind {E2DDF690-CBC3-44e3-91E3-B1C6CAD899FE} Rated motor run current in amps. motorRunCurrent {998D6F29-FB81-4424-97B5-CC05634FC07A} Rated motor start current in amps. motorStartCurrent {97BFB3F3-C987-43b4-8A38-6729D54038C7} Nominal motor voltage in volts DC. motorVoltage {AE0A2159-D904-4884-AEDE-17CDB6B8FB8C} Trip current nominal. tripAmps {0762F532-1818-4a10-BB84-F74D30629D0F} Trip voltage in volts DC. tripVoltage {EA3B14F8-6C27-4377-99B3-5AA95E5B14D8} The operating shares of this operating participant. An operating participant can be resused for any number of power system resources. OperatingShare {C8C2BA26-2410-41d8-9E77-EC3873BDCE5B}.ClientEnd The operating participant having this share with the associated power system resource. OperatingParticipant {C8C2BA26-2410-41d8-9E77-EC3873BDCE5B}.SupplierEnd The power system resource to which the share applies. PowerSystemResource {343B3487-FA8E-4906-A8F1-4D6E3B27F4AF}.SupplierEnd Percentage operational ownership between the pair power system resource and operating participant associated with this share. The total percentage ownership for a power system resource should add to 100. percentage {91E1E9AB-B240-4b98-9917-82000F0A4CFB} NetworkModelCaseDefinition {33808218-A5AF-495e-8ACC-888EF93D696E}.ClientEnd The limit dependency models which are used to calculate this limit. If no limit dependencies are specified then the native limit value is used. LimitDependencyModel {930C423F-F107-4857-A500-C7D5C97E88CB}.SupplierEnd LimitScalingLimit {312BBC54-9F5A-4000-8A02-754DB702EB90}.ClientEnd The limit type associated with this limit. OperationalLimitType {E3D73666-E647-4b0a-B020-0700E4FCDECC}.SupplierEnd The equipment to which the limit set applies. Equipment {AEB22FF5-0EEF-4e3a-BE8C-07931F2FAE92}.SupplierEnd The terminal where the operational limit set apply. Terminal {E741C3E3-646B-4238-BE21-DFE9B0A603C1}.SupplierEnd The operational limits associated with this type of limit. OperationalLimit {E3D73666-E647-4b0a-B020-0700E4FCDECC}.ClientEnd SourceOperationalLimitTypeScaling {B089AC15-CDFC-4c0d-9765-7F449337E6AB}.ClientEnd TargetOperationalLimitmTypeScaling {870033E1-C96D-4c7f-BC97-DB2B6D26C20F}.ClientEnd The nominal acceptable duration of the limit. Limits are commonly expressed in terms of the time limit for which the limit is normally acceptable. The actual acceptable duration of a specific limit may depend on other local factors such as temperature or wind speed. The attribute has meaning only if the flag isInfiniteDuration is set to false hence it shall not be exchanged when isInfiniteDuration is set to true. acceptableDuration {4596C956-5F6F-4af5-9726-AA67E22FD030} The direction of the limit. direction {247D5C99-6296-4916-93DB-C4DA1CFF667F} All equipments to which this restriction applies. Equipments {A11D842D-BDDB-42a4-B8FB-43C199D5E3BA}.SupplierEnd Asset model to which this restriction applies. ProductAssetModel {52B7FEC7-526D-4b4e-8839-1C5E1DE7D0A4}.SupplierEnd Interval during which this restriction is applied. activePeriod {9403F5A8-AF55-43eb-B08A-29A04BD09050} Restricted new value includes unit of measure and potentially multiplier. restrictedValue {E7974231-35DC-4526-BC91-D229A5682DF4} Asset on which this tag has been placed. Asset {6C60E3EC-3A0D-400d-BFBB-48BE5355B286}.SupplierEnd Power system resource on which this tag has been placed. PowerSystemResource {AB49BFBC-0F00-4bf2-95B2-BCBAD3CA1BA5}.SupplierEnd Tag action associated with this tag. TagAction {987DD03E-CEAD-487e-B8AA-EDF24171399B}.ClientEnd Planned equipment outage with this updated rating. PlannedOutage {C5F3A5B0-064B-4cc4-AA34-0296D8D7919A}.SupplierEnd All safety documents issued by this supervisor. IssuedSafetyDocuments {019E9E3C-C2CC-4a76-9DB0-DEC77795FB72}.SupplierEnd All safety documents released to this supervisor. ReleasedSafetyDocuments {9101B352-8544-44a4-9F4A-B24425BA24E4}.SupplierEnd SourceOperationalLimitType {B089AC15-CDFC-4c0d-9765-7F449337E6AB}.SupplierEnd TargetOperationalLimit {870033E1-C96D-4c7f-BC97-DB2B6D26C20F}.SupplierEnd The percentage scaling of the source limit to compute the target limit. Applys to operational limits within an operaitonal limit set when both source and target operational limit types exist. scalingPercent {F075EE22-BD60-410a-BD34-DB3EC0782816} All incidents owned by this operator. Incidents {C2056AB7-C6BB-48a9-9AC4-CC384465DB27}.ClientEnd All switching steps this operator is responsible for. SwitchingSteps {4CE8C00C-90B0-4798-B63D-CD522B565717}.ClientEnd Pnode {94E0B2E3-2515-46e5-ACE3-EE9FFB04B4EA}.SupplierEnd Maximum MW for the SourceSink for the Allocation maxMWAllocation {E4946B4E-E169-4321-B2ED-317D8034E5D2} RegisteredResource {AB61B549-CFB6-4874-A737-21DD7CC11D7A}.ClientEnd association type for the association between Organisation and Resource asscType {57004E7F-B083-4ef7-AF68-8908ED46D738} Flag to indicate that the SC representing the Resource is the Master SC. masterSchedulingCoordinatorFlag {EE0A5D17-AD01-473e-9608-EAB24A2125D6} ownership percentage for each resource ownershipPercent {355B6F0A-5E7A-48d9-A4A8-C5937075C606} Parent organisation of this organisation. ParentOrganisation {859EDB59-64A7-41fc-8B17-1A318CDA46C9}.SupplierEnd All roles of this organisation. Roles {69EAE008-4E1D-4248-A3AB-1554BEBAB5B8}.ClientEnd SwitchingPlanRequest {9F41E5C9-778C-4e68-B6F3-EE634A0DD569}.ClientEnd Electronic address. electronicAddress {420B480C-5DE3-4687-811D-95091C63FC97} Phone number. phone1 {C6A9116C-C752-4c65-B59B-9A77B6149795} Additional phone number. phone2 {1857252F-D8A8-45d0-AD06-817CBCA55A73} Postal address potentially different than streetAddress e.g. another city. postalAddress {F59336DC-7E1F-4ef6-8534-6BDF3F957952} Street address. streetAddress {6EDF9FBB-9D0C-4b28-96A8-6E023DBAFD26} All configuration events created for this organisation role. ConfigurationEvents {83D1A41E-45C6-49ba-883F-D9E6B3E0643C}.SupplierEnd Organisation having this role. Organisation {69EAE008-4E1D-4248-A3AB-1554BEBAB5B8}.SupplierEnd Crew {D0947F3D-A8D0-4b21-9924-B957AF56DC82}.SupplierEnd all deenergized useage points associated with the outage. DeEnergizedUsagePoint {97DDAF6C-65B2-463f-8202-046CC1702F4C}.SupplierEnd All energized usage points associated with this outage. EnergizedUsagePoint {13D27FCF-5727-416e-9B7E-FCE3388F7C11}.SupplierEnd All equipments associated with this outage. Equipments {7CB5F824-2EAC-4c6e-B3CE-B2B245253D31}.SupplierEnd EstimatedRestorationTime {ABABDC87-C805-4e9a-86E2-7C263386DF76}.ClientEnd All faults involved in this outage. Faults {B23C14B3-6E9C-4b0c-82C5-781ED12E4406}.SupplierEnd Incident reported in trouble call that results in this outage. Incident {91D33A1C-B14C-40a2-8C56-19764D00E571}.ClientEnd OutageArea {FA533EAF-39C8-41ca-8599-A37602141D77}.ClientEnd OutageIsolationEquipment {EEA2935F-26F1-463e-890E-676B5DDA189A}.SupplierEnd All switch actions to apply within the scope of this planned outage. Each such action groups switches to which the action is to apply in order to produce the desired network state considered as outage. PlannedSwitchActions {7DAECB14-3133-4fec-91BB-CBC4E6C8147D}.SupplierEnd All switching plans that lead to supply restoration due to this outage. Only one will be retained for execution. SwitchingPlans {D2D106C9-7B45-4172-8201-66E3FAC64E75}.ClientEnd Actual outage period end of the period corresponds to the actual restoration time. actualPeriod {0AD368D5-C6D0-47a8-B938-051F2AC57B2C} Estimated outage period for a planned outage. The start of the period is the start of the planned outage and the end of the period corresponds to the end of the planned outage. estimatedPeriod {8C9C1A9F-3138-4ade-A916-15CC7860C66E} Defines if the outage has been verified or is only estimated outageKind {4EEF77FC-63B4-44f5-9831-FB5BBDD0FD98} defines the status of the crew as in dispatched or arrived etc. statusKind {CEB45334-9B67-4ff2-AC41-C15BAC571F12} Summary counts of service points customers affected by this outage. summary {092BCE4E-C750-42c7-8623-55B144F00805} Outage {FA533EAF-39C8-41ca-8599-A37602141D77}.SupplierEnd defines the type of area that has the outage county state zipcode etc. outageAreaKind {84A9A4DF-C2DA-44d1-880E-B2535B286214} Location {5D0E1B69-67C1-469c-B013-AE8901A8B015}.SupplierEnd OutagePlan {CC6A368B-E2F3-4765-8252-5F09775C61A8}.ClientEnd The customers that are affected by this planned outage. Customer {2B68C98E-D3F5-4de1-9693-2F2E3F99F1BC}.ClientEnd OutageOrder {CC6A368B-E2F3-4765-8252-5F09775C61A8}.SupplierEnd The outage resulting from the execution of the outage plan. PlannedOutage {D5052A16-C1AA-4cfa-B0E4-1C79BE08873C}.SupplierEnd The swiching plan that is associated with the outage plan. SwitchingPlan {205E346A-7AC3-4f63-9926-D90B3687F39B}.ClientEnd planned start and end time of the planned outage. plannedPeriod {5FA03C41-4627-4d3a-B71B-75B8A5497E8E} Limit value of rated field current iIiisubFDLIMsubi. Typical value 105. ifdlim {66957AD8-4FCD-4213-90F5-FB82CD9E5D86} Gain Over excitation limiter iKiisubOIsubi. Typical value 01. koi {B0ACAB27-BDEE-4a04-A31A-6EA6EAAEFD2F} Maximum error signal iViisubOIMAXsubi gt OverexcLim2.voimin. Typical value 0. voimax {3B23EBC7-34DE-4930-B0C7-C48EF5B11E0C} Minimum error signal iViisubOIMINsubi lt OverexcLim2.voimax. Typical value 9999. voimin {115E6DFC-68FC-4812-8490-EB8F660FF379} OEL pickupdropout hysteresis iHYSTi. Typical value 003. hyst {6775D95B-4AD1-4381-81F2-3AD4F9BCE7D5} OEL timed field current limit iIiisubFDLIMsubi. Typical value 105. ifdlim {F9830F3B-CA71-4dbd-B07D-C8B89AB17045} OEL instantaneous field current limit iIiisubFDMAXsubi. Typical value 15. ifdmax {E26BD0DE-A3DF-44d1-B28A-72D67687AB1D} OEL timed field current limiter pickup level iIiisubTFPUsubi. Typical value 105. itfpu {683231C5-5A6A-4b2c-ADEF-07DC80EA390A} OEL cooldown gain iKiisubCDsubi. Typical value 1. kcd {A06197E1-D459-4d9f-B272-50F1E02B0B62} Low voltage point on the inverse time characteristic iEFDiisub1subi. Typical value 11. efd1 {6E93D0F1-706F-4a97-BD16-CA06018C721A} Mid voltage point on the inverse time characteristic iEFDiisub2subi. Typical value 12. efd2 {C0FA5CFE-B194-40cb-9A5B-4CA852B9CF6F} High voltage point on the inverse time characteristic iEFDiisub3subi. Typical value 15. efd3 {D2E6E305-DDE8-4145-8A00-E4CF232BF980} Desired field voltage iEFDiisubDESsubi. Typical value 09. efddes {5EBC6BC9-3478-486d-85C2-959082B3CFEE} Rated field voltage iEFDiisubRATEDsubi. Typical value 105. efdrated {DE1555D8-E82B-4a71-B5F0-F7F81738792E} Gain iKiisubMXsubi. Typical value 001. kmx {F522FB66-52E2-4e73-A046-67AB96645898} Time to trip the exciter at the low voltage point on the inverse time characteristic iTIMEiisub1subi gt 0. Typical value 120. t1 {5A860B82-5646-45df-B2AE-F0DF75FC21BD} Time to trip the exciter at the mid voltage point on the inverse time characteristic iTIMEiisub2subi gt 0. Typical value 40. t2 {8D730482-987C-4cfa-A383-2512A411A957} Time to trip the exciter at the high voltage point on the inverse time characteristic iTIMEiisub3subi gt 0. Typical value 15. t3 {7D221F50-39E9-4fdf-AA40-9A4A701E2B6F} Low voltage limit iViisubLOWsubi gt 0. vlow {A978FFFC-55EA-4ed3-939F-E99DECBAD1E3} Low voltage or current point on the inverse time characteristic iEFDiisub1subi. Typical value 11. efd1 {80810BAD-6ADD-4804-8F1E-90CD58477DB0} Mid voltage or current point on the inverse time characteristic iEFDiisub2subi. Typical value 12. efd2 {5BC46827-7294-48b7-9FC2-A50165561794} High voltage or current point on the inverse time characteristic iEFDiisub3subi. Typical value 15. efd3 {A666F92C-2DE4-4692-A0A5-EA163E033A7A} Desired field voltage if imi false or desired field current if im i true iEFDiisubDESsubi. Typical value 1. efddes {DA111266-23DB-4016-9E0B-3018AFE61789} Rated field voltage if m false or rated field current if m true iEFDiisubRATEDsubi. Typical value 105. efdrated {3C1D582F-A381-492d-816D-78728741AE89} Gain iKiisubMXsubi. Typical value 0002. kmx {CE7DB459-ADDE-4c49-9048-BD054F2A038E} Time to trip the exciter at the low voltage or current point on the inverse time characteristic iTIMEiisub1subi gt 0. Typical value 120. t1 {BEDF4730-E0B9-4e21-9A52-E169A0F6E360} Time to trip the exciter at the mid voltage or current point on the inverse time characteristic iTIMEiisub2subi gt 0. Typical value 40. t2 {566048CD-4F3D-4c43-A8FA-115FAC3A4DF2} Time to trip the exciter at the high voltage or current point on the inverse time characteristic iTIMEiisub3subi gt 0. Typical value 15. t3 {43D2DB67-39E9-496a-971C-FA7680F2EEA7} Low voltage limit iViisubLOWsubi gt 0. vlow {7880978D-4726-4959-AF94-9218A6379989} Excitation system model with which this overexcitation limiter model is associated. ExcitationSystemDynamics {A6EC8E29-6996-4dba-B736-0ACEAFBAD928}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {8154CFB5-D525-420f-B290-005306255D1B}.ClientEnd WorkCostDetails {C5ADCDD4-2638-408f-9377-13A155EB81D7}.SupplierEnd WorkTasks {B41A8F8E-876B-48ea-B6D2-DE732BA34F6E}.ClientEnd The overhead cost to be applied. cost {E32E78A7-3219-47cf-9C1C-AE27EA7630A7} status {F7C9CC16-861A-4d8d-8574-52EFB5A9CDA3} Asset that is object of this ownership. Asset {7323F8B4-3F0F-40c7-8BCA-72BFFF4394A9}.SupplierEnd Asset owner that is subject in this ownership. AssetOwner {4276D5C7-95E8-44db-84E8-C01DA2834B6C}.SupplierEnd Share of this ownership. share {D0968FCF-20A0-4260-8B4A-87C53082B98D} Excitation system model with which this power actor or VAr controller type 1 model is associated. ExcitationSystemDynamics {A9638A5A-FA55-428d-8A6E-7CD1F44F4703}.SupplierEnd Remote input signal used by this power factor or VAr controller type 1 model. RemoteInputSignal {08E5127F-7B16-4f73-A4EF-20E79A544461}.SupplierEnd Voltage adjuster model associated with this power factor or VAr controller type 1 model. VoltageAdjusterDynamics {7A74A658-111A-4af6-B1B7-CAA3F6F7BA11}.ClientEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {836BD709-E07C-4f9e-A2CD-CD5C69C06B2A}.ClientEnd Excitation system model with which this power factor or VAr controller type 2 is associated. ExcitationSystemDynamics {5FBF52C8-0201-4d22-996D-1457516FB808}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {1FD4D65B-F0C9-4390-8928-11A647913605}.ClientEnd PF controller time delay iTiisubPFCsubi gt 0. Typical value 5. tpfc {BF35DF2A-BB20-44b5-9A29-D379F8CF2949} Minimum machine terminal current needed to enable pfvar controller iViisubITMINsubi. vitmin {AA4EDA55-39C8-4770-A4F2-5A260F4FE82F} Synchronous machine power factor iViisubPFsubi. vpf {5C6C7E59-9AC8-4cbd-9DCC-362FDB1A209A} PF controller reference iViisubPFREFsubi. vpfref {9D3C22AD-4A21-45b7-8F5F-02207FA2020E} Maximum machine terminal voltage needed for pfvar controller to be enabled iViisubVTMAXsubi gt PFVArType1IEEEPFController.vvtmin. vvtmax {895E640F-E9DD-4763-B6D9-8E3B8C9E4A51} Minimum machine terminal voltage needed to enable pfvar controller iViisubVTMINsubi lt PFVArType1IEEEPFController.vvtmax. vvtmin {23D4E471-0C6F-42a6-9546-8FB0A3B5BE14} Var controller time delay iTiisubVARCsubi gt 0. Typical value 5. tvarc {949BDAB4-CC6F-4a23-B3D4-52075E7BDC09} Synchronous machine power factor iViisubVARsubi. vvar {1D63915C-5CDA-4d19-84CA-BE19B7275C97} Var controller reference iViisubVARREFsubi. vvarref {A1324C55-CF8C-4767-A8E5-524A379F8C81} Maximum machine terminal voltage needed for pfVAr controller to be enabled iViisubVTMAXsubi gt PVFArType1IEEEVArController.vvtmin. vvtmax {48B2E327-00AB-4caf-82C3-49A30B4DC865} Minimum machine terminal voltage needed to enable pfvar controller iViisubVTMINsubi lt PVFArType1IEEEVArController.vvtmax. vvtmin {A2A74F95-ADFD-49b4-AB46-50E851F92A73} Reset gain iKii. ki {53F1EC69-C547-42db-B42C-D2AAED592E24} Proportional gain iKpi. kp {571AF56B-26D3-4a5e-9C78-FEF6A5799D29} Output limit imaxi. max {FA2E3192-8365-4020-92E1-76CC4DEFE0F9} Reference value of reactive power or power factor iRefi.The reference value is initialised by this model. This initialisation can override the value exchanged by this attribute to represent a plant operators change of the reference setting. ref {3F4F381E-3DE4-4ef0-AB78-89550E557272} Integral gain of the pf controller iKiisubIsubi. Typical value 1. ki {D712B5A8-89FE-4344-BB00-62DD4AC67CFE} Proportional gain of the pf controller iKiisubPsubi. Typical value 1. kp {0944DB7C-E782-431a-AC24-8396563AB454} Power factor reference iPiisubFREFsubi. pfref {BD8E49CB-E735-48c8-9638-2823E1AB8E84} Maximum output of the pf controller iViisubCLMTsubi. Typical value 01. vclmt {AA81F228-F401-43d6-A216-B5038249011E} Voltage regulator reference iViisubREFsubi. vref {8418DF35-E9F9-426a-B701-7B6C66A2A62F} Integral gain of the pf controller iKiisubIsubi. ki {909D4B6B-EC0A-46f2-81E6-162163E00AF1} Proportional gain of the pf controller iKiisubPsubi. kp {F998AC26-3547-4dfe-8BAE-9F779A2BC157} Reactive power reference iQiisubREFsubi. qref {89323CED-C9D0-40bf-9C18-E8ADFAE7F49B} Maximum output of the pf controller iViisubCLMTsubi. vclmt {0E592614-4AF3-4bef-8E8E-4924F3D0B073} Voltage regulator reference iViisubREFsubi. vref {EA57344E-35F0-4549-99AA-3428C83A2157} Delay {0A11698D-6954-4f58-B75E-3CBA73047718}.ClientEnd VSCtype1 {E76FDA89-DE78-4412-88D5-5554DBCA51D8}.SupplierEnd Power system resource that generated this event. PowerSystemResource {8A1816B8-B53E-4ace-9651-A32675F78437}.SupplierEnd Kind of event. kind {A5054EAE-D869-4ceb-BCDB-5062E267179B} Power system resources classified with this power system resource type. PowerSystemResources {739158B5-6CE8-473f-87FF-1CDA17078612}.ClientEnd multiplier {39670F5A-8684-4c87-A5BD-DDCDAE008F27} unit {D54E5F22-5150-4af7-AFB8-57E4C7ACD22E} Cold leg feedback lag time constant. coldLegFBLagTC {537FBCC6-8E5E-4b3f-993B-CC6782D90488} Cold leg feedback lead time constant. coldLegFBLeadTC1 {BF0CAE76-4807-4ef4-A45D-6616C49B5164} Cold leg feedback lead time constant. coldLegFBLeadTC2 {DC1ACE90-F79F-4afa-93C6-105B67E9D5FA} Cold leg feedback gain 1. coldLegFG1 {A457C8C2-0F4B-4b58-9C75-37B5F1DD314B} Cold leg feedback gain 2. coldLegFG2 {6EFAFC52-D699-4ba0-AA4B-A577D5AB1402} Cold leg lag time constant. coldLegLagTC {6F87418C-03EF-41e6-B6D3-8AF359594DB9} Core heat transfer lag time constant. coreHTLagTC1 {3D313F7F-D2B2-4b52-A841-85512A06655E} Core heat transfer lag time constant. coreHTLagTC2 {BFF946CF-FCBC-488a-B8CD-6C058DEF6527} Core neutronics effective time constant. coreNeutronicsEffTC {2D1AF5A9-4D0D-4dfc-83B4-7FE73678BAB3} Core neutronics and heat transfer. coreNeutronicsHT {F57DEBE5-909E-439f-8B91-0B5C93A1A064} Feedback factor. feedbackFactor {4BD8579F-0FAF-42cd-B648-D416F38B32C6} Hot leg lag time constant. hotLegLagTC {12D5B892-82E2-434c-B4F0-5F3E959D68B0} Hot leg steam gain. hotLegSteamGain {A5BD787B-5C20-45e6-9393-EBC04734313A} Hot leg to cold leg gain. hotLegToColdLegGain {6B67E4DD-756E-4f40-BEF5-31F78CF13704} Pressure control gain. pressureCG {567AC90A-B9D1-41a8-A60F-5F3DCF47773F} Steam flow feedback gain. steamFlowFG {2BE21F18-A2C3-4243-B7E5-C38F1BE91577} Steam pressure drop lag time constant. steamPressureDropLagTC {64695027-4AD8-4826-9CA1-ADBDE27C4037} Steam pressure feedback gain. steamPressureFG {E20F458A-A1C2-4a28-A22E-400E8C96228A} Throttle pressure factor. throttlePressureFactor {736545C0-A272-4846-8F52-5094C2E4AB83} Throttle pressure setpoint. throttlePressureSP {C79842D4-4106-4adb-B8B2-CE38462B6A7B} Appliance being controlled. appliance {78E102A7-2078-4ba0-A5C9-D473517F8D89} Used to define a maximum energy usage limit as a percentage of the client implementations specific average energy usage. The load adjustment percentage is added to 100 creating a percentage limit applied to the client implementations specific average energy usage. A 10 load adjustment percentage will establish an energy usage limit equal to 90 of the client implementations specific average energy usage. Each load adjustment percentage is referenced to the client implementations specific average energy usage. There are no cumulative effects.The range of this field is 100 to 100 with a resolution of 1. A 100 value equals a total load shed. A 100 value will limit the energy usage to the client implementations specific average energy usage. avgLoadAdjustment {05241FB8-A11C-473e-B34C-6431697AFC5C} Requested offset to apply to the normal cooling setpoint at the time of the start of the event. It represents a temperature change that will be applied to the associated cooling set point. The temperature offsets will be calculated per the local temperature in the thermostat. The calculated temperature will be interpreted as the number of degrees to be added to the cooling set point. Sequential demand response events are not cumulative. The offset shall be applied to the normal setpoint. coolingOffset {D6D19B3C-F964-42f2-9304-215DDA9C0F83} Requested cooling set point. Temperature set point is typically defined and calculated based on local temperature. coolingSetpoint {3394913E-3EC6-431e-8336-216F2807CFA8} Maximum on state duty cycle as a percentage of time. For example if the value is 80 the device would be in an on state for 80 of the time for the duration of the action. dutyCycle {6AE1150A-D257-4cfa-BB78-EBEDF16983AF} Requested offset to apply to the normal heating setpoint at the time of the start of the event. It represents a temperature change that will be applied to the associated heating set point. The temperature offsets will be calculated per the local temperature in the thermostat. The calculated temperature will be interpreted as the number of degrees to be subtracted from the heating set point. Sequential demand response events are not cumulative. The offset shall be applied to the normal setpoint. heatingOffset {D228B3BC-35C6-47f1-AF49-7D90DDC366B5} Requested heating set point. Temperature set point is typically defined and calculated based on local temperature. heatingSetpoint {0DEB60D7-E61F-42de-88A1-6368D55F2444} Transmission mode to be used for this PAN display control. transmissionMode {74849BCC-313E-4805-BB77-7927149BFCA8} All pricing details issued by this PAN pricing commandaction. PanPricingDetails {BAEC4D70-D943-4d13-ADC2-66BB67EDAF4E}.SupplierEnd PAN pricing commandaction issuing this price detail. PanPricing {BAEC4D70-D943-4d13-ADC2-66BB67EDAF4E}.ClientEnd Price of the commodity measured in base unit of currency per unitOfMeasure. generationPrice {D4641443-D044-4c9d-B689-A04D75E28388} Price of the commodity measured in base unit of currency per unitOfMeasure. price {B2954B45-91D3-47cb-8D37-8008B91E5C36} Organisation that is part of this parent organisation. Organisation {859EDB59-64A7-41fc-8B17-1A318CDA46C9}.ClientEnd multiplier {2DE44EFF-C5E7-4f44-8A44-C6476EBE3F62} unit {04DAA147-D0FD-43d2-A1CB-9FF94062683E} ChargeProfiles {7A4358BC-7C4E-4235-A405-C2C839499AA8}.ClientEnd MarketStatementLineItem {C9289981-55CD-40d3-9FB2-9C66EC3AEB17}.SupplierEnd MktUserAttribute {8190276C-7601-4378-973C-AE9F4C42620E}.SupplierEnd adjustedAmount {33178D57-6760-42a0-BC4F-DAC34BADC14C} The charge amount of the productservice. amount {AD6A886A-F200-43ad-ACB2-951FACCCB62D} The price of productservice. price {E508A505-F3C1-4431-BD6A-D9E1BEC893AC} The product quantity. quantity {3124D4DB-BB67-4995-9F52-9068696AC6FB} The tax on services taken. taxAmount {6AA26030-6540-4907-B8DE-4352D10D1009} Delay {BB5EF20F-F668-4cd3-A8C9-5EAA0AD5F5CF}.ClientEnd VSCtype1 {3E4C2CFA-1298-41b3-9038-5F139DAC76C3}.SupplierEnd All blocks of interval reading values to which this pending conversion applies. IntervalBlocks {6805BD0C-43D7-4b31-81D9-807FDA537C71}.ClientEnd Reading type resulting from this pending conversion. ReadingType {498A2163-CE45-41ed-9E07-BE86679D0941}.SupplierEnd A hydro generating unit has a penstock loss curve. HydroGeneratingUnit {7ACC0340-79B7-4e30-B609-66235FA04D5D}.SupplierEnd multiplier {A2810EB7-9B4B-4386-9EE5-CAE5AB1E6E2C} unit {A1336F58-9A3A-462d-A932-4C80CE9A24AB} All line segments described by this set of perlength parameters. DCLineSegments {2DD2B43E-76CD-494b-A33F-018342B6A5C3}.SupplierEnd Capacitance per unit of length of the DC line segment significant for cables only. capacitance {15E50782-BFC5-4868-AB01-397A205F429A} Inductance per unit of length of the DC line segment. inductance {5F8F991E-DBD5-439c-B634-1CBA1A6C8CC2} Resistance per length of the DC line segment. resistance {B64B75B7-7A9B-4a51-A817-628DCF8272BA} All line segments described by this perlength impedance. ACLineSegments {741AE432-C721-4a8d-92F4-C8B96FA98A3A}.SupplierEnd WireAssemblyInfo {07F81D46-A7D6-403d-9687-5A39ABF063FB}.ClientEnd All data that belong to this conductor phase impedance. PhaseImpedanceData {5506602F-6D0E-417e-A8EF-92CE8761DBB1}.SupplierEnd Zero sequence shunt charging susceptance per unit of length. b0ch {19485899-99EC-4153-8DF2-A8D9401CD14D} Positive sequence shunt charging susceptance per unit of length. bch {6BFECEA8-BE4E-401b-9E77-C2DF6A5B8688} Zero sequence shunt charging conductance per unit of length. g0ch {2F22AD1F-E6BD-48ab-AF0C-6FECA9347A61} Positive sequence shunt charging conductance per unit of length. gch {F7751ED0-0F91-48b8-BAE7-23EC99566689} Positive sequence series resistance per unit of length. r {7E44D42E-7317-458c-96BB-A3B855A661EE} Zero sequence series resistance per unit of length. r0 {8D5D71FD-6C26-4fc4-A1EB-A33694E47A0C} Positive sequence series reactance per unit of length. x {46EE2153-4161-4d60-93F1-342C0040A4D4} Zero sequence series reactance per unit of length. x0 {EE0F97E0-7903-463f-B5C2-61B2ACBB2AB5} MarketDocument {07DDBEDE-D21C-439d-AAF4-F347D1B02B1E}.ClientEnd Point {3D8A83E0-5619-4336-8E5E-7157CFB6ACD9}.ClientEnd Reason {E9655504-21F4-4c54-B6E8-8735610776CE}.SupplierEnd TimeSeries {2FF42F79-5F9B-4d18-9FE4-F2D14B85ADD8}.ClientEnd The start and end date and time for a given interval. timeInterval {DD1D6EC4-DA3E-4dc9-B849-543C06A8AA95} Unit in which calculation interval is defined. calculationIntervalUnit {D4D54AA8-3192-4eb7-AB62-BB65E7E0E451} All roles of this person. Roles {0E663BCA-51EE-49c8-AC1A-B4DDD37EBF8D}.SupplierEnd Electronic address. electronicAddress {B6E5566E-3885-474b-ADD7-3AA95C15EA3C} Landline phone number. landlinePhone {68F341A5-D6D0-4324-AEFF-6F52998EB8AD} Mobile phone number. mobilePhone {269C84CE-90F7-41ff-AA62-BCF12E049BA2} ErpPerson {694B40C4-6F8C-41a2-9D1E-27B7A4572BBE}.ClientEnd LandProperty {E882A219-E4D5-4259-AD38-2754C0D502A2}.ClientEnd Person {ABB493E7-418A-4fe4-B85B-23905A057C94}.ClientEnd All appointments for this person. Appointments {C9DF52B7-89D3-4d66-8D7F-13A02C9F8C6A}.SupplierEnd All configuration events created for this person role. ConfigurationEvents {472A820F-DB21-4935-A460-E5C9B71BB861}.SupplierEnd Person having this role. Person {0E663BCA-51EE-49c8-AC1A-B4DDD37EBF8D}.ClientEnd The mode of operation of the Petersen coil. mode {9E0AA2E1-5653-4ebc-B5B4-49027065D01D} The nominal voltage for which the coil is designed. nominalU {E1BE229C-3743-423e-8437-A7F7AEC0C9DD} The offset current that the Petersen coil controller is operating from the resonant point. This is normally a fixed amount for which the controller is configured and could be positive or negative. Typically 0 to 60 A depending on voltage and resonance conditions. offsetCurrent {B1508A24-D2C6-4199-A0A8-03BAED4649F6} The control current used to control the Petersen coil also known as the position current. Typically in the range of 20 mA to 200 mA. positionCurrent {C965BDE0-0426-46b5-A0C2-54956F9AD7EE} The maximum reactance. xGroundMax {1FB3F4FB-2915-4aed-92F5-58D3CD2ECDF5} The minimum reactance. xGroundMin {897F6E69-DAE7-4bd0-96F4-CBD61ED7257F} The nominal reactance. This is the operating point normally over compensation that is defined based on the resonance point in the healthy network condition. The impedance is calculated based on nominal voltage divided by position current. xGroundNominal {84902AD5-0FA1-4993-9BDD-9B736E29961E} Conductor phase impedance to which this data belongs. PhaseImpedance {5506602F-6D0E-417e-A8EF-92CE8761DBB1}.ClientEnd Susceptance matrix element value per length of unit. b {1DEC16E8-BB4B-4129-8426-571BE51A06DF} Refer to the class description. fromPhase {FE4138E8-9EA4-444c-8E8A-FE869BA285E5} Conductance matrix element value per length of unit. g {ABCF69F3-3654-4c50-B79A-732107602E40} Resistance matrix element value per length of unit. r {D98F796A-C101-40df-88AA-716D4B1ADDC6} Refer to the class description. toPhase {4F1C3521-EEBF-4308-BD6A-3FE4E034A175} Reactance matrix element value per length of unit. x {662B9C37-BBE3-4d7f-A8A8-1A351B492DD4} Transformer end to which this phase tap changer belongs. TransformerEnd {1CC9941E-7C40-434a-98D6-B767348B392C}.ClientEnd The phase angle between the inphase winding and the outof phase winding used for creating phase shift. The outofphase winding produces what is known as the difference voltage. Setting this angle to 90 degrees is not the same as a symmetrical transformer. The attribute can only be multiples of 30 degrees. The allowed range is 150 degrees to 150 degrees excluding 0. windingConnectionAngle {73F12408-9962-4614-8F76-9276D859E042} Phase shift per step position. A positive value indicates a positive angle variation from the Terminal at the PowerTransformerEnd where the TapChanger is located into the transformer.The actual phase shift increment might be more accurately computed from the symmetrical or asymmetrical models or a tap step table lookup if those are available. stepPhaseShiftIncrement {0A0AF042-84CF-4e48-996A-60122C60C8C7} The reactance depends on the tap position according to a u shaped curve. The maximum reactance xMax appears at the low and high tap positions. Depending on the u curve the attribute can be either higher or lower than PowerTransformerEnd.x. xMax {03CCD0FC-F097-4b6c-B818-30E1C538B4CC} The reactance depends on the tap position according to a u shaped curve. The minimum reactance xMin appears at the mid tap position. PowerTransformerEnd.x shall be consistent with PhaseTapChangerLinear.xMin and PhaseTapChangerNonLinear.xMin. In case of inconsistency PowerTransformerEnd.x shall be used. xMin {E65A4D9F-3409-4701-BCFA-927E64603CC6} The voltage step increment on the out of phase winding the PowerTransformerEnd where the TapChanger is located specified in percent of rated voltage of the PowerTransformerEnd. A positive value means a positive voltage variation from the Terminal at the PowerTransformerEnd where the TapChanger is located into the transformer.When the increment is negative the voltage decreases when the tap step increases. voltageStepIncrement {5CB8CF11-E238-4e2b-A64C-4D6F353E8BD7} The reactance depends on the tap position according to a u shaped curve. The maximum reactance xMax appears at the low and high tap positions. Depending on the u curve the attribute can be either higher or lower than PowerTransformerEnd.x. xMax {85F2E96A-037E-49cb-A502-52D5D496ECBF} The reactance depend on the tap position according to a u shaped curve. The minimum reactance xMin appear at the mid tap position. PowerTransformerEnd.x shall be consistent with PhaseTapChangerLinear.xMin and PhaseTapChangerNonLinear.xMin. In case of inconsistency PowerTransformerEnd.x shall be used. xMin {0E3B5325-2A89-476d-9A79-CD4ACD14C5FE} The points of this table. PhaseTapChangerTablePoint {8FA5B368-A444-46c0-8ABF-395C08B18AEA}.ClientEnd The phase tap changers to which this phase tap table applies. PhaseTapChangerTabular {C44C5EDF-9A90-4699-8F22-C6DB647DA10B}.SupplierEnd The table of this point. PhaseTapChangerTable {8FA5B368-A444-46c0-8ABF-395C08B18AEA}.SupplierEnd The angle difference in degrees. A positive value indicates a positive angle variation from the Terminal at the PowerTransformerEnd where the TapChanger is located into the transformer. angle {7D40B9B7-F9FC-45a0-A7CE-28D3DC182E4D} The phase tap changer table for this phase tap changer. PhaseTapChangerTable {C44C5EDF-9A90-4699-8F22-C6DB647DA10B}.ClientEnd Condition contributing to the classification of this phenomenon. ClassificationCondition {0E97F0E1-C420-4b89-983A-670FE0F14582}.ClientEnd Authority defining this environmental phenomenon. EnvironmentalDataAuthority {A0D7C120-ECE6-4c9b-B9F6-B37F0029DA01}.SupplierEnd EnvironmentalPhenomenon {CEAA1D59-2A12-4a25-A69D-ACC8789B4E11}.ClientEnd The branch group that should be used in compare. BranchGroup {CB739CC6-8BA5-4ceb-BD00-62D8654B263A}.SupplierEnd The compare operation done on the branch group. kind {E23F693A-5C82-4520-8600-24F5D9399438} The Equipment that should be used in compare. Equipment {83B2D8C8-5F34-4fbe-A13F-090F6823061D}.SupplierEnd The compare operation done on the equipment. kind {BE6A78EC-8295-48c4-8956-E03F158C1853} GateOutput {71584FA4-43BB-4d8b-84DF-B578C3B8580C}.ClientEnd The Measurement that should be used in compare. Measurement {D94A460B-0ABB-4872-900D-CDEEB9374DB3}.SupplierEnd Result of the calculation used as input to a gate. MeasurementCalculator {CFBABACD-D1FC-46de-8BA7-DA6F2F4B3CC9}.ClientEnd The Terminal that should be used in compare. Terminal {70327476-E811-4a87-97E1-35C5519C96DC}.SupplierEnd The compare operation done on the terminal. kind {EFEF51B4-E261-43f7-AE5A-4C78383F9CC9} A market plan has a number of markets DA HA RT. MarketPlan {9939F0DA-F147-4cab-A25A-C40C674AF836}.ClientEnd A planned market could have multiple market runs for the reason that a planned market could have a rerun. MarketRun {E537509E-3F2D-41ba-881E-85BABB782FC0}.SupplierEnd A planned market shall have a set of planned events PlannedMarketEvent {05AB4FB1-EAD5-41a2-A114-2A1E55AD4E0B}.SupplierEnd Market type. marketType {A36284FB-32CA-4120-9EEA-30D4848E0F2D} All actual events that execute this planned event. MarketActualEvent {6F2C5CBA-31FA-4fbf-93FC-0732720881FC}.ClientEnd A planned market shall have a set of planned events PlannedMarket {05AB4FB1-EAD5-41a2-A114-2A1E55AD4E0B}.ClientEnd FieldDispatchHistory {37072B50-0229-4a00-A050-8976613B5259}.ClientEnd Outage plan for executing a planned outage. OutagePlan {D5052A16-C1AA-4cfa-B0E4-1C79BE08873C}.ClientEnd All updated ratings for this planned equipment outage. UpdatedRatings {C5F3A5B0-064B-4cc4-AA34-0296D8D7919A}.ClientEnd Customer {C3BE4896-4663-4669-84A9-B881796117E5}.SupplierEnd SwitchingPlan {D86059AA-B4DC-4561-AA64-9EF56A447F18}.SupplierEnd AggregateNode {CAB06BAC-94AA-411c-9272-D4C6EB676F32}.ClientEnd CommodityDefinition {F9E2DDE2-0FFA-44c6-9186-CCF290EFA2ED}.ClientEnd DeliveryTransactionBids {34A3B7CA-5000-4f2c-85C0-4A822CE31BA9}.SupplierEnd ExPostResults {E05F725E-CEBB-458d-9E58-0F2247135211}.SupplierEnd FTRs {A43D8B73-D014-475b-8461-B03EC8169BB8}.ClientEnd Allows Measurements to be associated to Pnodes. MktMeasurement {72AD4107-7210-4172-B722-F58EA3179E3E}.SupplierEnd OrgPnodeAllocation {94E0B2E3-2515-46e5-ACE3-EE9FFB04B4EA}.ClientEnd PnodeResults {2F4D2395-38CC-4e92-B4E4-A65606A9903C}.SupplierEnd RTO {226E4117-5AE6-4526-BD59-AE3741B82CD9}.ClientEnd ReceiptTransactionBids {ACB6DCFB-9B97-4ab9-AE5A-A643C314A45D}.SupplierEnd A registered resource injects power at one or more connectivity nodes related to a pnode RegisteredResources {6A346D84-A25C-41c8-8AFD-BB63272C9F39}.SupplierEnd SinkCRRSegment {6840ECDE-F677-428f-9118-D01BDF989AE0}.SupplierEnd SourceCRRSegment {C97DA9A4-D136-4894-A6A2-CA207A447300}.SupplierEnd SubControlArea {EE82157A-8E48-4af6-9DC9-7A0098943EE0}.SupplierEnd Trade {D878BD22-6A72-4e0c-8DFA-7844C9BCA884}.SupplierEnd CommodityPrice {B037CDCC-4EA4-4d2d-8CF4-27BBEFA157FC}.SupplierEnd PnodeResults {BD964F65-1835-43f0-9378-E63CB1D35575}.SupplierEnd AggregatedPnode {C455B6B7-BDE8-4036-B32B-EFD8413FD6B7}.ClientEnd BidDistributionFactor {92BD0FDA-3BFA-4ea4-9233-9C19F31CCB39}.ClientEnd IndividualPnode {24E9F23C-430E-4596-B763-07DB8054801D}.ClientEnd Indication that this distribution factor is to apply during off peak. offPeak {403623AD-6F2D-4f82-8618-65C566EBCB23} Indication that this factor is to apply during Peak periods. onPeak {3264FF8A-5DA4-4a33-85F7-0AD012EAC3A3} Pnode {2F4D2395-38CC-4e92-B4E4-A65606A9903C}.ClientEnd PnodeClearing {BD964F65-1835-43f0-9378-E63CB1D35575}.ClientEnd updateType {78192DBC-041C-47f1-97CA-8C6FF75ECFF6} AceTariffType {BABB4FDB-5AA4-4c38-80B1-35F9E79D3BAE}.SupplierEnd FlowDirection {DA5D6A56-1992-4d38-994D-E118A3CDC921}.ClientEnd Period {3D8A83E0-5619-4336-8E5E-7157CFB6ACD9}.SupplierEnd Price {F4D10473-017B-4e8a-95D0-6C83335A55CB}.ClientEnd Quantity {70A03E37-CDFC-438e-BB13-DBBD82A9288E}.ClientEnd Reason {5937F13C-6809-4fd4-9A5E-CC24BE6B8CA7}.ClientEnd TimeSeries {E778FB34-70AF-4315-A61A-98894C17384B}.SupplierEnd All shifts this point of sale operated in. CashierShifts {5F23BDB7-8C52-4be9-BDFD-61927D2EA76C}.ClientEnd All streetlights attached to this pole. Streetlights {7CD98E1E-DB38-4f5f-B4AB-606B687CE71D}.SupplierEnd Kind of base for this pole. baseKind {624A4E48-10A0-4ab3-A7B4-8E81D1533FD0} Diameter of the pole. diameter {D98F5A13-BF6D-4ad0-A7D0-C58D478FC2CE} Length of the pole inclusive of any section of the pole that may be underground postinstallation. length {07335125-0D59-4779-9824-D767C3E0FDD4} Kind of preservative for this pole. preservativeKind {BEB20D48-1F28-4073-8A40-B0CF0E81670B} Kind of treatment for this pole. treatmentKind {11E35D3E-7280-4641-9746-9F283AFE6964} Location described by this position point. Location {DBF35456-ABE1-4deb-A885-2E48B3D6F8F6}.ClientEnd Potential transformer construction type. type {EBA48103-D1D0-40ca-A26E-1192BB845D6B} nominalRatio {DE855743-0E60-46a8-BF3B-DF1F23D95114} Ratio for the primary winding tap changer. primaryRatio {A5150EE5-BFDD-4a2e-BB70-C2E92F558421} Rated voltage on the primary side. ratedVoltage {F7E6C2CB-1DFE-4249-9440-837196C8F912} Ratio for the secondary winding tap changer. secondaryRatio {BE6A3168-8DD7-48ef-80AE-0C2C8E680535} Ratio for the tertiary winding tap changer. tertiaryRatio {00C30FD6-1010-4aad-9D11-E2DE46FCD426} Energy consumer is assigned to the power cut zone. EnergyConsumers {10EFC7AF-BD27-4bf9-A05B-BA2A5970F59A}.SupplierEnd First level amount of load to cut as a percentage of total zone load. cutLevel1 {DB7E760E-68D5-47b3-B342-CA51A4134645} Second level amount of load to cut as a percentage of total zone load. cutLevel2 {84DC2C8B-8922-4736-A581-3989CB5D79FB} The individual phases models for the power electronics connection. PowerElectronicsConnectionPhase {99A71DC5-9620-460a-B0F1-AE69019A3DB9}.SupplierEnd An AC network connection may have several power electronics units connecting through it. PowerElectronicsUnit {8AC914EE-116B-477b-A122-C5E4A57DECDE}.SupplierEnd The wind turbine type 3 or type 4 dynamics model associated with this power electronics connection. WindTurbineType3or4Dynamics {55DFB003-A30A-4242-A110-1251E461ED28}.ClientEnd Maximum fault current this device will contribute in perunit of rated current before the converter protection will trip or bypass. maxIFault {9E9630BE-7754-4d85-A4A9-D48ED99DB232} Maximum reactive power limit. This is the maximum nameplate limit for the unit. maxQ {923BD813-8AFE-4d59-89ED-D9E09A386346} Minimum reactive power limit for the unit. This is the minimum nameplate limit for the unit. minQ {50765898-4B48-40ad-8D81-0544B670F0CA} Active power injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for a steady state solution. p {E50A8D52-31FA-46ce-A1A7-1A680426BCE0} Reactive power injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for a steady state solution. q {653A93F9-690F-4825-8C09-B75BC246100B} Equivalent resistance RG of generator. RG is considered for the calculation of all currents except for the calculation of the peak current ip. Used for short circuit data exchange according to IEC 60909. r {981CA1B3-83EF-46c2-BAC5-BF1A66770D46} Zero sequence resistance of the synchronous machine. r0 {C264E3E0-424B-4042-B6BB-B8D2E54E29BC} Nameplate apparent power rating for the unit.The attribute shall have a positive value. ratedS {AF84AC1B-4955-464e-BCC2-F4DAE8E96958} Rated voltage nameplate data Ur in IEC 609090. It is primarily used for short circuit data exchange according to IEC 60909.The attribute shall be a positive value. ratedU {07C8D926-E1AA-4271-8FED-BE90CAB30360} Negative sequence Thevenin resistance. rn {A4C54A90-737E-467e-8AE4-F86A7E30E637} Positive sequence Thevenin reactance. x {F091C7E2-D681-44f0-B0E1-7F74529A9B93} Zero sequence Thevenin reactance. x0 {B70E3ED7-0B60-44f4-A893-9E40B93AD501} Negative sequence Thevenin reactance. xn {D46879D7-923F-4270-94B0-53E739144605} Power electronics connection of this power electronics connection phase. PowerElectronicsConnection {99A71DC5-9620-460a-B0F1-AE69019A3DB9}.ClientEnd Active power injection. Load sign convention is used i.e. positive sign means flow into the equipment from the network. p {3C2706EB-9824-4f51-BC9E-568AE958790F} Phase of this energy producer component. If the energy producer is wye connected the connection is from the indicated phase to the central ground or neutral point. If the energy producer is delta connected the phase indicates an energy producer connected from the indicated phase to the next logical nonneutral phase. phase {FE3E371D-D600-4c25-83DF-6FAC560B4C5C} Reactive power injection. Load sign convention is used i.e. positive sign means flow into the equipment from the network. q {73316C88-88F9-4b33-84AE-4D9A2A3F8B5A} A power electronics unit has a connection to the AC network. PowerElectronicsConnection {8AC914EE-116B-477b-A122-C5E4A57DECDE}.ClientEnd Maximum active power limit. This is the maximum nameplate limit for the unit. maxP {7E4ECD94-7AF7-4272-B3A0-9D43EB43396B} Minimum active power limit. This is the minimum nameplate limit for the unit. minP {A00BE308-7FF6-494b-AC6D-4F0EF01F6D84} Emergency high voltage limit. emergencyHighVoltLimit {53493219-2615-4730-B13F-FD3B8110A474} Emergency low voltage limit. emergencyLowVoltLimit {3C73A8F4-962D-4adc-B790-2AE44E40DC45} Normal high voltage limit. normalHighVoltLimit {3121953F-E24E-4330-BF3F-C6855B0B9658} Normal low voltage limit. normalLowVoltLimit {733F6E47-0C19-4434-938B-6C3F220A8ECA} Value of uninterrupted service Cost per energy. valueUninterruptedServiceEnergy {48C24858-8B1B-48e0-933E-AF52E7748427} Datasheet information for this power system resource. AssetDatasheet {009BA3E8-B2DD-4bef-B118-F700692FC9EA}.ClientEnd All assets represented by this power system resource. For example multiple conductor assets are electrically modelled as a single AC line segment. Assets {9709C87C-3A85-4ce4-BA02-CEBB104E7DB5}.ClientEnd All clearances applicable to this power system resource. Clearances {65134A4B-0FD0-4c17-A353-8696C19D36F6}.ClientEnd ConfigurationEvent {26DFEBF9-D038-4c7e-96A1-F4832AC44307}.SupplierEnd The controller outputs used to actually govern a regulating device e.g. the magnetization of a synchronous machine or capacitor bank breaker actuator. Controls {A1BE05F6-8AA3-4c36-B00D-9A3BC3D8B4D3}.SupplierEnd GenericAction {7F56BF7C-C7AA-432b-8454-59AE37E0C7F8}.ClientEnd Location of this power system resource. Location {9F4B30FA-0A66-4ce4-9A00-413B0DB058C7}.ClientEnd The measurements associated with this power system resource. Measurements {78186A65-461E-4479-9917-94B5C4F2F9F6}.SupplierEnd The operating shares of this power system resource. OperatingShare {343B3487-FA8E-4906-A8F1-4D6E3B27F4AF}.ClientEnd All operational tags placed on this power system resource. OperationalTags {AB49BFBC-0F00-4bf2-95B2-BCBAD3CA1BA5}.ClientEnd All events associated with this power system resource. PSREvents {8A1816B8-B53E-4ace-9651-A32675F78437}.ClientEnd Custom classification for this power system resource. PSRType {739158B5-6CE8-473f-87FF-1CDA17078612}.SupplierEnd Reporting groups to which this power system resource belongs. ReportingGroup {62E3FEEC-F7FE-4ee8-88DC-231AEF7F6DE3}.ClientEnd VerificationAction {4F85BB5D-133B-4060-B422-86E5B9320EE2}.ClientEnd Excitation system model with which this power system stabilizer model is associated. ExcitationSystemDynamics {EC18A533-5643-4fe6-87AE-2182DD4C9F1F}.SupplierEnd Remote input signal used by this power system stabilizer model. RemoteInputSignal {57187DF7-A206-4e9a-BEB5-C8CEE8478241}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {7EC302C9-2A4C-4779-A3DB-B8F2587D9C33}.ClientEnd The ends of this power transformer. PowerTransformerEnd {AAC9230B-982D-4588-BD28-882E60820FEA}.SupplierEnd All transformers that belong to this bank. TransformerTanks {732D3510-8B59-4b75-8EBD-5E7EFC0BD19D}.ClientEnd The highest operating current Ib in IEC 609090 before short circuit depends on network configuration and relevant reliability philosophy. It is used for calculation of the impedance correction factor KT defined in IEC 609090. beforeShCircuitHighestOperatingCurrent {AE4EA8D2-F7DE-4b53-BB69-AC364144A1CF} The highest operating voltage Ub in IEC 609090 before short circuit. It is used for calculation of the impedance correction factor KT defined in IEC 609090. This is worst case voltage on the low side winding 3.7.1 of IEC 609092001. Used to define operating conditions. beforeShCircuitHighestOperatingVoltage {4E3E92DC-A260-4f23-87CC-E569FF4567A7} The angle of power factor before short circuit phib in IEC 609090. It is used for calculation of the impedance correction factor KT defined in IEC 609090. This is the worst case power factor. Used to define operating conditions. beforeShortCircuitAnglePf {041C6D4A-4D33-416b-869F-3546D7B28527} The minimum operating voltage uQmin in IEC 609090 at the high voltage side Q side of the unit transformer of the power station unit. A value well established from longterm operating experience of the system. It is used for calculation of the impedance correction factor KG defined in IEC 609090. highSideMinOperatingU {B621D953-1CCB-4d6e-AE7D-6231CCE96831} The power transformer of this power transformer end. PowerTransformer {AAC9230B-982D-4588-BD28-882E60820FEA}.ClientEnd Magnetizing branch susceptance B mag. The value can be positive or negative. b {049B7FAE-6F21-4fa4-9BDC-744C262C99AB} Zero sequence magnetizing branch susceptance. b0 {9F90313E-3782-459e-A4BC-66938E5A52F5} Kind of connection. connectionKind {BC71F2C6-F76B-459a-A7AF-04800FBD1AE6} Magnetizing branch conductance. g {1DB7A689-A778-4f98-821B-549122D33482} Zero sequence magnetizing branch conductance starmodel. g0 {40582586-E7A8-4d85-9328-02F6B38300A1} Resistance starmodel of the transformer end.The attribute shall be equal to or greater than zero for nonequivalent transformers. r {7B85D922-082E-482e-A2FB-D2164647BE6E} Zero sequence series resistance starmodel of the transformer end. r0 {ED74BF4C-8DAC-425b-9352-4051C611F9BC} Normal apparent power rating.The attribute shall be a positive value. For a twowinding transformer the values for the high and low voltage sides shall be identical. ratedS {03C41DCA-8576-4294-B1A4-64D6289BC413} Rated voltage phasephase for threephase windings and either phasephase or phaseneutral for singlephase windings.A high voltage side as given by TransformerEnd.endNumber shall have a ratedU that is greater than or equal to ratedU for the lower voltage sides.The attribute shall be a positive value. ratedU {38795744-6A3E-4a62-A8D9-E3FCF020A456} Positive sequence series reactance starmodel of the transformer end. x {0DDEF3C0-D3D0-475e-8C6F-D7363D0E5AF4} Zero sequence series reactance of the transformer end. x0 {9F61AC19-7526-4234-AB78-F7FC96E9833F} Data for all the tanks described by this power transformer data. TransformerTankInfos {C20239B0-27AB-4040-9B55-35834EB98EDC}.ClientEnd multiplier {AD8A8750-8E4A-4e85-87DF-E1E986A67FBA} unit {6D35CBFE-ECA6-4cdd-B823-9E7AC7B978D6} Domain {58FBC0F0-40DD-4dbd-A8BE-9C241403F4DB}.SupplierEnd Point {F4D10473-017B-4e8a-95D0-6C83335A55CB}.SupplierEnd TimeSeries {76FC513C-3CAE-45e6-9CD8-53B33147F936}.SupplierEnd CommodityPrice {0E804F54-A29B-4452-B7D6-078FE7D84D1F}.ClientEnd The time frame for the price using the standard conventions associated with the MarketType enumeration. marketType {4E6648A6-B0B8-4314-A3BA-B5BC6FA737AC} The kind of price being described. In general the priceType will either be total to signify that the price is the price paid to buy or sell the commodity sometimes referred to as an allin price or one of potentially many components. priceType {5FDB37AC-5F5B-4580-A8EA-D994C2E04281} All customer agreements with this pricing structure. CustomerAgreements {2EF6BAD9-95F9-48bf-9408-24054A043C0F}.ClientEnd Service category to which this pricing structure applies. ServiceCategory {4940002E-34B8-4d2b-96A5-2E4EC7A20FF2}.ClientEnd All tariffs used by this pricing structure. Tariffs {680631D0-BB57-456d-A598-1F9D4D60D510}.SupplierEnd All transactions applying this pricing structure. Transactions {25EA2CE6-048D-4220-8F20-CA27D99F9BAE}.SupplierEnd All service delivery points with prepayment meter running as a standalone device with no CustomerAgreement or Customer to which this pricing structure applies. UsagePoints {E0F674C9-204B-4aa1-9887-8B17137752E6}.SupplierEnd accounting Kind of revenue often used to determine the grace period allowed before collection actions are taken on a customer grace periods vary between revenue classes. revenueKind {9C08315F-A074-429a-A117-3870EAACDD77} Synchronous machines this Prime mover drives. SynchronousMachines {9C153102-5D80-4895-9BF2-7371CA48A80D}.SupplierEnd All assets to which this procedure applies. Assets {3458C266-F6A0-4e72-8A55-BFFF83421DE2}.SupplierEnd CompatibleUnits {A0D146CA-A291-4aa2-8C93-C33AFCBB974E}.ClientEnd Limits {B58288B5-634A-4da2-AF81-FC8EE0EB0F45}.SupplierEnd Document containing this measurement. Measurements {FEA58AE6-6428-4541-9097-FEFB35D64AD7}.SupplierEnd All data sets captured by this procedure. ProcedureDataSets {BBF99755-5B8E-4ec2-9DBC-F1E8BD1714ED}.SupplierEnd Kind of procedure. kind {622F03BF-37D4-4cc6-A997-5D10A488B99F} Asset to which this procedure data set applies. Asset {F1E16F01-CC4F-4170-9610-3C1C6E17A43F}.SupplierEnd MeasurementValue {A0C93754-F2B4-4597-96C0-BDCA60E5BC09}.SupplierEnd Procedure capturing this data set. Procedure {BBF99755-5B8E-4ec2-9DBC-F1E8BD1714ED}.ClientEnd UserAttributes used to specify further properties of this procedure data set. Use name to specify what kind of property it is and value.value attribute for the actual value. Properties {779BA9D1-950E-4184-B4C5-D887B32ECEDB}.ClientEnd TransformerObservations {8D7EAE31-2FA3-4a2f-84AC-416327FD5679}.SupplierEnd Work task that created this procedure data set. WorkTask {78EB6E9E-9B0C-466e-B813-E041B622EF3D}.SupplierEnd MarketDocument {02A672D8-0CED-4250-99DC-0E425C62E548}.SupplierEnd An asset of this model. Asset {24E0529D-66B4-4bd0-BE95-E9F7A501079C}.ClientEnd Asset information nameplate for this product asset model. AssetInfo {C53749B6-0642-4045-81C7-6DC6CDBC280D}.SupplierEnd AssetModelCatalogueItems {4AAC30DE-2757-4a42-BD3F-E6C4713581FA}.SupplierEnd Catalog asset type to which this product asset model conforms. CatalogAssetType {2558E36F-4A9B-4eab-B70C-B1D8802138AE}.SupplierEnd Manufacturer of this asset model. Manufacturer {4B21049D-BA80-4bd7-A107-BD54730986AA}.SupplierEnd All operational restrictions applying to this asset model. OperationalRestrictions {52B7FEC7-526D-4b4e-8839-1C5E1DE7D0A4}.ClientEnd Kind of corporate standard for this asset model. corporateStandardKind {BB1C84F5-BD18-4030-A6BF-76BDB18B182F} Overall length of this asset model. overallLength {1D1B7E6D-C796-4ea3-BE5C-E190FD99677F} Intended usage for this asset model. usageKind {D588FE49-9E84-416d-A061-0F2C2A66CEBD} Total manufactured weight of asset. weightTotal {5BA8CFE6-3E0B-4d77-8910-62D0B57A2537} A bid comprises one or more product bids of market products Bid {BCC6B1A9-977E-41f0-9C3A-DDB18F4AA27F}.SupplierEnd BidDistributionFactor {566D5A4B-E23C-4c3e-81A6-C484F10859CC}.SupplierEnd BidHourlyProductSchedule {ED4A9CB4-F670-45e4-B569-BC258596026F}.ClientEnd BidSchedule {E6A900FF-246B-49e3-8F19-A2DBF2BB4BB5}.SupplierEnd BidSelfSched {62141B29-E60E-480d-B668-C305C09264D7}.SupplierEnd MarketProduct {E7348A42-CD3B-49ba-B555-9BE41638E702}.ClientEnd The data sets that make use of the profile. DataSet {A554D44F-37A9-44b7-878F-CDC356BA0B3A}.ClientEnd A profile has profile data associated with it. ProfileDatas {4E6C16FA-9BCA-473a-841B-EB80A9400115}.ClientEnd A profile has profile data associated with it. Profile {4E6C16FA-9BCA-473a-841B-EB80A9400115}.SupplierEnd Capacity level for the profile in MW. capacityLevel {4C847B36-679A-4036-9C3B-B42AD11BAB02} Energy level for the profile in MWH. energyLevel {E6477DF2-D56C-4bb1-A721-AAF48E6C609E} BusinessCase {3E0CE628-2617-4405-B164-788B1A9E8408}.ClientEnd ErpProjectAccounting {55D017C7-9C0F-40fb-81EF-FC182E6BDAAE}.ClientEnd ParentProject {21F63393-A2CF-4d44-A733-C5191FBFB5E1}.ClientEnd SubProjects {21F63393-A2CF-4d44-A733-C5191FBFB5E1}.SupplierEnd Works {FD74BD30-960D-447e-B2BA-F87F95FF9001}.ClientEnd Overall project budget. budget {92E4D4E2-B3DF-4940-9EAA-EA899D2D51DD} LandProperty {125BFBC7-E66A-4486-A898-CE2D1087BB13}.ClientEnd CUMaterialItems {EBAAAA49-96BE-4f07-8F12-EAF5BDD82A20}.SupplierEnd CompatibleUnits {730C905B-BBFC-44aa-A988-5BCE91C46E12}.SupplierEnd WorkCostDetails {A4CC1ED7-99AE-40a3-8386-8274E4C431D9}.ClientEnd Activity code identifies a specific and distinguishable work action. activityCode {2974AAA7-F19D-4001-8DE1-65656B62A853} status {F4B6353B-20EA-4317-938E-796D5052841C} distributionFactor {0BF94D9F-91D4-4536-B51C-E765D72885A2} Proprietary userdefined model with which this parameter is associated. AsynchronousMachineUserDefined {D22E87BF-F1D2-49ef-B02C-1F3F666251B8}.SupplierEnd Proprietary userdefined model with which this parameter is associated. CSCUserDefined {BDBA0EFE-6EA8-41c4-B3E1-5DE008753AF0}.ClientEnd Proprietary userdefined model with which this parameter is associated. DiscontinuousExcitationControlUserDefined {2215F246-53D4-4620-8772-22C2E52230A8}.SupplierEnd Proprietary userdefined model with which this parameter is associated. ExcitationSystemUserDefined {5206A5D1-9E7E-4283-B6EF-7F3C51885F61}.SupplierEnd Proprietary userdefined model with which this parameter is associated. LoadUserDefined {42F5637B-59FE-4442-AC86-EC1605637C40}.SupplierEnd Proprietary userdefined model with which this parameter is associated. MechanicalLoadUserDefined {16E261AB-0A61-4015-A4AF-C0D1E3AADE99}.SupplierEnd Proprietary userdefined model with which this parameter is associated. OverexcitationLimiterUserDefined {8154CFB5-D525-420f-B290-005306255D1B}.SupplierEnd Proprietary userdefined model with which this parameter is associated. PFVArControllerType1UserDefined {836BD709-E07C-4f9e-A2CD-CD5C69C06B2A}.SupplierEnd Proprietary userdefined model with which this parameter is associated. PFVArControllerType2UserDefined {1FD4D65B-F0C9-4390-8928-11A647913605}.SupplierEnd Proprietary userdefined model with which this parameter is associated. PowerSystemStabilizerUserDefined {7EC302C9-2A4C-4779-A3DB-B8F2587D9C33}.SupplierEnd Proprietary userdefined model with which this parameter is associated. SVCUserDefined {16A60C5C-8F8E-4e74-BF69-62A6C79FF350}.ClientEnd Proprietary userdefined model with which this parameter is associated. SynchronousMachineUserDefined {996B609E-F446-4d2f-89B1-0A3771AD65C2}.SupplierEnd Proprietary userdefined model with which this parameter is associated. TurbineGovernorUserDefined {E9CE179B-FE93-40fa-AF55-290AFD448CA7}.SupplierEnd Proprietary userdefined model with which this parameter is associated. TurbineLoadControllerUserDefined {B43C2066-FB4C-497e-9C4F-E259EF67913D}.SupplierEnd Proprietary userdefined model with which this parameter is associated. UnderexcitationLimiterUserDefined {B7D39B4A-5132-4f2d-8450-A510C4F0B92A}.SupplierEnd Proprietary userdefined model with which this parameter is associated. VSCUserDefined {AB07F11F-12BF-40f7-A3A5-86F42927D688}.ClientEnd Proprietary userdefined model with which this parameter is associated. VoltageAdjusterUserDefined {DF4D0AAC-C129-47a1-ADAF-DB0071F13178}.SupplierEnd Proprietary userdefined model with which this parameter is associated. VoltageCompensatorUserDefined {8A60B7E2-A760-4eba-9D83-DDFC09AE0C14}.SupplierEnd Proprietary userdefined model with which this parameter is associated. WindPlantUserDefined {92B518F0-1BFC-4f7d-A5E3-B076C3298208}.ClientEnd Proprietary userdefined model with which this parameter is associated. WindType1or2UserDefined {88DDF410-39C9-46c0-AC56-EC92DA7D9E97}.ClientEnd Proprietary userdefined model with which this parameter is associated. WindType3or4UserDefined {7F96DE9C-5421-45cc-A5C5-B8C03C2B4B23}.ClientEnd Protection equipments that operate this ProtectedSwitch. OperatedByProtectionEquipment {AEDB116C-6830-4d8b-96FA-C4ADA5EFF5CB}.ClientEnd A breaker may have zero or more automatic reclosures after a trip occurs. RecloseSequences {6447ED06-EC4F-4efc-88F3-7FB21521C7FC}.ClientEnd The maximum fault current a breaking device can break safely under prescribed conditions of use. breakingCapacity {52EB29C5-1F53-46e6-84EC-400C4B5AF75F} Protection equipment may be used to protect specific conducting equipment. ConductingEquipments {1A223051-2D2E-4ca4-8FF1-9C8D1BDE000B}.SupplierEnd Protected switches operated by this ProtectionEquipment. ProtectedSwitches {AEDB116C-6830-4d8b-96FA-C4ADA5EFF5CB}.SupplierEnd Protective action can emulate the action done by one or more protection equipment. In a node breaker model were protective equipment is model this association will be used. ProtectiveAction {F800024C-67E3-43ed-8940-DC3AA37C7171}.SupplierEnd The time delay from detection of abnormal conditions to relay operation. relayDelayTime {5C71AC12-B479-4721-892B-CED42C5F9CA9} The unit multiplier of the value. unitMultiplier {ED1638AD-1A5B-45ec-B4B3-FE9F63AF652D} The unit of measure of the value. unitSymbol {23D1C552-3A55-4563-A003-1120FEE90AAE} Actual ground trip for this type of relay if applicable. groundTrip {B9914730-5FE2-4932-8C55-5A129880D5DB} Actual phase trip for this type of relay if applicable. phaseTrip {12416897-F0DB-44d8-99DF-038EA4B370F5} GateComCondition {D34B99BA-6D10-4f96-88B9-7AD3024A8166}.SupplierEnd Association to a Gate that through a gate logic and input pin defines enabling of the ProtectiveAction. GateEnabledCondition {1A878962-D12D-4598-ADE4-4D8B2DDE6CA7}.SupplierEnd ProtectionEquipment {F800024C-67E3-43ed-8940-DC3AA37C7171}.ClientEnd ProtectiveActionCollection {010F7F0E-C9F9-4f9e-A4BA-61BCFAFC99D7}.ClientEnd ConductingEquipment whose operating condition is changed when this protective action adjustment gets activated. ConductingEquipment {44AD5B78-D603-43d9-A73C-68DCFE8B9C09}.ClientEnd The operating condition to the Conducting Equipment is changed when protective action adjustment is activated. DCConductingEquipment {83F32DD1-007E-48c2-AD47-79FF388FCEDF}.SupplierEnd The measurement is used to control the operation of an equipment. Measurement {9685ABB8-FD59-47dc-891C-CFC7E0CC0A6F}.ClientEnd The adjustment is given in percent of the active value. byPercentage {78CF5B22-20FA-4227-938B-B92D200F57E1} Defines the kind of adjustment that should be done. With this value the correct attribute containing the value needs to be used. kind {89F17D7E-BFBA-406e-91C8-14A649F3F8CA} Set of ProtectiveAction belonging to a ProtectiveActionCollection. ProtectiveAction {010F7F0E-C9F9-4f9e-A4BA-61BCFAFC99D7}.SupplierEnd When condition to the StageTrigger is met the actions in the ProtectiveActionCollection are activatedtriggered. StageTrigger {E36506E6-0D19-4846-93FA-EA04CBD6AC84}.SupplierEnd Equipment {C2B4064B-C361-4230-9F19-21614F4EFABE}.SupplierEnd RegulatingControl {2FDA9413-8CFA-434f-8187-40289D0A95BA}.SupplierEnd Remote peer that will receive ICCP information in a Bilateral table. BilateralExchangeActor {D71D178C-4ECF-4cf5-A2F9-02324DC52065}.SupplierEnd Measurement or control for the bilateral ICCP point. IOPoint {D2E53A93-0C08-4243-8A32-01EF61C12DBB}.ClientEnd Minimum power PSS enabling iPmini. Typical value 025. pmin {D1BC7E22-C311-46c5-BCD1-7D0E17C75813} Leadlag time constant iTiisub10subi gt 0. Typical value 0. t10 {70693E88-D22B-4f77-915D-E4B7E7FFA527} Washout iTiisub5subi gt 0. Typical value 35. t5 {89FC20AE-5F4D-49ab-9B9A-EE5CDAEDC377} Filter time constant iTiisub6subi gt 0. Typical value 0. t6 {CB40BBB5-10C1-48f4-8D0D-DB0DC8132F65} Leadlag time constant iTiisub7subi gt 0. If 0 both blocks are bypassed. Typical value 0. t7 {B1ACDEAB-EC5D-4fe8-BAC6-4E44A25DC539} Leadlag time constant iTiisub8subi gt 0. Typical value 0. t8 {A4B89A31-6631-4501-9E0F-7615193D55CE} Leadlag time constant iTiisub9subi gt 0. If 0 both blocks are bypassed. Typical value 0. t9 {37C2987F-6FEA-4f8e-9B13-8633B1B4BEC6} Electric power filter time constant iTiisubPEsubi gt 0. Typical value 005. tpe {207ED9A0-EE7A-4337-8985-86693BB79299} Stabilizer output maximum limit iViisubSMNsubi. Typical value 006. vsmn {9B53532B-528A-48f9-AD6A-2C79864D8156} Stabilizer output minimum limit iViisubSMXsubi. Typical value 006. vsmx {DE083CFE-9A2E-44f2-9A9C-BC746A6B14FE} Notch filter parameter iAiisub1subi. a1 {18432371-9711-49b6-B1E3-36801F34C756} Notch filter parameter iAiisub2subi. a2 {BD0FBD73-A34E-4b53-B8ED-1E2D32B0C557} Notch filter parameter iAiisub3subi. a3 {DD1DAC48-A59F-4da9-A350-B7F6B3A57338} Notch filter parameter iAiisub4subi. a4 {2A824CFC-A7F1-4ebe-A191-4D2E2D51FC7C} Notch filter parameter iAiisub5subi. a5 {E02771C6-A44B-4b21-9E02-4013371C576C} Notch filter parameter iAiisub6subi. a6 {50A21182-7D54-468a-A17A-4C53486D1664} Notch filter parameter iAiisub7subi. a7 {ED6658F9-1EC8-4b9e-9676-DC40AF1CCCE7} Notch filter parameter iAiisub8subi. a8 {C4CBC178-352C-4ed5-B79E-E6DDBFBC475C} Type of input signal rotorAngularFrequencyDeviation busFrequencyDeviation generatorElectricalPower generatorAcceleratingPower busVoltage or busVoltageDerivative. inputSignalType {2858FCD2-D037-4074-82B5-AD33CEF04C1B} Stabilizer gain iKiisubssubi. ks {4303A89C-5AA6-43a7-A286-35AF5508C5EF} Leadlag time constant iTiisub1subi gt 0. t1 {7BDE7BA3-0B4A-492c-B859-D322F71B8A36} Leadlag time constant iTiisub2subi gt 0. t2 {6CE2A59E-2589-4c97-9EE7-43A2B58DBC54} Leadlag time constant iTiisub3subi gt 0. t3 {E6A8B5CE-3598-49e9-AE4F-B74E409461E7} Leadlag time constant iTiisub4subi gt 0. t4 {6B32F9E5-47E4-42aa-8CDC-C9C979D70DFF} Washout time constant iTiisub5subi gt 0. t5 {40876337-80B0-4c33-BF46-B10E1CA977CF} Transducer time constant iTiisub6subi gt 0. t6 {0BFB60DD-4358-4513-BF1D-1EC4EC342DF5} Time constant iTdelayi gt 0. tdelay {771EE399-66B7-4e17-B1C1-5DF41E2C6DFD} Stabilizer input cutoff threshold iVcli. vcl {88C5C11B-4CA3-4132-9E77-9A607D4917D8} Stabilizer input cutoff threshold iVcui. vcu {DE33EFF0-939C-4369-AA15-97A5446F26C3} Maximum stabilizer output iVrmaxi gt Pss1A.vrmin. vrmax {99706091-CA51-4943-A518-326FC76D3803} Minimum stabilizer output iVrmini lt Pss1A.vrmax. vrmin {1261CBB1-5D73-4fff-84C5-215FE3F49A22} Stabilizer gain iKs1i. Typical value 12. ks1 {F98828C5-A1C2-44fc-B0AF-D784EF3EF827} Gain on signal 2 iKs2i. Typical value 02. ks2 {302E91AA-0C44-428b-A559-CD0A7452186A} Gain on signal 2 input before ramptracking filter iKs3i. Typical value 1. ks3 {20CB34FA-0659-436b-AB1D-D48095CFDF54} Gain on signal 2 input after ramptracking filter iKs4i. Typical value 1. ks4 {93B590B5-CCE0-49d4-BDCD-758A565F72A8} Leadlag time constant iTiisub1subi gt 0. Typical value 012. t1 {0EAEED4C-C880-469d-82DB-8F8E28942DFB} Leadlag time constant iTiisub10subi gt 0. Typical value 0. t10 {2FED642A-038A-4837-85EE-46CB44438329} Leadlag time constant iTiisub11subi gt 0. Typical value 0. t11 {55181E61-DB6D-420e-9CC4-E247603D68B0} Leadlag time constant iTiisub2subi gt 0. Typical value 002. t2 {49972815-84C7-40d5-8DC9-01E40B9FF4AC} Leadlag time constant iTiisub3subi gt 0. Typical value 03. t3 {E9EAA9DB-B818-4790-A7C4-0E0AAB404386} Leadlag time constant iTiisub4subi gt 0. Typical value 002. t4 {AC479311-251E-4322-8F5D-284C676E4FC4} Time constant on signal 1 iTiisub6subi gt 0. Typical value 0. t6 {B5CE0BE2-50B8-4faf-86A9-91FDB13CABE5} Time constant on signal 2 iTiisub7subi gt 0. Typical value 2. t7 {720E50D0-1801-4675-A681-272A90DE0FEE} Lead of ramp tracking filter iTiisub8subi gt 0. Typical value 02. t8 {46D0A834-18CD-4d07-9B9F-4FD29F1D4C02} Lag of ramp tracking filter iTiisub9subi gt 0. Typical value 01. t9 {26216F3D-DDF0-4a35-9681-9341D9EFB636} Lead constant iTiisubasubi gt 0. Typical value 0. ta {DCA88921-CAF2-4e0a-B7BB-A36F5C258E67} Lag time constant iTiisubbsubi gt 0. Typical value 0. tb {D3E4EA3B-1104-4ecf-8872-6D281C46C378} First washout on signal 1 iTiisubw1subi gt 0. Typical value 2. tw1 {34DD18BA-660C-4ad6-9994-FE8ECDDFA178} Second washout on signal 1 iTiisubw2subi gt 0. Typical value 2. tw2 {910C3354-DA65-4a67-B00F-F5C0FAD0F174} First washout on signal 2 iTiisubw3subi gt 0. Typical value 2. tw3 {A25D5A7F-D5AE-467a-A191-9B4F3890739D} Second washout on signal 2 iTiisubw4subi gt 0. Typical value 0. tw4 {09FCB5F3-76DC-49c8-929F-34328D10BE70} Input signal 1 maximum limit iVsi1maxi gt Pss2B.vsi1min. Typical value 2. vsi1max {C47E9535-5CE2-456a-9641-DF992F63E0BA} Input signal 1 minimum limit iVsi1mini lt Pss2B.vsi1max. Typical value 2. vsi1min {7D098878-DFC5-44d2-940A-CFC474E045C4} Input signal 2 maximum limit iVsi2maxi gt Pss2B.vsi2min. Typical value 2. vsi2max {D6867E7D-B7E9-49ae-9136-CFDAD504D56A} Input signal 2 minimum limit iVsi2mini lt Pss2B.vsi2max. Typical value 2. vsi2min {83753CE1-73AF-48ac-B037-06258ECBBEEB} Stabilizer output maximum limit iVstmaxi gt Pss2B.vstmin. Typical value 01. vstmax {395AE089-D808-4724-948A-3EB7D04F80E2} Stabilizer output minimum limit iVstmini lt Pss2B.vstmax. Typical value 01. vstmin {84433A80-593D-467e-8144-1308967CFB3D} Type of input signal 1 rotorAngularFrequencyDeviation busFrequencyDeviation generatorElectricalPower generatorAcceleratingPower busVoltage or busVoltageDerivative shall be different than Pss2ST.inputSignal2Type. Typical value rotorAngularFrequencyDeviation. inputSignal1Type {CFF0885B-F7BC-487a-9AC2-719DC9E9A863} Type of input signal 2 rotorAngularFrequencyDeviation busFrequencyDeviation generatorElectricalPower generatorAcceleratingPower busVoltage or busVoltageDerivative shall be different than Pss2ST.inputSignal1Type. Typical value busVoltageDerivative. inputSignal2Type {DA8C256C-E543-4cfd-A25C-E46B4B4ABFD2} Gain iKiisub1subi. k1 {388BFF8E-5BAC-40b1-BCE7-711F32CE9069} Gain iKiisub2subi. k2 {09EAE50B-660F-431b-A3DF-60FE1B6D0362} Limiter iLiisubSMAXsubi gt Pss2ST.lsmin. lsmax {36ED1D9F-45B0-469b-AB1B-43DAB35DFC06} Limiter iLiisubSMINsubi lt Pss2ST.lsmax. lsmin {A152649C-2F91-4c19-AF69-A4BDA7C603D7} Time constant iTiisub1subi gt 0. t1 {4C8A06A4-7FF2-42d7-A7D9-BDA8DE0CC6EA} Time constant iTiisub10subi gt 0. t10 {9703E541-D28A-45c6-89FA-3912BE731C39} Time constant iTiisub2subi gt 0. t2 {00A324FA-3866-4999-8A2C-268B8C4CD76E} Time constant iTiisub3subi gt 0. t3 {2E4DA1B4-E5DB-4823-98B8-5A29EE892DB9} Time constant iTiisub4subi gt 0. t4 {1EED62C2-46E1-4b27-907D-246EA1CE8E16} Time constant iTiisub5subi gt 0. t5 {8618BBA0-9FB2-426e-975B-6D84FD5BCB43} Time constant iTiisub6subi gt 0. t6 {43E5A382-DFD7-4a5a-8281-2896BB4E833E} Time constant iTiisub7subi gt 0. t7 {6B8331C1-9313-4da9-B130-6654B279D498} Time constant iTiisub8subi gt 0. t8 {327B8744-12B6-4c93-8E7F-0BF0FD0AB3B0} Time constant iTiisub9subi gt 0. t9 {E4E354AD-D199-4111-BEEB-1618A4783C8F} Cutoff limiter iViisubCLsubi. vcl {E9B81925-DEB1-4d91-926B-F0A5EA1EF9C7} Cutoff limiter iViisubCUsubi. vcu {B1729CBD-2156-46b0-9718-2927AEA5825B} Stabilizer output deadband iDEADBANDi. Typical value 0. deadband {09829B27-F382-4cfd-9877-D0F8D6F45D86} Minimum power PSS enabling iPmini. Typical value 025. pmin {2716F17A-F333-4229-8B2D-7F0B19389A8F} Leadlag time constant iTiisubL1subi gt 0. Typical value 0. tl1 {972149E2-7329-49d7-B143-C91CE1D0D0CF} Leadlag time constant iTiisubL2subi gt 0. If 0 both blocks are bypassed. Typical value 0. tl2 {43397194-BE33-40b2-8EF4-A94168040611} Leadlag time constant iTiisubL3subi gt 0. Typical value 0. tl3 {08F21632-907E-4d2e-BBB9-5730DC0C6B52} Leadlag time constant TsubL4sub gt 0. If 0 both blocks are bypassed. Typical value 0. tl4 {9E52C1D5-4573-4968-BD27-F6B3016C6677} Electric power filter time constant iTiisubPEsubi gt 0. Typical value 005. tpe {FF15A722-A340-44d3-B1A1-C8472C183AB7} First washout iTiisubW1subi gt 0. Typical value 35. tw1 {6117E3AD-8E40-45b0-B2CA-EF18017F7BD2} Second washout iTiisubW2subi gt 0. Typical value 0. tw2 {340AD2DB-7807-49b1-BBCA-07A89716F3A2} Stabilizer output maximum limit iViisubSMNsubi. Typical value 01. vsmn {9B6B07F2-A39E-445e-8CB5-34A6B595996D} Stabilizer output minimum limit iViisubSMXsubi. Typical value 01. vsmx {7C25E501-C92A-47b9-931B-4C55DDF1DA2B} Coefficient iaPSSi. Typical value 01. apss {C4097C61-41F7-42c7-A518-DEBC279A5A1A} Gain iKs1i. Typical value 1. ks1 {4FC53F60-7C4B-408d-BC41-874A5EDDB13F} Gain iKs2i. Typical value 01. ks2 {9207B864-DFE6-4ca4-85C6-9D73FEF61911} Coefficient ipPSSi gt 0 and lt 4. Typical value 01. ppss {5386C61F-F104-48b5-B5D9-F072A7E193D6} PSS limiter ipsslimi. Typical value 01. psslim {C591CA0E-9828-4264-BF06-AC81A5C08487} Time constant iTs1i gt 0. Typical value 0. ts1 {28F9E71C-64F9-4a8e-BC68-1F237AF91080} Time constant iTs2i gt 0. Typical value 1. ts2 {1EA22630-7B09-4870-83F9-D2951596D853} Time constant iTs3i gt 0. Typical value 1. ts3 {4EF98AD2-1049-4221-B1FC-1C1879FB8FD3} Time constant iTs4i gt 0. Typical value 01. ts4 {5AA64434-E7B2-446f-B0A8-5EB187CF40F1} Time constant iTs5i gt 0. Typical value 0. ts5 {1FEB7B31-979D-47e7-B552-C15A9EDC24EB} Time constant iTs6i gt 0. Typical value 1. ts6 {9EC34595-ECC6-4286-8D0A-466908BBD3A1} PSS signal conditioning frequency filter constant iA1i. Typical value 0061. a1 {3A42ABB9-11F1-4a35-8886-7F6BC8AF4B92} PSS signal conditioning frequency filter constant iA2i. Typical value 00017. a2 {60DFB355-6080-49e2-B574-9CD273250A1A} Type of input signal rotorAngularFrequencyDeviation generatorElectricalPower or busFrequencyDeviation. Typical value rotorAngularFrequencyDeviation. inputSignalType {9BEB25F6-CC27-40a7-BF6A-30E9CB472F5C} Stabilizer gain iKsi. Typical value 5. ks {1EA8B903-0881-4864-9106-6484CEE4899F} Leadlag time constant iT1i gt 0. Typical value 03. t1 {DF29EFDC-0824-4420-B49B-300F1D1D3BAA} Leadlag time constant iT2i gt 0. Typical value 003. t2 {9F627C73-4C0E-4a88-A74E-B8077F9B2B01} Leadlag time constant iT3i gt 0. Typical value 03. t3 {7A92A9D3-93F2-43f2-9A88-028EC34903A0} Leadlag time constant iT4i gt 0. Typical value 003. t4 {0C4DEB3F-D76E-4961-8AC3-BCA446EBE55A} Washout time constant iT5i gt 0. Typical value 10. t5 {B3A436DD-788F-466d-A6A8-6FEC93704172} Transducer time constant iT6i gt 0. Typical value 001. t6 {118961FB-9D75-4866-8DC8-534F6906C308} Maximum stabilizer output iVrmaxi gt PssIEEE1A.vrmin. Typical value 005. vrmax {620CE161-D66D-4ff4-B914-653AF376B883} Minimum stabilizer output iVrmini lt PssIEEE1A.vrmax. Typical value 005. vrmin {43B4D9BC-6CE5-4948-A360-DA5CA9D4F64B} Type of input signal 1 rotorAngularFrequencyDeviation busFrequencyDeviation. Typical value rotorAngularFrequencyDeviation. inputSignal1Type {5422DA40-A15B-477d-BEBA-D0F93E671F10} Type of input signal 2 generatorElectricalPower. Typical value generatorElectricalPower. inputSignal2Type {D51693EB-EDE4-45d7-BEBE-4C01EE3CC744} Stabilizer gain iKs1i. Typical value 12. ks1 {9EDB2C0C-B5B1-4969-9BB8-15E88D445A74} Gain on signal 2 iKs2i. Typical value 02. ks2 {42040DA0-97DA-4d23-B935-02768C9077A4} Gain on signal 2 input before ramptracking filter iKs3i. Typical value 1. ks3 {FE1D8234-330D-47f9-9DD6-4CF126F472BC} Leadlag time constant iT1i gt 0. Typical value 012. t1 {A29BE3F3-46B5-4700-A3E6-DED949328BA7} Leadlag time constant iT10i gt 0. Typical value 0. t10 {CAD1F821-393F-4240-B41E-28A2E6036531} Leadlag time constant iT11i gt 0. Typical value 0. t11 {6AA08681-7EEF-43d6-9E3B-F6352C1AFEC0} Leadlag time constant iT2i gt 0. Typical value 002. t2 {0325A8EA-E44D-49c1-AC84-A43A5F960594} Leadlag time constant iT3i gt 0. Typical value 03. t3 {7578052C-8C82-4061-8FA4-B088AA9E0BF3} Leadlag time constant iT4i gt 0. Typical value 002. t4 {E7FCEDB2-B9B7-48a2-B6D9-C7F0A6433893} Time constant on signal 1 iT6i gt 0. Typical value 0. t6 {E8160673-0560-4ed3-BAA7-BEE04561C031} Time constant on signal 2 iT7i gt 0. Typical value 2. t7 {E62B50F7-069F-4749-ADA5-D1AE91D6AD9B} Lead of ramp tracking filter iT8i gt 0. Typical value 02. t8 {8B585680-5B86-4b0d-89A5-7666CB401B30} Lag of ramp tracking filter iT9i gt 0. Typical value 01. t9 {88F08006-7320-454c-89C1-B7E0ED841935} First washout on signal 1 iTw1i gt 0. Typical value 2. tw1 {247C6F44-DA26-4c69-A790-7D51421F7173} Second washout on signal 1 iTw2i gt 0. Typical value 2. tw2 {3657663A-7327-4532-B814-B9932AF6103F} First washout on signal 2 iTw3i gt 0. Typical value 2. tw3 {22EF3559-3803-4f96-95B8-1FA1FDCD2B57} Second washout on signal 2 iTw4i gt 0. Typical value 0. tw4 {68328808-0B10-4cec-BAF9-366F7E2C5E25} Input signal 1 maximum limit iVsi1maxi gt PssIEEE2B.vsi1min. Typical value 2. vsi1max {E2717352-71CF-495e-8411-037CF6F9ABE1} Input signal 1 minimum limit iVsi1mini lt PssIEEE2B.vsi1max. Typical value 2. vsi1min {4674160B-50EA-4c0d-8EAB-9F0BB26BD044} Input signal 2 maximum limit iVsi2maxi gt PssIEEE2B.vsi2min. Typical value 2. vsi2max {20B9E8F1-9CE9-4dcc-8F8F-DE3D04C7762C} Input signal 2 minimum limit iVsi2mini lt PssIEEE2B.vsi2max. Typical value 2. vsi2min {B1CCB690-974A-4131-A1B9-B69592C85D15} Stabilizer output maximum limit iVstmaxi gt PssIEEE2B.vstmin. Typical value 01. vstmax {740E3F53-BF89-48d6-9D3D-2293D4546513} Stabilizer output minimum limit iVstmini lt PssIEEE2B.vstmax. Typical value 01. vstmin {932B2B40-7B7C-4ecb-A109-9EABEF808831} Notch filter parameter iA1i. Typical value 0359. a1 {29C3988D-1FA0-4156-AA65-041AD1E3A91A} Notch filter parameter iA2i. Typical value 0586. a2 {3B30B23B-C248-438d-807B-5CEC02C3C3EF} Notch filter parameter iA3i. Typical value 0429. a3 {BADBDF74-BBF6-4617-B923-B9DE59B83EFC} Notch filter parameter iA4i. Typical value 0564. a4 {E4214356-9AC0-4570-B593-1CB76075CD56} Notch filter parameter iA5i. Typical value 0001. a5 {0B37C17C-CD7E-4d90-B766-DAE5E2C6CBA0} Notch filter parameter iA6i. Typical value 0. a6 {C8E8DF62-715D-41da-B028-15F5AC5B4586} Notch filter parameter iA7i. Typical value 0031. a7 {F8D369DF-90B4-4dd4-9ABC-4C724682D725} Notch filter parameter iA8i. Typical value 0. a8 {675C1F36-6FC8-4cff-89C3-9EE8B307B481} Gain on signal 1 iKs1i. Typical value 0602. ks1 {A07F2DD1-C835-4d95-AE33-04A03887E4EF} Gain on signal 2 iKs2i. Typical value 3012. ks2 {596EDE0C-3D07-43b6-9885-E7B8641AFF8A} Transducer time constant iT1i gt 0. Typical value 0012. t1 {EDD30EB8-DCEB-4c45-B5F2-F8EC487167F2} Transducer time constant iT2i gt 0. Typical value 0012. t2 {40699E7A-CFE1-4188-B007-37BFB93BCC12} Washout time constant iTw1i gt 0. Typical value 03. tw1 {C5598A2E-3817-4a5e-B26C-BF21362A2B64} Washout time constant iTw2i gt 0. Typical value 03. tw2 {AE19065C-FB01-4859-9897-361735D064E5} Washout time constant iTw3i gt 0. Typical value 06. tw3 {02C64498-6919-4278-9EB2-06CAD82A5785} Stabilizer output maximum limit iVstmaxi gt PssIEEE3B.vstmin. Typical value 01. vstmax {0C55A361-DEDC-41c9-A63F-0EF60120B92E} Stabilizer output minimum limit iVstmini lt PssIEEE3B.vstmax. Typical value 01. vstmin {63B2226D-3BF8-42a7-8E71-B71C132673F6} High band gain iKiisubHsubi. Typical value 120. kh {B330EB08-840E-4ad3-BA3E-2A7C11B7F1C7} High band differential filter gain iKiisubH1subi. Typical value 66. kh1 {B946A3C9-006B-44d7-A9F3-74B0B08B3BAF} High band first leadlag blocks coefficient iKiisubH11subi. Typical value 1. kh11 {3E829533-0365-408b-A6F3-0D25FE3D5635} High band first leadlag blocks coefficient iKiisubH17subi. Typical value 1. kh17 {A1EAC99C-2B7C-4416-9110-B034E435109B} High band differential filter gain iKiisubH2subi. Typical value 66. kh2 {B938E916-77C3-485a-B33E-11E55B3DA69D} Intermediate band gain iKiisubIsubi. Typical value 30. ki {CBE44C35-2773-4c37-930A-A846E509729A} Intermediate band differential filter gain iKiisubI1subi. Typical value 66. ki1 {228F3175-9E16-4322-B23E-03309CC0F389} Intermediate band first leadlag blocks coefficient iKiisubI11subi. Typical value 1. ki11 {42D1403C-7AC8-4a7f-AF3E-5AD19B6576D3} Intermediate band first leadlag blocks coefficient iKiisubI17subi. Typical value 1. ki17 {0126F076-9D98-43c5-ADAA-71EF12921BDA} Intermediate band differential filter gain iKiisubI2subi. Typical value 66. ki2 {F5D69F7F-2DA9-4fe6-B821-768C06D27F87} Low band gain iKiisubLsubi. Typical value 7.5. kl {F661FCE8-795F-47dc-B4EE-1F4D64A86ED5} Low band differential filter gain iKiisubL1subi. Typical value 66. kl1 {A25D9B28-CA02-428b-9B2B-FEB4ABE9B5CA} Low band first leadlag blocks coefficient iKiisubL11subi. Typical value 1. kl11 {9E02BB3C-E4C3-4136-A2B6-63AAA85FA572} Low band first leadlag blocks coefficient iKiisubL17subi. Typical value 1. kl17 {BAC5CF0A-2A3D-4d59-85D5-2FABE7399189} Low band differential filter gain iKiisubL2subi. Typical value 66. kl2 {27FFC2C9-0AD7-416c-BD97-7D5E4DD1C92E} High band time constant iTiisubH1subi gt 0. Typical value 001513. th1 {B1565F1D-937E-4f87-8E1B-F78219A1E793} High band time constant iTiisubH10subi gt 0. Typical value 0. th10 {3877A778-4B50-4384-AD8B-FD4ECC18A210} High band time constant iTiisubH11subi gt 0. Typical value 0. th11 {8E3C18EE-C082-4592-9E11-306A5865649A} High band time constant iTiisubH12subi gt 0. Typical value 0. th12 {EFBFA9DF-E84D-4910-8448-2CF72DBC59CA} High band time constant iTiisubH2subi gt 0. Typical value 001816. th2 {5126E6D4-989A-44e2-867B-287A3DFF7F71} High band time constant iTiisubH3subi gt 0. Typical value 0. th3 {A0FB3FAF-1A5F-401c-8C5F-E8F51A7FD0A0} High band time constant iTiisubH4subi gt 0. Typical value 0. th4 {333A2965-C561-42e7-ACE7-657656991630} High band time constant iTiisubH5subi gt 0. Typical value 0. th5 {2041028D-058A-442a-9E46-06D0EB098F7E} High band time constant iTiisubH6subi gt 0. Typical value 0. th6 {BEFD6842-39A2-411c-AD53-070714A22D7A} High band time constant iTiisubH7subi gt 0. Typical value 001816. th7 {C9DF4A27-8A3C-4e85-B1F8-415F5CAAE2A5} High band time constant iTiisubH8subi gt 0. Typical value 002179. th8 {3298914E-888F-48a0-AA51-35B2948C0CFB} High band time constant iTiisubH9subi gt 0. Typical value 0. th9 {899ED447-3FFE-4b9e-AC1D-325C18B2CD34} Intermediate band time constant iTiisubI1subi gt 0. Typical value 0173. ti1 {E9BAB416-CBF7-410f-B5AE-4C925AB37279} Intermediate band time constant iTiisubI10subi gt 0. Typical value 0. ti10 {F003E333-8DF9-4451-B83A-10242088D230} Intermediate band time constant iTiisubI11subi gt 0. Typical value 0. ti11 {84BC8320-5294-481a-AD82-B582D79C91A9} Intermediate band time constant iTiisubI12subi gt 0. Typical value 0. ti12 {ADE80289-4ED6-4df7-BA31-5D956C4A0B8F} Intermediate band time constant iTiisubI2subi gt 0. Typical value 02075. ti2 {133C2C29-0856-4fab-90D4-D7230A3A4066} Intermediate band time constant iTiisubI3subi gt 0. Typical value 0. ti3 {EC11DE7C-108C-4252-8901-42030560D618} Intermediate band time constant iTiisubI4subi gt 0. Typical value 0. ti4 {C57AA21C-4F7E-4650-BBA9-ADD5F1EF8CC5} Intermediate band time constant iTiisubI5subi gt 0. Typical value 0. ti5 {70F4E512-41F2-42dd-B791-9D445EF22D3D} Intermediate band time constant iTiisubI6subi gt 0. Typical value 0. ti6 {732159B4-C65D-47d9-966E-2DE2529A662A} Intermediate band time constant iTiisubI7subi gt 0. Typical value 02075. ti7 {7B8B831A-10FA-4f9b-A9F8-0303199D3098} Intermediate band time constant iTiisubI8subi gt 0. Typical value 02491. ti8 {07D34D54-9BD5-47f5-8CA8-D2D4CF1F8A39} Intermediate band time constant iTiisubI9subi gt 0. Typical value 0. ti9 {2A291614-DF59-46fc-AC26-BDCBE69E1766} Low band time constant iTiisubL1subi gt 0. Typical value 173. tl1 {EED80EC0-0995-44b1-92F4-33290BE3EFF0} Low band time constant iTiisubL10subi gt 0. Typical value 0. tl10 {18522492-E1BC-4a45-8BDF-3417466A8C1E} Low band time constant iTiisubL11subi gt 0. Typical value 0. tl11 {DB610C67-A0D1-4682-9D68-512F8417FB25} Low band time constant iTiisubL12subi gt 0. Typical value 0. tl12 {6E82C1C2-659E-49c2-9C6B-4BBA72FF5443} Low band time constant iTiisubL2subi gt 0. Typical value 2075. tl2 {DF838F6A-62DF-48dc-91CB-12C8DBAAD7AD} Low band time constant iTiisubL3subi gt 0. Typical value 0. tl3 {B5BE4EEE-8B6D-4bd6-ACF3-5C75E822571D} Low band time constant iTiisubL4subi gt 0. Typical value 0. tl4 {63EF51D4-1C99-41e3-80DF-8B8675F16B82} Low band time constant iTiisubL5subi gt 0. Typical value 0. tl5 {07D2B4C6-BAE5-439b-A0D5-B11E5C8CC87D} Low band time constant iTiisubL6subi gt 0. Typical value 0. tl6 {3A70AAE4-BD26-457b-A33B-BD09E448524F} Low band time constant iTiisubL7subi gt 0. Typical value 2075. tl7 {62B2B8D6-9440-4d9a-B3A9-CD373EB778B6} Low band time constant iTiisubL8subi gt 0. Typical value 2491. tl8 {AC91BB28-73A8-4eba-9C9B-C779447A714A} Low band time constant iTiisubL9subi gt 0. Typical value 0. tl9 {C1F0E4B7-5685-4cfe-80E5-5FBD47436C3B} High band output maximum limit iViisubHmaxsubi gt PssIEEE4B.vhmin. Typical value 06. vhmax {20BC2A7A-8F06-401e-AA8F-189D4FBA1414} High band output minimum limit iViisubHminsubi lt PssIEEE4V.vhmax. Typical value 06. vhmin {B5F36484-8F0C-45c6-B6A3-32361D83E7DE} Intermediate band output maximum limit iViisubImaxsubi gt PssIEEE4B.vimin. Typical value 06. vimax {D271E688-E2F9-4529-A703-A9D0E93006D7} Intermediate band output minimum limit iViisubIminsubi lt PssIEEE4B.vimax. Typical value 06. vimin {068865B9-E763-43f2-9650-B3A896A9CB65} Low band output maximum limit iViisubLmaxsubi gt PssIEEE4B.vlmin. Typical value 0075. vlmax {BDB0C9CE-DF5E-474b-B0B7-2E373C3295CB} Low band output minimum limit iViisubLminsubi lt PssIEEE4B.vlmax. Typical value 0075. vlmin {25C3E71D-B1B9-4fc0-A8FC-2432F05535D2} PSS output maximum limit iViisubSTmaxsubi gt PssIEEE4B.vstmin. Typical value 015. vstmax {331230C2-2EF0-41ce-9D5E-A29389371349} PSS output minimum limit iViisubSTminsubi lt PssIEEE4B.vstmax. Typical value 015. vstmin {73A3A5F1-5D59-4401-9A84-5205FF321148} Time step related to activation of controls ideltatci gt 0. Typical value 0025. dtc {21E26C02-B1FF-4a47-9FC1-31DBB1E94B91} Time step frequency calculation ideltatfi gt 0. Typical value 0025. dtf {9893B9AA-CB01-4bed-81C8-5EF5ADB4A506} Time step active power calculation ideltatpi gt 0. Typical value 00125. dtp {56B7F182-5BF0-4139-A6C9-6E82F5819074} Gain iKi. Typical value 9. k {149BED87-629F-4c78-95E2-39C8CA4C0969} iMi. iM i 2 x iHi. Typical value 5. m {771479EE-58B0-4922-8DB9-AD23C67D35D7} Time constant iT1i gt 0. Typical value 03. t1 {B247F970-6B77-4d46-9434-2ED921BE5F6D} Time constant iT2i gt 0. Typical value 1. t2 {5F178F5F-4EF0-4c1e-8A69-830923EC6304} Time constant iT3i gt 0. Typical value 02. t3 {7BDEEFBA-DDDA-404b-849D-1054B6347898} Time constant iT4i gt 0. Typical value 005. t4 {632D559B-A58E-419f-A685-58EAC15E2001} Time constant iTfi gt 0. Typical value 02. tf {C6C6644B-B6FB-4b0f-855F-6A7E0048EAA3} Time constant iTpi gt 0. Typical value 02. tp {751AFEC6-3A92-420b-B3E4-B31B5A11AA01} Filter coefficient iA0i. a0 {EA2F4BEA-73DB-4224-AA30-1E511B152E42} Limiter iAli. a1 {83D4F571-389C-41d7-B052-BAA01333CEB4} Filter coefficient iA2i. a2 {F908870E-691A-44cc-A668-30CE61054777} Filter coefficient iA3i. a3 {018F63E9-E39C-4ea8-9A79-2EA75B27DE72} Filter coefficient iA4i. a4 {50C3EDB5-3A00-4172-B546-CD483CFBFDBC} Filter coefficient iA5i. a5 {59F9C4F2-1DB4-4d8c-BE5E-1E0F2486A367} Limiter iAli. al {332AE08B-9AB0-4034-A703-B61289770C4C} Threshold value above which output averaging will be bypassed iAthresi. Typical value 0005. athres {8134EB59-AD5B-4b49-A78A-294E7D8ADAF3} Filter coefficient iB0i. b0 {310F2AFA-65E3-4fe7-969D-6E91C51E5D48} Filter coefficient iB1i. b1 {4F1E7567-EC5E-496a-A487-598C0CD4CED1} Filter coefficient iB2i. b2 {E038B8D2-EA4C-49f6-A65A-E309D19375BB} Filter coefficient iB3i. b3 {A88B6DD5-2A5C-454e-B840-C9834951F533} Filter coefficient iB4i. b4 {DDB2917A-448D-4e0c-BACD-ABA820B29208} Filter coefficient iB5i. b5 {34670B67-141E-420e-86DC-2B4C8582BD08} Limiter iDli. dl {521BE6A1-4207-47cc-BC15-894EF2CA779B} Time step related to activation of controls ideltatci gt 0. Typical value 0025 003 for 50 Hz. dtc {83D0BFCE-2064-47a5-B67C-70DA771BA68C} Time step frequency calculation ideltatfi gt 0. Typical value 0025 003 for 50 Hz. dtf {F98F6493-C793-4489-8838-54649844C2B8} Time step active power calculation ideltatpi gt 0. Typical value 00125 0015 for 50 Hz. dtp {73C6218C-1AFF-4762-A2BC-47FF4A9B7D3A} Gain iKi. Typical value 9. k {4A7D975B-A0B8-4261-9923-6C5AE0547A5B} Threshold value iLthresi. lthres {9F02270C-CBAB-4897-87B9-003C972E0CBB} iMi. iMi 2 x iHi. Typical value 5. m {7C0027A4-3774-4fce-A4E4-EE1C1C533475} iPmini. pmin {7867934E-3E65-40df-93A9-C827AF840E01} Time constant iT1i gt 0. Typical value 03. t1 {CB68C895-9B7A-4fe7-A0F4-8005860B9F47} Time constant iT2i gt 0. Typical value 1. t2 {47B8B379-59F0-4247-9B1B-2015B8F90E79} Time constant iT3i gt 0. Typical value 02. t3 {AA386BC3-B56E-497a-BAC9-2F0C3D50CA78} Time constant iT4i gt 0. Typical value 005. t4 {E423735B-F025-47fd-8D17-D8C34F44C439} Time constant iT5i gt 0. t5 {A5681E99-7069-43a4-8B6A-6EABF1D8B04B} Time constant iT6i gt 0. t6 {280A56E7-B1BD-4eaf-9EF0-4934AC38094C} Time constant iTfi gt 0. Typical value 02. tf {69438D6C-D640-4920-920E-D0E6D15B65C9} Time constant iTpi gt 0. Typical value 02. tp {A816A7FB-010D-475f-AB77-E5CA7BC6E200} Speed deadband iSIBVi. Typical value 0006. sibv {25A44BAC-70C2-4638-B867-62B3BEA331A2} Lead lag time constant iT4Fi gt 0. Typical value 0045. t4f {F10CB117-1EF4-4c87-941E-BB3779497DCC} Input time constant iT4Mi gt 0. Typical value 5. t4m {1E13B238-C8C7-4192-A70B-6091BA857E76} Speed time constant iT4MOMi gt 0. Typical value 127. t4mom {FEC1EADC-4517-4cb3-999E-0856192ED6D8} Speed delay iTOMDi gt 0. Typical value 002. tomd {47F8A6AC-DDC9-498b-AD23-F7976C685FAD} Speed time constant iTOMSLi gt 0. Typical value 004. tomsl {7B4D2D3F-23E8-4796-B85D-94130D50BCFB} Gain iKxi. Typical value 27. kx {2C28DCEE-9492-4588-AEF3-3FA52C9422B4} Time constant iTai gt 0. Typical value 037. ta {1ECE094C-3893-4314-8E19-1FF74F9BF815} Time constant iTbi gt 0. Typical value 037. tb {F9A9604C-C37F-4999-BDB9-0800579A98D6} Time constant iTci gt 0. Typical value 0035. tc {5A58D4A2-5E2B-4df8-801E-A3E812F55E06} Time constant iTdi gt 0. Typical value 00. td {374EEB43-BAA4-4b99-8C8B-028F0F6981F0} Time constant iTei gt 0. Typical value 00169. te {16F004D8-7B9B-42e3-AEE7-C4C4C30A752B} Time constant iTti gt 0. Typical value 018. tt {90A62BA6-6FF0-4588-AB47-C0F67C379895} Reset time constant iTx1i gt 0. Typical value 0035. tx1 {E30E060B-ECD1-4950-8615-3CFF8467F0D9} Time constant iTx2i gt 0. Typical value 50. tx2 {403B3C21-B95B-46ae-BE65-3A45D17F2666} Limiter iVsmaxi gt PssSB4.vsmin. Typical value 0062. vsmax {6D83076D-C50C-4308-9B7C-1FE83743D4B5} Limiter iVsmini lt PssSB4.vsmax. Typical value 0062. vsmin {807D80F6-6A45-4882-A0E8-7047DC33222D} Main gain iKi. Typical value 1. k {CF93D41D-54C5-4f36-8145-12FC07043368} Gain 0 iK0i. Typical value 0012. k0 {D82A667C-A7DE-45b6-9E7C-FDA163EB7B9C} Gain 1 iK1i. Typical value 0488. k1 {9876545C-0A30-4881-B2A6-56247A50A2D8} Gain 2 iK2i. Typical value 0064. k2 {9FCD558B-3085-4673-8E88-126F32495200} Gain 3 iK3i. Typical value 0224. k3 {F4F74F0D-485C-4579-B087-6220606DA960} Gain 4 iK4i. Typical value 01. k4 {8B9E0F2C-828C-418d-B995-198B38BA53E5} Time constant 1 iT1i gt 0. Typical value 0076. t1 {6726B2F3-C89C-4ec3-A10D-64D827D61C80} Time constant 2 iT2i gt 0. Typical value 0086. t2 {E508BE6D-BFAD-4bd3-9D58-487962567A80} Time constant 3 iT3i gt 0. Typical value 1068. t3 {EEDB48FD-466F-479f-8B50-2C9B934A2F55} Time constant 4 iT4i gt 0. Typical value 1913. t4 {5407ECA9-0AB4-46b7-8049-E6471B64A41F} Input time constant iTiisubdsubi gt 0. Typical value 10. td {9E863A8C-B2B5-43f2-9EC7-B7E7A208A606} Output maximum limit iVsmaxi gt PssSH.vsmin. Typical value 01. vsmax {1D97C9D0-E3DC-4a64-95F2-2FCAB7CE17A3} Output minimum limit iVsmini lt PssSH.vsmax. Typical value 01. vsmin {8E01C789-3734-4418-844F-8A638A81E0DF} Gain iPi iKiisub1subi. Typical value 03. k1 {CA6C05FC-A193-4963-BD3E-A73161D564CF} Gain ifiisubEsubii iiKiisub2subi. Typical value 015. k2 {6275FEEA-64E3-4d11-94B3-E85281DC1B0A} Gain iIiisubfsubii iiKiisub3subi. Typical value 10. k3 {696EFC91-3E54-42eb-8DB4-9E96E5011EDE} Denominator time constant iTiisub1subi gt 0005. Typical value 03. t1 {4EDF8011-93D6-4643-A556-ECC6BA91471E} Filter time constant iTiisub2subi gt 0005. Typical value 035. t2 {F3D23C47-4E69-4b24-9A20-9BD3059A78AE} Denominator time constant iTiisub3subi gt 0005. Typical value 022. t3 {5DEFCA45-CB72-4a12-BCB4-A207C56A374E} Filter time constant iTiisub4subi gt 0005. Typical value 002. t4 {7BE8F1D6-1D4C-4833-BA30-374703D06DE1} Denominator time constant iTiisub5subi gt 0005. Typical value 002. t5 {63DBFE0F-46D3-4e43-B9B6-9DDAB865512B} Filter time constant iTiisub6subi gt 0005. Typical value 002. t6 {59DB1983-0DAF-464e-947A-ABCEFFF0FD67} Stabilizer output maximum limit iViisubSMAXsubi gt PssSK.vsmin. Typical value 04. vsmax {C4B8BB7A-AF38-467f-86D4-46E08D0BDC50} Stabilizer output minimum limit iViisubSMINsubi lt PssSK.vsmax. Typical value 0.4. vsmin {7EED5614-AE1E-4890-A231-4857FA7C71A2} Stabilizer output limiter iHiisubLIMsubi. Typical value 05. hlim {9AC76FF9-DF83-4397-9F22-C0C4A4F8C561} Gain iK2i. Typical value 10. k2 {7239752A-FF81-47c0-A800-B0971A966180} Gain iK3i. Typical value 025. k3 {0E4E1CA9-DC9B-4687-8DD4-B668960CD165} Gain iK4i. Typical value 0075. k4 {734E1A07-7893-4f0d-8239-79AC28EF5E71} Gain iK5i. Typical value 25. k5 {0B0EE36D-7F50-4ab4-BC22-53B7D490FEAD} Time constant iT2i. Typical value 40. t2 {30211023-AA7E-4f57-BA0E-81262157838D} Time constant iT3i. Typical value 20. t3 {5E59E2BC-46B6-4a17-9692-732FBF0ABCDB} Time constant iT5i. Typical value 45. t5 {5874D4E5-3374-41ed-88EA-244E309F7C88} Type of input signal 1 rotorAngularFrequencyDeviation busFrequencyDeviation generatorElectricalPower generatorAcceleratingPower busVoltage or busVoltageDerivative shall be different than PssWECC.inputSignal2Type. Typical value rotorAngularFrequencyDeviation. inputSignal1Type {45AD9318-298A-4e62-A7A7-FC79EDBBCE83} Type of input signal 2 rotorAngularFrequencyDeviation busFrequencyDeviation generatorElectricalPower generatorAcceleratingPower busVoltage busVoltageDerivative shall be different than PssWECC.inputSignal1Type. Typical value busVoltageDerivative. inputSignal2Type {CE7A8469-3DFE-42c6-8303-F1660F8AB428} Input signal 1 gain iKiisub1subi. Typical value 113. k1 {4143B66A-209D-4a3b-BCAF-7BDE4AFF2B30} Input signal 2 gain iKiisub2subi. Typical value 00. k2 {C7C76093-3F49-42d9-8C89-A4F8E10C2661} Input signal 1 transducer time constant iTiisub1subi gt 0. Typical value 0037. t1 {8A8B471E-A930-4965-9C8E-47B351E3F1CB} Lag time constant iTiisub10subi gt 0. Typical value 0. t10 {E8999A42-A0F6-4585-AB5C-EB6BF5DA978D} Input signal 2 transducer time constant iTiisub2subi gt 0. Typical value 00. t2 {93B8BF85-A20B-4d8b-84A4-2B7FAD0322DB} Stabilizer washout time constant iTiisub3subi gt 0. Typical value 95. t3 {E2FE415A-8E6B-47ba-8123-CCE9648D2AF9} Stabilizer washout time lag constant iTiisub4subi gt 0. Typical value 95. t4 {93FA4FDB-11B5-4c8f-9261-F0903F324799} Lead time constant iTiisub5subi gt 0. Typical value 17. t5 {47CBD07D-EE09-4f33-A3DA-22777057AF60} Lag time constant iTiisub6subi gt 0. Typical value 15. t6 {5F729D59-B68C-410c-A948-C02D3D9A882E} Lead time constant iTiisub7subi gt 0. Typical value 17. t7 {D80371EC-9902-4d71-B3FC-8E2E03CDF3E4} Lag time constant iTiisub8subi gt 0. Typical value 15. t8 {C82F2A60-94E0-4360-AED3-2D2E01C4EE1E} Lead time constant iTiisub9subi gt 0. Typical value 0. t9 {7BEC731C-190E-4b0f-9F7E-AFC1E2C7ACC7} Minimum value for voltage compensator output iViisubCLsubi. Typical value 0. vcl {56D21C29-B8C0-4964-AF41-9D085F6B6B2E} Maximum value for voltage compensator output iViisubCUsubi. Typical value 0. vcu {FD20EFD0-D7BB-483a-B49B-92B5BE406B9C} Maximum output signal iVsmaxi gt PssWECC.vsmin. Typical value 005. vsmax {441910D0-BCB8-4114-A1EE-5B50748611C5} Minimum output signal iVsmini lt PssWECC.vsmax. Typical value 005. vsmin {124D95AC-84DB-4a66-81CC-46CBE8C0E32C} Application layer used with the certificate for mutual authentication. ISOUpperLayer {5562C131-015C-4469-BB74-1B33BA1A81D9}.SupplierEnd The association allows a certificate to be bound for use by TLS. TCPAccessPoint {D25EF464-773A-4ecc-AAF8-781EC96B694C}.SupplierEnd Delay {784225EE-19A9-4cf5-9299-DAD1950C5181}.ClientEnd VSCtype1 {28C86EC6-3D7B-4965-99CB-2AB0622D2C24}.SupplierEnd Delay {2303C7D4-EE85-47ba-A595-6180D607EEBD}.ClientEnd VSCtype1 {3EEAA87A-6141-43c6-AE82-9A6DAC9A62E9}.SupplierEnd Delay {B244C310-A752-4f97-8CF9-0D6D0C1AB836}.ClientEnd HVDClookUpTable {7AC340E9-74FE-45f9-8424-0F67D74E0B6A}.ClientEnd VSCtype1 {4CCAE11F-2B9B-48f1-B5A0-6357DC443AD7}.SupplierEnd CULaborItems {5E0A5A68-F3A6-4607-B782-EC1790EB274A}.ClientEnd Skills {E5C4C8B8-F4DA-4f11-BECD-A45EE50E9E7D}.ClientEnd Specifications {5119AA22-9D22-4252-BA20-4DF21D5E255F}.SupplierEnd WorkTasks {B3426602-AFB3-44a7-9BCB-107ADC91CCAB}.ClientEnd Source gives information related to the origin of a value. The value may be acquired from the process defaulted or substituted. source {E4D6FE8C-2979-4ab1-92C8-705335298653} Validity of the measurement value. validity {C5A711E6-F0C4-47c1-B00E-1FF68CD1B4F8} Additional information related to the associated quantity. Detail_Quantity {E4139F38-C2AF-497b-B916-ECD41EA35023}.ClientEnd Domain {3C6AC9D3-B254-422b-83E0-AD878F50E02C}.SupplierEnd Point {70A03E37-CDFC-438e-BB13-DBBD82A9288E}.SupplierEnd TimeSeries {B7D5F09D-C0DE-43ce-8CC2-0D383279A6BC}.SupplierEnd Bid {20A022E9-69A4-4231-A566-82296460EFB1}.SupplierEnd MitigatedBidClearing {5A2FDC45-69C0-48d6-B301-3B257BF71F43}.SupplierEnd RegisteredGenerator {EE70F7CB-C4DE-4b60-B550-F2637B3FCA48}.ClientEnd RegisteredResource {8E2C431E-EC49-4d10-AF9B-073F1BEBDF5F}.ClientEnd updateType {F7BC3A42-402E-4ea4-A9AD-F8263B7F94D2} RegisteredGenerator {BD442AE6-4D67-494f-9554-BB1CA9309001}.ClientEnd RegisteredGenerator {0F128EA3-56EC-44d9-9DCF-6D1D373C70D4}.ClientEnd RegisteredGenerator {CEE03ED5-21D8-4bd8-9EC7-78456D6479FB}.ClientEnd RegisteredGenerator {47819087-489C-452d-B08E-D0239FC0DFCA}.ClientEnd AdjacentCASet {E7E0DD2A-8D53-4ec2-BEE0-BFCCE3D2E252}.SupplierEnd AggregateNode {95DFE9B0-18E0-4c05-9AC1-211693BB8524}.SupplierEnd CommodityDefinition {9C7DB57F-73C7-4d73-B17D-1CE635F85AF4}.SupplierEnd EnergyMarkets {7B226990-9273-4097-A3EE-975B7273F323}.ClientEnd FuelRegion {D369B12F-39AD-45d8-B6C9-CDD43DE3458A}.SupplierEnd HostControlArea {61BC778B-58EC-4247-B85A-DA7F2D069EB9}.SupplierEnd LocalReliabilityArea {E6D2764A-B166-47aa-85A1-8B82794864DB}.SupplierEnd MSSAggregation {42061DAA-FC2A-4510-A0B6-81F8DDD07587}.ClientEnd MktConnectivityNode {E1B1E7AA-80C6-41cb-8B19-3F793E0E7B53}.SupplierEnd Pnodes {226E4117-5AE6-4526-BD59-AE3741B82CD9}.SupplierEnd ResourceGroupReqs {1D7D9A91-1BD0-4ef7-80D1-449BA51B49F1}.ClientEnd SecurityConstraints {B8D4120C-7577-4aba-A03D-07C4351445C2}.ClientEnd SecurityConstraintsLinear {83B2008B-320E-4b16-94B7-804FFDC9588F}.ClientEnd SubControlArea {BA94D32D-6765-457a-9130-34C38FCE2CD6}.SupplierEnd TransmissionContractRight {A3A25A93-B38D-4be8-AFA8-1F472DA6E232}.SupplierEnd TransmissionRightChain {1E012DD2-B528-4079-B377-8386C7DB1523}.SupplierEnd ClearingResourceAward {5EDD557D-2252-41e2-AB74-1A856B5BD487}.ClientEnd RegisteredResource {54ACC62F-CE0C-41aa-AF9B-3A4F0A5E245D}.ClientEnd major product type may include the following but not limited toEnergyRegulation UpRegulation DnSpinning ReserveNonSpinning ReserveOperating Reserve marketProductType {00C0F0FE-C31B-4f68-BF79-33C01A0AE5BE} updateType {9A3DBA39-FBD5-4e16-A824-1D4414287358} LossClearingResults {28810405-AFDC-42b6-889E-E5634F47D761}.SupplierEnd The ValueAliasSet used for translation of a Control value to a name. ValueAliasSet {689EAD20-E5B3-46ae-BABC-7A32ADA8F247}.SupplierEnd GeneratingBid {B75E5730-E5F1-4d60-BAEF-5B89FAB09454}.ClientEnd InterTieBid {1BDCCD9A-FE44-4136-9A38-58893BFCA0AA}.ClientEnd LoadBid {AD8B5072-D22F-4473-AF99-5A6CD5C52809}.ClientEnd RegisteredResource {B3D5D7A1-24C6-45ae-9EFE-8FCCE619290E}.ClientEnd condition for the ramp rate condition {3D4C9579-34DE-43b7-9C24-B9EFBB67739F} The condition that identifies whether a Generating Resource should be constrained from Ancillary Service provision if its Schedule or Dispatch change across Trading Hours or Trading Intervals requires more than a specified fraction of the duration of the Trading Hour or Trading Interval. Valid values are FastSlow constraintRampType {0A21AF83-027D-464f-B4D2-33421BF5EAAF} How ramp rate is applied e.g. raise or lower as when applied to a generation resource rampRateType {F8927E6D-38BE-4785-9C8D-7F9AD88EE1DE} The tap ratio table for this ratio tap changer. RatioTapChangerTable {9E0B115E-9239-415e-93A5-C5D5CDF33606}.SupplierEnd Transformer end to which this ratio tap changer belongs. TransformerEnd {D8F7848F-543A-4d91-BA97-2A9B3FCFF0C6}.ClientEnd Tap step increment in per cent of rated voltage of the power transformer end per step position.When the increment is negative the voltage decreases when the tap step increases. stepVoltageIncrement {D8CA42B3-3BCB-47df-BE8A-5DD4E3546D52} Specifies the regulation control mode voltage or reactive of the RatioTapChanger. tculControlMode {A7105B45-FAF9-4012-9A98-CCFA67F55C96} The ratio tap changer of this tap ratio table. RatioTapChanger {9E0B115E-9239-415e-93A5-C5D5CDF33606}.ClientEnd Points of this table. RatioTapChangerTablePoint {2D6853F4-72C6-433d-A408-600CB32AF0B0}.ClientEnd Table of this point. RatioTapChangerTable {2D6853F4-72C6-433d-A408-600CB32AF0B0}.SupplierEnd multiplier {19537A69-BEDD-487c-BFA7-131495198EB9} unit {9D48185D-2672-4a59-B967-AFE697937BD5} multiplier {7154DFD0-EE0B-4140-BEA8-7F728CE79C24} unit {BCDA3620-EC0B-4840-8EF5-CF87AEA8B0D8} The equivalent injection using this reactive capability curve. EquivalentInjection {FC08DB44-00BE-4bc5-8DE9-3538FD5307B8}.SupplierEnd Synchronous machines using this curve as default. InitiallyUsedBySynchronousMachines {6BEDDBFC-3D03-47f1-A9B8-266425DE28E8}.SupplierEnd Synchronous machines using this curve. SynchronousMachines {3724CB9D-F524-4771-91F7-6BDCEBD04E47}.SupplierEnd The machines coolant temperature e.g. ambient air or stator circulating water. coolantTemperature {2A37F217-BEF3-487c-9FFE-9384C84D555B} The hydrogen coolant pressure. hydrogenPressure {E5956813-39D3-4361-9782-0832C4ACFC99} multiplier {3ED78537-D36E-429a-AA73-EB86BF7020FB} unit {C4DA5044-2A5B-4504-997D-67F35395A5B0} All meter readings sets of values containing this reading value. MeterReadings {50ABD845-4A69-4a91-A0FE-99656D135A6F}.SupplierEnd Type information for this reading value. ReadingType {F4B9F142-89CC-4df5-93BC-B2C1BD389AE9}.SupplierEnd Reason for this reading being taken. reason {E186EC9F-5F21-4e1d-80AC-76674C2EE96E} Reading value to which this quality applies. Reading {DD6190AA-B446-4216-8E50-3E7421E80344}.SupplierEnd Type of this reading quality. ReadingQualityType {92E5364D-67C4-4eed-850C-DABD16BEC1BB}.SupplierEnd All reading qualities of this type. ReadingQualities {92E5364D-67C4-4eed-850C-DABD16BEC1BB}.ClientEnd Channel reportingcollecting register values with this type information. Channel {D4257F98-65DB-49d2-B38F-C912709EE1BE}.SupplierEnd All tariff intervals with consumption described by this reading type. ConsumptionTariffIntervals {2C44369F-3DF4-4dcd-9036-EDC39B37AB3D}.ClientEnd All blocks containing interval reading values with this type information. IntervalBlocks {5E2DE546-E491-4480-879B-2607C691B257}.ClientEnd All metrology requirements that require this reading type to be collected. MetrologyRequirements {B5CE221C-AAE6-4ae6-A720-B4E199752DF9}.ClientEnd Pending calculation that produced this reading type. PendingCalculation {498A2163-CE45-41ed-9E07-BE86679D0941}.ClientEnd All reading values with this type information. Readings {F4B9F142-89CC-4df5-93BC-B2C1BD389AE9}.ClientEnd Accumulation behaviour of a reading over time usually measuringPeriod to be used with individual endpoints as opposed to macroPeriod and aggregate that are used to describe aggregations of data from individual endpoints. accumulation {64DB8EA4-3709-455f-87D3-D2B76C275464} Salient attribute of the reading data aggregated from individual endpoints. This is mainly used to define a mathematical operation carried out over macroPeriod but may also be used to describe an attribute of the data when the macroPeriod is not defined. aggregate {4BCF265A-A069-46f1-AD91-840831A1CC69} Argument used to introduce numbers into the unit of measure description where they are needed e.g. 4 where the measure needs an argument such as CEMIn4. Most arguments used in practice however will be integers i.e. denominator1.Value 0 in numerator and denominator means not applicable. argument {F9EEB80B-15E0-443a-9A33-175857305C35} Commodity being measured. commodity {041374E8-07D8-4f28-9626-93D5D9DDC974} Meteringspecific currency. currency {EF6C9401-02C7-4b5f-9288-F2A9754845C4} Flow direction for a reading where the direction of flow of the commodity is important for electricity measurements this includes current energy power and demand. flowDirection {79AAA8D8-BCEE-4bd4-B34D-03475F29C42E} Indication of a harmonic or interharmonic basis for the measurement. Value 0 in numerator and denominator means not applicable. interharmonic {785937B7-DD8B-41e6-BF3E-28B1FFD90921} Time period of interest that reflects how the reading is viewed or captured over a long period of time. macroPeriod {41A1F323-E004-4ac6-9704-AB567B0B1E8E} Identifies what is being measured as refinement of commodity. When combined with unit it provides detail to the unit of measure. For example energy with a unit of measure of kWh indicates to the user that active energy is being measured while with kVAh or kVArh it indicates apparent energy and reactive energy respectively. power can be combined in a similar way with various power units of measure Distortion power distortionVoltAmperes with kVA is different from power with kVA. measurementKind {C3E2457C-C85C-458d-AD5A-350493DCA72A} Time attribute inherent or fundamental to the reading value as opposed to macroPeriod that supplies an adjective to describe aspects of a time period with regard to the measurement. It refers to the way the value was originally measured and not to the frequency at which it is reported or presented. For example an hourly interval of consumption data would have value hourly as an attribute. However in the case of an hourly sampled voltage value the meterReadings schema would carry the hourly interval size information.It is common for meters to report demand in a form that is measured over the course of a portion of an hour while enterprise applications however commonly assume the demand in kW or kVAr normalised to 1 hour. The system that receives readings directly from the meter therefore shall perform this transformation before publishing readings for use by the other enterprise systems. The scalar used is chosen based on the block size not any subinterval size. measuringPeriod {7B6C39D5-8341-4d3a-B4D2-72CB83E0400F} Meteringspecific multiplier. multiplier {BDF133DF-E3C4-4310-985C-766D4C7C0DF3} Meteringspecific phase code. phases {AD213E03-86C1-49f8-B2C3-ED6C169D645B} Meteringspecific unit. unit {C718D1BB-0BE8-4fd6-9EA1-96DA5ACD6476} multiplier {598000BC-F3E4-4b89-AB35-243CE95ED8C9} unit {95DF265F-6A3E-49c4-81DC-D37DD0CE521D} MarketDocument {B1D45B36-F3A6-4f96-A2D1-0E8AD7CFBBF6}.SupplierEnd Period {E9655504-21F4-4c54-B6E8-8735610776CE}.ClientEnd Point {5937F13C-6809-4fd4-9A5E-CC24BE6B8CA7}.SupplierEnd RegisteredResource {283FAB08-B9D7-4a6a-88C2-77B410F3C1C8}.ClientEnd TimeSeries {F3011AEA-011F-4ef6-A0F7-5ED118EF2480}.ClientEnd Cashier shift during which this receipt was recorded. CashierShift {3CC80665-07B4-4a5d-9D19-56F2B340FE1D}.ClientEnd All payments received in the form of tenders recorded by this receipt. Tenders {61AB1FC1-BB28-47a2-95E4-1FB09BBE1111}.ClientEnd All transactions recorded for this receipted payment. Transactions {436A1D66-C447-4f0e-84DE-DEE861AA01CD}.SupplierEnd Vendor shift during which this receipt was recorded. VendorShift {652E0D7A-D247-45a6-80F2-A0339EFE02D7}.ClientEnd Receipted amount with rounding date and note. line {877D2C12-4368-4021-B365-574E9255A543} A breaker may have zero or more automatic reclosures after a trip occurs. ProtectedSwitch {6447ED06-EC4F-4efc-88F3-7FB21521C7FC}.SupplierEnd Indicates the time lapse before the reclose step will execute a reclose. recloseDelay {A9398E5B-13B6-4991-9082-E30DAEE31044} Ground trip rating. groundTripRating {403CF97E-8E06-4419-AC52-415F19686A46} Phase trip rating. phaseTripRating {23CD3D1C-7840-4e17-915E-62FE5DCCF268} Asset {0EDF1A71-1F5E-42e5-9A94-8DFC165669B6}.ClientEnd PowerRatings {87E64861-9690-46b3-ADD5-CF931CEA7994}.ClientEnd TransformerObservations {8A289EE0-AF52-4d3d-B1DF-2BF047C45F44}.SupplierEnd status {9588E218-4A19-4b8d-B948-9777EFC26F0C} All channels that collectreport values from this register. Channels {BDCC2E66-6842-4911-B918-FE7BEF381847}.SupplierEnd End device function metering quantities displayed by this register. EndDeviceFunction {EFFC4614-770D-4c79-9E7C-AD272DF81815}.SupplierEnd Usage Point {04237804-35ED-45c5-A932-B74209BBA2C0}.ClientEnd Clock time interval for register to begingcease accumulating time of usage e.g. start at 800 am stop at 500 pm. touTier {21DCD64F-3A2F-4370-B0C5-7A4ED5CDB62D} Maximum Base Load MW per Participating Load Resource maxBaseLoad {E91CFE1F-3AA7-44ca-B919-CF280EC8B3F4} maximum load reduction maxLoadReduction {295B5406-67D1-44ba-BBAE-2EE5883A14F4} Minimum MW for a load reduction e.g. MW rating of a discrete pump.This attribute may be used also in the LoadBid class. The reason that the attribute is also modeled in this class is that it is resource attribute and needs to be persistently stored. minLoadReduction {E553FED0-9DFB-4025-B7FE-96E8499C8386} minimum load reduction cost. Single number for the load minLoadReductionCost {A4DD08BB-BA99-4f9e-B185-D79E98A6AC8A} ResourcePerformanceRatings {1449B836-5D46-40fb-ADF8-710E12AD33A4}.ClientEnd ResponseMethods {69F7D11C-2F4C-4da3-993F-D604EBFA8F53}.ClientEnd AuxillaryObject {B773A97C-0734-453a-BE6C-701847C433D6}.ClientEnd EnergyPriceIndex {984F3E09-1CA2-412e-9D3B-1138442A36D1}.ClientEnd FuelCostCurve {D73658B4-E454-4c33-84E3-F4704B76D7FD}.ClientEnd FuelRegion {2A9F12A2-E1BC-468f-B9A6-8FD550AE1D66}.ClientEnd GeneratingBids {C4BA4125-803E-42c1-9C0B-2D5179DA8B57}.SupplierEnd LocalReliabilityArea {2AFCD919-E0B4-402b-9374-D1683A531031}.ClientEnd MktHeatRateCurve {1BFB226F-6654-4314-8030-31CF5E037B03}.SupplierEnd Reliability must not run RMNR flag indicated whether the RMR unit is set as an RMNR in the current market RMNRFlag {3C38B0C5-574D-4496-8B47-F052EEEF14F9} Reliability must run RMR flag indicates whether the unit is RMR Indicates whether the unit is RMRN not an RMR unit1 RMR Condition 1 unit2 RMR Condition 2 unit RMRFlag {D81E98D7-B8B8-419c-B4D2-F4ECC0E3A8D1} RMRHeatRateCurve {EE70F7CB-C4DE-4b60-B550-F2637B3FCA48}.SupplierEnd Indicates the RMR Manual predetermination status YN RMRManualIndicator {7E3BD8DC-18A2-43cd-A600-0E6161E405F5} RMRStartUpCostCurve {BD442AE6-4D67-494f-9554-BB1CA9309001}.SupplierEnd RMRStartUpEnergyCurve {0F128EA3-56EC-44d9-9DCF-6D1D373C70D4}.SupplierEnd RMRStartUpFuelCurve {CEE03ED5-21D8-4bd8-9EC7-78456D6479FB}.SupplierEnd RMRStartUpTimeCurve {47819087-489C-452d-B08E-D0239FC0DFCA}.SupplierEnd Reliability must take RMT flag YesNo indicates whether the unit is RMT RMTFlag {4018C7E3-AEA6-4fe1-BDD5-4DED3FBEA373} RegulatingLimit {A0FB2AF5-A2A8-4edb-9EE5-789F40B1C427}.SupplierEnd StartUpCostCurves {5280EFA9-0801-4e47-AE46-18FA93656505}.ClientEnd StartUpEnergyCurve {6F584527-B9F8-4bf0-8BA6-16C6A099CFDF}.SupplierEnd StartUpFuelCurve {AA03FF31-0541-46dc-AC61-8F38D2603BD6}.SupplierEnd StartUpTimeCurve {70E6AE66-01DD-4461-AE89-C87284489617}.SupplierEnd Trade {039D769F-A03A-444a-8786-96815FE89B99}.SupplierEnd UnitInitialConditions {F5E62ED0-90DD-4d2f-AAD2-99DD94F92779}.ClientEnd The ratio of actual energy produced by resource divided by the maximum potential energy if the resource is fully utilized. As an example wind farms. capacityFactor {F8F927B4-6F19-4592-A711-4B09F4431850} Constrained Output Generator COG Indicator YesNo per Generating Resource constrainedOutputFlag {C2483159-69F8-4d10-8ADD-BDBF9A609313} Response rate in MW per minute for ramping energy down. energyDownRampRate {ED118D24-B87E-4d60-9410-753DF1C65663} Response rate in MW per minute for ramping energy up. energyUpRampRate {56D40FD5-F57B-4293-AAB0-E9DE80348F27} Some longstart up time units may need to receive start up instruction before DA market results are available. LongStart resources may be either physical resources within the control with startup times greater than 18 hours or the longstart contractual intertie commitment that shall be completed by 6 am oneday ahead. Therefore there is a need for a process to determine the commitment of such resources before the DA market. extremeLongStart {9C7CD5E9-01B8-421f-8AE5-D7E5A998647B} Values Natural Gas Based Resource Non Natural Gas Based ResourceNG NaturalGasBased Resource a Resource that is powered by Natural GasNNG NonNaturalGasBased Resource a Resouce that is powered by some other fuel than Natural Gas fuelSource {B6D6D10F-6B80-4b64-AC0E-CF1166C1B6EB} High limit for secondary AGC control highControlLimit {616ECE19-D953-4d06-B73E-A0C875029250} Certifies resources for use in MSS Load Following Down loadFollowingDownMSS {31674352-5DEF-4033-8B8C-9D24C027C060} Certifies resources for use in MSS Load Following Up loadFollowingUpMSS {A9549DD6-70A9-47ca-B549-A6CCE737A641} Low limit for secondary AGC control lowControlLImit {0D02E7CA-AED9-4c85-9B28-03ACEAAEE1FA} Maximum Dependable Capacity MNDC. Maximun Net Dependable Capacity is used in association with an RMR contract. maxDependableCap {1037A1B4-581D-475c-8340-62EFCFB5A529} The registered maximum Minimum Load Cost of a Generating Resource registered with a Cost Basis of Bid Cost. maxMinLoadCost {F81A7EBB-F994-44fa-B8D5-6FA3A87D53B2} max pumping level of a hydro pump unit maxPumpingLevel {5C768E97-D0E0-4158-BB9C-D572F56C590F} Maximum allowable spinning reserve. Spinning reserve will never be considered greater than this value regardless of the current operating point. maximumAllowableSpinningReserve {6A059B2A-FF73-4a94-8286-E871D9110A7E} This is the maximum operating MW limit the dispatcher can enter for this unit maximumOperatingLimit {F5C35730-CF9E-4344-B01C-E6C75DBF3E15} minimum load cost. Value is currencyhr minLoadCost {0D435EBF-DB38-4e07-8A50-1FBF02893792} The cost basis for minimum load. minimumLoadCostBasis {493F7DCE-BB9C-4b18-A74D-C4487B4AFEAB} The cost for the fuel required to get a Generating Resource to operate at the minimum load level minimumLoadFuelCost {292FA130-17FA-45f9-9C9B-00B20DEE4675} This is the minimum operating MW limit the dispatcher can enter for this unit. minimumOperatingLimit {603B2BE3-B094-4fce-8760-E31F572CC5C3} Flag to indicate that this unit is a resource adequacy resource and must offer. mustOfferRA {F233261E-A5E6-487e-85DE-85B0C99C20BF} MW value stated on the nameplate of the Generator the value it potentially could provide. nameplateCapacity {8DC5C99C-FE18-4300-A4E5-84BE92D36BED} The portion of the Operating Cost of a Generating Resource that is not related to fuel cost. operatingMaintenanceCost {B29BE4AB-51AA-4d93-B667-1AD031995F95} pumpingCost {5AC99121-D3D1-4075-87C9-B746A21D658B} Quick start flag YesNo. Identifies the registered generator as a quick start unit. A quick start unit is a unit that has the ability to be available for load within a 30 minute period. quickStartFlag {A8D3D311-0CB4-40cc-B84F-85402703BC59} Ramp curve type. Identifies the type of curve which may be a fixed static or dynamic. rampCurveType {966632EF-831B-4119-B75B-24EA7B803E51} Regulation down response rate in MW per minute regulationDownRampRate {3C864244-2D28-4eab-83A8-5D238415357D} Specifies if the unit is regulating or not regulating or expected to be regulating but is not. regulationFlag {63769B37-4425-437f-AE0D-217CB2427CF3} Regulation up response rate in MW per minute. regulationUpRampRate {38769D89-C10C-4a5e-BE11-AC78944BB1AF} Response rate in MW per minute for spinning reserve. spinRampRate {DAD7E13C-5A29-4bf3-8666-B134A4EDB980} The cost basis for start up. startUpCostBasis {22ABD753-BBCC-45d9-8948-1C316D758F58} Is the Resource Synchronous Condenser capable Resource? syncCondCapable {BB67E8CA-A308-47b2-92F7-815A5623518A} Generating unit type Combined Cycle Gas Turbine Hydro Turbine Other Photovoltaic Hydro PumpTurbine Reciprocating Engine Steam Turbine Synchronous Condenser Wind Turbine unitType {10C48566-74A2-4d03-A82D-19FEF2253140} Use limit flag indicates if the uselimited resource is fully scheduled or has some slack for realtime dispatch YN useLimitFlag {57B50884-A51F-4a19-BBBC-3B5AF04619B5} Provides an indication that this resource is intending to participate in an intermittent resource program. variableEnergyResource {2B5595DF-8888-4cb5-A799-B7F6CAB2DD03} Flowgate {B4B4DF5E-5FDD-4ed9-B4E9-ADE4754D4D34}.ClientEnd InterTieBid {E8B2FD01-4BC1-4e68-B739-26E746DDB71F}.ClientEnd InterTieDispatchResponse {C1ECE446-41CB-4935-9DD9-BB8E3EA8F832}.SupplierEnd InterchangeSchedule {EB89CB04-1946-4823-B7D2-6E517A703273}.ClientEnd WheelingCounterParty {A446E5B3-C506-49f2-A28E-A19EEAB812A7}.ClientEnd Indicates the direction exportimport of an InterTie resource. direction {001882C9-B9D3-4fb1-84A7-5336BDCBE3FF} Under each major product type the commodity type can be applied to further specify the type. energyProductType {4650C03C-A67C-4583-A83C-5DBC9CB27091} Flag to indicated whether this Intertie is a DC Tie. isDCTie {E292375A-3614-4ed1-AAE2-39E9BDC80DF2} Specifies whether the intertie resource is registered for the dynamic interchange. isDynamicInterchange {4CD99B77-3154-48a7-A2AA-EE764BAD5442} AuxillaryObject {E8E1ADFD-2A7D-4748-8265-3F63BD1FED9B}.ClientEnd LoadBids {4D1C0118-19FE-4b30-B956-5BEF77F618EE}.SupplierEnd Indication that this resource is associated with an Adjacent Control Area. ACAFlag {60097741-A438-46d9-B8A9-B2E48A18679F} Indication that the resource participates in the optimization process by default. ASSPOptimizationFlag {0A5B9A2D-4F1C-46c1-86B7-820C54B3D615} AdjacentCASet {886205D7-4ADB-42fe-A010-F455E9A5B54F}.SupplierEnd An AggregateNode may be associated with up to many RegisteredResources. AggregateNode {E4F5F679-427A-4403-B876-8642E8E03574}.SupplierEnd AllocationResultValues {5074A0CF-AF43-4460-BC17-3037761F765B}.SupplierEnd Commitments {61A71384-CC3E-4247-AE63-5AD07C4A3E89}.SupplierEnd ContractDistributionFactor {B2C73AF1-CB11-4c78-BE4B-750739E77C5F}.SupplierEnd ControlAreaDesignation {E2FACF8B-8529-4118-B66B-ABACB5D4B6A4}.ClientEnd DefaultBid {F24F3D0F-AE1B-4418-B515-B72D77505E5F}.ClientEnd DispatchInstReply {E391D3A8-763C-4236-AF13-BC42EC2166B1}.SupplierEnd Domain {2883C3D9-C348-4a3e-A321-5E35C932E66E}.ClientEnd DopInstruction {0A0711E7-CD6A-49ca-AFBB-0BB1AE61425F}.SupplierEnd DotInstruction {090DD6C1-3007-4b20-A995-9A43659E6687}.ClientEnd Indication that this resource is associated with an Embedded Control area. ECAFlag {D12DD9FD-30B3-45fd-8FFB-2979539DBB2C} EnergyMarkets {27C8750F-C833-4de8-B407-CF325D392A50}.ClientEnd ExPostResourceResults {A5DD0CDB-1742-4212-BFFE-9A1405F36B62}.ClientEnd ExpectedEnergyValues {29590DFD-E80A-489e-9558-7515799A9C17}.SupplierEnd ForbiddenRegion {F7D2A98A-9DDF-4461-8515-85812EF2DDD4}.SupplierEnd FormerReference {6E79A630-6C5D-4ba3-86D5-0BE5A92B7A38}.SupplierEnd HostControlArea {4F7E336A-F935-41ea-B46D-CA4A8FBC907C}.ClientEnd Instructions {7B076588-700D-4bbc-80C9-CA48511DE042}.ClientEnd InterTie {10599FAD-DB09-4c8e-AB20-91BBA790855D}.SupplierEnd IntermittentResourceEligibility {6E8D1E08-8516-4936-BA3D-566DD94BE286}.SupplierEnd LMPM flag indicates whether the resource is subject to the LMPM test YesNo. LMPMFlag {7EB83470-2118-44ae-B5CE-1269BEBD213B} LoadFollowingInst {3C97A30C-33B1-4e87-8AAE-BC2568E2F4BD}.SupplierEnd LoadFollowingOperatorInput {D80F6DFF-96C2-4687-ABA8-88B11C00DF6E}.ClientEnd MPMResourceStatus {606C8F33-4FFF-4ea5-A5B5-CEB460B07A57}.SupplierEnd MPMTestThreshold {BEDAF373-FFF3-488c-94D4-242E91A60CFB}.ClientEnd MarketObjectStatus {E489A51C-813C-4dd4-B929-320AFC501DEA}.ClientEnd MarketParticipant {7EC28792-B0B8-4baa-9CE0-B5896FAAB9BA}.SupplierEnd MktConnectivityNode {102246E9-40F9-404f-A841-A49127DDD797}.SupplierEnd OrgResOwnership {AB61B549-CFB6-4874-A737-21DD7CC11D7A}.SupplierEnd A registered resource injects power at one or more connectivity nodes related to a pnode Pnode {6A346D84-A25C-41c8-8AFD-BB63272C9F39}.ClientEnd RMROperatorInput {8E2C431E-EC49-4d10-AF9B-073F1BEBDF5F}.SupplierEnd RUCAwardInstruction {54ACC62F-CE0C-41aa-AF9B-3A4F0A5E245D}.SupplierEnd RampRateCurve {B3D5D7A1-24C6-45ae-9EFE-8FCCE619290E}.SupplierEnd Reason {283FAB08-B9D7-4a6a-88C2-77B410F3C1C8}.SupplierEnd RegisteredResources are qualified for resource ancillary service types which include market product types as well as other types such as BlackStart by the association to the class ResourceAncillaryServiceQualification. ResourceAncillaryServiceQualification {2E6B6A80-3A52-4eb7-BA69-7EEAF4ED407E}.SupplierEnd ResourceAwardInstruction {B6254365-DEB6-483c-875B-4D6152FA2C38}.ClientEnd ResourceCapacity {28093C63-595E-4d62-9B92-32DCFA9B4573}.SupplierEnd ResourceCertification {198AD87C-C5A0-4f5f-A7C2-F108234D452C}.SupplierEnd ResourceDispatchResults {8D71D0FE-0F4C-4878-9AB1-1987773508D8}.SupplierEnd ResourceGroups {0E6C97A8-F5B9-4a7e-BDB1-71642B518DC3}.SupplierEnd ResourceLoadFollowingInst {3633FC0F-EC33-44ac-AE95-ACFD3E22EDD6}.SupplierEnd ResourceVerifiableCosts {F273F12C-B3BA-4688-8600-74598825F110}.ClientEnd SMPM flag indicates whether the resource is subject to the SMPM test YesNo. SMPMFlag {DEAB88BD-73C1-4aae-BEE5-80619CD8544E} SubControlArea {8406940A-7751-48cd-BEC8-1C7154E28625}.SupplierEnd SubstitutionResourceList {8BD04841-261A-42f1-AF12-1F6BE08DB56A}.SupplierEnd TimeSeries {DF9EE60B-C140-4257-AED0-716349B4B59B}.SupplierEnd Contingent operating reserve availiability YesNo. Resource is availiable to participate with capacity in contingency dispatch. contingencyAvailFlag {E34999CD-45F1-4e09-8CA9-59EDDCA45DEA} Flexible offer flag YN. flexibleOfferFlag {91A73064-5EE8-4792-B3ED-D8A64CCB68B7} Indicates need to dispatch before the start of the operating hour. Only relevant in RealTime Market. Applies to generation intertie and participating load resource. Value YN. hourlyPredispatch {5434514C-FBE7-455a-86F9-7262A9031EB2} A flag to indicate if a resource is an aggregated resource. isAggregatedRes {8A330AF7-AAA2-408c-AD75-1EA4F74F70F3} Market Participation flag indicates whether the resource participate in the market. marketParticipationFlag {2B107CA6-4719-4466-B301-3CA1F3793B3B} Minimum number of consecutive hours a resource shall be dispatched if bid is accepted. minDispatchTime {990B339C-1043-4943-B04E-B912FD1BF8A8} Must offer flag indicates whether the unit is subject to the must offer provisions YN. mustOfferFlag {1E22D6A5-86D1-4a93-A894-FF4121AB71B5} Flag to indicate that the Resource is not participating in the Market Operations. nonMarket {B16143F2-E7F9-44c1-90AA-16E6B8E18A22} Indication that the registered resource is a Point of Delivery YES resource which implies there is a POD Loss Factor. pointOfDeliveryFlag {D4363E65-3FF5-432c-A700-91B640849A06} Price setting flag indicates whether a resource is capable of setting the Market Clearing Price Y for the DA market and if not indicates whether the resource shall submit bids for energy at 0 S or not N.Initially in the RegisteredGenerator class. It was moved to the RegisteredResource class for the participating load dispatch purpose. priceSetFlagDA {F2F8884B-1565-4f8c-AA64-B95482046781} Price setting flag indicates whether a resource is capable of setting the Market Clearing Price Y for the RT market and if not indicates whether the resource shall submit bids for energy at 0 S or not N.Initially in the RegisteredGenerator class. It was moved to the RegisteredResource class for the participating load dispatch purpose. priceSetFlagRT {6EE3E81D-1087-470a-9310-2C9690FA5B94} Registration Status of resource Active Mothballed Planned or Decommissioned. registrationStatus {BD6EA656-8A84-41e7-974D-FD9129191247} Indication that this resource participates in the resource adequacy function. resourceAdequacyFlag {D03179F8-B019-4757-B3FC-447742DE5E63} The regular interval time point data values that define this schedule. TimePoints {BC2A40CA-8EF4-4afa-8676-9EA3886E7EE6}.SupplierEnd The time between each pair of subsequent regular time points in sequence order. timeStep {DFAEFBCD-8780-41f2-9D97-388E50F9709D} Regular interval schedule containing this time point. IntervalSchedule {BC2A40CA-8EF4-4afa-8676-9EA3886E7EE6}.ClientEnd The regulating control scheme in which this equipment participates. RegulatingControl {DA01278E-D92F-45c7-8007-F72728FA9797}.SupplierEnd Enabledisable a regulating control or set new target value. ProtectiveActionRegulation {2FDA9413-8CFA-434f-8187-40289D0A95BA}.ClientEnd The equipment that participates in this regulating control scheme. RegulatingCondEq {DA01278E-D92F-45c7-8007-F72728FA9797}.ClientEnd Schedule for this regulating control. RegulationSchedule {C1558282-923D-4767-9EF7-BF4C4E82AE43}.ClientEnd The terminal associated with this regulating control. The terminal is associated instead of a node since the terminal could connect into either a topological node or a connectivity node. Sometimes it is useful to model regulation at a terminal of a bus bar object. Terminal {329F27E5-05A7-4f46-AD18-D92971CC1BF3}.ClientEnd The regulating control mode presently available. This specification allows for determining the kind of regulation without need for obtaining the units from a schedule. mode {0A56ECD7-3F74-4730-9F39-FFCB836BBBDB} Phase voltage controlling this regulator measured at regulator location. monitoredPhase {478DE43F-60E6-4f99-92E2-CB59E264B2B8} Specify the multiplier for used for the targetValue. targetValueUnitMultiplier {31FF79A4-B2A7-4692-A7A9-992283FEEB2E} RegisteredGenerator {A0FB2AF5-A2A8-4edb-9EE5-789F40B1C427}.ClientEnd highLimit {51D40332-8C3E-4650-9010-6712523EC22B} lowLimit {6BBDEA79-983A-4d9a-BA90-D2B1BE029057} Regulating controls that have this schedule. RegulatingControl {C1558282-923D-4767-9EF7-BF4C4E82AE43}.SupplierEnd A VoltageControlZone may have a voltage regulation schedule. VoltageControlZones {56DF2E78-015D-485f-9708-D84FAFD9124C}.SupplierEnd displacement {4B7B980C-63C0-4a50-9862-0F4B53612F42} kind {51E8894A-C37A-449c-8268-866609668EA0} Assets {2FBB4D9A-182E-47c5-8227-76C599CC4086}.SupplierEnd Specification {D1E9877C-BF93-4c20-98EC-841633A21B58}.SupplierEnd Mean time to repair MTTR hours. mTTR {0427917F-6CD8-432f-81E7-18C337342A4F} Momentary failure rate temporary failureskftyear. momFailureRate {D663F042-87CB-4a19-ADBE-232D9C32561E} Gate that through a gate logic and input pin defines arming of the Remedial Action Schemes RAS. GateArmed {F4AEF34E-199A-4f15-B975-FF0B28FD8751}.ClientEnd A Remedial Action Scheme RAS consist of one or more stage that are trigger and execute protection action. Stage {8DCB0B7D-45B9-483c-A5E0-6AD156D9B7A1}.ClientEnd Triggering of the Remedial Action Schemes RAS. TriggerCondition {2D5E06E1-6BCA-41a9-9B81-E5FFA56FE6AC}.ClientEnd Kind of Remedial Action Scheme RAS. kind {7BCE4598-196E-40b9-A8B3-D23E10784AF4} Setting of the timeout elapsed time. armedTimeout {8B577ED4-82CE-43a2-9A38-4B30BAC60C04} Voltage limit on customer side of RCD switch above which the connect should not be made. customerVoltageLimit {ABB8657C-24A9-40bd-9D82-83B8C3915231} Limit of energy before disconnect. energyLimit {92297B46-8B9F-4876-9716-BE6F2A3B2D3E} Warning energy limit used to trigger event code that energy usage is nearing limit. energyUsageWarning {345CAAF2-594E-40a3-BECF-FDF5513E3B74} Load limit above which the connect should either not take place or should cause an immediate disconnect. powerLimit {FD1A6CBC-10B3-44cb-9128-DCCC36851BC6} The Control for the RemoteControl point. Control {D8E2547F-5EE8-425a-88B2-6878C15AFEF6}.SupplierEnd Discontinuous excitation control model using this remote input signal. DiscontinuousExcitationControlDynamics {912E18D5-6BA7-4363-935C-5AAF4DB0471F}.ClientEnd Power factor or VAr controller type 1 model using this remote input signal. PFVArControllerType1Dynamics {08E5127F-7B16-4f73-A4EF-20E79A544461}.ClientEnd Power system stabilizer model using this remote input signal. PowerSystemStabilizerDynamics {57187DF7-A206-4e9a-BEB5-C8CEE8478241}.ClientEnd Remote terminal with which this input signal is associated. Terminal {7CA6A357-5876-45c2-9ED0-266641C5D519}.SupplierEnd Underexcitation limiter model using this remote input signal. UnderexcitationLimiterDynamics {926FD0F1-B98A-492d-AD1E-CCA64FBEB605}.ClientEnd Voltage compensator model using this remote input signal. VoltageCompensatorDynamics {F5F154AE-0B1E-4436-BB0A-FB640908FA63}.ClientEnd The wind plant using the remote signal. WindPlantDynamics {A386534A-CECA-4cf5-B0FB-5C4A4D5EA497}.ClientEnd Wind generator type 1 or type 2 model using this remote input signal. WindTurbineType1or2Dynamics {87FA8C90-E6B5-40bb-A4FC-AD947AB5E303}.ClientEnd Wind turbine type 3 or type 4 models using this remote input signal. WindTurbineType3or4Dynamics {6BAC6893-7D0D-407c-903E-4E5F0755C0CE}.ClientEnd Type of input signal. remoteSignalType {72DA94DD-E3E3-4960-8AD3-66CDF0F4B6F8} Remote unit this point belongs to. RemoteUnit {76D05D85-2279-4d21-AFD6-336064DBAF22}.SupplierEnd Link to the physical telemetered point associated with this measurement. MeasurementValue {A7C88F72-6063-4225-8BCA-A830CE33CAC0}.ClientEnd The time interval between scans. scanInterval {27C5E1A2-B3C0-4142-98E3-55D454CF7D61} RTUs may be attached to communication links. CommunicationLinks {E4ED6E40-6C5C-406f-B61F-EFE533D3AE61}.ClientEnd Remote points this Remote unit contains. RemotePoints {76D05D85-2279-4d21-AFD6-336064DBAF22}.ClientEnd Type of remote unit. remoteUnitType {111D4E3D-B96D-4c71-9196-AFD9439B30B7} Repair work task under which breaker item of this type is repaired. RepairWorkTask {C716C74F-2E3C-498a-85C0-DA5BD43AEA95}.SupplierEnd Breaker component or problem area which is the focus of this maintenance work task for work tasks related to breakers only. breakerRepairItem {B3ACED35-1012-4523-ABC2-4F7A28E6C099} Transformer component or problem area which is the focus of this maintenance work task for work tasks related to transformers only. transformerRepairItem {58D810FD-373D-4e8a-A148-A94D2CCB7448} Type of breaker item to be repaird by this repair work task. BreakerRepairItem {C716C74F-2E3C-498a-85C0-DA5BD43AEA95}.ClientEnd One of the environmental value sets expressing one of the reporting capabilities. EnvironmentalAnalog {33EE49E4-C5C2-447f-B5D2-DA0AF83C0024}.ClientEnd The environmental monitoring station to which this set of reporting capabilities belong. EnvironmentalMonitoringStation {6335EFF8-1839-4f0f-A97C-CC890F5D5411}.SupplierEnd Unit of time in which reporting period is expressed. reportingIntervalType {1DD5725E-06D1-4f1a-A7D9-E788F45F453D} Indicates how the weather station reports observations. reportingMethod {291E5936-8313-4a59-805F-73B01DDE076B} The bus name markers that belong to this reporting group. BusNameMarker {37254491-51A1-43fd-8EA9-325A03BB2B8F}.ClientEnd Power system resources which belong to this reporting group. PowerSystemResource {62E3FEEC-F7FE-4ee8-88DC-231AEF7F6DE3}.SupplierEnd The topological nodes that belong to the reporting group. TopologicalNode {1134BB7B-6737-4184-A156-3E1FE506083D}.ClientEnd ASRequirements {6B2BD6A2-CC2E-4cf3-BCDE-BB717B4A931B}.ClientEnd MarketRegion {C2EA5FDF-AB5A-4353-86E1-3AC96CCCA3CC}.ClientEnd Reserve requirement type that the max and curve apply to. For example operating reserve regulation and contingency. reserveRequirementType {3AD9C24B-EC97-459e-8ABA-5FB7B74E8342} Market product associated with reserve requirement must be a reserve or regulation product. MarketProduct {B135E6CF-CF03-4e34-8A2A-CAB47CB13C0C}.SupplierEnd ReserveReqCurve {9181F9BC-7A3E-4c83-87CC-B9FEC9AC20B7}.ClientEnd SensitivityPriceCurve {7EED99BC-CD41-443b-94DE-ED7BDA941A80}.SupplierEnd ReserveReq {9181F9BC-7A3E-4c83-87CC-B9FEC9AC20B7}.SupplierEnd Generators discharge water to or pumps are supplied water from a downstream reservoir. HydroPowerPlants {2C3E96AE-B573-4669-98A0-A1B15E5B69A2}.ClientEnd A reservoir may have a natural inflow forecast. InflowForecasts {390FA231-DEA9-4f7c-9E58-9EA15F9F2F0C}.ClientEnd A reservoir may have a level versus volume relationship. LevelVsVolumeCurves {1CA34C6F-D018-451a-B9BA-91A089FCA0F8}.ClientEnd A reservoir may spill into a downstream reservoir. SpillsFromReservoir {D6D8406C-3239-432c-8EF7-EA8C64638856}.ClientEnd A reservoir may spill into a downstream reservoir. SpillsIntoReservoirs {D6D8406C-3239-432c-8EF7-EA8C64638856}.SupplierEnd A reservoir may have a water level target schedule. TargetLevelSchedule {B07A132F-C127-483d-A307-B2513535A40A}.ClientEnd Generators are supplied water from or pumps discharge water to an upstream reservoir. UpstreamFromHydroPowerPlants {00B2E13E-C0A8-4011-8062-D47DDF498C70}.ClientEnd Storage volume between the full supply level and the normal minimum operating level. activeStorageCapacity {17391B1F-DFAA-4e5d-8050-B45943CA2AD3} Full supply level above which water will spill. This can be the spillway crest level or the top of closed gates. fullSupplyLevel {90E3C69E-1138-41e8-A4FC-6FDD25360069} Total capacity of reservoir. grossCapacity {F7AA9685-2312-46f5-B54D-BDEEB76A659D} Normal minimum operating level below which the penstocks will draw air. normalMinOperateLevel {FD40FEA9-7B4D-42bb-9403-CBCCD05DF2C7} The spillway water travel delay to the next downstream reservoir. spillTravelDelay {BA136AFA-1D9E-470e-8298-BAD7AC41930C} The length of the spillway crest. spillwayCrestLength {C89E2806-58B3-4c6c-B9E7-112DFF10158F} Spillway crest level above which water will spill. spillwayCrestLevel {C50C7FF9-3DC6-494b-B117-64C94342B7EE} multiplier {6256F839-CBEB-4164-926A-0C7D450E1529} unit {CDBE0328-0DCE-4f27-A805-49EC479BCAD4} multiplier {99CB440E-D654-4929-9D1A-3B22407B5ADC} unit {93670290-AE2E-44b4-BF92-B336ACF73EAA} RUCAwardInstruction {5EDD557D-2252-41e2-AB74-1A856B5BD487}.SupplierEnd ResourceAwardInstruction {CBA2B259-50D6-4c20-9DEA-8E0D4B92E07F}.SupplierEnd Indication that the system is currently operating in a contingency mode. contingencyActive {61E1FBA0-8C2A-493f-BAC8-5961682EE118} dispatchMode {416EFBA8-81FC-4e97-B702-A5EE79F9BFF1} ClearingResourceAward {CBA2B259-50D6-4c20-9DEA-8E0D4B92E07F}.ClientEnd MarketProduct {DCAE610D-01F2-4d9d-84E5-FC64B8C205A5}.ClientEnd RegisteredResource {B6254365-DEB6-483c-875B-4D6152FA2C38}.SupplierEnd SelfScheduleBreakdown {905CC309-F54E-43fc-BE60-1DD63FC99CAC}.SupplierEnd Indicates if an award was manually blocked YN. Valid for Spinning and Nonspinning. manuallyBlocked {9CE9D015-E1F1-4b71-B5E7-F2704E5E2EE3} Indicator Yes No that this resource set the price for this dispatch schedule. marginalResourceIndicator {0167C2E5-9519-4175-8732-DD9E793AE30F} updateType {1B33CF60-DE9D-4e41-919C-79FBC0EB56A6} BidError {1733E069-3742-4625-B384-DB2661EDD78B}.SupplierEnd contingent operating reserve availiability YesNo. Resource is availiable to participate with capacity only in contingency dispatch. contingencyAvailFlag {46E5EF0C-D885-430b-B19A-B0B7F059814F} A Yes indicates that this bid was created by the ISO. createdISO {0D9AAAA1-12D7-4853-A7AB-2C06EB523E6C} RegisteredResource {28093C63-595E-4d62-9B92-32DCFA9B4573}.ClientEnd capacity typeThe types are but not limited toRegulation UpRegulation DnSpinning ReserveNonSpinning ReserveFOO capacityMOO capacity capacityType {60727D62-1399-49f7-A12D-3AC4831BB915} Unit selection for the capacity values. unitSymbol {385B9EEF-12AF-487d-9907-5E3E872105C5} RegisteredResources are qualified for resource ancillary service types which include market product types as well as other types such as BlackStart by the association to the class ResourceAncillaryServiceQualification. RegisteredResource {198AD87C-C5A0-4f5f-A7C2-F108234D452C}.ClientEnd {2E6B6A80-3A52-4eb7-BA69-7EEAF4ED407E}.ClientEnd certifiedDAM {8E67568B-FBF5-49a6-91E8-583C4B36DF92} certifiedNonspinDAM {CE5927C8-C38E-49a2-90F8-AC75F1C4FDB1} certifiedNonspinRTM {48D46413-A88D-4d51-A38D-E33613610E72} certifiedPIRP {85BA9F07-099E-4179-A007-2F0957C4D9EA} certifiedRTM {AB7147FB-5633-4594-906B-9F3431D7BA5D} certifiedRUC {DB42263C-314D-47d6-9084-7F4D8D458977} certifiedRegulation {90F51713-A6EA-45ef-94ED-1F5D71118BFE} certifiedReplaceAS {5EBBA86E-A3B5-4fe7-A9E5-7A979EB74C11} certifiedSpin {D661A50C-00DE-4826-A2E6-8A1988ED303C} market type market {385FE5E5-114D-42d0-8180-65B855B33CD0} Status of the qualification Y Active N Inactive qualificationFlag {29A74821-4943-41f1-A65D-9EC9F6AADF60} Type of service based on ResourceAncillaryServiceType enumeration type {6327F78A-BC21-4ef1-BB69-684E4BC85CE8} ResourceDispatchResults {1719FC4E-4D25-4f3d-8F87-8A99542BBE51}.SupplierEnd ResourceLoadFollowingInst {98A7253A-C806-4b6f-8EF0-E5922B92E7C2}.SupplierEnd InstructionClearing {23E96A97-D54D-4d70-8585-71267B61B888}.ClientEnd RegisteredResource {8D71D0FE-0F4C-4878-9AB1-1987773508D8}.ClientEnd ResourceClearing {1719FC4E-4D25-4f3d-8F87-8A99542BBE51}.ClientEnd Contingent Operating Reserve Indicator YesNo. Resource participating with AS capacity in contingency dispatch. contingencyFlag {608BFBE0-B85E-4b13-BB26-239BACFDE997} Penalty Dispatch Indicator Yes No indicating an uneconomic adjustment. penaltyDispatchIndicator {BFD70DEE-3780-4848-8341-846815E97B37} updateType {67D29C7A-92E7-43be-85D2-417C22BECBC0} RegisteredResources {0E6C97A8-F5B9-4a7e-BDB1-71642B518DC3}.ClientEnd ResourceGroupReqs {2BED8656-05D2-4daf-890F-B14948CB3F57}.SupplierEnd Status of this group. status {684974AF-BC80-4eaf-9717-025040FFA2DD} RTOs {1D7D9A91-1BD0-4ef7-80D1-449BA51B49F1}.SupplierEnd ResourceGroup {2BED8656-05D2-4daf-890F-B14948CB3F57}.ClientEnd RegisteredResource {3633FC0F-EC33-44ac-AE95-ACFD3E22EDD6}.ClientEnd ResourceClearing {98A7253A-C806-4b6f-8EF0-E5922B92E7C2}.ClientEnd ResourceVerifiableCosts {627F546D-4614-4c83-BC0E-7D5722D3FC8B}.SupplierEnd Percentage of Fuel Index Price gas for operating above Low Sustained Limit LSL gasPercentAboveLowSustainedLimit {9E3D2AEB-6365-4a62-93A3-A6B617216F75} Percentage of Fuel Oil Price FOP for operating above Low Sustained Limit LSL oilPercentAboveLowSustainedLimit {5D681789-53C6-43ad-BAC8-78427A931871} Percentage of Solid Fuel for operating above Low Sustained Limit LSL solidfuelPercentAboveLowSustainedLimit {4639ACA7-0212-461a-8E4E-3FAA4CA6549E} DemandResponseActualEvent {568AA2F2-D906-4139-AA0D-393E92602084}.ClientEnd ResorcePerformanceGlobalFactor {A5B613FC-5B70-40eb-B760-4948D4892332}.ClientEnd ResourcePerformanceTimeSeriesFactors {67DF97CB-CE1E-4576-9B2A-5FB9AD92D4B2}.SupplierEnd ResourcePerformanceEvaluation {A5B613FC-5B70-40eb-B760-4948D4892332}.SupplierEnd RegisteredResource {1449B836-5D46-40fb-ADF8-710E12AD33A4}.SupplierEnd ResourcePerformanceEvaluation {67DF97CB-CE1E-4576-9B2A-5FB9AD92D4B2}.ClientEnd Percentage of Fuel Index Price gas for cold startup gasPercentColdStartup {B1F5F6DC-A7A7-48f5-AF5A-9B0AB262CF92} Percentage of Fuel Index Price gas for hot startup gasPercentHotStartup {C271D4D2-EBEA-4da0-9510-BBEF40C8946F} Percentage of Fuel Index Price gas for intermediate startup gasPercentIntermediateStartup {1C9D49B7-8902-40b4-A3DC-20E2C171E4D9} Percentage of FIP gas for operating at LSL gasPercentLowSustainedLimit {0C7D89B4-1CDC-4e6d-8EDF-A6CE80E536FB} Percentage of Fuel Oil Price FOP for cold startup oilPercentColdStartup {FADF9E8F-646A-4bf6-8546-51CAA5F648B0} Percentage of Fuel Oil Price FOP for hot startup oilPercentHotStartup {BC1CF5BB-B77D-4b3d-80AA-277DB6069B0F} Percentage of Fuel Oil Price FOP for intermediate startup oilPercentIntermediateStartup {BAEFFD3F-902B-4a0d-8AD9-F5C989BD46C9} Percentage of FOP oil for operating at LSL oilPercentLowSustainedLimit {7EED2EC4-B830-43fd-A23E-DBD0EC4C8FB6} Percentage of Solid Fuel for cold startup solidfuelPercentColdStartup {7AC412DF-4E08-4aec-A4C8-53B70C678463} Percentage of Solid Fuel for hot startup solidfuelPercentHotStartup {460A370E-259B-447b-92F0-49E74E78E6C2} Percentage of Solid Fuel for intermedite startup solidfuelPercentIntermediateStartup {A864BE35-4819-4980-ACD3-2E9A153EB3EE} Percentage of Solid Fuel for operating at LSL solidfuelPercentLowSustainedLimit {149C7ED3-9938-4fe5-B965-617196195FB4} MktHeatRateCurve {19E8F4BC-BA0C-4a8b-8AFC-83E8D5EE0E8D}.SupplierEnd RegisteredResource {F273F12C-B3BA-4688-8600-74598825F110}.SupplierEnd ResourceOperationMaintenanceCost {627F546D-4614-4c83-BC0E-7D5722D3FC8B}.ClientEnd RegisteredResource {69F7D11C-2F4C-4da3-993F-D604EBFA8F53}.SupplierEnd All land properties this right of way applies to. LandProperties {EB5019C4-5ACE-4ae3-BA94-0695131D9A29}.SupplierEnd Individual health score associated with this risk score. AssetHealthScore {35D3A10F-8986-4cb3-84BA-68730CC19A28}.ClientEnd The risk kind such as CustomerRisk FinancialRisk SafetyRisk etc. kind {4DC2763A-42AD-45aa-AD90-1395DBBEC173} status {5A535BCE-5B60-42c0-B302-220654AB6048} A synchronous machine may operate as a generator and as such becomes a member of a generating unit. GeneratingUnit {075455B4-8BAD-4ff0-BF82-B9A27A62A8D2}.ClientEnd The synchronous machine drives the turbine which moves the water from a low elevation to a higher elevation. The direction of machine rotation for pumping may or may not be the same as for generating. HydroPump {B7907DA2-3474-44e7-8BA4-9B2DB3D1D425}.SupplierEnd Active power injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for a steady state solution. p {792C720E-AF6B-47ed-84D7-C08A882047CD} Reactive power injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for a steady state solution. q {9444CBB2-5BC1-46df-B4EA-356639D6F3F9} Nameplate apparent power rating for the unit.The attribute shall have a positive value. ratedS {5E80BBF0-7614-49da-9D9C-AC059D65E824} Rated voltage nameplate data Ur in IEC 609090. It is primarily used for short circuit data exchange according to IEC 60909.The attribute shall be a positive value. ratedU {5DD8EA89-5A11-4fe2-8700-3F88CB0E5DAC} Inertia constant of generator or motor and mechanical load iHi gt 0. This is the specification for the stored energy in the rotating mass when operating at rated speed. For a generator this includes the generator plus all other elements turbine exciter on the same shaft and has units of MW x s. For a motor it includes the motor plus its mechanical load. Conventional units are PU on the generator MVA base usually expressed as MW x s MVA or just s. This value is used in the accelerating power reference frame for operator training simulator solutions. Typical value 3. inertia {79CEC581-6B20-4d45-AD35-EFE623343AAD} Stator leakage reactance iXli gt 0. Typical value 015. statorLeakageReactance {0AAC33B1-D461-46e7-A2C4-46A5D40E45D9} Stator armature resistance iRsi gt 0. Typical value 0005. statorResistance {E651F525-F913-4b2b-ADFC-236B404DB0DB} multiplier {82A7E88E-89CA-46ed-8FAA-1B2E2CFF4928} unit {0919D36A-A771-475c-85DA-CEF54827C06D} Crews {E3EA714F-98DF-4908-8D66-9D4D2D2ECDBE}.ClientEnd Locations {BD8B4DA4-D676-478b-B855-5DB85DFFDB26}.SupplierEnd status {2EEF5127-ED4A-4b5c-8A7C-2020591E45C1} Maximum capacitive reactive power. capacitiveRating {210D8469-2544-4d53-BF19-137D5C6A5B6D} Maximum inductive reactive power. inductiveRating {98DDDB20-C1D2-4cfa-BA1E-D6C62545D3C8} Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {16A60C5C-8F8E-4e74-BF69-62A6C79FF350}.SupplierEnd Supervisor that issued this safety document. IssuedBySupervisor {019E9E3C-C2CC-4a76-9DB0-DEC77795FB72}.ClientEnd Supervisor to whom this safety document is issued. IssuedToSupervisor {9928D926-C37A-4b01-9B70-087C54DA13DA}.ClientEnd Supervisor that released this safety document. ReleasedBySupervisor {D76F467F-64BC-408a-BE7C-AEA257C59F88}.ClientEnd Supervisor to which this safety document is released. ReleasedToSupervisor {9101B352-8544-44a4-9F4A-B24425BA24E4}.ClientEnd Switching plan to which this safety document applies. SwitchingPlan {27C9D948-FDCD-4bb2-9FA5-B01A6569D284}.ClientEnd value {D97A1BB5-F8C5-4d41-A24D-79D2E425B1E2} The apparent power limit value for the scheduled time. value {7EF6CD0D-2350-4a60-94EC-F4C71CA24433} The current flow limit value applicable at the scheduled time. value {B264B48B-449E-4dec-A0A0-3453274F6B7A} Assets {E182BB37-0828-425d-B4E7-9C8FE6B40993}.SupplierEnd Specification for this scheduled event. ScheduledEventData {15E116B8-63BD-4073-A9A6-7D5FDF290740}.ClientEnd Duration of the scheduled event for example the time to ramp between values. duration {D5EAF14A-79D1-4d17-93B0-B9E9C9D6886F} status {0A536F7A-8AB5-4b30-8669-79BBC3298B09} InspectionDataSet {37ACB8AF-5C2E-4faa-8C9D-87E718507CBD}.SupplierEnd All scheduled events with this specification. ScheduledEvents {15E116B8-63BD-4073-A9A6-7D5FDF290740}.SupplierEnd Estimated date and time for activity execution with earliest possibility of activity initiation and latest possibility of activity completion. estimatedWindow {05F7F71F-1BB8-41f2-A908-6195E76E8179} Requested date and time interval for activity execution. requestedWindow {85E209E1-2D1D-4d3e-920D-1ECC0FBCFA47} status {E1112898-C686-40af-A921-5FAC00352F0B} The season for which the scheduled limits applies. If not specified then applicable ot any season. Season {292AF232-83A8-4d6a-9D01-F01B02F5ADF3}.SupplierEnd The voltage limit value for the scheduled time. value {87464AFE-82F5-4627-B0AB-93487057CB13} FromSCTrade {6D895553-2440-4f7c-BC33-B46D1B29C9D3}.SupplierEnd LoadRatio {1F7B041F-E74A-417c-95DE-6C226FA9485B}.ClientEnd MarketParticipant {B7A4F593-994A-4de3-804C-823ABC09CB5B}.SupplierEnd SubmitFromSCTrade {5BFC46E8-DD4B-4516-8376-1EFDF9C076C7}.SupplierEnd SubmitToSCTrade {AC7FD549-FA5C-45d6-B2D9-4609F963A05C}.SupplierEnd ToSCTrade {7714A894-C9FB-420d-B21E-799E489A3AC8}.SupplierEnd TransmissionContractRight {9344B7EF-5714-48c0-9CD5-ABBE8A690C30}.SupplierEnd Flag to indicate creditworthiness Y N creditFlag {239B5BB2-0418-485a-8DB4-9509C6634009} Flowgate {001E125A-BECE-4e28-A128-A8ADBBEFE8D0}.ClientEnd InterchangeSchedule {F470E1A6-33AE-4803-A2CA-A8627C7D6956}.ClientEnd RegisteredResource {10599FAD-DB09-4c8e-AB20-91BBA790855D}.ClientEnd Asset container to which this seal is applied. AssetContainer {FDAAA9DF-09C4-4044-B2F9-0C70CD16B243}.ClientEnd Condition of seal. condition {59CDFA31-796A-49c1-891D-CB71C65EE6BF} Kind of seal. kind {242B0C46-91B9-49ad-A49B-FEBAE5DB649C} The scheduled limits associated with the season. ScheduledLimits {292AF232-83A8-4d6a-9D01-F01B02F5ADF3}.ClientEnd Schedules that use this Season. SeasonDayTypeSchedules {D7DD6204-0DD9-4e66-89F5-66E3F0610825}.SupplierEnd DayType for the Schedule. DayType {9B2613ED-CF92-429b-B26F-0EB80C658169}.ClientEnd Season for the Schedule. Season {D7DD6204-0DD9-4e66-89F5-66E3F0610825}.ClientEnd multiplier {DF58DF5F-F450-4b71-A1A9-1BBA5C696E5C} unit {383E0AEB-B11C-4c02-8C56-5E84FCDA0D3B} BaseCaseConstraintLimit {8FF929E3-7DF8-484e-9AE6-E78FD919B4C1}.ClientEnd ConstraintTerms {BB8340BB-8D35-4db5-B3EA-6A408762BF83}.SupplierEnd ContingencyConstraintLimits {BF65240F-A284-4af5-8E7D-B230D8362719}.ClientEnd DefaultConstraintLimit {59C7A4B0-0AB0-47cf-B08A-D99F0E01C0D2}.ClientEnd RTO {83B2008B-320E-4b16-94B7-804FFDC9588F}.SupplierEnd Flowgate {D96B3C19-134E-4b97-96C3-34675C1BB168}.ClientEnd GeneratingBid {EF812433-5985-4f7f-AEE9-C31F08021E9B}.ClientEnd RTO {B8D4120C-7577-4aba-A03D-07C4351445C2}.SupplierEnd Actual branch or group of branches MW flow only for transmission constraints actualMW {3F4F5E44-40C3-4fb2-ABF6-6CCD01F0B8B7} Maximum MW limit maxMW {A553DBCE-3908-4d10-8777-D39412F3583C} Minimum MW limit only for transmission constraints. minMW {C452A034-8A7B-41a2-AC43-F11FEFDC2C1F} Optimal MW flow mwFlow {9C18181A-43C1-451f-BAA5-B055EBEB110B} Binding MW limit. mwLimit {EE4C25B6-CA8B-450b-BC29-B761B0C43343} Security constraint shadow price. shadowPrice {0D5172D6-0E6B-4767-BA3D-E70AD5D318D4} ResourceAwardInstruction {905CC309-F54E-43fc-BE60-1DD63FC99CAC}.ClientEnd Self schedule breakdown type. selfSchedType {D94DCDEB-89BA-49f1-96AA-1EB2DA733DD9} ReserveReq {7EED99BC-CD41-443b-94DE-ED7BDA941A80}.ClientEnd SelfSeries {C719B547-0548-4e82-8A7C-4150017941AB}.SupplierEnd Series {C719B547-0548-4e82-8A7C-4150017941AB}.ClientEnd Positive sequence resistance. r {0921F3FA-D656-43fd-979B-13401C2AC583} Zero sequence resistance. r0 {E37FE89F-D6D7-4728-894D-1797E5FE6B15} The maximum current the varistor is designed to handle at specified duration. It is used for short circuit calculations and exchanged only if SeriesCompensator.varistorPresent is true.The attribute shall be a positive value. varistorRatedCurrent {A64EF97A-B0EC-45de-B90A-1A86F08CA31B} The dc voltage at which the varistor starts conducting. It is used for short circuit calculations and exchanged only if SeriesCompensator.varistorPresent is true. varistorVoltageThreshold {5E30BCEC-E8EB-4b1d-9AE5-E44FF6B0FFDE} Positive sequence reactance. x {F6F38E50-1E7A-4736-9E5E-0A3058E1D256} Zero sequence reactance. x0 {B3898136-E885-48bc-BBFB-A9F50D36078B} All configuration events created for this service category. ConfigurationEvents {460BA6C7-2417-41f6-8AC0-A21EE240B5BC}.SupplierEnd All customer agreements with this service category. CustomerAgreements {1CD25DA9-4F95-43aa-A7CF-B41C352C30AA}.ClientEnd All pricing structures applicable to this service category. PricingStructures {4940002E-34B8-4d2b-96A5-2E4EC7A20FF2}.SupplierEnd All usage points that deliver this category of service. UsagePoints {E8ABDA4A-FD10-41db-B40A-285E3E93266A}.ClientEnd Kind of service. kind {2EBA6E82-3221-4395-829D-A3E65904FFC2} Period in which this service guantee applies. applicationPeriod {0BFD8F02-C834-4a59-8DFB-2717DC74C117} Amount to be paid by the service provider to the customer for each violation of the serviceRequirement. payAmount {8D25CF2E-092C-48f3-A976-8DB91767633B} All customer agreements regulating this service location. CustomerAgreements {C20149AA-BEFF-43c5-B26A-F75F414F345B}.ClientEnd All end devices that measure the service delivered to this service location. EndDevices {E1374558-A400-46da-9FB2-5F7497097A3D}.SupplierEnd TroubleTicket {61FDCE34-6ACD-4edb-A961-05C33EC48E86}.SupplierEnd All usage points delivering service of the same type to this service location. UsagePoints {9FD59FA1-2361-4259-948C-56433EAAF9B0}.SupplierEnd Usage point applying this multiplier. UsagePoint {79BFF755-2D9F-4654-B2FF-58E647CF5C97}.ClientEnd Kind of multiplier. kind {FD0F696B-C1EF-4d5f-AD59-106A1F4AF45E} A transmission path has a pointofdelivery service point PODTransmissionPath {21CB6E87-75AD-4919-B4ED-4192EC9CC857}.SupplierEnd A transmission path has a pointofreceipt service point PORTransmissionPath {94CD1232-0212-4261-9FE4-36493F16F0E4}.SupplierEnd SinkReservation {64CB9D37-23DD-46f9-A4A8-47CF257C8105}.SupplierEnd SourceReservation {E205C545-1AF7-4249-9970-5E34913BCC3E}.SupplierEnd All BackAccounts this ServiceSupplier owns. BankAccounts {A4F61027-A9D2-47ab-AAEA-74678D39E4DE}.SupplierEnd All customer agreements of this service supplier. CustomerAgreements {47FE73EC-DD27-4731-8091-E3020EACA869}.SupplierEnd All usage points this service supplier utilises to deliver a service. UsagePoints {543EBBDE-C4D2-433d-AA02-21917EA65375}.SupplierEnd Kind of supplier. kind {97BCE74A-66DA-41c5-B277-E5E426C84E5B} EnergyMarket {53E470E2-1BB8-49d7-B69A-D59030A5D75A}.ClientEnd MajorChargeGroup {66C30E2D-CB35-48aa-A9C2-A0E325DA6FD5}.ClientEnd MarketInvoiceLineItem {C0177491-5DB7-458c-8967-3D68B4E446EA}.ClientEnd MarketLedgerEntry {DE87169A-1AAE-49ed-BD84-5D34B06D5FC7}.ClientEnd Interval for activity of this shift. activityInterval {D6FE67F4-3C80-4b32-9818-8D5532DE061F} Total of amounts receipted during this shift that can be manually banked cash and cheques for example. Values are obtained from Receipt attributessumReceipt.receiptAmount for all Receipt.bankable true. receiptsGrandTotalBankable {D5335364-235D-4a48-861B-7AF98AAB8DED} Total of amounts receipted during this shift that cannot be manually banked card payments for example. Values are obtained from Receipt attributessumReceipt.receiptAmount for all Receipt.bankable false. receiptsGrandTotalNonBankable {BC17E248-6477-4d51-B41B-4E4E78CB5829} Cumulative amount in error due to process rounding not reflected in receiptsGrandTotal. Values are obtained from Receipt attributessumReceipt.receiptRounding. receiptsGrandTotalRounding {C3518183-0A41-4389-9A21-109535A6EE06} Cumulative total of transacted amounts during this shift. Values are obtained from transactionsumTransaction.transactionAmount. It also has to be reconciled against transaction summarysumTransactionSummary.transactionsTotal. transactionsGrandTotal {6C451EBA-C13A-4b82-82F8-FBB163AD8BA7} Cumulative amount in error due to process rounding not reflected in transactionsGandTotal. Values are obtained from Transaction attributessumTransaction.transactionRounding. transactionsGrandTotalRounding {8A10D665-72FD-4267-AA34-9A63931D2A21} Crews {764EE186-E180-4d38-9772-53A73AAE0278}.ClientEnd status {6178AA14-8632-4cdf-90B8-12138E280E35} Date and time interval for which this shift pattern is valid when it became effective and when it expires. validityInterval {5F729D51-43E5-41b8-A854-85A58F6206FB} Transformer end that voltage is applied to in this shortcircuit test. The test voltage is chosen to induce rated current in the energised end. EnergisedEnd {2E74ED8F-7D38-402e-861A-F390B8A642DD}.SupplierEnd All ends shortcircuited in this shortcircuit test. GroundedEnds {B6AF9146-CA85-4239-9212-97F858E8662C}.SupplierEnd Short circuit current.. current {1F3F5D90-C113-4284-9E85-BDC58EAA8C76} Leakage impedance measured from a positivesequence or singlephase shortcircuit test. leakageImpedance {C03D7C4E-BB84-4120-AA44-C46A92A28D85} Leakage impedance measured from a zerosequence shortcircuit test. leakageImpedanceZero {BBD1204C-898A-4f87-9751-5E8F3B3D4AE5} Load losses from a positivesequence or singlephase shortcircuit test. loss {225E0C38-4C00-4998-9880-DEF76F478BAA} Load losses from a zerosequence shortcircuit test. lossZero {9FC0751F-4F3E-4419-AF99-6FA178C8DD27} Short circuit apparent power. power {DE0DBBF2-103F-48e0-B037-B395D72EF1C8} Short circuit voltage.. voltage {A20E661F-6064-42af-BA8B-CF34F8A2C0F0} ShuntCompensatorAction {9AE30218-76B9-40f7-A698-BEA89FA25113}.SupplierEnd The individual phases models for the shunt compensator. ShuntCompensatorPhase {C9E66DE4-0CA6-4e91-A991-5377B910EB14}.SupplierEnd The state for the number of shunt compensator sections in service. SvShuntCompensatorSections {E34ED370-94B3-4e27-B2EC-76FFEED7FAF5}.ClientEnd An automatic voltage regulation delay AVRDelay which is the time delay from a change in voltage to when the capacitor is allowed to change state. This filters out temporary changes in voltage. aVRDelay {41DD5C9D-F00A-412d-B1CA-33CA58C7440E} The voltage at which the nominal reactive power may be calculated. This should normally be within 10 of the voltage at which the capacitor is connected to the network. nomU {FF89F4A3-5F28-4e65-82C7-AE0A0164C161} The type of phase connection such as wye or delta. phaseConnection {53CF7DD7-A76B-40c3-9D46-B8F4B2AD9A24} Voltage sensitivity required for the device to regulate the bus voltage in voltagereactive power. voltageSensitivity {FA12B93F-FE0C-4b5a-9028-226FA7BAE2E9} ShuntCompensator {9AE30218-76B9-40f7-A698-BEA89FA25113}.ClientEnd Switching action to perform kind {D61F7ED2-3034-446c-A7E6-A0227DE1FD1C} ShuntCompensatorInfo {A5EB9D9A-15FF-4076-9909-2B14A074EA9C}.ClientEnd The size of the individual units that make up the bank. cellSize {ACAEE29C-5B26-4a73-B6AE-12EBEC5331DE} Kind of control if any. controlKind {85BB5EC6-8B89-430a-AA64-7EF587EF3876} For locally controlled shunt impedances which have a voltage override feature the high voltage override value. If the voltage is above this value the shunt impedance will be turned off regardless of the other local controller settings. highVoltageOverride {1B170E34-1AC6-490e-9F3A-798EC6F79CAE} Kind of local controller. localControlKind {86E40043-1E27-47bf-89B1-6A17E0F30CAB} For locally controlled shunt impedances which have a voltage override feature the low voltage override value. If the voltage is below this value the shunt impedance will be turned on regardless of the other local controller settings. lowVoltageOverride {FDEB0357-8EAB-44b8-87E8-DA9A6ED0A801} For VAR amp or power factor locally controlled shunt impedances Kind of regulation branch. regBranchKind {65BCE8A9-0D6F-4265-B4FE-D828403B58D4} Phases that are measured for controlling the device. sensingPhaseCode {B38D809A-2A66-41d6-BE06-2D6FADC5DFC8} Time interval between consecutive switching operations. switchOperationCycle {055BF15E-41F1-4025-B226-79E6A5420387} MktShuntCompensator {4C898DD2-7D9D-4138-A8D0-B271310AE638}.SupplierEnd ShuntCompensatorControl {A5EB9D9A-15FF-4076-9909-2B14A074EA9C}.SupplierEnd Maximum allowed apparent power loss. maxPowerLoss {54CBED91-48A8-49bb-BEDA-05CFF307441B} Rated current. ratedCurrent {4A99376B-5DC3-4624-A07C-747A7172A8F6} Rated reactive power. ratedReactivePower {4608D242-6EF9-42be-B3FD-9F96542D71C5} Rated voltage. ratedVoltage {BA81D35A-EDC6-4968-8264-56C8F0954E71} Shunt compensator of this shunt compensator phase. ShuntCompensator {C9E66DE4-0CA6-4e91-A991-5377B910EB14}.ClientEnd Phase of this shunt compensator component. If the shunt compensator is wye connected the connection is from the indicated phase to the central ground or neutral point. If the shunt compensator is delta connected the phase indicates a shunt compensator connected from the indicated phase to the next logical nonneutral phase. phase {623751D6-D4B2-463b-8D77-0E4BD5D0A99B} A thermal generating unit may have a shutdown curve. ThermalGeneratingUnit {4D553F1E-EFC5-42c1-92D6-0E421FE8975B}.SupplierEnd Fixed shutdown cost. shutdownCost {09C3B77C-60B5-452a-AB1F-2D43BD4EE800} Kind of this function. kind {3ECD9B17-7937-4d8d-B398-2F9197F585AD} Crafts {F6C636B7-1341-45e9-9F57-F9DAF8AA60FC}.SupplierEnd ErpPerson {9D792EF4-F8E0-42ce-A1BF-B84E9BA01D5F}.ClientEnd QualificationRequirements {E5C4C8B8-F4DA-4f11-BECD-A45EE50E9E7D}.SupplierEnd Interval between the certification and its expiry. certificationPeriod {116B8739-9A90-48b6-B6AD-98F5CA835FB2} Level of skill for a Craft. level {E2D47EC8-BA96-4046-8C2B-27FCEBEB216A} Kind of space analog. kind {5F3FC9AB-6EDA-4390-8E8C-646A41CD6034} UserAttributes used to specify further properties of the asset covered with this specification. Use name to specify what kind of property it is and value.value attribute for the actual value. AssetProperites {77BA456A-7BFE-460d-9B1F-6CFF50541E78}.ClientEnd AssetPropertyCurves {54F87E6E-39D6-413c-AF0C-2BC67DD4F008}.SupplierEnd DimensionsInfos {5070DD0D-A85D-4e3a-8E88-6373ED2A15DE}.ClientEnd Mediums {E64B800B-A4D4-4190-B7C3-AC53BAA0C1DD}.SupplierEnd QualificationRequirements {5119AA22-9D22-4252-BA20-4DF21D5E255F}.ClientEnd UserAttributes used to specify ratings of the asset covered by this specification. Ratings also can be used to set the initial value of operational measurement limits. Use name to specify what kind of rating it is e.g. voltage current and value attribute for the actual value and unit information of the rating. Ratings {A095B451-1D6E-48b1-8999-6944FB2D21D0}.ClientEnd ReliabilityInfos {D1E9877C-BF93-4c20-98EC-841633A21B58}.ClientEnd Test sampler taker who gathered this specimen. AssetTestSampleTaker {B057FDCC-0EE2-422a-A257-ADAE38F4BB01}.SupplierEnd Results from lab testing done on specimen. LabTestDataSet {C2DD4DA1-4B26-4df0-8A58-EA8BE7DC80D4}.ClientEnd Operating ambient temperature in C. ambientTemperatureAtSampling {0FA4E55E-ED4B-4f68-90CB-6A4CF4CA436B} Operating ambient humidity in percent. humidityAtSampling {71765497-90E9-417c-ABEB-2D69386FB5A3} multiplier {FBDA5FCF-A38C-4346-92F6-2DFB2B0D3895} unit {74C09094-CAA7-4c9a-95C3-47A5B2404762} RemedialActionScheme {8DCB0B7D-45B9-483c-A5E0-6AD156D9B7A1}.SupplierEnd A Stage consist of one or more StageTrigger. StageTrigger {A409C34B-147C-43be-B5D6-51CEB1F7EC3F}.ClientEnd Association to a Gate that through a gate logic and input pin defines arming of the StageTrigger. GateArmed {EB996EFA-4676-43b1-8D6E-DCBC54112791}.SupplierEnd For the StageTrigger to active the set of protective actions the condition for communication needs to be met true. GateComCondition {5CBC56EA-4603-4ba3-93A1-162E6A7AC535}.SupplierEnd The Gate result that trigger the StageTrigger and thereby executing the a set of protective actions. GateTrigger {5AED1733-5EAF-4438-9A42-E9656E4508DA}.SupplierEnd ProtectiveActionCollection {E36506E6-0D19-4846-93FA-EA04CBD6AC84}.ClientEnd Stage {A409C34B-147C-43be-B5D6-51CEB1F7EC3F}.SupplierEnd CustomerAgreements {6081B3B7-6BE2-4dff-BD8D-9BAF5855DE67}.ClientEnd The units startup model may have a startup ignition fuel curve. StartupModel {C38D6633-D0B0-4d21-B763-449DFF5AF2B2}.SupplierEnd Type of ignition fuel. ignitionFuelType {C0AFBB3C-2C3E-4e9e-BFD8-47888F84708B} The units startup model may have a startup main fuel curve. StartupModel {09B7E8E0-2AC8-4a66-AB2A-A93F87445E7D}.SupplierEnd Type of main fuel. mainFuelType {E3D51998-0F3A-45fc-886D-E130B8765796} The units startup model may have a startup ramp curve. StartupModel {4425F095-1419-4c26-8C88-C49B274DA364}.SupplierEnd The startup ramp rate in gross for a unit that is on hot standby. hotStandbyRamp {AF249DD9-1266-4768-8BDD-23C837C7A198} GeneratingBid {2C224C9B-54C9-40f5-8796-E455294849C7}.SupplierEnd RegisteredGenerators {5280EFA9-0801-4e47-AE46-18FA93656505}.SupplierEnd RegisteredGenerator {6F584527-B9F8-4bf0-8BA6-16C6A099CFDF}.ClientEnd RegisteredGenerator {AA03FF31-0541-46dc-AC61-8F38D2603BD6}.ClientEnd GeneratingBid {70D9DB41-202E-44ce-B18A-F7269093B950}.SupplierEnd RegisteredGenerator {70E6AE66-01DD-4461-AE89-C87284489617}.ClientEnd The units startup model may have a startup ignition fuel curve. StartIgnFuelCurve {C38D6633-D0B0-4d21-B763-449DFF5AF2B2}.ClientEnd The units startup model may have a startup main fuel curve. StartMainFuelCurve {09B7E8E0-2AC8-4a66-AB2A-A93F87445E7D}.ClientEnd The units startup model may have a startup ramp curve. StartRampCurve {4425F095-1419-4c26-8C88-C49B274DA364}.ClientEnd A thermal generating unit may have a startup model. ThermalGeneratingUnit {99C4296C-33D5-4c79-A4FB-0A9EC0794967}.SupplierEnd Fixed maintenance cost. fixedMaintCost {760B633F-99EF-4f6d-8CA8-B4B5880A26CE} The amount of heat input per time unit required for hot standby operation. hotStandbyHeat {E71276CD-C2B1-42ce-8481-78CBA4F6394F} Incremental maintenance cost. incrementalMaintCost {DFCA0C86-9A51-43bf-B5A3-BDBEEDE377E4} The minimum number of hours the unit must be down before restart. minimumDownTime {4CD20558-5875-4ac7-86A2-20DA3BD585B9} The minimum number of hours the unit must be operating before being allowed to shut down. minimumRunTime {ECF4E9FF-B38E-4962-BD09-AA1DF2E8D2DC} The opportunity cost associated with the return in monetary unit. This represents the restarts share of the unit depreciation and risk of an event which would damage the unit. riskFactorCost {68F157E6-FEC4-43c4-BDD6-16465BC7913E} Total miscellaneous start up costs. startupCost {09CB2A01-9830-4356-9049-4065388E8C1C} The units auxiliary active power consumption to maintain standby mode. stbyAuxP {4DF7BFED-0C3C-4474-B711-8787C7070917} Static Var Compensator dynamics model used to describe dynamic behaviour of this Static Var Compensator. StaticVarCompensatorDynamics {13F2FB39-01AE-4cc8-8B2D-1E843943E145}.ClientEnd Capacitive reactance at maximum capacitive reactive power. Shall always be positive. capacitiveRating {E35F733F-7F1A-4124-8539-BE6FEE250CCD} Inductive reactance at maximum inductive reactive power. Shall always be negative. inductiveRating {3F4C093D-2CC5-4ee5-A225-31D4B7AFD3AC} Reactive power injection. Load sign convention is used i.e. positive sign means flow out from a node.Starting value for a steady state solution. q {EAA3BC8D-A193-4c4e-BE22-F45A9C2A491C} SVC control mode. sVCControlMode {5D29151B-3D23-4964-BE66-3C58A2D84411} The characteristics slope of an SVC defines how the reactive power output changes in proportion to the difference between the regulated bus voltage and the voltage setpoint.The attribute shall be a positive value or zero. slope {71A799EF-C590-4631-A53A-EC207BFFC113} The reactive power output of the SVC is proportional to the difference between the voltage at the regulated bus and the voltage setpoint. When the regulated bus voltage is equal to the voltage setpoint the reactive power output is zero. voltageSetPoint {170589DF-9B85-487a-BC91-4BC8ECB1D88C} Static Var Compensator to which Static Var Compensator dynamics model applies. StaticVarCompensator {13F2FB39-01AE-4cc8-8B2D-1E843943E145}.SupplierEnd The order in which this statistical calculation is done. CalculationMethodOrder {3472E24D-F0B4-42fa-AC2A-06A47816E2D7}.SupplierEnd Calculation mode. calculationMode {14CDE2CD-4A7E-48e5-BDD0-317BA89E9C8A} Kind of statistical calculation specifying how the measurement value is calculated. calculationTechnique {9D14D95E-1052-43eb-9FD3-BFB300D4F236} A cogeneration plant has a steam sendout schedule. CogenerationPlant {29FFC448-2620-47ba-BE72-7DE2E8858FD0}.SupplierEnd Steam turbines may have steam supplied by a steam supply. SteamTurbines {93AA313B-1303-4624-9368-557ED82DDB59}.SupplierEnd Steam turbines may have steam supplied by a steam supply. SteamSupplys {93AA313B-1303-4624-9368-557ED82DDB59}.ClientEnd Crossover time constant. crossoverTC {BC022F6E-0F59-432b-877C-B9F0BE686B85} First reheater time constant. reheater1TC {F882F483-4C43-4bdc-A2E2-E17CD57AB9B0} Second reheater time constant. reheater2TC {69FADD2A-834A-4af5-9042-6B51AF8B0840} Steam chest time constant. steamChestTC {2AC91EE6-4C0A-47f3-B4E3-746439190A8D} Status of this address. status {32354147-6588-46c6-9B6F-C327E702BCAC} Street detail. streetDetail {080F12A9-718C-4a10-A2BE-878231C3927F} Town detail. townDetail {07E7BC8F-BAA8-4462-BDA1-BA35D58B129D} Pole to which thiss streetlight is attached. Pole {7CD98E1E-DB38-4f5f-B4AB-606B687CE71D}.ClientEnd Length of arm. Note that a new light may be placed on an existing arm. armLength {83A307A1-6E90-47dc-8716-3A1FF0F2CF0C} Lamp kind. lampKind {AE93BE6F-645B-40ce-916E-9D30BEBAA915} Power rating of light. lightRating {369AE287-31F6-48aa-911D-DF8B05944CBB} The values connected to this measurement. StringMeasurementValues {05328E98-5B4F-4f0b-B2C2-BDCB0EF11D35}.ClientEnd Measurement to which this value is connected. StringMeasurement {05328E98-5B4F-4f0b-B2C2-BDCB0EF11D35}.SupplierEnd Unit multiplier of this quantity. multiplier {63AA3365-459E-41b7-B43C-645BEF9F9DAD} Unit of this quantity. unit {175C2CD1-448B-4e14-A8E5-7811DF130C49} Structure support for this structure. StructureSupports {56A18E04-CDA2-4508-BE62-DE15B2FDE7D7}.SupplierEnd WireSpacingInfos {7995689F-9BD5-49e1-BAE8-C986A5446310}.ClientEnd Visible height of structure above ground level for overhead construction e.g. Pole or Tower or below ground level for an underground vault manhole etc. Refer to associated DimensionPropertiesInfo for other types of dimensions. height {85F62439-56B8-4ec7-AC19-4C99CD234A67} Material this structure is made of. materialKind {7D3CB05A-3B0D-4075-9C4C-AC060E8857F0} Maximum rated voltage of the equipment that can be mounted oncontained within the structure. ratedVoltage {3EE72D69-2ED8-493f-93CC-7CA89A9619F6} The secured structure supported by this structure support. SecuredStructure {56A18E04-CDA2-4508-BE62-DE15B2FDE7D7}.ClientEnd if anchor Kind of anchor. anchorKind {C4434326-F3F2-4200-9473-F8E26B0B92D0} if anchor Length of rod used. anchorRodLength {40123234-BEBF-48f4-B938-21D72C3D2970} Direction of this support structure. direction {E16D0A41-D1A0-4b09-95AD-1ABA0E5EA383} Kind of structure support. kind {0E185E57-D6CD-4929-8F09-373419661020} Length of this support structure. length {B2008BB0-6908-4871-8FB7-D045954082F6} AdjacentCASet {6E3CCC1F-13F4-4f39-8628-7EAC38F18D74}.ClientEnd AggregateNode {95FCC4C7-2611-4267-9EF0-B7A30B49ECE8}.ClientEnd AreaReserveSpecification {F6EC071D-A9FE-4972-8340-7B298A3F59EF}.ClientEnd BidSelfSched {8B909238-F00E-4f58-A22C-21C482041260}.SupplierEnd CnodeDistributionFactor {69BC43A4-9AD8-4639-A0FA-43901913DEDB}.ClientEnd ControlAreaDesignation {ABACF27C-565A-45bd-B69C-0A1A99CECFC2}.ClientEnd ExPostLossResults {82BD4DEF-763E-4739-B4DC-07A529BF1E77}.ClientEnd Energy is transferred between interchange areas Export_EnergyTransactions {FE5AFCF1-5AF3-41b8-A9F4-38F6BDF94098}.SupplierEnd From_Flowgate {1041B4DE-551C-4099-85BD-E8EBC12523E1}.ClientEnd GeneralClearingResults {52EA9C29-FB61-4524-A03E-85E09C194BB4}.SupplierEnd The interchange area may operate as a control area HostControlArea {FBEF4124-D3C2-4585-A504-3D5551015F14}.ClientEnd Energy is transferred between interchange areas Import_EnergyTransactions {2143F763-800E-436a-B8FB-44CEB5B9E1EB}.SupplierEnd A control area can have one or more net inadvertent interchange accounts InadvertentAccount {3CB78F17-FFCF-48bc-835B-C78BF0FB4994}.ClientEnd LossClearingResults {609C0491-3062-444d-9F49-61791CBD647B}.ClientEnd Pnode {EE82157A-8E48-4af6-9DC9-7A0098943EE0}.ClientEnd RTO {BA94D32D-6765-457a-9130-34C38FCE2CD6}.ClientEnd A control area can receive dynamic schedules from other control areas Receive_DynamicSchedules {83DC5357-DC69-4c13-B260-5026E5DFD942}.ClientEnd RegisteredResource {8406940A-7751-48cd-BEC8-1C7154E28625}.ClientEnd A control area can send dynamic schedules to other control areas Send_DynamicSchedules {CB9AAC47-376D-4a7e-9E56-D14A4F86E63E}.ClientEnd The SubControlArea is on the A side of a collection of metered points which define the SubControlAreas boundary for a ControlAreaOperator or CustomerConsumer. SideA_TieLines {A0461DED-D054-4723-9A90-182B86F0177A}.ClientEnd The SubControlArea is on the B side of a collection of metered points which define the SubControlAreas boundary for a ControlAreaOperator or CustomerConsumer. SideB_TieLines {3DBD1F56-AC7D-4daa-BEA3-1F36902AF8D6}.ClientEnd To_Flowgate {84D89B72-DEA9-4433-B8A9-4EEC604AA936}.ClientEnd Used in conjunction with the InternalCA flag. If the InternalCA flag is YES this flag does not apply. If the InternaCA flag is NO this flag provides an indication of AdjacentCA NO or Embedded CA YES. embeddedControlArea {AE6DA985-8D93-461a-BA70-C1E1E7B240EC} A YesNo indication that this control area is contained internal to the system. internalCA {C18E7C81-E2C6-44b2-BF64-3ED3C6803CC2} Indication that this control area is the local control area. localCA {8827F780-172A-4aa8-8A9A-0FD8CB344649} The DC lines in this subgeographical region. DCLines {87933AA2-5F6F-4768-BCDE-772A53C5248C}.ClientEnd The lines within the subgeographical region. Lines {BAB73169-D3BE-43c3-A58B-F1B87EAA1239}.SupplierEnd The geographical region which this subgeographical region is within. Region {023E20DF-DF02-4ffb-A047-E5BBDB18AB59}.ClientEnd The substations in this subgeographical region. Substations {66E7D72B-2889-483c-80A2-2E51B283F2B1}.SupplierEnd The LoadArea where the SubLoadArea belongs. LoadArea {985B4F6F-A487-4691-9470-6EE3C9636DC8}.ClientEnd The Loadgroups in the SubLoadArea. LoadGroups {6910F2B1-E481-496a-91B7-7AAA14F6D47E}.SupplierEnd Bays contained in the substation. Bays {51152F4A-1B03-451f-BA84-6A05A6AE1630}.ClientEnd The primary feeder that normally energizes the secondary substation. Used for naming purposes. Either this association or the substation to subgeographical region should be used for hierarchical containment specification. NamingFeeder {D06442E1-D688-4393-8B71-E08E4CA4685F}.ClientEnd The normal energized feeders of the substation. Also used for naming purposes. NormalEnergizedFeeder {D83ED2BA-7B91-4a91-81C0-A7CF3669C450}.ClientEnd The feeders that potentially energize the downstream substation. Should be consistent with the associations that describe the naming hierarchy. NormalEnergizingFeeder {11C09449-0F39-4372-A153-258CD2A57196}.ClientEnd The SubGeographicalRegion containing the substation. Region {66E7D72B-2889-483c-80A2-2E51B283F2B1}.ClientEnd The voltage levels within this substation. VoltageLevels {0E9E9E28-C575-47c5-BF01-7F4EB8B36D16}.SupplierEnd RegisteredResource {8BD04841-261A-42f1-AF12-1F6BE08DB56A}.ClientEnd TransmissionContractRight {869976B9-DCEB-44ff-8BDB-956B7D44DFE7}.ClientEnd Maximum continuous power frequency voltage allowed on the surge arrester. continuousOperatingVoltage {6CDB06F8-CA6A-4e35-A80A-FC270829F0B5} Residual voltage during an 8x20 microsecond current impulse at the nominal discharge current level. lightningImpulseDischargeVoltage {8BDDADF7-055C-44a7-9962-CD64321A6839} The lightning discharge current used to classify the arrester. Choices are limited to 1.5 2.5 5 10 and 20 kA by IEC 60099. nominalDischargeCurrent {5E1A8FC6-62BA-405e-BB8B-76F9DA205829} Fault current level at which all parts of the failed arrester lie within a circle prescribed by IEC 60099. pressureReliefClass {3953FC64-1B9E-4db3-A163-338F0ECA9143} The temporary overvoltage TOV level at power frequency that the surge arrester withstands for 10 seconds. ratedVoltage {5AEEF44D-CC1A-4514-A087-4E6350EB6ABF} Residual voltage during a current impulse with front time of 1 microsecond and magnitude equal to the nominal discharge current level. steepFrontDischargeVoltage {FA9DB83F-62F9-452c-926D-6F473208F93A} Residual voltage during a current impulse with front time of at least 30 microseconds and magnitude specified in IEC 60099 for the line discharge class. Does not apply to line discharge class 0. switchingImpulseDischargeVoltage {923A09AB-C1E2-4a71-AFB2-63E400F061DA} multiplier {E0742F08-9A12-471f-ABF4-DD7CC752C0C9} unit {5F029910-FE0C-4726-A5FD-9CBECFF40F29} multiplier {4E5C6626-C0DA-457e-9F3B-1CB0C6CFCCCE} unit {2F3A3342-2DA4-445c-A69F-E2F935C427FA} The topological node associated with the flow injection state variable. TopologicalNode {65235B7E-6091-4035-BB6C-FD64EA32C24B}.SupplierEnd The active power mismatch between calculated injection and initial injection. Positive sign means injection into the TopologicalNode bus. pInjection {B02C5723-912A-4bd8-BA35-6887EBD8AED0} The terminal phase at which the connection is applied. If missing the injection is assumed to be balanced among nonneutral phases. phase {CD960FEC-49EB-489f-9CC2-069E98BF3109} The reactive power mismatch between calculated injection and initial injection. Positive sign means injection into the TopologicalNode bus. qInjection {3E4BB80E-3418-47b4-AB66-36177D470417} EnergyGroup {9E145EE8-2544-4933-9DE4-FB008FF09419}.SupplierEnd The terminal associated with the power flow state variable. Terminal {652607BF-3991-4400-89A1-D3208A9FB60D}.SupplierEnd The active power flow. Load sign convention is used i.e. positive sign means flow out from a TopologicalNode bus into the conducting equipment. p {626A0C29-2FD5-41d3-ADD9-D11D922B2D72} The individual phase of the flow. If unspecified then assumed to be balanced among phases. phase {3A0A5CD8-DB0E-41fc-860F-DC7769CB16F2} The reactive power flow. Load sign convention is used i.e. positive sign means flow out from a TopologicalNode bus into the conducting equipment. q {B7D95D29-FFA8-4bd2-B8CF-621150B9A9CE} The shunt compensator for which the state applies. ShuntCompensator {E34ED370-94B3-4e27-B2EC-76FFEED7FAF5}.SupplierEnd The terminal phase at which the connection is applied. If missing the injection is assumed to be balanced among nonneutral phases. phase {5B5AF88F-78C1-4d6c-97D5-07760B029804} The conducting equipment associated with the status state variable. ConductingEquipment {A1BADE18-494C-4d12-B7E2-2C9AF7F526ED}.SupplierEnd The individual phase status. If the attribute is unspecified then three phase model is assumed. phase {0C299D0C-7EE7-4696-BFAE-7DD091F24B14} The switch associated with the switch state. Switch {F56E3CEE-AA4F-4da4-B8AA-A646C6EC8FBD}.SupplierEnd The terminal phase at which the connection is applied. If missing the injection is assumed to be balanced among nonneutral phases. phase {5501A636-5B85-4d71-8330-E9ED8F51CD46} The tap changer associated with the tap step state. TapChanger {CAAE86A7-3A22-41ff-A8A4-68A4B4723DD2}.SupplierEnd The topological node associated with the voltage state. TopologicalNode {4628B761-2D2E-4428-AB48-91ADDAB6ED29}.SupplierEnd The voltage angle of the topological node complex voltage with respect to system reference. angle {1D320E89-265C-41ec-A654-A0FE668376BD} If specified the voltage is the line to ground voltage of the individual phase. If unspecified then the voltage is assumed balanced. phase {49991EDC-1187-4282-8771-D71CBDDBE7C5} The voltage magnitude at the topological node. The attribute shall be a positive value. v {B4D2EA92-2DE6-41bb-9362-77F68809B646} Composite switch to which this Switch belongs. CompositeSwitch {E6CD744D-0D2A-4e23-9C5E-B2A3778D7618}.ClientEnd ConnectDisconnectFunctions {ABF72E73-E9B7-40a5-8FC4-D1B196EC3845}.ClientEnd The switch state associated with the switch. SvSwitch {F56E3CEE-AA4F-4da4-B8AA-A646C6EC8FBD}.ClientEnd Action changing status of this switch. SwitchAction {FE121092-F0C3-453d-81C5-4E473EC5F7A5}.ClientEnd The individual switch phases for the switch. SwitchPhase {ECD7A6EB-ADCC-4463-898C-77400900FFDC}.SupplierEnd A Switch can be associated with SwitchSchedules. SwitchSchedules {440A6BB4-CEFF-4c2b-8512-9008A52371C0}.SupplierEnd UnavailabilitySwitchAction {0C9534D4-CB50-4b67-88A1-762995554EA1}.ClientEnd The maximum continuous current carrying capacity in amps governed by the device material and construction.The attribute shall be a positive value. ratedCurrent {486957C7-D5EF-499f-8CE3-7A2E88765D52} Switch that is the object of this switch action. OperatedSwitch {FE121092-F0C3-453d-81C5-4E473EC5F7A5}.SupplierEnd Planned outage for whose scope this switch action applies. PlannedOutage {7DAECB14-3133-4fec-91BB-CBC4E6C8147D}.ClientEnd Switching action to perform. kind {CB209D30-15D7-4525-8F66-9B0E2CF7BCCF} The maximum fault current a breaking device can break safely under prescribed conditions of use. breakingCapacity {D1E70A4D-6D44-451d-95BC-F4CBDA3BF165} Weight of gas in each tank of SF6 dead tank breaker. gasWeightPerTank {FB310EDA-3064-4783-896C-ECE09394DE3F} Gas or air pressure at or below which a low pressure alarm is generated. lowPressureAlarm {1F0BA60A-B64C-41c3-9B46-0B1D3C4B1F45} Gas or air pressure below which the breaker will not open. lowPressureLockOut {4411A396-B4BE-4b4b-AB8A-DFB67AD2A3DD} Volume of oil in each tank of bulk oil breaker. oilVolumePerTank {EF23AC03-FC2D-44db-862D-C7D913D369A6} Rated current. ratedCurrent {4977C6DF-6942-44b1-9737-FFF45E46AF9E} Frequency for which switch is rated. ratedFrequency {39398985-20DE-4183-9AC1-4613C7F54560} Rated impulse withstand voltage also known as BIL Basic Impulse Level. ratedImpulseWithstandVoltage {9427D894-AA4D-4a9d-9F1F-9239B284E984} Switch rated interrupting time in seconds. ratedInterruptingTime {30D9FDC7-4B28-4869-86C2-B9C405EBE65A} Rated voltage. ratedVoltage {BBC6C1D2-BBBE-48a9-B7D8-CE65E2BD9970} Breaker asset to which this operation information applies. Breaker {D39D36F1-D054-4dbc-8E93-564DC921D2DB}.SupplierEnd The switch of the switch phase. Switch {ECD7A6EB-ADCC-4463-898C-77400900FFDC}.ClientEnd Phase of this SwitchPhase on the side with terminal sequence number equal to 1. Should be a phase contained in that terminals phases attribute. phaseSide1 {2DA4F4E9-B9A5-443a-9E85-E7AEAB2C7ACD} Phase of this SwitchPhase on the side with terminal sequence number equal to 2. Should be a phase contained in that terminals Terminal.phases attribute. phaseSide2 {BFC8496F-8B0D-4303-BD3E-4229B57A7D10} The maximum continuous current carrying capacity in amps governed by the device material and construction.The attribute shall be a positive value. ratedCurrent {96858D1B-7CBC-4335-9D29-760A0394032C} A SwitchSchedule is associated with a Switch. Switch {440A6BB4-CEFF-4c2b-8512-9008A52371C0}.ClientEnd MktSwitch {F865D7AC-3978-4a82-A41D-4131DB7D21B2}.SupplierEnd Circuit Breaker Status closed or open of the circuit breaker from the power flow. switchStatus {C01AFC8E-EF1B-4657-8684-10E35AE10CA2} Crew {A7E0FAFD-8B4F-45b4-B614-D821AB007EF9}.SupplierEnd Operator responsible for this switching step. Operator {4CE8C00C-90B0-4798-B63D-CD522B565717}.SupplierEnd SwitchingEvent {D6B0C16A-D051-4e89-A8B6-F922CDD37B8A}.SupplierEnd SwitchingPlan {342466CF-F77D-455b-AE6E-601403A7AC6D}.SupplierEnd SwitchingStep {AEB3B57B-446D-4886-89F5-9B26EA823237}.ClientEnd Phases of the Switching Action phases {EF2EBC58-D3DB-4167-95C6-50D1F274E39B} SwitchingAction {D6B0C16A-D051-4e89-A8B6-F922CDD37B8A}.ClientEnd Location {4909DE0B-FF1E-4cd5-8339-71D4430BBEF1}.ClientEnd SwitchingPlan {997A942D-55D5-453f-8757-284E88136668}.SupplierEnd The planned start and end time for the switching order. plannedExecutionInterval {94F12B92-AB9B-428e-9771-3064A2E98519} Outage that will be activated or eliminated when this switching plan gets executed. Outage {D2D106C9-7B45-4172-8201-66E3FAC64E75}.SupplierEnd The outage plan for which the switching plan is defined. OutagePlan {205E346A-7AC3-4f63-9926-D90B3687F39B}.SupplierEnd PlannedOutageNotification {D86059AA-B4DC-4561-AA64-9EF56A447F18}.ClientEnd All safety documents applicable to this swtiching plan. SafetyDocuments {27C9D948-FDCD-4bb2-9FA5-B01A6569D284}.SupplierEnd SwitchingAction {342466CF-F77D-455b-AE6E-601403A7AC6D}.ClientEnd SwitchingOrder {997A942D-55D5-453f-8757-284E88136668}.ClientEnd SwitchingPlanRequest {648AFF78-8D22-4600-A50C-89FA5615F248}.ClientEnd All groups of switching steps within this switching plan. SwitchingStepGroups {3BD787CE-70EE-4500-B66D-3B01AA018B58}.SupplierEnd All work tasks to execute this switching plan. WorkTasks {1B1B92E7-633C-4e30-BCDE-9C62496BE1E8}.SupplierEnd the planned start and end times for the switching plan. plannedPeriod {1F964C14-A51B-47aa-9AF9-8840741E6592} RequestingOrganization {9F41E5C9-778C-4e68-B6F3-EE634A0DD569}.SupplierEnd SwitchingPlan {648AFF78-8D22-4600-A50C-89FA5615F248}.SupplierEnd forwardSwitchingDateTimeInterval {6228BA53-09CE-41fd-9CB1-53406E58683A} The window of time during which one or more customers will be deenergized during execution of the switching plan. outageDateTimeInterval {16EB8BE0-A988-4316-9CE8-FC73C73875CC} reverseSwitchingDateTimeInterval {A048C3B4-26CB-469e-B1C5-31C960EEA918} SwitchingAction {AEB3B57B-446D-4886-89F5-9B26EA823237}.SupplierEnd SwitchingStepGroup {9979325A-954B-4a3c-8836-B2C1A866D545}.SupplierEnd Switching plan to which this group belongs. SwitchingPlan {3BD787CE-70EE-4500-B66D-3B01AA018B58}.ClientEnd SwitchingStep {9979325A-954B-4a3c-8836-B2C1A866D545}.ClientEnd The maximum allowable voltage vector phase angle difference across the open device. maxAngleDiff {CF9BEE80-A0FD-4099-8E9B-74E0E1F23122} The maximum allowable frequency difference across the open device. maxFreqDiff {79177A3F-6BA1-4c98-ACC8-D4E2859634A7} The maximum allowable difference voltage across the open device. maxVoltDiff {C8AFFA34-11D5-4367-A006-E2A26954F064} The default reactive capability curve for use by a synchronous machine. InitialReactiveCapabilityCurve {6BEDDBFC-3D03-47f1-A9B8-266425DE28E8}.ClientEnd Prime movers that drive this SynchronousMachine. PrimeMovers {9C153102-5D80-4895-9BF2-7371CA48A80D}.ClientEnd All available reactive capability curves for this synchronous machine. ReactiveCapabilityCurves {3724CB9D-F524-4771-91F7-6BDCEBD04E47}.ClientEnd Synchronous machine dynamics model used to describe dynamic behaviour of this synchronous machine. SynchronousMachineDynamics {EAEF3FB4-D1E0-417a-9741-F25D491661F0}.ClientEnd Time delay required when switching from Automatic Voltage Regulation AVR to Manual for a lagging MVAr violation. aVRToManualLag {8E8FAE0F-8AB3-461e-87AE-13D268F13340} Time delay required when switching from Automatic Voltage Regulation AVR to Manual for a leading MVAr violation. aVRToManualLead {EC465023-F164-4b10-8FCB-FACEE28A4D66} Default base reactive power value. This value represents the initial reactive power that can be used by any application function. baseQ {4257F82E-4A8B-4da5-968D-82DBD19AA3EA} Active power consumed when in condenser mode operation. condenserP {0B22702D-FD5C-4b09-93A6-65E19B875E3D} Method of cooling the machine. coolantType {C236899A-1671-494f-8F38-0B8F1F4FBFA3} Generator star point earthing resistance Re. Used for short circuit data exchange according to IEC 60909. earthingStarPointR {91080667-F08F-4376-A5BB-2FF78C475574} Generator star point earthing reactance Xe. Used for short circuit data exchange according to IEC 60909. earthingStarPointX {ED9C53CE-C21E-4d12-B219-BE9E666EF2AA} Steadystate shortcircuit current in A for the profile of generator with compound excitation during 3phase short circuit. Ikk0 Generator with no compound excitation. Ikkltgt0 Generator with compound excitation.Ikk is used to calculate the minimum steadystate shortcircuit current for generators with compound excitation.4.6.1.2 in IEC 6090902001.Used only for single fed short circuit on a generator. 4.3.4.2. in IEC 6090902001. ikk {8A08EE9F-30F4-4ddd-9531-161EAB9B8F7E} Time delay required when switching from Manual to Automatic Voltage Regulation. This value is used in the accelerating power reference frame for powerflow solutions. manualToAVR {70C785D8-FE57-4b1d-ABC1-6F6247089D83} Maximum reactive power limit. This is the maximum nameplate limit for the unit. maxQ {0381E429-3037-4d2d-9AC8-CBED18D6B275} Maximum voltage limit for the unit. maxU {3A71319C-C9FB-449d-AAB9-EAE1C75907FC} Minimum reactive power limit for the unit. minQ {D2AAFB98-B566-478d-A769-6475747B2200} Minimum voltage limit for the unit. minU {60A97F8C-C22B-4d32-8728-24E8EFC7C318} Current mode of operation. operatingMode {AD303DEF-0BE9-4364-91F7-68A8CAA1C408} Part of the coordinated reactive control that comes from this machine. The attribute is used as a participation factor not necessarily summing up to 100 for the participating devices in the control. qPercent {3CBD29B9-1D15-4816-8720-F72FF7CE0C5D} Equivalent resistance RG of generator. RG is considered for the calculation of all currents except for the calculation of the peak current ip. Used for short circuit data exchange according to IEC 60909. r {F5F4EFCA-977E-4231-ACF7-CEDC8A85CD6F} Zero sequence resistance of the synchronous machine. r0 {3734B4AC-4BD3-4f19-A04C-3435D7EE6C14} Negative sequence resistance. r2 {3D5502B1-D49E-4c17-87D6-44C0850D2D41} Directaxis subtransient reactance saturated also known as Xdsat. satDirectSubtransX {5155AE7B-4DBA-4521-B3B8-B3623D53AF96} Directaxes saturated synchronous reactance xdsat reciprocal of shortcircuit ration. Used for short circuit data exchange only for single fed short circuit on a generator. 4.3.4.2. in IEC 6090902001. satDirectSyncX {FB6AA45C-2D6E-4ce4-92F0-5669E53A8EDF} Saturated Directaxis transient reactance. The attribute is primarily used for short circuit calculations according to ANSI. satDirectTransX {B56C10AE-7F4B-4b90-BE6C-BC1D10973D6F} Type of rotor used by short circuit applications only for single fed short circuit according to IEC 60909. shortCircuitRotorType {B1ED2B65-1FE5-47b0-B3A5-66BABE52A30E} Modes that this synchronous machine can operate in. type {546739CC-1CB9-4986-A713-D882FF155AEA} Range of generator voltage regulation PG in IEC 609090 used for calculation of the impedance correction factor KG defined in IEC 609090.This attribute is used to describe the operating voltage of the generating unit. voltageRegulationRange {EA18FF08-9F66-47bc-BF32-90256C925F9C} Zero sequence reactance of the synchronous machine. x0 {B18BF255-A3E4-4cba-B7D0-6E4F825191A9} Negative sequence reactance. x2 {BF860696-8442-4a51-A9C4-D369A3154954} Excitation base system mode. It should be equal to the value of iWLMDVi given by the user. iWLMDVi is the PU ratio between the field voltage and the excitation current iEfdi iWLMDVi x iIfdi. Typical value ifag. ifdBaseType {56BE4D5E-9BF0-4130-98D0-08E12BD43448} The crosscompound turbine governor with which this highpressure synchronous machine is associated. CrossCompoundTurbineGovernorDyanmics {4EEEDF69-9BB6-4d02-B662-A156239AF9B8}.ClientEnd The crosscompound turbine governor with which this lowpressure synchronous machine is associated. CrossCompoundTurbineGovernorDynamics {9C225B93-4040-4753-80B9-1A3D0F2B6D81}.ClientEnd Excitation system model associated with this synchronous machine model. ExcitationSystemDynamics {C7679E92-5BAF-4548-868A-CE939B02A5E8}.ClientEnd Compensation of voltage compensators generator for current flow out of this generator. GenICompensationForGenJ {E86FBA0E-B146-4508-95E0-F005CB0E4DF5}.ClientEnd Mechanical load model associated with this synchronous machine model. MechanicalLoadDynamics {2298CEEA-3BC8-4a46-9C31-9B6C0CDB1324}.ClientEnd Synchronous machine to which synchronous machine dynamics model applies. SynchronousMachine {EAEF3FB4-D1E0-417a-9741-F25D491661F0}.SupplierEnd Turbinegovernor model associated with this synchronous machine model. Multiplicity of greater than one is intended to support hydro units that have multiple turbines on one generator. TurbineGovernorDynamics {7E94D7D8-30B5-4d27-A321-7C51BCCE5C42}.SupplierEnd Directaxis damper 1 winding resistance. r1d {9E798A67-DC42-425f-A10D-9610076DCF0F} Quadratureaxis damper 1 winding resistance. r1q {F1213B97-B871-4549-BF5F-5F16B1B0D639} Quadratureaxis damper 2 winding resistance. r2q {849F71C7-D146-45cb-A4BE-753B6726F94F} Field winding resistance. rfd {1B9F3978-4D5C-4980-A1C3-C884DA4885A2} Directaxis damper 1 winding leakage reactance. x1d {C4E53960-70A6-47e5-9311-176463359305} Quadratureaxis damper 1 winding leakage reactance. x1q {CE53BB3B-68BC-4086-9F34-E4A21BF68277} Quadratureaxis damper 2 winding leakage reactance. x2q {D3593FFF-9C2F-4247-84FB-6DAE7962B470} Directaxis mutual reactance. xad {5051FDB0-1D4E-430b-BC09-503C3DA07790} Quadratureaxis mutual reactance. xaq {DE956CD6-ADD5-46cd-9B1C-33B2398D501D} Differential mutual Canay reactance. xf1d {50022E63-E39D-429b-AE4E-975F9006E67A} Field winding leakage reactance. xfd {5AE2A85B-6BEB-47af-8821-E927CF95B709} Type of synchronous machine model used in dynamic simulation applications. modelType {73D6CB74-566F-4841-8A9E-3BAD3C224435} Type of rotor on physical machine. rotorType {231BC777-B2A8-4e3d-B83E-FF8C3710102E} Damping time constant for Canay reactance gt 0. Typical value 0. tc {C1919777-31F2-4644-A6D1-28C6DAA9043C} Directaxis transient rotor time constant iTdoi gt SynchronousMachineTimeConstantReactance.tppdo. Typical value 5. tpdo {8E796ADA-01A1-4ef9-8324-8039862B5514} Directaxis subtransient rotor time constant iTdoi gt 0. Typical value 003. tppdo {BA422BE7-8810-45d5-BF06-7FFAE8DF6AB4} Quadratureaxis subtransient rotor time constant iTqoi gt 0. Typical value 003. tppqo {44000A7F-C655-4c11-BAA8-0B20B5067545} Quadratureaxis transient rotor time constant iTqoi gt SynchronousMachineTimeConstantReactance.tppqo. Typical value 05. tpqo {3CD276B4-CB60-4bdd-9B3E-830D1571FC0C} Directaxis subtransient reactance unsaturated iXdi gt RotatingMachineDynamics.statorLeakageReactance. Typical value 02. xDirectSubtrans {C8601C6E-0A50-4b75-82E5-C945BF86BF82} Directaxis synchronous reactance iXdi gt SynchronousMachineTimeConstantReactance.xDirectTrans. The quotient of a sustained value of that AC component of armature voltage that is produced by the total directaxis flux due to directaxis armature current and the value of the AC component of this current the machine running at rated speed. Typical value 18. xDirectSync {E5E769E3-B497-4bb4-9663-3EA4746454F0} Directaxis transient reactance unsaturated iXdi gt SynchronousMachineTimeConstantReactance.xDirectSubtrans. Typical value 05. xDirectTrans {E3134A5A-B4EC-48e4-86E7-155A1C2AFC7E} Quadratureaxis subtransient reactance iXqi gt RotatingMachineDynamics.statorLeakageReactance. Typical value 02. xQuadSubtrans {0E7D135F-5F3A-46c6-AE4C-B60EC7FBEA1E} Quadratureaxis synchronous reactance iXqi gt SynchronousMachineTimeConstantReactance.xQuadTrans.The ratio of the component of reactive armature voltage due to the quadratureaxis component of armature current to this component of current under steady state conditions and at rated frequency. Typical value 16. xQuadSync {A305C84C-5B1A-4031-B732-D563DB6CF731} Quadratureaxis transient reactance iXqi gt SynchronousMachineTimeConstantReactance.xQuadSubtrans. Typical value 03. xQuadTrans {0DD0CE8E-9CD0-41c7-AE60-A9BC031E2532} Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {996B609E-F446-4d2f-89B1-0A3771AD65C2}.ClientEnd DistributionFactorSet {5262F3D5-E6F1-466a-998C-AE0F2E35DBDF}.ClientEnd HostControlArea {451D980C-3785-4de0-AC06-5515EF2C589B}.ClientEnd MktConnectivityNode {C9774777-9F95-427f-B6A2-3AD33980CE68}.SupplierEnd AggregatedPnode {172CCB30-32D5-4d42-90DE-5FC85FCBF6C3}.ClientEnd AreaLoadCurve {825890F9-E350-40bd-AAE5-57E92CB28556}.SupplierEnd Edition of TAPPI standard. standardEdition {FC3D0B9B-514A-49e1-A275-B5E4E57FC4FA} TAPPI standard number. standardNumber {178BCCDB-B058-4f73-B130-5B5769DD3406} Informational message to be included in a Bilateral Table agreement. ICCPInformationMessage {D286EEBB-4C7C-449f-8621-C35CE7904696}.ClientEnd Is the Public Certificate used for mutual authentication between peers. PublicX509Certificate {D25EF464-773A-4ecc-AAF8-781EC96B694C}.ClientEnd TransmissionContractRight {646BBA57-9F62-43b1-9636-2CBBCFAC508B}.ClientEnd Tag associated with this tag action. OperationalTag {987DD03E-CEAD-487e-B8AA-EDF24171399B}.SupplierEnd Kind of tag action. kind {8ED3BAEC-B5E3-42ee-9454-4335FA916550} A hydro generating unit has a tailbay loss curve. HydroGeneratingUnit {F9B9CD62-2EEB-4f1a-969B-6EE451A47D3F}.SupplierEnd The tap step state associated with the tap changer. SvTapStep {CAAE86A7-3A22-41ff-A8A4-68A4B4723DD2}.ClientEnd The regulating control scheme in which this tap changer participates. TapChangerControl {422A1828-CD78-4432-8BAE-244E4B58419D}.SupplierEnd A TapChanger can have TapSchedules. TapSchedules {277E86F7-F72A-4768-9169-BE7D66F087B6}.ClientEnd For an LTC the delay for initial tap changer operation first step change. initialDelay {0AA6B766-F046-494b-9390-05BD55E7879C} Voltage at which the winding operates at the neutral tap setting. It is the voltage at the terminal of the PowerTransformerEnd associated with the tap changer when all tap changers on the transformer are at their neutralStep position. Normally neutralU of the tap changer is the same as ratedU of the PowerTransformerEnd but it can differ in special cases such as when the tapping mechanism is separate from the winding more common on lower voltage transformers.This attribute is not relevant for PhaseTapChangerAsymmetrical PhaseTapChangerSymmetrical and PhaseTapChangerLinear. neutralU {773D3CD1-ED8D-4b55-9D8B-93CFB1E9F5B3} For an LTC the delay for subsequent tap changer operation second and later step changes. subsequentDelay {4F65DA6B-7334-4903-AA61-23253E9E5FE6} The tap changers that participates in this regulating tap control scheme. TapChanger {422A1828-CD78-4432-8BAE-244E4B58419D}.ClientEnd Maximum allowed regulated voltage on the PT secondary regardless of line drop compensation. Sometimes referred to as firsthouse protection. limitVoltage {261AF2D6-5458-4172-B562-A5B87EF2DE46} Line drop compensator resistance setting for normal forward power flow. lineDropR {CD06DD47-4320-478a-8A92-D221920A8F11} Line drop compensator reactance setting for normal forward power flow. lineDropX {8508D424-8BD1-4091-ACDB-421EBDE54070} Line drop compensator resistance setting for reverse power flow. reverseLineDropR {7E55A13C-2039-4480-94D6-3D5349B78D50} Line drop compensator reactance setting for reverse power flow. reverseLineDropX {26287D63-3073-4251-BB04-A62DA3D4D241} MktTapChanger {FD943330-575B-40e5-BD88-67AED345044F}.SupplierEnd Basic Insulation Level BIL expressed as the impulse crest voltage of a nominal wave typically 1.2 X 50 microsecond. This is a measure of the ability of the insulation to withstand very high voltage surges. bil {07C90492-435C-4506-957B-77D770A68C06} Builtin current transformer primary rating. ctRating {7D5BDC10-5874-459c-A4B0-ADEE6521C215} Frequency at which the ratings apply. frequency {D58B8023-ABD8-428e-A20F-003A4E938A57} Voltage at which the winding operates at the neutral tap setting. neutralU {96E8E752-183F-4c03-918E-07D614C09B53} Rated apparent power. ratedApparentPower {499E7222-8003-4284-B65F-2BB2A1938EA7} Rated current. ratedCurrent {786D4754-E158-43cb-A811-1E4F65A2AD49} Rated voltage. ratedVoltage {63094176-6903-4c9e-A5A8-8F80346B7C45} Phase shift per step position. stepPhaseIncrement {DBDEA3D1-F974-4cc5-8CA6-5AD750F4D9E3} Tap step increment in per cent of rated voltage per step position. stepVoltageIncrement {6B881398-B17D-42e8-A4F8-18E054F82BF5} The magnetizing branch susceptance deviation as a percentage of nominal value. The actual susceptance is calculated as followscalculated magnetizing susceptance bnominal 1 bfrom this class100. The bnominal is defined as the static magnetizing susceptance on the associated power transformer end or ends. This model assumes the star impedance pi model form. b {EA68668F-E3EE-4702-978C-26D6BCED0B86} The magnetizing branch conductance deviation as a percentage of nominal value. The actual conductance is calculated as followscalculated magnetizing conductance gnominal 1 gfrom this class100. The gnominal is defined as the static magnetizing conductance on the associated power transformer end or ends. This model assumes the star impedance pi model form. g {F33BB85C-0624-4ff6-BA15-DBDA563BB4FB} The resistance deviation as a percentage of nominal value. The actual reactance is calculated as followscalculated resistance rnominal 1 rfrom this class100. The rnominal is defined as the static resistance on the associated power transformer end or ends. This model assumes the star impedance pi model form. r {81B79598-EB65-43c7-A0E5-B982F1EDF158} The series reactance deviation as a percentage of nominal value. The actual reactance is calculated as followscalculated reactance xnominal 1 xfrom this class100. The xnominal is defined as the static series reactance on the associated power transformer end or ends. This model assumes the star impedance pi model form. x {55B6B5C3-6A91-4136-936A-8AF71058D544} A TapSchedule is associated with a TapChanger. TapChanger {277E86F7-F72A-4768-9169-BE7D66F087B6}.SupplierEnd Percentage of the tape shield width that overlaps in each wrap typically 10 to 25. tapeLap {DA7ECDFF-E1EF-44c0-9DD2-A7EAF89A4681} Thickness of the tape shield before wrapping. tapeThickness {B2318584-1C47-4dee-8AE7-E811DE174D87} A reservoir may have a water level target schedule. Reservoir {B07A132F-C127-483d-A307-B2513535A40A}.SupplierEnd High target level limit above which the reservoir operation will be penalized. highLevelLimit {107C6947-5FB4-499d-BC3D-B968E8D3A5CF} Low target level limit below which the reservoir operation will be penalized. lowLevelLimit {2113498E-1110-4b1e-A32E-2243B5BFB42A} All pricing structures using this tariff. PricingStructures {680631D0-BB57-456d-A598-1F9D4D60D510}.ClientEnd All tariff profiles using this tariff. TariffProfiles {ACE9DED4-6714-43a2-B1E5-D6530EDBACDC}.SupplierEnd All consumption tariff intervals used to define this tariff profile. ConsumptionTariffIntervals {7F5C8247-4764-43ce-8B24-F568152BB763}.SupplierEnd All tariffs defined by this tariff profile. Tariffs {ACE9DED4-6714-43a2-B1E5-D6530EDBACDC}.ClientEnd All time tariff intervals used to define this tariff profile. TimeTariffIntervals {75A8F24D-7EEA-437e-830C-234893BB85F2}.SupplierEnd multiplier {28CABC7C-75AF-4bd8-AD42-B3EE3582114F} unit {191926AD-DB8F-466a-94B7-D3BA4C4167F6} The scaling of the operational limit in percent. limitPercent {1952BC3C-BA32-48d2-AFB3-CFAAB7AB11C1} The temperature of the table point. temperature {C9440439-DED1-4c1e-B707-94FF631925B3} AuxillaryData {FBA403AA-DCD7-404a-9D19-752C36A45A12}.SupplierEnd Card used to tender payment. Card {61A73D4C-E942-43c5-8D12-F351276DE012}.ClientEnd Cheque used to tender payment. Cheque {96162BCD-6CF6-40e7-B42A-5D0EB89F2B16}.ClientEnd Receipt that recorded this receiving of a payment in the form of tenders. Receipt {61AB1FC1-BB28-47a2-95E4-1FB09BBE1111}.SupplierEnd Amount tendered by customer. amount {9C95CEAE-B189-4f6b-A800-24FF7042BDD7} Difference between amount tendered by customer and the amount charged by point of sale. change {E3BE4E86-1F65-4d06-91DD-EFDC0EDE78C0} Kind of tender from customer. kind {C955372D-A862-4ae2-97DC-C11D107DD503} The auxiliary equipment connected to the terminal. AuxiliaryEquipment {43A2A194-FB7E-4b55-8C73-A2E6C7AA2BF4}.ClientEnd The directed branch group terminals for which this terminal is monitored. BranchGroupTerminal {D1FC8C2B-42F2-4d32-95B9-1C5FE76F9BAD}.ClientEnd Bushing {1E353A86-0A4E-4184-8B22-CE084F0A6AA8}.ClientEnd Circuit {6876E705-D5F6-4c77-9072-D14AF881DA08}.ClientEnd The conducting equipment of the terminal. Conducting equipment have terminals that may be connected to other conducting equipment terminals via connectivity nodes or topological nodes. ConductingEquipment {5FEF5186-7804-4dad-8E18-8C5DB7FCE6B2}.SupplierEnd The connectivity node to which this terminal connects with zero impedance. ConnectivityNode {C7E01609-F4E6-4a6e-8ACF-BDD413E62DE3}.SupplierEnd All converters DC sides linked to this point of common coupling terminal. ConverterDCSides {6880D3F9-475B-4887-8B4A-332FABFC8F47}.ClientEnd The equipment faults at this terminal. EquipmentFaults {2CF11C93-156B-4725-864D-F54BFFEBEEB6}.ClientEnd Mutual couplings associated with the branch as the first branch. HasFirstMutualCoupling {E0778435-CE76-4d56-9FCA-FF9F04ED4FCA}.ClientEnd Mutual couplings with the branch associated as the first branch. HasSecondMutualCoupling {3849B779-18E4-46d5-B987-8359D8A98A12}.ClientEnd The feeder that this terminal normally feeds. Only specified for the terminals at head of feeders. NormalHeadFeeder {C1A181B0-A25E-4eca-9A0E-394B6E20BB6C}.ClientEnd PinTerminal {70327476-E811-4a87-97E1-35C5519C96DC}.ClientEnd The controls regulating this terminal. RegulatingControl {329F27E5-05A7-4f46-AD18-D92971CC1BF3}.SupplierEnd Input signal coming from this terminal. RemoteInputSignal {7CA6A357-5876-45c2-9ED0-266641C5D519}.ClientEnd The power flow state variable associated with the terminal. SvPowerFlow {652607BF-3991-4400-89A1-D3208A9FB60D}.ClientEnd The control area tie flows to which this terminal associates. TieFlow {30EE4FA9-5A0A-4d1f-ADEC-2FAEA55B9F47}.ClientEnd The topological node associated with the terminal. This can be used as an alternative to the connectivity node path to topological node thus making it unnecessary to model connectivity nodes in some cases. Note that the if connectivity nodes are in the model this association would probably not be used as an input specification. TopologicalNode {F490BFCA-36A8-4fe2-B28B-66466134B41E}.SupplierEnd All transformer ends connected at this terminal. TransformerEnd {D79E7AD2-9F0B-42d7-8CB3-107B2534515E}.ClientEnd Represents the normal network phasing condition. If the attribute is missing three phases ABC shall be assumed except for terminals of grounding classes specializations of EarthFaultCompensator GroundDisconnector GroundSwitch and Ground which will be assumed to be N. Therefore phase code ABCN is explicitly declared when needed e.g. for star point grounding equipment.The phase code on terminals connecting same ConnectivityNode or same TopologicalNode as well as for equipment between two terminals shall be consistent. phases {8C0E221E-4988-48bf-BFC3-F9FFD7E7E075} MktTerminal {B8192AA1-3321-4d5a-9823-446CC79C90D7}.SupplierEnd An asset health analog related to this lab test standard. AssetAnalog {2E6CE9AA-C3EE-4729-8DE4-6CB4B1AC3E42}.ClientEnd An asset health discrete related to this lab test standard. AssetDiscrete {7AF83EF1-4332-45fc-ADCA-D6AC1324070C}.ClientEnd An asset health string related to this lab test standard. AssetString {12941279-B146-4307-A6F4-220520C33D5E}.ClientEnd Identification of test method used if multiple methods specified by test standard. testMethod {CCF095C2-E957-493b-95E1-2DC1C067C6E4} Which ASTM standard used to determine analog value result. Applies only if ASTM standard used. testStandardASTM {2DA20E52-0F06-4464-857F-286769BA95D6} Which CIGRE standard used to determine analog value result. Applies only if CIGRE standard used. testStandardCIGRE {67CCFE80-A44F-4b79-BB61-DA6E0CBA92A6} Which DIN standard used to determine analog value result. Applies only if DIN standard used. testStandardDIN {42389BCD-7E85-4859-96E8-8B60D089FCEE} Which Doble standard used to determine analog value result. Applies only if Doble standard used. testStandardDoble {A082407F-DBA4-4150-81F5-A04247D81A94} Which EPA standard used to determine analog value result. Applies only if EPA standard used. testStandardEPA {34CEA855-A9B8-4a0f-B8DF-A7413C49146F} Which IEC standard used to determine analog value result. Applies only if IEC standard used. testStandardIEC {739D469C-9BCE-4150-91ED-DB84E0C935C3} Which IEEE standard used to determine analog value result. Applies only if IEEE standard used. testStandardIEEE {0CFAE803-7015-456b-9C27-8CAB9FAFCBCD} Which ISO standard used to determine analog value result. Applies only if ISO standard used. testStandardISO {3D9C3CAB-EE77-4ecf-96D7-4DF5F0EECFD8} Which Laborelec standard used to determine analog value result. Applies only if Laborelec standard used. testStandardLaborelec {2B85C983-D5DF-4c0f-81AF-321B44325569} Which TAPPI standard used to determine analog value result. Applies only if TAPPI standard used. testStandardTAPPI {1FB9DCBA-6B38-4652-958C-95EB5B7A54E6} Which UK Ministry of Defence standard used to determine analog value result. Applies only if UK Ministry of Defence standard used. testStandardUKMinistryOfDefence {F1675D39-DE17-41af-9E1D-F115202C8004} Which WEP standard used to determine analog value result. Applies only if WEP standard used. testStandardWEP {25666DF8-FF56-4b54-BFF0-8CC0551BA561} Identification of variant of test method or standard if one is specified by the standard. testVariant {0F15BD3C-ED7D-4f6e-8EDA-DEAD81F2AB9B} A thermal generating unit may be a member of a compressed air energy storage plant. CAESPlant {22CD9D0F-3294-4b03-B8CD-2834FB574022}.ClientEnd A thermal generating unit may be a member of a cogeneration plant. CogenerationPlant {E1908858-346B-40b8-9CAB-D6DDC55C0455}.ClientEnd A thermal generating unit may be a member of a combined cycle plant. CombinedCyclePlant {1A607D5D-0E44-490a-B14D-8A8B2A3D7057}.ClientEnd A thermal generating unit may have one or more emission curves. EmissionCurves {754BD49F-EE90-408a-AEBF-B56AA6C8DA69}.ClientEnd A thermal generating unit may have one or more emission allowance accounts. EmmissionAccounts {0EFC6C1E-3654-4ea3-8239-30E44E8AE7C6}.ClientEnd A thermal generating unit may have one or more fossil fuels. FossilFuels {2839ECA7-4BCD-4b58-8243-16046DF6DFBA}.ClientEnd A thermal generating unit may have one or more fuel allocation schedules. FuelAllocationSchedules {B6363E4A-4FC1-40b5-AE09-A51CCFB2B37E}.ClientEnd A thermal generating unit may have a heat input curve. HeatInputCurve {0F7AF31F-7DEC-4822-9117-8C921A5EADD4}.ClientEnd A thermal generating unit may have a heat rate curve. HeatRateCurve {E732F28C-0BF4-4edf-8CAB-14E807036F6F}.ClientEnd A thermal generating unit may have an incremental heat rate curve. IncrementalHeatRateCurve {44777851-6FBC-4f50-AF92-1EA11CE04CA8}.ClientEnd A thermal generating unit may have a shutdown curve. ShutdownCurve {4D553F1E-EFC5-42c1-92D6-0E421FE8975B}.ClientEnd A thermal generating unit may have a startup model. StartupModel {99C4296C-33D5-4c79-A4FB-0A9EC0794967}.ClientEnd Operating and maintenance cost for the thermal unit. oMCost {9E07717A-8138-4a67-B588-2648A3EDB6C8} The terminal to which this tie flow belongs. Terminal {30EE4FA9-5A0A-4d1f-ADEC-2FAEA55B9F47}.SupplierEnd A dynamic energy transaction can act as a pseudo tie line. EnergyTransaction {F598C617-D4AC-4af6-8714-13A45A6CFB71}.ClientEnd A ControlAreaOperator has a collection of tie points that ring the ControlArea called a TieLine. ParentOfA {1FE3925A-54B7-4008-8CC6-93CD443CC3C0}.ClientEnd A CustomerConsumer may ring its perimeter with metering which can create a unique SubControlArea at the collection of metering points called a TieLine. ParentOfB {BE10D423-5810-4e4c-A856-4B2A6F2C2D59}.ClientEnd The SubControlArea is on the A side of a collection of metered points which define the SubControlAreas boundary for a ControlAreaOperator or CustomerConsumer. SideA_SubControlArea {A0461DED-D054-4723-9A90-182B86F0177A}.SupplierEnd The SubControlArea is on the B side of a collection of metered points which define the SubControlAreas boundary for a ControlAreaOperator or CustomerConsumer. SideB_SubControlArea {3DBD1F56-AC7D-4daa-BEA3-1F36902AF8D6}.SupplierEnd A measurement is made on the B side of a tie point ByMktMeasurement {405D53E3-14AD-4d07-9D1F-3F3285139237}.SupplierEnd A measurement is made on the A side of a tie point ForMktMeasurement {BE3DB3DE-E7FF-4f27-8DC0-5606F98986E5}.SupplierEnd The MW rating of the tie point. tiePointMWRating {0E359BD0-AB1C-4b90-9CD0-5B37239D59FF} Time schedule owning this time point. TimeSchedule {625A1F67-1CDE-402f-98D9-030899992A1B}.ClientEnd if intervalbased A point in time relative to scheduled start time in TimeSchedule.scheduleInterval.start. relativeTimeInterval {4CE7089B-723E-4f30-905D-7660B02A13BE} Status of this time point. status {11905F1C-71EB-4b95-83FC-D104DEDB53B9} Interval defining the window of time that this time point is valid for example seasonal only on weekends not on weekends only 800 am to 500 pm etc.. window {8080DB7B-1AE8-4827-AC27-2F17BDCC4BF5} Sequence of time points belonging to this time schedule. TimePoints {625A1F67-1CDE-402f-98D9-030899992A1B}.SupplierEnd The offset from midnight i.e. 0 h 0 min 0 s for the periodic time points to begin. For example for an interval meter that is set up for five minute intervals recurrencePeriod3005 min setting offset1202 min would result in scheduled events to read the meter executing at 2 min 7 min 12 min 17 min 22 min 27 min 32 min 37 min 42 min 47 min 52 min and 57 min past each hour. offset {FE7D56EF-99D8-46f2-8229-2D9285D48E61} Duration between time points from the beginning of one period to the beginning of the next period. Note that a device like a meter may have multiple interval periods e.g. 1 min 5 min 15 min 30 min or 60 min. recurrencePeriod {1108D50A-817E-402a-9227-1AF82F685CD4} Schedule date and time interval. scheduleInterval {5A773436-47DB-4da3-8C1F-F6D8070A63C6} AttributeInstanceComponent {12A8F6B9-95CA-4bbd-9E17-5C2026B33D51}.ClientEnd Auction {5894E7F6-D7B8-4658-85C7-272AEC744D46}.ClientEnd ConstraintDuration {07DEE107-FB99-4586-A9B9-7F52BB893EAE}.ClientEnd DateAndOrTime {492E4897-E2BA-43e1-ABB0-94017A298B9D}.SupplierEnd Domain {35183B72-4EB4-4c7d-BDCB-158AC35D6ACC}.SupplierEnd EnvironmentalMonitoringStation {6E714075-8668-4e58-A652-65C0CBEF02BF}.SupplierEnd FlowDirection {090E7580-E214-4627-9E02-CE3051F6B408}.SupplierEnd MarketDocument {8685CC5C-5A4F-4b05-AC0B-AE70B37260A5}.SupplierEnd MarketEvaluationPoint {D819A727-1DB3-424c-9D73-1E1D3668972A}.SupplierEnd MarketObjectStatus {DFA9145B-F296-4711-93A0-08DAEC6641D6}.ClientEnd MarketParticipant {1ACE2F82-31E4-482b-B2EF-A568B3991A86}.SupplierEnd MktPSRType {CBE02ED5-1004-4fe7-8827-53E8B4BDDE03}.ClientEnd Period {2FF42F79-5F9B-4d18-9FE4-F2D14B85ADD8}.SupplierEnd Point {E778FB34-70AF-4315-A61A-98894C17384B}.ClientEnd Price {76FC513C-3CAE-45e6-9CD8-53B33147F936}.ClientEnd Quantity {B7D5F09D-C0DE-43ce-8CC2-0D383279A6BC}.ClientEnd Reason {F3011AEA-011F-4ef6-A0F7-5ED118EF2480}.SupplierEnd RegisteredResource {DF9EE60B-C140-4257-AED0-716349B4B59B}.ClientEnd Unit {2CD55C37-FF3C-4881-B74E-437DAEAFB82E}.ClientEnd All charges used to define this time tariff interval. Charges {0A0C819B-B021-48a1-BE23-8DEE728FFA6C}.SupplierEnd All consumption tariff intervals that introduce variation in this time of use tariff interval allows to express e.g. peak hour prices that are different with different consumption blocks. ConsumptionTariffIntervals {8AA39685-1453-4631-B85A-DA04510557D0}.ClientEnd All tariff profiles defined by this time tariff interval. TariffProfiles {75A8F24D-7EEA-437e-830C-234893BB85F2}.ClientEnd The angle reference for the island. Normally there is one TopologicalNode that is selected as the angle reference for each island. Other reference schemes exist so the association is typically optional. AngleRefTopologicalNode {7537BE85-0F89-40e3-89A0-C8C7F534F430}.SupplierEnd A topological node belongs to a topological island. TopologicalNodes {C890568A-2C06-4a80-B381-F84EBB81CE0A}.ClientEnd The island for which the node is an angle reference. Normally there is one angle reference node for each island. AngleRefTopologicalIsland {7537BE85-0F89-40e3-89A0-C8C7F534F430}.ClientEnd The base voltage of the topological node. BaseVoltage {6F37A2BE-FB37-4a6c-8BB1-CFC6690C1867}.SupplierEnd BusnameMarkers that may refer to a pre defined TopologicalNode. BusNameMarker {33820695-1C8F-47c2-96B4-E770AF9728EF}.ClientEnd The connectivity node container to which the topological node belongs. ConnectivityNodeContainer {88BD0C47-4CB3-44db-9A6B-20C783A24478}.SupplierEnd The connectivity nodes combine together to form this topological node. May depend on the current state of switches in the network. ConnectivityNodes {ACD76E10-125A-4f7a-A20A-475AC4334414}.ClientEnd The reporting group to which the topological node belongs. ReportingGroup {1134BB7B-6737-4184-A156-3E1FE506083D}.SupplierEnd The injection flows state variables associated with the topological node. SvInjection {65235B7E-6091-4035-BB6C-FD64EA32C24B}.ClientEnd The state voltage associated with the topological node. SvVoltage {4628B761-2D2E-4428-AB48-91ADDAB6ED29}.ClientEnd The terminals associated with the topological node. This can be used as an alternative to the connectivity node path to terminal thus making it unnecessary to model connectivity nodes in some cases. Note that if connectivity nodes are in the model this association would probably not be used as an input specification. Terminal {F490BFCA-36A8-4fe2-B28B-66466134B41E}.ClientEnd A topological node belongs to a topological island. TopologicalIsland {C890568A-2C06-4a80-B381-F84EBB81CE0A}.SupplierEnd The active power injected into the bus at this location in addition to injections from equipment. Positive sign means injection into the TopologicalNode bus.Starting value for a steady state solution. pInjection {2C6F17C9-E8CD-4fdb-8029-A612C4EF7C6D} The reactive power injected into the bus at this location in addition to injections from equipment. Positive sign means injection into the TopologicalNode bus.Starting value for a steady state solution. qInjection {1F312481-3DC3-4029-8B50-C8BA23CE0972} Fujita scale referred to as EFscale starting in 2007 for the tornado. fScale {00289016-4A09-43be-AE71-4E4802CE7959} Width of the tornado during the time interval. width {F2E6BD32-E569-48bd-ADB4-4C5C7F51B2AF} Construction structure on the tower. constructionKind {2697D3C3-0A65-4816-BA14-4BCEA757E1A0} ActionRequest {54A2C406-8667-40cf-88A9-3A48629020FE}.ClientEnd From_SC {6D895553-2440-4f7c-BC33-B46D1B29C9D3}.ClientEnd Pnode {D878BD22-6A72-4e0c-8DFA-7844C9BCA884}.ClientEnd RegisteredGenerator {039D769F-A03A-444a-8786-96815FE89B99}.ClientEnd To_SC {7714A894-C9FB-420d-B21E-799E489A3AC8}.ClientEnd TradeError {C4DD2011-EF22-4fc2-A435-9C9F02E742A6}.SupplierEnd TradeProduct {9C3C0AFA-2A91-406d-9B41-CCF03BAA1C90}.ClientEnd marketType {4684F3F1-E6F3-4981-904D-7FB77AFA4A5C} submitFromSchedulingCoordinator {5BFC46E8-DD4B-4516-8376-1EFDF9C076C7}.ClientEnd submitToSchedulingCoordinator {AC7FD549-FA5C-45d6-B2D9-4609F963A05C}.ClientEnd Trade {C4DD2011-EF22-4fc2-A435-9C9F02E742A6}.ClientEnd Trade {9C3C0AFA-2A91-406d-9B41-CCF03BAA1C90}.SupplierEnd IST InterSC Trade AST Ancilliary Services Trade UCT Unit Commitment Trade tradeType {59B065E2-D032-42db-823F-C81F0D0389F9} TradingHubValues {E2DFBA75-A026-4167-A09D-D673685B25A5}.SupplierEnd marketType {8F4686A6-0AF0-4ae4-830C-8ECA95AC626F} AggregatedPnode {28734C41-4653-42fe-A8E1-178A7444F6EC}.SupplierEnd TradingHubPrice {E2DFBA75-A026-4167-A09D-D673685B25A5}.ClientEnd Auxiliary account for this payment transaction. AuxiliaryAccount {DF6F03CB-FADB-4f4b-BE70-872C51D6376A}.ClientEnd Cashier shift during which this transaction was recorded. CashierShift {2D10DF39-BE65-4644-A37D-1155967E0230}.ClientEnd Customer account for this payment transaction. CustomerAccount {0B5E9E95-37C0-4b1a-8C38-C1995B9D1EC8}.ClientEnd Meter for this vending transaction. Meter {95682AE1-DDB3-4fa2-AC18-655296065A72}.SupplierEnd Pricing structure applicable for this transaction. PricingStructure {25EA2CE6-048D-4220-8F20-CA27D99F9BAE}.ClientEnd The receipted payment for which this transaction has been recorded. Receipt {436A1D66-C447-4f0e-84DE-DEE861AA01CD}.ClientEnd All snapshots of meter parameters recorded at the time of this transaction. Use name and value.value attributes to specify name and value of a parameter from meter. UserAttributes {2749DDBF-3B2B-40e4-AF4B-40B8874DF1F9}.ClientEnd Vendor shift during which this transaction was recorded. VendorShift {C7BF480F-86A2-4fe5-BB3D-D4EA91B0C386}.ClientEnd Kind of transaction. kind {65B0E136-6632-46ff-ADF7-8701F09AFE7F} Transaction amount rounding date and note for this transaction line. line {6926B3B1-11AF-49c2-B386-83FCFE189E71} Actual amount of service units that is being paid for. serviceUnitsEnergy {0B863D4C-B4D0-4eeb-8165-B9469112080E} Number of service units not reflected in serviceUnitsEnergy due to process rounding or truncating errors. serviceUnitsError {9BB33DE3-8DA4-429c-8120-ACBF3C4C9EA2} Delivery_Pnode {34A3B7CA-5000-4f2c-85C0-4A822CE31BA9}.ClientEnd EnergyProfiles {E51D8A6A-35CA-4b26-B4D3-9E33C8AF5D95}.ClientEnd Receipt_Pnode {ACB6DCFB-9B97-4ab9-AE5A-A643C314A45D}.ClientEnd TransactionBidResults {2D2D0010-F20C-446b-A623-73D0BD29F617}.ClientEnd TransmissionReservation {B39F413C-7625-4635-8150-E32231965E94}.ClientEnd TransactionBidResults {CA24857F-3571-4389-90DB-F93AF9F4E45C}.ClientEnd TransactionBid {2D2D0010-F20C-446b-A623-73D0BD29F617}.SupplierEnd TransactionBidClearing {CA24857F-3571-4389-90DB-F93AF9F4E45C}.SupplierEnd All merchant accounts registered with this transactor. MerchantAccounts {4E9EC9E2-B298-41e8-9F52-493E9BBBDAC4}.ClientEnd HostControlArea {916AF086-1537-4361-A735-CFC6D28337F9}.ClientEnd TransferInterfaceSolution {B93FC9AB-985E-49f5-80B0-93755B80C82B}.ClientEnd MktContingencyA {C3F0F2CA-4331-417e-BB6F-AC8830FC9ABF}.SupplierEnd MktContingencyB {A997CE1E-D37D-451f-AAE5-0DEBC8D07E52}.SupplierEnd TransferInterface {B93FC9AB-985E-49f5-80B0-93755B80C82B}.SupplierEnd All transformer ends having this core admittance. TransformerEnd {DE4C9D0B-23BA-4ce9-83D1-BF12F521B593}.SupplierEnd Transformer end datasheet used to calculate this core admittance. TransformerEndInfo {B327563C-A528-49f8-827D-F19F78BD5C59}.ClientEnd Magnetizing branch susceptance B mag. The value can be positive or negative. b {928EB30C-C38B-45ed-BECF-DE3FCC6C9308} Zero sequence magnetizing branch susceptance. b0 {AFD9DEEF-8A95-4753-9A43-0F26BF54DE65} Magnetizing branch conductance G mag. g {EAEA9448-77A7-4e23-9496-89BE1A58E225} Zero sequence magnetizing branch conductance. g0 {9DE460B2-6CED-4c6f-A389-E54FA2BE13C9} Base voltage of the transformer end. This is essential for PU calculation. BaseVoltage {DEF1E6AE-B7B9-43bf-9A91-E4BFC453DC4D}.SupplierEnd Core admittance of this transformer end representing magnetising current and core losses. The full values of the transformer should be supplied for one transformer end only. CoreAdmittance {DE4C9D0B-23BA-4ce9-83D1-BF12F521B593}.ClientEnd All mesh impedances between this to and other from transformer ends. FromMeshImpedance {0C083589-3190-4ac0-ACA6-6C089CF712A1}.ClientEnd FromWindingInsulations {85692DA6-1368-431a-B29A-40C8C1AD42B8}.ClientEnd Phase tap changer associated with this transformer end. PhaseTapChanger {1CC9941E-7C40-434a-98D6-B767348B392C}.SupplierEnd Ratio tap changer associated with this transformer end. RatioTapChanger {D8F7848F-543A-4d91-BA97-2A9B3FCFF0C6}.SupplierEnd accurate for 2 or 3winding transformers only Pimodel impedances of this transformer end. By convention for a two winding transformer the full values of the transformer should be entered on the high voltage end endNumber1. StarImpedance {5078C60A-39BE-4141-9354-41C6894404A6}.SupplierEnd Terminal of the power transformer to which this transformer end belongs. Terminal {D79E7AD2-9F0B-42d7-8CB3-107B2534515E}.SupplierEnd All mesh impedances between this from and other to transformer ends. ToMeshImpedance {E43C771D-3409-4e2c-B0A8-D0643B55F7A5}.ClientEnd ToWindingInsulations {F014FE41-F5D2-4748-870B-0A78530405BD}.ClientEnd Core shunt magnetizing susceptance in the saturation region. bmagSat {4950386F-0EBF-4612-B5A1-D6E0BA9ED7E0} The reference voltage at which the magnetizing saturation measurements were made. magBaseU {57D6ABA6-A7AD-4761-A186-972500D1F6E5} Core magnetizing saturation curve knee flux level. magSatFlux {803C147E-320E-4c05-8C2E-1F4CB27D5217} for Yn and Zn connections Resistance part of neutral impedance where grounded is true. rground {EE05F10D-59F9-4a26-84CF-01E7909E179B} for Yn and Zn connections Reactive part of neutral impedance where grounded is true. xground {50CE0265-4A20-4352-B5D6-FCFECC48E995} Core admittance calculated from this transformer end datasheet representing magnetising current and core losses. The full values of the transformer should be supplied for one transformer end info only. CoreAdmittance {B327563C-A528-49f8-827D-F19F78BD5C59}.SupplierEnd All noload test measurements in which this transformer end was energised. EnergisedEndNoLoadTests {F3E7A0B0-A48C-4358-8A44-11C4C94ABFB4}.ClientEnd All opencircuit test measurements in which this transformer end was excited. EnergisedEndOpenCircuitTests {71BB3848-4B63-4fd1-9254-66CEBBF18C94}.ClientEnd All shortcircuit test measurements in which this transformer end was energised. EnergisedEndShortCircuitTests {2E74ED8F-7D38-402e-861A-F390B8A642DD}.ClientEnd All mesh impedances between this to and other from transformer ends. FromMeshImpedances {9F2DA196-8DEB-4c6c-B505-2954675E7A50}.SupplierEnd All shortcircuit test measurements in which this transformer end was shortcircuited. GroundedEndShortCircuitTests {B6AF9146-CA85-4239-9212-97F858E8662C}.ClientEnd All opencircuit test measurements in which this transformer end was not excited. OpenEndOpenCircuitTests {AC00E333-4A04-486e-AA1A-D3D83FB22682}.ClientEnd All mesh impedances between this from and other to transformer ends. ToMeshImpedances {3EAF2DD7-ACE0-4031-970E-D1D4B25FBAEA}.SupplierEnd Transformer star impedance calculated from this transformer end datasheet. TransformerStarImpedance {6B73B4A4-6B37-4a21-88C2-6A840F845023}.SupplierEnd Transformer tank data that this end description is part of. TransformerTankInfo {6324A313-0688-4347-972B-AB0ED0E65531}.ClientEnd Kind of connection. connectionKind {FAC8E176-2837-4a78-80FE-938B199A7579} Apparent power that the winding can carry under emergency conditions also called longterm emergency power. emergencyS {44FBD108-12C1-434b-88BD-A508AE03F156} Basic insulation level voltage rating. insulationU {30C7D2E4-5F41-4a18-A5A0-5B01DC907E85} DC resistance. r {B185B333-46D3-4a80-8449-F5BAAFB5B275} Normal apparent power rating. ratedS {9F419B0D-B321-4881-947A-129B555A0F08} Rated voltage phasephase for threephase windings and either phasephase or phaseneutral for singlephase windings. ratedU {DB2C5D96-5C2F-49ed-B129-F0647D5800BD} Apparent power that this winding can carry for a short period of time in emergency. shortTermS {734AED57-B659-47f4-A0F1-AFD48B66E8EE} From end this mesh impedance is connected to. It determines the voltage reference. FromTransformerEnd {0C083589-3190-4ac0-ACA6-6C089CF712A1}.SupplierEnd from transformer end datasheet this mesh impedance is calculated from. It determines the voltage reference. FromTransformerEndInfo {9F2DA196-8DEB-4c6c-B505-2954675E7A50}.ClientEnd All transformer ends this mesh impedance is connected to. ToTransformerEnd {E43C771D-3409-4e2c-B0A8-D0643B55F7A5}.SupplierEnd All to transformer end datasheets this mesh impedance for from transformer end is calculated from. ToTransformerEndInfos {3EAF2DD7-ACE0-4031-970E-D1D4B25FBAEA}.ClientEnd Resistance between the from and the to end seen from the from end. r {21BB6532-5B66-45eb-8BD7-0DA588282A4A} Zerosequence resistance between the from and the to end seen from the from end. r0 {366E684D-52D4-41c2-B293-CC65EA5FBC28} Reactance between the from and the to end seen from the from end. x {1EFF11FE-5520-4c57-90FB-E0EECA189682} Zerosequence reactance between the from and the to end seen from the from end. x0 {9444EE0F-D215-47d2-A536-7DADD5FA2D62} BushingInsultationPFs {DE9B5DD5-948F-45ee-967F-41C9BA2892AE}.ClientEnd ProcedureDataSets {8D7EAE31-2FA3-4a2f-84AC-416327FD5679}.ClientEnd Reconditioning {8A289EE0-AF52-4d3d-B1DF-2BF047C45F44}.ClientEnd Transformer {472A2705-2D9A-4589-BBE2-8A3AC63A9DE5}.SupplierEnd WindingInsulationPFs {97F8FF5D-183D-4b1c-B364-25B5C98E0F5F}.SupplierEnd Bushing temperature. bushingTemp {FE4BCB99-058A-4eac-8129-0A2CFDB02501} Hotspot oil temperature. hotSpotTemp {F83771D3-9987-4930-B423-5ED74B4A649C} Oil Quality AnalysisDielectric Strength. oilDielectricStrength {D69A827D-834A-49e8-B6D9-C927574C6BC9} status {6ADE4A75-BDDB-482b-B53B-A179805B1C1F} Top oil temperature. topOilTemp {25E30821-C0D4-4500-911C-0A5D9AE66DEC} All transformer ends having this star impedance. TransformerEnd {5078C60A-39BE-4141-9354-41C6894404A6}.ClientEnd Transformer end datasheet used to calculate this transformer star impedance. TransformerEndInfo {6B73B4A4-6B37-4a21-88C2-6A840F845023}.ClientEnd Resistance of the transformer end. r {5B9D7450-DA41-4af2-BFC7-25FD2258A98C} Zero sequence series resistance of the transformer end. r0 {E99F040E-F78C-4483-913E-8C4A35E9A91D} Positive sequence series reactance of the transformer end. x {DF5DFD38-6773-4727-8D72-5B6C82EB0ECB} Zero sequence series reactance of the transformer end. x0 {2B4BC0D1-E16A-40c5-8678-D2FBC1A38DD6} Bank this transformer belongs to. PowerTransformer {732D3510-8B59-4b75-8EBD-5E7EFC0BD19D}.SupplierEnd TransformerObservations {472A2705-2D9A-4589-BBE2-8A3AC63A9DE5}.ClientEnd All windings of this transformer. TransformerTankEnds {BD3E9F56-CE54-46c2-AD6E-0BF1AF5013B8}.ClientEnd Transformer this winding belongs to. TransformerTank {BD3E9F56-CE54-46c2-AD6E-0BF1AF5013B8}.SupplierEnd Describes the phases carried by a conducting equipment. phases {ECEAD537-8731-44da-A641-EDEF7450C23A} Power transformer data that this tank description is part of. PowerTransformerInfo {C20239B0-27AB-4040-9B55-35834EB98EDC}.SupplierEnd Data for all the ends described by this transformer tank data. TransformerEndInfos {6324A313-0688-4347-972B-AB0ED0E65531}.SupplierEnd Base power at which the tests are conducted usually equal to the rateds of one of the involved transformer ends. basePower {056471A6-B8A8-433c-9FB2-095E6C4C2F8E} Temperature at which the test is conducted. temperature {88CF359F-297E-409b-864E-7DBEFBC169B4} Flowgate {8921D733-BE8B-4a9f-BB12-03E6AB71B1AB}.ClientEnd GenericConstraints {384C3E51-C664-4bf5-A75C-E0697CE38B7D}.ClientEnd A TransmissionPath is contained in a TransmissionCorridor. ContainedIn {BBFEDE77-77EC-472b-8A6E-AAE200EDE3DB}.ClientEnd A transmission rightofway is a member of a transmission corridor TransmissionRightOfWays {4FBC14D9-C78F-424f-A518-E6A6E2D5C45F}.SupplierEnd ContractRight {BD4EDF28-A98E-4529-8A20-3113450CEBF4}.SupplierEnd Flowgate {4577596A-E96F-49da-9220-E1987860787A}.ClientEnd A transmission path has a pointofdelivery service point DeliveryPoint {21CB6E87-75AD-4919-B4ED-4192EC9CC857}.ClientEnd A TransmissionPath is contained in a TransmissionCorridor. For {BBFEDE77-77EC-472b-8A6E-AAE200EDE3DB}.SupplierEnd A transmission product is located on a transmission path. LocatedOn {809F7661-A156-4e85-AE91-4F035C749051}.ClientEnd A transmission path has a pointofreceipt service point PointOfReceipt {94CD1232-0212-4261-9FE4-36493F16F0E4}.ClientEnd TransmissionReservation {FF809EA0-FAD0-4d14-B083-AD186EADB2CF}.SupplierEnd The available transmission capability of a transmission path for the reference direction. availTransferCapability {435EE2C8-310E-45fb-93AA-5787EC45EB5B} The total transmission capability of a transmission path in the reference direction. totalTransferCapability {EC8178AE-269B-4126-AE61-3F5A0768194E} A transmission product is located on a transmission path. LocationFor {809F7661-A156-4e85-AE91-4F035C749051}.SupplierEnd A TransmissionProvider offers a TransmissionProduct. TransmissionProvider {EC0C3662-DB09-4af3-BA2A-86166CE1C300}.SupplierEnd Part of the LossProfile for an EnergyTransaction may be a loss for a TransmissionProvider. If so the TransmissionProvider must be one of the participating entities in the EnergyTransaction. For {A0E07F75-BF34-4a53-91DA-8AC7F9199E13}.ClientEnd A TransmissionProvider offers a TransmissionProduct. TransmissionProducts {EC0C3662-DB09-4af3-BA2A-86166CE1C300}.ClientEnd EnergyTransaction {AC1E24EF-9143-4c28-B275-913E3666B245}.SupplierEnd Sink {64CB9D37-23DD-46f9-A4A8-47CF257C8105}.ClientEnd Source {E205C545-1AF7-4249-9970-5E34913BCC3E}.ClientEnd TransactionBid {B39F413C-7625-4635-8150-E32231965E94}.SupplierEnd TransmissionPath {FF809EA0-FAD0-4d14-B083-AD186EADB2CF}.ClientEnd Chain_ContractRight {1D17EEA8-4DC7-4648-B0A4-3D0516BC89C2}.SupplierEnd Ind_ContractRight {2A59E041-E065-428d-9918-A42D868C16C6}.SupplierEnd RTO {1E012DD2-B528-4079-B377-8386C7DB1523}.ClientEnd MktLine {30BB45B0-2DB4-4d68-BC65-DFE2DF74D8D1}.ClientEnd A transmission rightofway is a member of a transmission corridor TransmissionCorridor {4FBC14D9-C78F-424f-A518-E6A6E2D5C45F}.ClientEnd The resulting Gate that is the condition for the Trigger. GateTrigger {1E9CF642-F79D-453e-840A-CCAA1AB4A74D}.SupplierEnd RemedialActionScheme {2D5E06E1-6BCA-41a9-9B81-E5FFA56FE6AC}.SupplierEnd Incident {3D79F2D5-BE8F-4d59-A6FE-14060E81D5FA}.SupplierEnd Location {2BE0988C-AEEE-43e6-9FB2-B3C811465CE1}.SupplierEnd TroubleTicket {42D4F687-C45E-4afb-8E19-6BD1A3F5E209}.SupplierEnd UnplannedOutage {D36FE243-EBDF-427d-841A-BF9DD24E97E4}.ClientEnd WorkTask {0C2AE19D-0F46-483f-BA2C-8AFA95A466F6}.ClientEnd The planned start and end time for the trouble order. plannedExecutionInterval {4B5AA04E-6220-4276-BCCB-C781325E39DA} Customer for whom this trouble ticket is relevant. Customer {DB18A09B-52CE-46d9-98B1-DA9F32529CC5}.SupplierEnd Incident reported in this trouble ticket Incident {604AF98C-C65C-46ec-828D-96FE5F906C35}.SupplierEnd All hazards reported with this trouble ticket. IncidentHazard {F1DCAE08-2CD6-4c12-9B22-D06B9E9DAA02}.SupplierEnd Notification for this trouble ticket. Notification {2E2B0349-61DB-4eeb-9A2F-465DC303A460}.ClientEnd ServiceLocation {61FDCE34-6ACD-4edb-A961-05C33EC48E86}.ClientEnd TroubleOrder {42D4F687-C45E-4afb-8E19-6BD1A3F5E209}.ClientEnd UnplannedOutage {76C1C366-6D04-44f8-B3FA-BD123E9196FD}.ClientEnd Indicates how the customer reported trouble. reportingKind {1F8F0207-79BC-48ab-BF72-DE1D9CFDB9F2} Controller deadband idbi. Typical value 0. db {E218CC9F-E5CC-4c05-872F-508374139965} Maximum control error iEmaxi see parameter detail 4. Typical value 002. emax {5293C632-28A0-45d4-9820-4AF63CE2AFC8} Frequency bias gain iFbi. Typical value 0. fb {318CC923-F6AF-4ccc-B364-CF85DE83A1D3} Maximum turbine speedload reference bias iIrmaxi see parameter detail 3. Typical value 0. irmax {594A2700-90F0-4ca2-9FB3-0FAD84B96E2C} Integral gain iKii. Typical value 0. ki {5AA55CDC-9469-4f03-B327-AE36DD877738} Proportional gain iKpi. Typical value 0. kp {85A716AE-3B40-4bdb-A829-B53CDDDC52E0} Base for power values iMWbasei gt 0. Unit MW. mwbase {5DEE3DCC-9C0F-4a44-B20A-A41F1BFA6213} Power controller setpoint iPmwseti see parameter detail 1. Unit MW. Typical value 0. pmwset {80B91A23-4C94-420f-A5B3-38783A465994} Power transducer time constant iTpeleci gt 0. Typical value 0. tpelec {D74FEDF5-5775-47aa-B051-49EF1F447195} Asynchronous machine model with which this turbinegovernor model is associated. TurbineGovernorDynamics shall have either an association to SynchronousMachineDynamics or to AsynchronousMachineDynamics. AsynchronousMachineDynamics {6884320E-0E98-4316-859C-B1DF18D6ED2A}.SupplierEnd Synchronous machine model with which this turbinegovernor model is associated. TurbineGovernorDynamics shall have either an association to SynchronousMachineDynamics or to AsynchronousMachineDynamics. SynchronousMachineDynamics {7E94D7D8-30B5-4d27-A321-7C51BCCE5C42}.ClientEnd Turbine load controller providing input to this turbinegovernor. TurbineLoadControllerDynamics {21C6EABE-ECAB-4ae5-BF01-82E439E5696A}.ClientEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {E9CE179B-FE93-40fa-AF55-290AFD448CA7}.ClientEnd Turbinegovernor controlled by this turbine load controller. TurbineGovernorDynamics {21C6EABE-ECAB-4ae5-BF01-82E439E5696A}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {B43C2066-FB4C-497e-9C4F-E259EF67913D}.ClientEnd TypeAssets {C03D47F2-A60F-4e08-BAA2-09494FC4FFE5}.ClientEnd status {53086566-D1AB-4f97-A080-68924093C387} CUMaterialItems {5FD8B251-F630-475d-9DE8-4E62B3FDAF21}.ClientEnd ErpIssueInventories {593B111A-12A5-4f96-B00C-4A37F1AB05D7}.ClientEnd ErpReqLineItems {3878A953-62BF-4865-AD6B-E5B11C7EB681}.SupplierEnd MaterialItems {1D24C169-2407-4dc7-9946-2E7695DD3662}.SupplierEnd The estimated unit cost of this type of material either for a unit cost or cost per unit length. Cost is for material or asset only and does not include labor to installconstruct or configure it. estUnitCost {A2BE6366-D8C6-41fd-8A86-19948B28FE14} Edition of UK Ministry of Defence standard. standardEdition {6C0454BD-DD4E-40a0-BD64-BD476D4EFF35} UK Ministry of Defence standard number. standardNumber {23ABC5E2-8191-4fd3-B23B-85836D537533} Delay {84D84ECC-705D-4a61-8B63-60A505B5791B}.ClientEnd VSCtype1 {ABBAB2B2-1509-4175-A3E8-48DBC8251AFA}.SupplierEnd UnavailabilityScheduleDependsOn {90D8D560-4E3D-4b2e-8C5A-1081DB355463}.SupplierEnd UnavailabilityScheduleImpacts {08883996-485F-438c-8235-9EABAB0ED9A2}.SupplierEnd EquipmentUnavailabilitySchedule {A621ED73-8721-4170-8819-24FA003C3372}.SupplierEnd Switch {0C9534D4-CB50-4b67-88A1-762995554EA1}.SupplierEnd AvailablityPlan {A2312A8D-C0CB-4b47-98F8-79E9ADD45A56}.SupplierEnd DependsOn {08883996-485F-438c-8235-9EABAB0ED9A2}.ClientEnd EquipmentUnavailabilitySchedule {E688F5A4-D2F9-4a84-85F2-980B6307E7AB}.ClientEnd Impacts {90D8D560-4E3D-4b2e-8C5A-1081DB355463}.ClientEnd Gain Under excitation limiter iKiisubUIsubi. Typical value 01. kui {F1CC5232-22AF-497d-9315-F0CB76173769} Segment P initial point iPiisub0subi. Typical value 0. p0 {AA7D77B2-176F-4aea-A4E7-14DBF9A4BB63} Segment P end point iPiisub1subi. Typical value 1. p1 {B088E1D0-1D81-4440-9F8B-F953DA64138F} Segment Q initial point iQiisub0subi. Typical value 031. q0 {AC6B4982-0E6C-4a30-8E10-C2DA8E3E7783} Segment Q end point iQiisub1subi. Typical value 01. q1 {AED2F338-9CC8-4f9f-981C-D1190C9B029E} Maximum error signal iViisubUIMAXsubi gt UnderexcLim2Simplified.vuimin. Typical value 1. vuimax {17B0573A-B105-449a-8086-57A21D6E8A4C} Minimum error signal iViisubUIMINsubi lt UnderexcLim2Simplified.vuimax. Typical value 0. vuimin {AAB703B4-E112-4652-B083-10C983E1FE2D} UEL centre setting iKiisubUCsubi. Typical value 138. kuc {95624309-574B-4a7d-95A8-D7B74A51CC80} UEL excitation system stabilizer gain iKiisubUFsubi. Typical value 33. kuf {A041F713-6AA1-4469-A442-AA6C9F6618B9} UEL integral gain iKiisubUIsubi. Typical value 0. kui {D150083F-440F-4529-A5E4-28A0EE01FCC9} UEL proportional gain iKiisubULsubi. Typical value 100. kul {E0650CD7-D55C-42ae-AF62-9E6973017E11} UEL radius setting iKiisubURsubi. Typical value 195. kur {64920A14-D8E7-4bdc-9BC7-928FAB1DA88D} UEL lead time constant iTiisubU1subi gt 0. Typical value 0. tu1 {504D7CFF-F1F2-4e49-9C4C-539CCDBF8A3B} UEL lag time constant iTiisubU2subi gt 0. Typical value 005. tu2 {FE82EA04-AD03-49b4-994A-0F5718B96D51} UEL lead time constant iTiisubU3subi gt 0. Typical value 0. tu3 {F0EA1404-1DE1-4527-BAD7-FFA84D2FB1F7} UEL lag time constant iTiisubU4subi gt 0. Typical value 0. tu4 {909FDF1E-8257-4738-8E77-07C9C514969E} UEL maximum limit for operating point phasor magnitude iViisubUCMAXsubi. Typical value 58. vucmax {28B8D1B7-18FD-4289-85E7-C484ECE27255} UEL integrator output maximum limit iViisubUIMAXsubi gt UnderexcLimIEEE1.vuimin. vuimax {8F78C41F-55AF-41ee-B034-5A24A69371A9} UEL integrator output minimum limit iViisubUIMINsubi lt UnderexcLimIEEE1.vuimax. vuimin {5CB635B8-4B94-4cfc-A7D5-4082AF8ED4BD} UEL output maximum limit iViisubULMAXsubi gt UnderexcLimIEEE1.vulmin. Typical value 18. vulmax {122CC9B8-792D-4c95-B9A8-22E46A576BC6} UEL output minimum limit iViisubULMINsubi lt UnderexcLimIEEE1.vulmax. Typical value 18. vulmin {C3BFB41C-6613-484a-99EB-A479BBCCB746} UEL maximum limit for radius phasor magnitude iViisubURMAXsubi. Typical value 58. vurmax {E5F17609-3CDB-4279-8CBF-7E2EC3AD5995} Gain associated with optional integrator feedback input signal to UEL iKiisubFBsubi. Typical value 0. kfb {386D854B-91F4-4396-8863-AB26E8AE48A7} UEL excitation system stabilizer gain iKiisubUFsubi. Typical value 0. kuf {82AE58AB-5557-4846-A849-07C8CC17EA36} UEL integral gain iKiisubUIsubi. Typical value 05. kui {44808547-9B47-42c8-909C-A179DBE007BF} UEL proportional gain iKiisubULsubi. Typical value 08. kul {106D7EED-180C-4757-92C5-03614E5D3F88} Real power values for endpoints iPiisub0subi. Typical value 0. p0 {CAF5C974-04A4-404f-A555-D2F6A0499FDA} Real power values for endpoints iPiisub1subi. Typical value 03. p1 {60939239-B9B9-4623-A3AB-DE77A4F9A24D} Real power values for endpoints iPiisub10subi. p10 {97F7FF2B-E4A6-4d50-BDB5-ED8C95175B1D} Real power values for endpoints iPiisub2subi. Typical value 06. p2 {8666CA72-BB27-4137-A8EA-62D73DD31CC7} Real power values for endpoints iPiisub3subi. Typical value 09. p3 {02661186-1F76-4688-AACD-D55B0A04733C} Real power values for endpoints iPiisub4subi. Typical value 102. p4 {AE843EBB-828F-4374-A4D4-5BCE03711D71} Real power values for endpoints iPiisub5subi. p5 {8284C4A4-A60D-43c8-A25C-5F13D836B7AB} Real power values for endpoints iPiisub6subi. p6 {84CE15EF-D9A4-464c-A933-7A6006336790} Real power values for endpoints iPiisub7subi. p7 {56191AD7-E237-4246-8A0E-DDF29118C567} Real power values for endpoints iPiisub8subi. p8 {A45644B1-5F12-4556-935B-C20EB3C1F707} Real power values for endpoints iPiisub9subi. p9 {3EB11732-31A3-4f4a-9E47-1A63A9470CD5} Reactive power values for endpoints iQiisub0subi. Typical value 031. q0 {40CDC020-FAB5-4dae-9E02-5D40CCA6D573} Reactive power values for endpoints iQiisub1subi. Typical value 031. q1 {156904B0-6A59-4fdd-A79D-2972E0085799} Reactive power values for endpoints iQiisub10subi. q10 {075CA9C7-7410-4697-9E03-D02AD24D2C5B} Reactive power values for endpoints iQiisub2subi. Typical value 028. q2 {4EEF0485-9E68-448f-B7BA-737FC4EE2513} Reactive power values for endpoints iQiisub3subi. Typical value 021. q3 {B363EC37-038F-4f47-8267-789AD3E1E404} Reactive power values for endpoints iQiisub4subi. Typical value 0. q4 {F4526DBD-78C5-4fe3-BCA6-36BF889E64D6} Reactive power values for endpoints iQiisub5subi. q5 {DF8A8A62-10D3-4e00-81C5-E33FF45525E0} Reactive power values for endpoints iQiisub6subi. q6 {58634D5B-228B-4c38-A808-87D2D0084789} Reactive power values for endpoints iQiisub7subi. q7 {8935F65A-5B90-4938-B3FC-A81A7EB8F84D} Reactive power values for endpoints iQiisub8subi. q8 {45C2DBF5-B4CD-4dd6-AB5E-1BEA1ADAB2D7} Reactive power values for endpoints iQiisub9subi. q9 {D603A8C8-C4D0-4979-A5C6-6F8686AB3D84} UEL lead time constant iTiisubU1subi gt 0. Typical value 0. tu1 {AC3107E9-DCED-46d6-A6EE-C7A778EB7155} UEL lag time constant iTiisubU2subi gt 0. Typical value 0. tu2 {89D6BE50-CABD-4557-952A-42B87DF9B507} UEL lead time constant iTiisubU3subi gt 0. Typical value 0. tu3 {FC40F1E9-BD13-440d-93A3-FE9A04CE44CC} UEL lag time constant iTiisubU4subi gt 0. Typical value 0. tu4 {89D67718-CAF8-40fd-B776-9C8CFE779735} Time constant associated with optional integrator feedback input signal to UEL iTiisubULsubi gt 0. Typical value 0. tul {C4145812-72D6-4160-A11D-A754E8E6509B} Real power filter time constant iTiisubUPsubi gt 0. Typical value 5. tup {214758BD-1260-4bb6-BF0E-831FF3EECEB7} Reactive power filter time constant iTiisubUQsubi gt 0. Typical value 0. tuq {BCF3CB8A-3E8C-44c3-97CA-8FC2728BC9CD} Voltage filter time constant iTiisubUVsubi gt 0. Typical value 5. tuv {35453060-020C-4ef9-99CE-F203C7822D4C} UEL integrator output maximum limit iViisubUIMAXsubi gt UnderexcLimIEEE2.vuimin. Typical value 025. vuimax {D0363285-3A59-48fb-A774-07352E446BFC} UEL integrator output minimum limit iViisubUIMINsubi lt UnderexcLimIEEE2.vuimax. Typical value 0. vuimin {0DFFCB2E-EA7D-4ef9-88FD-2318FF02820F} UEL output maximum limit iViisubULMAXsubi gt UnderexcLimIEEE2.vulmin. Typical value 025. vulmax {29808C5A-033D-49d6-AA2C-4B4244C83B91} UEL output minimum limit iViisubULMINsubi lt UnderexcLimIEEE2.vulmax. Typical value 0. vulmin {EBF244D6-78BC-48de-BA08-591E5AC62C84} Minimum excitation limit slope iKi gt 0. k {393861D0-4831-4a0b-8A47-8A6705AA4B61} Differential gain iKiisubF2subi. kf2 {38205257-9623-4ad4-A69F-215C8ABCAC8A} Minimum excitation limit gain iKiisubMsubi. km {C0BAAC97-0910-4b91-99D7-FAEA81D6666D} Minimum excitation limit value iMELMAXi. melmax {F283213F-4E1B-4a1e-9738-C415747C7FB4} Differential time constant iTiisubF2subi gt 0. tf2 {06CB3671-4833-4eb0-9EC2-0044EB0D54D1} Minimum excitation limit time constant iTiisubMsubi gt 0. tm {0B9CEC1C-8751-43e1-A44A-6EA02C8F2B5A} Differential gain iKiisubF2subi. kf2 {6788CA10-5EE0-4bd1-98E4-1803BE1F6E5F} Minimum excitation limit gain iKiisubMsubi. km {DDAD4165-7BEF-43d4-931D-45F28BFA2269} Minimum excitation limit value iMELMAXi. melmax {B7F4A273-8C3F-47e1-A3E3-D516FDC0288A} Excitation centre setting iQiisubOsubi. qo {05135508-D21A-4931-9287-C8206F7B76F8} Excitation radius iRi. r {3653B548-15A7-4567-AF03-FB105BB888BD} Differential time constant iTiisubF2subi gt 0. tf2 {84764C85-8303-4ce0-AF51-3795FA7421EE} Minimum excitation limit time constant iTiisubMsubi gt 0. tm {D96C94D2-4D71-4995-B4BE-AFB1752956EB} Excitation system model with which this underexcitation limiter model is associated. ExcitationSystemDynamics {280D64B5-2696-4d89-8390-C68A8F827258}.SupplierEnd Remote input signal used by this underexcitation limiter model. RemoteInputSignal {926FD0F1-B98A-492d-AD1E-CCA64FBEB605}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {B7D39B4A-5132-4f2d-8450-A510C4F0B92A}.ClientEnd True if vault is ventilating. kind {DEFA1FFB-3BA1-4ee9-9397-8B080F2F1413} AceTariffType {ED2E671C-C32B-4348-BE5F-95F220417E34}.ClientEnd TimeSeries {2CD55C37-FF3C-4881-B74E-437DAEAFB82E}.SupplierEnd GeneratingUnit {F5E62ED0-90DD-4d2f-AAD2-99DD94F92779}.SupplierEnd Cumulative energy production over trading period. cumEnergy {1704C461-51E5-4fea-B90C-993A7596EFAB} Resource MW output at the end of previous clearing period. resourceMW {81C0AEEA-DB38-4dd0-B3AB-34E20523A6EF} FieldDispatchHistory {D82C3366-0534-4013-898A-7202071B4EF5}.ClientEnd Incident {F41F931E-15E0-43ea-9BBE-8F6DB650B1D9}.ClientEnd TroubleOrder {D36FE243-EBDF-427d-841A-BF9DD24E97E4}.SupplierEnd TroubleTicket {76C1C366-6D04-44f8-B3FA-BD123E9196FD}.SupplierEnd causeKind {E7CB3D63-CEE5-4a8e-BBB0-0CF9B08C9FCD} WorkTask {AADBFD79-5E2A-47b4-A108-F25824E68687}.ClientEnd status {DA37264B-748A-4905-83DA-5922BA220AC2} All configuration events created for this usage point. ConfigurationEvents {BA6788B9-B467-4d11-81A1-9DFE88730490}.SupplierEnd Customer agreement regulating this service delivery point. CustomerAgreement {0FEA25EE-6DB0-45d0-99F9-D5895A91A455}.ClientEnd All end device controls sending commands to this usage point. EndDeviceControls {86BE91D2-4532-408d-85BE-C4192311A77E}.ClientEnd All end device events reported for this usage point. EndDeviceEvents {8DB1B043-3C92-412a-967D-F037C7FA8E36}.ClientEnd All end devices at this usage point. EndDevices {6B05F0D3-B04B-4b78-AF42-4AC3046EF869}.SupplierEnd EnvironmentalMonitoringStation {11F52D5E-EFC9-4c29-A3F6-7C2E9E192F0C}.ClientEnd All equipment connecting this usage point to the electrical grid. Equipments {3E4B9C55-FCC6-42ec-B364-27C62004847F}.SupplierEnd All meter readings obtained from this usage point. MeterReadings {EB5C430A-F69D-402a-9806-69357BFC879C}.ClientEnd All meter service work tasks at this usage point. MeterServiceWorkTasks {30B864E4-AFB6-47b2-BF72-C36AA03A3F68}.ClientEnd All metrology requirements for this usage point. MetrologyRequirements {28F71A07-2CD9-466b-BB76-3CAC30AEEC8F}.ClientEnd All outages at this usage point. Outage {13D27FCF-5727-416e-9B7E-FCE3388F7C11}.ClientEnd {97DDAF6C-65B2-463f-8202-046CC1702F4C}.ClientEnd All pricing structures applicable to this service delivery point with prepayment meter running as a standalone device with no CustomerAgreement or Customer. PricingStructures {E0F674C9-204B-4aa1-9887-8B17137752E6}.ClientEnd Register {04237804-35ED-45c5-A932-B74209BBA2C0}.SupplierEnd Service category delivered by this usage point. ServiceCategory {E8ABDA4A-FD10-41db-B40A-285E3E93266A}.SupplierEnd Service location where the service delivered by this usage point is consumed. ServiceLocation {9FD59FA1-2361-4259-948C-56433EAAF9B0}.ClientEnd All multipliers applied at this usage point. ServiceMultipliers {79BFF755-2D9F-4654-B2FF-58E647CF5C97}.SupplierEnd ServiceSupplier utility utilising this usage point to deliver a service. ServiceSupplier {543EBBDE-C4D2-433d-AA02-21917EA65375}.ClientEnd All groups to which this usage point belongs. UsagePointGroups {335E5091-3753-4b0d-A678-4F7E2FC7939E}.ClientEnd Location of this usage point. UsagePointLocation {A316F4EB-589A-4ae7-B7EC-033A447035E7}.ClientEnd Tracks the lifecycle of the metering installation at a usage point with respect to readiness for billing via advanced metering infrastructure reads. amiBillingReady {FE7C731F-08A5-4b5f-8BAF-76DBF14FBB92} State of the usage point with respect to connection to the network. connectionState {BC27BB0A-1E26-401a-9B22-7589BA214A67} Estimated load. estimatedLoad {898BD45F-3FC0-496c-AB0E-B3F2F5AA82E8} Nominal service voltage. nominalServiceVoltage {55F34C1B-875B-416f-AEA5-5B3A8B49ED28} Phase code. Number of wires and specific nominal phases can be deduced from enumeration literal values. For example ABCN is threephase fourwire s12n splitSecondary12N is singlephase threewire and s1n and s2n are singlephase twowire. phaseCode {62172E4F-C15C-401b-BD41-16E98E4CD81C} Quantitative information about the maximum physical capacity of the connection for the usage point. physicalConnectionCapacity {0925388C-D1EC-47ba-8DC4-79BC4A110D4B} Current flow that this usage point is configured to deliver. ratedCurrent {142F3AD8-CABE-43ae-9AF3-A6D2F3118862} Active power that this usage point is configured to deliver. ratedPower {7FA07ABB-E5D0-4635-B946-967B8DD8F39A} All demand response programs this usage point group is enrolled in. DemandResponsePrograms {36AB849B-4EDC-45e7-98B2-FCA2BC154E2B}.ClientEnd All end device controls sending commands to this usage point group. EndDeviceControls {DD9C2BA9-EDBB-4e7b-852C-9AD603C00339}.ClientEnd All usage points in this group. UsagePoints {335E5091-3753-4b0d-A678-4F7E2FC7939E}.SupplierEnd All usage points at this location. UsagePoints {A316F4EB-589A-4ae7-B7EC-033A447035E7}.SupplierEnd ErpInvoiceLineItems {5DECAD82-C8FA-4209-A6DC-EC593C447EE3}.ClientEnd ErpLedgerEntries {930F2019-2141-4f10-80A0-CECF3D224F2D}.ClientEnd ProcedureDataSets {779BA9D1-950E-4184-B4C5-D887B32ECEDB}.SupplierEnd PropertySpecification {77BA456A-7BFE-460d-9B1F-6CFF50541E78}.SupplierEnd RatingSpecification {A095B451-1D6E-48b1-8999-6944FB2D21D0}.SupplierEnd Transaction for which this snapshot has been recorded. Transaction {2749DDBF-3B2B-40e4-AF4B-40B8874DF1F9}.SupplierEnd Value of an attribute including unit information. value {2FCC8C5A-9B5B-4bb9-9AE3-A9BE83ACBD93} Time that adjuster pulses are off iTiisubAOFFsubi gt 0. Typical value 05. taoff {6C268358-8AE5-4f8d-8B29-0238E71101E8} Time that adjuster pulses are on iTiisubAONsubi gt 0. Typical value 01. taon {6D27B57A-5F30-402d-861F-26BA63FD411C} Maximum output of the adjuster iViisubADJMAXsubi gt VAdjIEEE.vadjmin. Typical value 11. vadjmax {59BBB8E6-1F97-4e17-9F06-42FC7F297EB0} Minimum output of the adjuster iViisubADJMINsubi lt VAdjIEEE.vadjmax. Typical value 09. vadjmin {A2D5F296-0E9C-408d-A62E-1EBD165805ED} font color0f0f0fResistive component of compensation of a generator iRci gt 0.font rc {E797D9B3-C339-4333-830D-ABF7A3C52C4E} font color0f0f0fTime constant which is used for the combined voltage sensing and compensation signal iTri gt 0.font tr {D1040A70-C25C-41fe-8E2F-9DC914E76223} font color0f0f0fReactive component of compensation of a generator iXci gt 0.font xc {C7EF60C2-87A9-432b-973B-072320CE7AFD} Compensation of this voltage compensators generator for current flow out of another generator. GenICompensationForGenJ {85A30109-1473-4ba8-A00B-DA4D28CE2463}.ClientEnd font color0f0f0fTime constant which is used for the combined voltage sensing and compensation signal iTri gt 0.font tr {82548F40-3D95-4117-A774-371E257F2A08} Delay {DA56FBC7-3797-4264-AE29-61FEBA3C58F7}.ClientEnd HVDCLookUpTable {14C2B235-371D-4ebf-BFF8-1E462660C3D0}.ClientEnd IdcInverterControl {D9D8D23C-3E4B-4af0-B456-954687DFA9E6}.SupplierEnd Voltage source converter to which voltage source converter dynamics model applies. VsConverter {0D53C0FB-F7F9-4e32-BFFE-42DC43308D29}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {AB07F11F-12BF-40f7-A3A5-86F42927D688}.SupplierEnd BlockingFunction {EA954A70-DF63-404b-98A9-063F5571B46A}.ClientEnd DCvoltageControl {86E86FC3-61BD-4a5f-A4F1-6BDFD8ADE591}.SupplierEnd PFmodel {E76FDA89-DE78-4412-88D5-5554DBCA51D8}.ClientEnd Pcontrol {3E4C2CFA-1298-41b3-9038-5F139DAC76C3}.ClientEnd Qlimiter {28C86EC6-3D7B-4965-99CB-2AB0622D2C24}.ClientEnd Qmode {3EEAA87A-6141-43c6-AE82-9A6DAC9A62E9}.ClientEnd Qregulator {4CCAE11F-2B9B-48f1-B5A0-6357DC443AD7}.ClientEnd Umode {ABBAB2B2-1509-4175-A3E8-48DBC8251AFA}.ClientEnd The Commands using the set for translation. Commands {E47F1C07-76A3-4828-BB41-624EB0C9DAE0}.ClientEnd The Measurements using the set for translation. Discretes {27083F43-08EC-487a-A912-C969A351E021}.SupplierEnd The Commands using the set for translation. RaiseLowerCommands {689EAD20-E5B3-46ae-BABC-7A32ADA8F247}.ClientEnd The ValueToAlias mappings included in the set. Values {24118167-9D7E-45ac-967E-8BE0BD4E1375}.SupplierEnd The ValueAliasSet having the ValueToAlias mappings. ValueAliasSet {24118167-9D7E-45ac-967E-8BE0BD4E1375}.ClientEnd Odometer reading of this vehicle as of the odometerReadingDateTime. Refer to associated ActivityRecords for earlier readings. odometerReading {17651248-7852-4708-BB6D-DC8D83BA2413} Kind of usage of the vehicle. usageKind {8BE9F017-D4FC-47d4-BD18-39C1888B845B} All vendor shifts opened and owned by this vendor. VendorShifts {B8537A91-B364-489c-BB0B-6BA861574DC1}.SupplierEnd Merchant account this vendor shift periodically debits based on aggregated transactions. MerchantAccount {28C890D5-DD6C-419b-AC03-0323BBD41D10}.ClientEnd All receipts recorded during this vendor shift. Receipts {652E0D7A-D247-45a6-80F2-A0339EFE02D7}.SupplierEnd All transactions recorded during this vendor shift. Transactions {C7BF480F-86A2-4fe5-BB3D-D4EA91B0C386}.SupplierEnd Vendor that opens and owns this vendor shift. Vendor {B8537A91-B364-489c-BB0B-6BA861574DC1}.ClientEnd The amount that is to be debited from the merchant account for this vendor shift. This amount reflects the sumPaymentTransaction.transactionAmount. merchantDebitAmount {0ED883FA-D8C0-4f3d-B6D1-ADFF9B663BC4} PowerSystemResource {4F85BB5D-133B-4060-B422-86E5B9320EE2}.SupplierEnd Flowgate {60BE8E0E-9F8A-4813-93AA-E5DC48BEF7A5}.SupplierEnd MktMeasurement {7B62C3C6-7398-40f5-BDE5-CBD6C32FC0EF}.SupplierEnd A visibility layer can contain one or more diagram objects. VisibleObjects {86380B03-52EA-473d-9BFA-DCDAAE9D1275}.ClientEnd Particulate density of the ash cloud during the time interval. density {2FEF2762-BE41-4966-902F-21C2B962D4C3} The diameter of the particles during the time interval. particleSize {2563D202-782B-405b-950C-92598A5831DA} multiplier {5CFD034E-D7E1-4d20-BE0B-BB9E4F9D2D4B} unit {6E959BD4-0ACC-4884-99F5-0B158661A3D9} Power factor or VAr controller type 1 model with which this voltage adjuster is associated. PFVArControllerType1Dynamics {7A74A658-111A-4af6-B1B7-CAA3F6F7BA11}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {DF4D0AAC-C129-47a1-ADAF-DB0071F13178}.ClientEnd Excitation system model with which this voltage compensator is associated. ExcitationSystemDynamics {261F59A6-26BA-4cfc-9309-36D92F002250}.SupplierEnd Remote input signal used by this voltage compensator model. RemoteInputSignal {F5F154AE-0B1E-4436-BB0A-FB640908FA63}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {8A60B7E2-A760-4eba-9D83-DDFC09AE0C14}.ClientEnd A VoltageControlZone is controlled by a designated BusbarSection. BusbarSection {77D2F437-1BDA-463c-AC93-F25EAC4B04AF}.ClientEnd A VoltageControlZone may have a voltage regulation schedule. RegulationSchedule {56DF2E78-015D-485f-9708-D84FAFD9124C}.ClientEnd The base voltage used for all equipment within the voltage level. BaseVoltage {F610FDC8-D98D-4367-99A9-E9CA1C8A8CC5}.SupplierEnd The bays within this voltage level. Bays {5E328091-5BC1-4fa8-9BA3-F087A215492A}.SupplierEnd The substation of the voltage level. Substation {0E9E9E28-C575-47c5-BF01-7F4EB8B36D16}.ClientEnd The bus bars high voltage limit.The limit applies to all equipment and nodes contained in a given VoltageLevel. It is not required that it is exchanged in pair with lowVoltageLimit. It is preferable to use operational VoltageLimit which prevails if present. highVoltageLimit {D1BAD493-B22A-497f-B6A6-CDFDF46EA012} The bus bars low voltage limit.The limit applies to all equipment and nodes contained in a given VoltageLevel. It is not required that it is exchanged in pair with highVoltageLimit. It is preferable to use operational VoltageLimit which prevails if present. lowVoltageLimit {EB17FEAC-CDBA-4bbd-B45E-86D3EA333C08} The normal limit on voltage. High or low limit nature of the limit depends upon the properties of the operational limit type. The attribute shall be a positive value or zero. normalValue {3AF6D9EB-CF4A-4a6a-9981-91BC90013436} Limit on voltage. High or low limit nature of the limit depends upon the properties of the operational limit type. The attribute shall be a positive value or zero. value {8FB525FF-AD28-448b-A341-12A345E4F498} multiplier {39EBF43D-BF3B-422f-8AFC-F6270D86CE37} unit {0D0A9B79-90D9-49de-A575-7F0FF7992C42} multiplier {5BA1C598-89A3-406f-996B-9CF6DAC63C7E} unit {D0E1658C-A431-4226-BAC0-DD2B9F148D2D} multiplier {3140412A-C74C-40b5-950C-0022CB841EDC} unit {A829C826-5E30-413d-B779-035125B7FAD3} All converters with this capability curve. VsConverterDCSides {088AB6E2-983D-4208-B04F-916A1B2C598B}.ClientEnd Capability curve of this converter. CapabilityCurve {088AB6E2-983D-4208-B04F-916A1B2C598B}.SupplierEnd Voltage source converter dynamics model used to describe dynamic behaviour of this converter. VSCDynamics {0D53C0FB-F7F9-4e32-BFFE-42DC43308D29}.ClientEnd Angle between VsConverter.uv and ACDCConverter.uc. It is converters state variable used in power flow. The attribute shall be a positive value or zero. delta {2189316A-172E-44de-824E-A54EC07B70C2} Droop constant. The pu value is obtained as D kVMW x Sb Ubdc. The attribute shall be a positive value. droop {09DF9A01-EFD3-483a-B7A2-00A69CFEBCD4} Compensation constant. Used to compensate for voltage drop when controlling voltage at a distant bus. The attribute shall be a positive value. droopCompensation {0C9168D8-85A0-4744-8BE8-15988CAD1B4E} The maximum current through a valve. It is converters configuration data. maxValveCurrent {49F91CB7-09CB-414b-8DBA-C54CC75EFDBA} Kind of control of real power andor DC voltage. pPccControl {5FA48BB1-3740-42bd-9B95-58218BB9B057} Kind of reactive power control. qPccControl {566B426C-68EF-4aa8-97EA-EEE5345A722F} Reactive power sharing factor among parallel converters on Uac control. The attribute shall be a positive value or zero. qShare {23E9AEE5-97B8-4a61-95F2-E91D567FAB7A} Phase target at AC side at point of common coupling. The attribute shall be a positive value. targetPhasePcc {B2315AB9-3665-4aed-BF4E-409B8B241E41} Reactive power injection target in AC grid at point of common coupling. Load sign convention is used i.e. positive sign means flow out from a node. targetQpcc {B7B87909-9557-4459-98B0-380ED4A93C30} Voltage target in AC grid at point of common coupling. The attribute shall be a positive value. targetUpcc {90F337A1-08D6-4eed-8416-47EC2B390E2D} Linetoline voltage on the valve side of the converter transformer. It is converters state variable result from power flow. The attribute shall be a positive value. uv {3A33C9B0-B1FE-46e0-B489-EA92C58DD05A} Edition of WEP standard. standardEdition {B738DDE1-247A-4ef8-A466-2527680AA1B1} WEP standard number. standardNumber {C7562412-18BC-4fbf-9208-2C97DC90F5E6} multiplier {3F719CBC-2202-44be-B94E-6BEBC34F61A2} unit {03F9AD2F-6E74-4484-9EB6-38209DC617A4} Equipment {C35B9B9D-C271-4005-801D-B7B44FF8D8C7}.ClientEnd RegisteredInterTie {A446E5B3-C506-49f2-A28E-A19EEAB812A7}.SupplierEnd Wind turbine type 1A model with which this wind aerodynamic model is associated. WindGenTurbineType1aIEC {DAD6324C-3404-453d-B801-EE89B1034AF5}.SupplierEnd Wind turbine type 3 model with which this wind aerodynamic model is associated. WindTurbineType3IEC {0A379016-96C1-4d07-8589-6AE172CD1DA8}.SupplierEnd Initial pitch angle ithetaiisubomega0subi. It is a casedependent parameter. thetaomega {25856E22-B92F-4ae2-A2DF-D2DF9665619E} Wind turbine type 3 model with which this wind aerodynamic model is associated. WindTurbineType3IEC {A9340DAA-2D75-4953-8AB2-F705D0EF27D6}.SupplierEnd Partial derivative of aerodynamic power with respect to changes in WTR speed idpiisubomegasubi. It is a typedependent parameter. dpomega {77894102-33FE-42d0-8C69-5A78456D6C54} Partial derivative of aerodynamic power with respect to changes in pitch angle idpiisubthetasubi. It is a typedependent parameter. dptheta {B8179740-D164-4929-AF75-085340CE97D8} Partial derivative idpiisubv1subi. It is a typedependent parameter. dpv1 {BB70D550-A30F-478c-B099-4BCD1D8ABC05} Rotor speed if the wind turbine is not derated iomegaiisub0subi. It is a typedependent parameter. omegazero {50D30958-9EC8-4630-B439-4062802E0534} Available aerodynamic power ipiisubavailsubiii. It is a casedependent parameter. pavail {CDD8685B-0D1D-4e26-921D-65E57C35B979} Blade angle at twice rated wind speed ithetaiisubv2subi. It is a typedependent parameter. thetav2 {F3EA8003-633F-4643-9993-B7701F88E0DA} Pitch angle if the wind turbine is not derated ithetaiisub0subi. It is a casedependent parameter. thetazero {9864969E-3C94-4660-BD25-00677AE0CE02} The wind dynamics lookup table associated with this current control limitation model. WindDynamicsLookupTable {AADAA3E0-9016-4044-A073-CB41756815C3}.ClientEnd Wind turbine type 3 or type 4 model with which this wind control current limitation model is associated. WindTurbineType3or4IEC {B15E3709-C78C-4e94-AF81-81277B45B7F1}.SupplierEnd Maximum continuous current at the wind turbine terminals iiiisubmaxsubi. It is a typedependent parameter. imax {9BC14E87-7F01-49a5-8338-8F700DDCE48A} Maximum current during voltage dip at the wind turbine terminals iiiisubmaxdipsubi. It is a projectdependent parameter. imaxdip {01DCA53F-E465-44bc-BC5C-121D2C7090F5} Partial derivative of reactive current limit iKiisubpqusubi versus voltage. It is a typedependent parameter. kpqu {A699AE14-77C6-4d4a-A0EC-21E7FFE2BD45} Voltage measurement filter time constant iTiisubufiltclsubi gt 0. It is a typedependent parameter. tufiltcl {85854FDE-4244-492a-8C35-9BEE5EEE3A31} Wind turbine voltage in the operation point where zero reactive current can be delivered iuiisubpqumaxsubi. It is a typedependent parameter. upqumax {0BFFB084-CCEA-45ef-97EC-87A01767718A} The wind dynamics lookup table associated with this P control type 3 model. WindDynamicsLookupTable {38915014-704F-43c1-8F16-D050EE005809}.ClientEnd Wind turbine type 3 model with which this wind control P type 3 model is associated. WindTurbineType3IEC {1125BB6A-BC13-4945-8BBC-ABB49A1938CE}.SupplierEnd Maximum wind turbine power ramp rate idpiisubmaxsubi. It is a typedependent parameter. dpmax {14AE625C-69FC-4d9d-8A3B-6038B20B1B45} Maximum ramp rate of wind turbine reference power idpiisubrefmaxsubi. It is a projectdependent parameter. dprefmax {E2C2E735-8B4D-4d0f-AA8B-3C2F2A1A3E8C} Minimum ramp rate of wind turbine reference power idpiisubrefminsubi. It is a projectdependent parameter. dprefmin {0B71894B-67C4-40e0-A9E0-C51022AC9CC9} Ramp limitation of torque required in some grid codes idtiisubmaxsubi. It is a projectdependent parameter. dthetamax {3F30470B-8C37-4477-AECB-6B5BD66CBBC4} Limitation of torque rise rate during UVRT idthetaiisubmaxUVRTsubi. It is a projectdependent parameter. dthetamaxuvrt {0C7553B6-1000-49a3-8EC3-828323127A74} Gain for active drive train damping iKiisubDTDsubi. It is a typedependent parameter. kdtd {2A6582BE-A66D-4462-9471-DFC650E20E06} PI controller integration parameter iKisubIpsub. It is a typedependent parameter. kip {27060C22-2320-435f-9026-08AA5841E582} PI controller proportional gain iKisubPpsub. It is a typedependent parameter. kpp {E7B9AC70-DD0C-4ed5-8FC3-83B272A53801} Active drive train damping frequency iomegaiisubDTDsubi. It can be calculated from two mass model parameters. It is a typedependent parameter. omegadtd {4F1A9B58-0F9E-4c57-A23B-07EF638F9B22} Offset to reference value that limits controller action during rotor speed changes iomegaiisuboffsetsubi. It is a casedependent parameter. omegaoffset {F3D8AF72-7AE4-46da-AC04-1CFD8091993E} Maximum active drive train damping power ipisubDTDmaxsub. It is a typedependent parameter. pdtdmax {D93E5688-ABD0-47bb-AFA5-5F88EDB1F6B1} Timesub subdelay after deep voltage sags iTiisubDVSsubi gt 0. It is a projectdependent parameter. tdvs {F1D92A86-FF8A-46b5-9191-C4BC9D7296E4} Minimum electrical generator torque itisubeminsub. It is a typedependent parameter. thetaemin {A5B91875-A172-4ede-AFC9-C0065B0C15EF} Voltage scaling factor of resettorque itisubuscalesub. It is a projectdependent parameter. thetauscale {E969BD5C-1E28-4ee2-B66D-22309EA4E7A7} Filter time constant for generator speed measurement iTisubomegafiltp3sub gt 0. It is a typedependent parameter. tomegafiltp3 {639011EC-0E08-48fd-B854-63EC7A4ED2F7} Time constant in speed reference filter iTisubomegarefsub gt 0. It is a typedependent parameter. tomegaref {739A6C35-F9F6-4908-A1E1-E97CBC91D3F4} Filter time constant for power measurement iTisubpfiltp3sub gt 0. It is a typedependent parameter. tpfiltp3 {80E91633-36F8-4df7-A47A-B33F4B10A361} Time constant in power order lag iTisubpordsub. It is a typedependent parameter. tpord {4D5DCC45-BF32-4e81-973E-5584F68EE3C4} Filter time constant for voltage measurement iTisubufiltp3sub gt 0. It is a typedependent parameter. tufiltp3 {394D12B5-70DA-45a7-BC2D-C88AA4505DCD} Voltage limit for hold UVRT status after deep voltage sags iuiisubDVSsubi. It is a projectdependent parameter. udvs {8BA50F61-AD66-47f5-BE03-A1E2A389A5E9} Voltage dip threshold for Pcontrol iuisubPdipsub. Part of turbine control often different e.g 0.8 from converter thresholds. It is a projectdependent parameter. updip {2A4F2828-1735-4c1a-AE25-F4A272C50B22} Wind turbine type 4A model with which this wind control P type 4A model is associated. WindTurbineType4aIEC {DA5D31C7-93C5-460a-887B-F6F3620C8AB7}.SupplierEnd Maximum wind turbine power ramp rate idpiisubmaxp4Asubi. It is a projectdependent parameter. dpmaxp4a {5937836E-B408-4800-9ED7-1D53ACBD0EC1} Time constant in power order lag iTiisubpordp4Asubi gt 0. It is a typedependent parameter. tpordp4a {4AD005E4-70D5-4153-90EE-2CBAAD64DACC} Voltage measurement filter time constant iTiisubufiltp4Asubi gt 0. It is a typedependent parameter. tufiltp4a {DC49301D-E1E5-4f46-AB43-E16ACE4A84C6} Wind turbine type 4B model with which this wind control P type 4B model is associated. WindTurbineType4bIEC {674DEC61-D931-4c8f-95C6-127BDFBD3C9A}.SupplierEnd Maximum wind turbine power ramp rate idpiisubmaxp4Bsubi. It is a projectdependent parameter. dpmaxp4b {A44F18B6-1014-45fe-89C7-DA88A60D04CF} Time constant in aerodynamic power response iTiisubpaerosubi gt 0. It is a typedependent parameter. tpaero {03035F3F-A209-4655-A342-C1836187D91E} Time constant in power order lag iTiisubpordp4Bsubi gt 0. It is a typedependent parameter. tpordp4b {4B1A6B14-BDEF-48ba-8E9F-EE75E292D972} Voltage measurement filter time constant iTiisubufiltp4Bsubi gt 0. It is a typedependent parameter. tufiltp4b {3B82A793-6C2B-4ebd-B0A2-55A03400C7F2} Wind turbine type 3 model with which this pitch control model is associated. WindTurbineType3IEC {6C1D2665-2EAD-48e1-8020-FED105CE3F96}.SupplierEnd Power PI controller integration gain iKiisubIcsubi. It is a typedependent parameter. kic {4C4E3437-054F-4a21-B948-4FF973E34687} Speed PI controller integration gain iKiisubIomegasubi. It is a typedependent parameter. kiomega {71A2E5DB-DC12-405b-B950-DD021DCADB35} Power PI controller proportional gain iKiisubPcsubi. It is a typedependent parameter. kpc {4F0E4016-E3A1-4fdf-A64E-CD3967604373} Speed PI controller proportional gain iKiisubPomegasubi. It is a typedependent parameter. kpomega {7D5057C5-33C8-493d-8500-23CC9DDBC8E1} Pitch cross coupling gain iKiisubPXsubi. It is a typedependent parameter. kpx {8282719A-920F-4cae-8B55-A9BBE2A56B6D} Maximum pitch angle ithetaiisubmaxsubi gt WindContPitchAngleIEC.thetamin. It is a typedependent parameter. thetamax {7F157065-34CF-4ea0-BA27-E2373B1F57E9} Minimum pitch angle ithetaiisubminsubi lt WindContPitchAngleIEC.thetamax. It is a typedependent parameter. thetamin {F51D84B7-D87F-4541-8145-6579C8A6602D} Pitch time constant itthetai gt 0. It is a typedependent parameter. ttheta {59736BAD-6516-4df7-B683-1078B54CA855} Wind turbine type 3 or type 4 model with which this reactive control model is associated. WindTurbineType3or4IEC {30981A01-0238-4403-ADC6-906C4187F62A}.SupplierEnd Maximum reactive current injection during dip iiiisubqh1subi. It is a typedependent parameter. iqh1 {0C8911DF-BD69-40b1-A451-EA5DECDB9CE0} Maximum reactive current injection iiiisubqmaxsubi gt WindContQIEC.iqmin. It is a typedependent parameter. iqmax {4DD2C0A7-1C8A-4e67-889D-DD9EFCF1FBBC} Minimum reactive current injection iiiisubqminsubi lt WindContQIEC.iqmax. It is a typedependent parameter. iqmin {E6922880-7E99-47dc-8EFE-7A5885AD089D} Post fault reactive current injection iiiisubqpostsubi. It is a projectdependent parameter. iqpost {27A21870-0F96-49fb-90A6-BD70CB539BAB} Reactive power PI controller integration gain iKiisubIqsubi. It is a typedependent parameter. kiq {D7AAE1DF-4260-45bf-8B97-E8B6BB3FC88C} Voltage PI controller integration gain iKiisubIusubi. It is a typedependent parameter. kiu {A228380E-56FA-4618-B1EE-2898DC0814E0} Reactive power PI controller proportional gain iKiisubPqsubi. It is a typedependent parameter. kpq {A524204E-A3E8-47ae-8EFF-2D48F3F915B3} Voltage PI controller proportional gain iKiisubPusubi. It is a typedependent parameter. kpu {35A2EAF9-BF21-40d6-B878-241A73D0DBBF} Voltage scaling factor for UVRT current iKiisubqvsubi. It is a projectdependent parameter. kqv {B1406641-4E8F-4778-8C5D-047F9C836C41} Resistive component of voltage drop impedance iriisubdroopsubi gt 0. It is a projectdependent parameter. rdroop {B6FA8038-FA60-44b0-B8E1-D7A95C55E2D6} Power measurement filter time constant iTiisubpfiltqsubi gt 0. It is a typedependent parameter. tpfiltq {100EAF7C-D940-4446-8975-312E086FBB4E} Length of time period where post fault reactive power is injected iTiisubpostsubi gt 0. It is a projectdependent parameter. tpost {4813D25A-9B96-43e3-A558-BB8E98329254} Time constant in reactive power order lag iTiisubqordsubi gt 0. It is a typedependent parameter. tqord {93B68A05-BF83-4d81-9B71-089AF0A486EB} Voltage measurement filter time constant iTiisubufiltqsubi gt 0. It is a typedependent parameter. tufiltq {681B2820-FBE5-4622-A1F2-ED4E3FDFA516} Voltage deadband lower limit iuiisubdb1subi. It is a typedependent parameter. udb1 {72D155DB-DD39-4065-80D2-A492877759FF} Voltage deadband upper limit iuiisubdb2subi. It is a typedependent parameter. udb2 {CFCC87DF-C495-4ab5-9FFD-90DA17FD07FA} Maximum voltage in voltage PI controller integral term iuiisubmaxsubi gt WindContQIEC.umin. It is a typedependent parameter. umax {7058E625-CA26-4a95-9512-95BD0AC09095} Minimum voltage in voltage PI controller integral term iuiisubminsubi lt WindContQIEC.umax. It is a typedependent parameter. umin {7CFF046C-4647-4a39-8A08-E13024DA28DB} Voltage threshold for UVRT detection in Q control iuiisubqdipsubi. It is a typedependent parameter. uqdip {688AAA9C-54E6-42da-AA90-220CA155D906} Userdefined bias in voltage reference iuiisubref0subi. It is a casedependent parameter. uref0 {F36AD473-7963-4e52-8D34-0BA9C79E8439} Types of general wind turbine Q control modes iMiisubqGsubi. It is a projectdependent parameter. windQcontrolModesType {9A783FE2-3B0D-4de5-A4E5-1A07C56944E3} Types of UVRT Q control modes iMiisubqUVRTsubi. It is a projectdependent parameter. windUVRTQcontrolModesType {E15D6894-4910-4aca-B0B5-81C9B9E9552F} Inductive component of voltage drop impedance ixiisubdroopsubi gt 0. It is a projectdependent parameter. xdroop {BB27A9E3-0C0D-42fe-A5AD-C466F4905938} Wind generator type 3 or type 4 model with which this constant Q limitation model is associated. WindTurbineType3or4IEC {0017E503-888C-407e-A297-BB307A040C9A}.SupplierEnd Maximum reactive power iqiisubmaxsubi gt WindContQLimIEC.qmin. It is a typedependent parameter. qmax {A89C54BD-A1E1-4d10-877C-893932674865} Minimum reactive power iqiisubminsubi lt WindContQLimIEC.qmax. It is a typedependent parameter. qmin {6E33D596-DD23-4655-AE16-8E2E7E01CD33} The wind dynamics lookup table associated with this QP and QU limitation model. WindDynamicsLookupTable {B8ADA92B-7E1A-4977-BE55-E8C3C952D529}.ClientEnd Wind generator type 3 or type 4 model with which this QP and QU limitation model is associated. WindTurbineType3or4IEC {B403375C-0F8C-45f3-92A9-700935E21AD2}.SupplierEnd Power measurement filter time constant for Q capacity iTiisubpfiltqlsubi gt 0. It is a typedependent parameter. tpfiltql {F4228B0E-2501-4854-A5CF-83704FDEDEFC} Voltage measurement filter time constant for Q capacity iTiisubufiltqlsubi gt 0. It is a typedependent parameter. tufiltql {82A92A58-DFAF-42b1-9993-72176C10ED8B} The wind dynamics lookup table associated with this rotor resistance control model. WindDynamicsLookupTable {DF3BE6FA-0490-4959-97AD-E2F9E7E8B72B}.ClientEnd Wind turbine type 2 model with whitch this wind control rotor resistance model is associated. WindGenTurbineType2IEC {B197F42D-0871-46cb-9470-FB7C83C76D53}.SupplierEnd Integral gain in rotor resistance PI controller iKiisubIrrsubi. It is a typedependent parameter. kirr {2EBA1C05-DEA6-41fc-B2FA-BFD872893BFF} Proportional gain in rotor resistance PI controller iKiisubPrrsubi. It is a typedependent parameter. kprr {68B9D395-C2A3-4dc7-A86E-99AB08F68BE4} Maximum rotor resistance iriisubmaxsubi gt WindContRotorRIEC.rmin. It is a typedependent parameter. rmax {98E0B7BF-35A6-40f8-96B8-433938E168BF} Minimum rotor resistance iriisubminsubi lt WindContRotorRIEC.rmax. It is a typedependent parameter. rmin {AD5028B6-684A-4f6c-A8A9-516181593AA1} Filter time constant for generator speed measurement iTiisubomegafiltrrsubi gt 0. It is a typedependent parameter. tomegafiltrr {1800DF42-CD71-49d6-8707-D85A3B5EC6BD} Filter time constant for power measurement iTiisubpfiltrrsubi gt 0. It is a typedependent parameter. tpfiltrr {46EF755E-5A61-4df6-AEBB-275B0C25C11F} The current control limitation model with which this wind dynamics lookup table is associated. WindContCurrLimIEC {AADAA3E0-9016-4044-A073-CB41756815C3}.SupplierEnd The P control type 3 model with which this wind dynamics lookup table is associated. WindContPType3IEC {38915014-704F-43c1-8F16-D050EE005809}.SupplierEnd The QP and QU limitation model with which this wind dynamics lookup table is associated. WindContQPQULimIEC {B8ADA92B-7E1A-4977-BE55-E8C3C952D529}.SupplierEnd The rotor resistance control model with which this wind dynamics lookup table is associated. WindContRotorRIEC {DF3BE6FA-0490-4959-97AD-E2F9E7E8B72B}.SupplierEnd The generator type 3B model with which this wind dynamics lookup table is associated. WindGenType3bIEC {07DB8FC1-6EFF-4245-916A-DB83D61B50D6}.SupplierEnd The pitch control power model with which this wind dynamics lookup table is associated. WindPitchContPowerIEC {43C4AEB1-F841-4657-AD07-5DCC12ECD3FB}.SupplierEnd The frequency and active power wind plant control model with which this wind dynamics lookup table is associated. WindPlantFreqPcontrolIEC {270439E2-372B-4fe6-97E5-0B33363C463D}.SupplierEnd The voltage and reactive power wind plant control model with which this wind dynamics lookup table is associated. WindPlantReactiveControlIEC {28BA1D32-A6C1-4d3c-9E93-99FC047529D4}.SupplierEnd The grid protection model with which this wind dynamics lookup table is associated. WindProtectionIEC {C3C3FBA5-3DF3-43fb-B61D-884F27F86A76}.SupplierEnd Type of the lookup table function. lookupTableFunctionType {63FC5B5B-9FB1-4982-B612-BB9BD18DA175} Wind aerodynamic model associated with this wind turbine type 1A model. WindAeroConstIEC {DAD6324C-3404-453d-B801-EE89B1034AF5}.ClientEnd Pitch control power model associated with this wind turbine type 1B model. WindPitchContPowerIEC {16C044ED-F9D1-4331-8143-13D0E5D17A9F}.SupplierEnd Wind control rotor resistance model associated with wind turbine type 2 model. WindContRotorRIEC {B197F42D-0871-46cb-9470-FB7C83C76D53}.ClientEnd Pitch control power model associated with this wind turbine type 2 model. WindPitchContPowerIEC {9D56255A-58CA-4569-AC81-725F7E0262B0}.ClientEnd Wind turbine type 3 model with which this wind generator type 3 is associated. WindTurbineType3IEC {46227D47-50B8-490b-A51B-3E8D8812364C}.SupplierEnd Maximum active current ramp rate idiiisubpmaxsubi. It is a projectdependent parameter. dipmax {8AD7ED6E-7C11-47bc-AFC0-BF3C7B287664} Maximum reactive current ramp rate idiiisubqmaxsubi. It is a projectdependent parameter. diqmax {63D01275-C601-4efe-B244-C95E58CC78C4} Electromagnetic transient reactance ixiisubSsubi. It is a typedependent parameter. xs {854150C6-CC99-4125-84E9-0261FDD78467} Wind turbine type 4 model with which this wind generator type 3A model is associated. WindTurbineType4IEC {CADDE3B0-B9F9-4524-8093-96B4A07DCEB0}.SupplierEnd Current PI controller integration time constant iTiisubIcsubi gt 0. It is a typedependent parameter. tic {04D419CD-198C-469a-81BE-C293B02F9BF9} The wind dynamics lookup table associated with this generator type 3B model. WindDynamicsLookupTable {07DB8FC1-6EFF-4245-916A-DB83D61B50D6}.ClientEnd Current generation time constant iTiisubgsubi gt 0. It is a typedependent parameter. tg {85DA4F3F-5BC7-45a5-9FB1-1B1F39033184} Time constant for crowbar washout filter iTiisubwosubi gt 0. It is a casedependent parameter. two {0AA36B18-1CD9-4386-A06B-7402285B1A95} Wind turbine type 4A model with which this wind generator type 4 model is associated. WindTurbineType4aIEC {11A4D311-CB84-4368-A12C-4259083A726C}.SupplierEnd Wind turbine type 4B model with which this wind generator type 4 model is associated. WindTurbineType4bIEC {CF7D044B-E56E-4d33-ABD3-F06CEB5C6888}.SupplierEnd Maximum active current ramp rate idiiisubpmaxsubi. It is a projectdependent parameter. dipmax {BA0D3C43-090D-49ac-BBFA-DB621E339E36} Maximum reactive current ramp rate idiiisubqmaxsubi. It is a projectdependent parameter. diqmax {0CFFD36D-4811-4608-8A7A-65AC6E8DAE6E} Minimum reactive current ramp rate idiiisubqminsubi. It is a projectdependent parameter. diqmin {0F64C553-CD05-46f3-987A-EBABC9C62B51} Time constant iTiisubgsubi gt 0. It is a typedependent parameter. tg {29ECC791-252C-42db-B11E-71ABF51FA479} The kind of wind generating unit. windGenUnitType {CE84D052-100C-4ce8-AC2A-9A9DEEA8DE18} Wind generator type 1 or type 2 model with which this wind mechanical model is associated. WindTurbineType1or2IEC {36490F42-A405-4d4a-B4FD-D070F544D39F}.SupplierEnd Wind turbine type 3 model with which this wind mechanical model is associated. WindTurbineType3IEC {6DFF546C-9D1C-42e3-B137-EB0D010C21D1}.SupplierEnd Wind turbine type 4B model with which this wind mechanical model is associated. WindTurbineType4bIEC {B31E0647-9F5B-4d5d-91A2-C5F15B48924F}.SupplierEnd Drive train damping iciisubdrtsubiii. It is a typedependent parameter. cdrt {369F30EB-7A69-4d9e-A001-9C38F31FB560} Inertia constant of generator iHiisubgensubi gt 0. It is a typedependent parameter. hgen {A9FDD0FD-16BE-40db-B824-B296BB1A004F} Inertia constant of wind turbine rotor iHiisubWTRsubi gt 0. It is a typedependent parameter. hwtr {CBF4C2E5-978A-4fa6-A500-5CE0B94F0E15} Drive train stiffness ikiisubdrtsubi. It is a typedependent parameter. kdrt {948C22E5-DF89-4497-8AE8-65897DB85495} The wind dynamics lookup table associated with this pitch control power model. WindDynamicsLookupTable {43C4AEB1-F841-4657-AD07-5DCC12ECD3FB}.ClientEnd Wind turbine type 1B model with which this pitch control power model is associated. WindGenTurbineType1bIEC {16C044ED-F9D1-4331-8143-13D0E5D17A9F}.ClientEnd Wind turbine type 2 model with which this pitch control power model is associated. WindGenTurbineType2IEC {9D56255A-58CA-4569-AC81-725F7E0262B0}.SupplierEnd Rate limit for increasing power idpiisubmaxsubi gt WindPitchContPowerIEC.dpmin. It is a typedependent parameter. dpmax {54AC2D61-B542-48fc-BC5E-9E5BB8D8EB6F} Rate limit for decreasing power idpiisubminsubi lt WindPitchContPowerIEC.dpmax. It is a typedependent parameter. dpmin {D8E76175-17AF-405a-9F10-9FD1D51D3305} Minimum power setting ipiisubminsubi. It is a typedependent parameter. pmin {F210E10E-FA24-4778-B1D4-3064A7CB0D02} If ipiisubinitsubisub sublt ipiisubsetsubisub subthen power will be ramped down to ipiisubminsubi. It is ipiisubsetsubi in the IEC 614002712015. It is a typedependent parameter. pset {6914DA61-3243-4294-935E-DB35E6CF9020} Lag time constant iTiisub1subi gt 0. It is a typedependent parameter. t1 {2731822F-1E6C-4215-BEBD-DAB989F6E305} Voltage measurement time constant iTiisubrsubi gt 0. It is a typedependent parameter. tr {3D85E934-89B4-4c33-9004-860CECC24306} Dip detection threshold iuiisubUVRTsubi. It is a typedependent parameter. uuvrt {ED9AB655-E925-4ccd-B58B-4BDD30C42195} The remote signal with which this power plant is associated. RemoteInputSignal {A386534A-CECA-4cf5-B0FB-5C4A4D5EA497}.SupplierEnd The wind turbine type 3 or type 4 associated with this wind plant. WindTurbineType3or4Dynamics {C63D4493-2486-43ff-9F01-3552D8AA93FE}.SupplierEnd The wind dynamics lookup table associated with this frequency and active power wind plant model. WindDynamicsLookupTable {270439E2-372B-4fe6-97E5-0B33363C463D}.ClientEnd Wind plant model with which this wind plant frequency and active power control is associated. WindPlantIEC {2E9106F6-53D0-4e64-ADF7-56F69BF49942}.SupplierEnd Maximum ramp rate of ipiisubWTrefsubi request from the plant controller to the wind turbines idpiisubrefmaxsubi gt WindPlantFreqPcontrolIEC.dprefmin. It is a casedependent parameter. dprefmax {DF676706-43EC-42b9-BA95-B3125ABBF2C8} Minimum negative ramp rate of ipiisubWTrefsubi request from the plant controller to the wind turbines idpiisubrefminsubi lt WindPlantFreqPcontrolIEC.dprefmax. It is a projectdependent parameter. dprefmin {7124716F-E419-4411-B4AD-302B0E5509B4} Maximum positive ramp rate for wind plant power reference idpiisubWPrefmaxsubi gt WindPlantFreqPcontrolIEC.dpwprefmin. It is a projectdependent parameter. dpwprefmax {F89C74D5-4443-4634-84C2-9B5BD9A54042} Maximum negative ramp rate for wind plant power reference idpiisubWPrefminsubi lt WindPlantFreqPcontrolIEC.dpwprefmax. It is a projectdependent parameter. dpwprefmin {7A99CB00-42BE-451d-84B0-B7992628CAB4} Maximum PI integrator term iKiisubIWPpmaxsubi gt WindPlantFreqPcontrolIEC.kiwppmin. It is a projectdependent parameter. kiwppmax {B92C5A9F-0F1B-4e72-B16F-5AA9A81CA0BC} Minimum PI integrator term iKiisubIWPpminsubi lt WindPlantFreqPcontrolIEC.kiwppmax. It is a projectdependent parameter. kiwppmin {FEEDDDF7-D54E-456b-A47D-47F55ED44CB1} Power reference gain iKiisubWPprefsubi. It is a projectdependent parameter. kwppref {723F66A9-EB7D-4d64-8005-EEECE80C7ED6} Maximum ipiisubWTrefsubi request from the plant controller to the wind turbines ipiisubrefmaxsubi gt WindPlantFreqPcontrolIEC.prefmin. It is a projectdependent parameter. prefmax {06F0FC1F-537C-423e-A07B-9BD5FCC4AE4C} Minimum ipiisubWTrefsubi request from the plant controller to the wind turbines ipiisubrefminsubi lt WindPlantFreqPcontrolIEC.prefmax. It is a projectdependent parameter. prefmin {1790AB59-133A-47aa-A5B1-5A00821D84CB} Lead time constant in reference value transfer function iTiisubpftsubi gt 0. It is a projectdependent parameter. tpft {FB37D3E3-0C6F-46e1-9FC8-D84EB4B4C16E} Lag time constant in reference value transfer function iTiisubpfvsubi gt 0. It is a projectdependent parameter. tpfv {9ABA17F1-800C-495d-8AF8-4446EC9D48AC} Filter time constant for frequency measurement iTiisubWPffiltpsubi gt 0. It is a projectdependent parameter. twpffiltp {278C7EB3-E847-4d13-8943-BB8F227C20B9} Filter time constant for active power measurement iTiisubWPpfiltpsubi gt 0. It is a projectdependent parameter. twppfiltp {1202D059-C098-428b-BE09-7F81B35270A7} Wind plant frequency and active power control model associated with this wind plant. WindPlantFreqPcontrolIEC {2E9106F6-53D0-4e64-ADF7-56F69BF49942}.ClientEnd Wind plant model with which this wind reactive control is associated. WindPlantReactiveControlIEC {106A7682-9DCE-4670-B630-80B1555E4A66}.SupplierEnd The wind dynamics lookup table associated with this voltage and reactive power wind plant model. WindDynamicsLookupTable {28BA1D32-A6C1-4d3c-9E93-99FC047529D4}.ClientEnd Wind plant reactive control model associated with this wind plant. WindPlantIEC {106A7682-9DCE-4670-B630-80B1555E4A66}.ClientEnd Maximum positive ramp rate for wind turbine reactive powervoltage reference idxiisubrefmaxsubi gt WindPlantReactiveControlIEC.dxrefmin. It is a projectdependent parameter. dxrefmax {9F1D6E92-6885-41ea-8EE5-67FBD0E68DB2} Maximum negative ramp rate for wind turbine reactive powervoltage reference idxiisubrefminsubi lt WindPlantReactiveControlIEC.dxrefmax. It is a projectdependent parameter. dxrefmin {24CB0B9C-3538-46ad-844C-2F5A219B4A25} Maximum reactive powervoltage reference from integration iKiisubIWPxmaxsubi gt WindPlantReactiveControlIEC.kiwpxmin. It is a projectdependent parameter. kiwpxmax {993C9A59-F78F-413b-86BE-BF639E98C5D5} Minimum reactive powervoltage reference from integration iKiisubIWPxminsubi lt WindPlantReactiveControlIEC.kiwpxmax. It is a projectdependent parameter. kiwpxmin {1069CA82-358B-476f-91D5-393BEEA774B0} Reactive power reference gain iKiisubWPqrefsubi. It is a projectdependent parameter. kwpqref {BE64B7B0-90C8-4ad2-A140-1DD896EB3B3C} Plant voltage control droop iKiisubWPqusubi. It is a projectdependent parameter. kwpqu {338E6148-4BF5-4cb9-A6CA-6DECD750181E} Filter time constant for voltagedependent reactive power iTiisubuqfiltsubi gt 0. It is a projectdependent parameter. tuqfilt {0E36E3C6-74B5-487e-B772-0AEDF1CE4265} Filter time constant for active power measurement iTiisubWPpfiltqsubi gt 0. It is a projectdependent parameter. twppfiltq {C06F778B-75BD-495e-A8AB-C6D244929E0C} Filter time constant for reactive power measurement iTiisubWPqfiltqsubi gt 0. It is a projectdependent parameter. twpqfiltq {9CC1ECD7-3B56-467c-96CF-45783C2ABC0E} Filter time constant for voltage measurement iTiisubWPufiltqsubi gt 0. It is a projectdependent parameter. twpufiltq {AB6C51D7-2DD3-4740-AE4F-EA58E97FC69B} Lead time constant in reference value transfer function iTiisubxftsubi gt 0. It is a projectdependent parameter. txft {B724D26E-37B7-4379-A607-97AC1B1FF19F} Lag time constant in reference value transfer function iTiisubxfvsubi gt 0. It is a projectdependent parameter. txfv {B1849A88-6791-4bda-B74C-2ECD83274551} Voltage threshold for UVRT detection in Q control iuiisubWPqdipsubi. It is a projectdependent parameter. uwpqdip {2951891F-CF05-4f6c-8E52-C69CE3AA2F5D} Reactive powervoltage controller mode iMiisubWPqmodesubi. It is a casedependent parameter. windPlantQcontrolModesType {781C9B32-D351-40f8-8DE5-D353D49C6336} Maximum ixisubWTrefsub iqiisubWTrefsubi or deltai uiisubWTrefsubi request from the plant controller ixiisubrefmaxsubi gt WindPlantReactiveControlIEC.xrefmin. It is a casedependent parameter. xrefmax {C90EBAB3-10ED-4d50-9ADD-68C6C07F9095} Minimum ixiisubWTrefsubi iqiisubWTrefsubi or delta iuiisubWTrefsubi request from the plant controller ixiisubrefminsubi lt WindPlantReactiveControlIEC.xrefmax. It is a projectdependent parameter. xrefmin {86A3E49F-1059-4956-A437-A29B97281E4E} Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {92B518F0-1BFC-4f7d-A5E3-B076C3298208}.SupplierEnd The wind dynamics lookup table associated with this grid protection model. WindDynamicsLookupTable {C3C3FBA5-3DF3-43fb-B61D-884F27F86A76}.ClientEnd Wind generator type 1 or type 2 model with which this wind turbine protection model is associated. WindTurbineType1or2IEC {3C3632FA-BE2B-49dd-88C8-E46159B964DB}.SupplierEnd Wind generator type 3 or type 4 model with which this wind turbine protection model is associated. WindTurbineType3or4IEC {4FAB4F77-0662-42f6-B383-068B941B8877}.SupplierEnd Maximum rate of change of frequency idFiisubmaxsubi. It is a typedependent parameter. dfimax {33D75444-7D6A-428a-9610-75BAA1C915DB} Wind turbine over frequency protection activation threshold ifiisuboversubi. It is a projectdependent parameter. fover {3723800E-4BF0-495f-9656-051631E77E0D} Wind turbine under frequency protection activation threshold ifiisubundersubi. It is a projectdependent parameter. funder {10EFDEC9-54EB-4da0-BFFF-BFBDE01EB834} Time interval of moving average window iTfMAi gt 0. It is a typedependent parameter. tfma {A632CA90-2955-4def-A008-8B96B473EC14} Wind turbine over voltage protection activation threshold iuiisuboversubi. It is a projectdependent parameter. uover {B83AD84B-CECC-43e4-9393-26A1F999D3F6} Wind turbine under voltage protection activation threshold iuiisubundersubi. It is a projectdependent parameter. uunder {C463FC22-9EFA-4066-A905-1584D805AE36} Wind turbine type 3 or type 4 model with which this reference frame rotation model is associated. WindTurbineType3or4IEC {2F7B4345-63FE-4a94-A3A0-0FA22E7F9E64}.SupplierEnd Time constant for PLL first order filter model iTiisubPLLsubi gt 0. It is a typedependent parameter. tpll {EDD13201-A420-4b3e-9242-2CFC69E652B1} Voltage below which the angle of the voltage is filtered and possibly also frozen iuiisubPLL1subi. It is a typedependent parameter. upll1 {D603B0E1-CB76-4840-B001-926357BDA7EE} Voltage iuiisubPLL2subi below which the angle of the voltage is frozen if iuiisubPLL2subisub subis smaller or equal to iuiisubPLL1subi . It is a typedependent parameter. upll2 {1B636322-5BAF-4600-876E-8DEF619CA9F1} Asynchronous machine model with which this wind generator type 1 or type 2 model is associated. AsynchronousMachineDynamics {28333A44-C128-4d1f-91A9-C4815D05A17C}.SupplierEnd Remote input signal used by this wind generator type 1 or type 2 model. RemoteInputSignal {87FA8C90-E6B5-40bb-A4FC-AD947AB5E303}.SupplierEnd Wind mechanical model associated with this wind generator type 1 or type 2 model. WindMechIEC {36490F42-A405-4d4a-B4FD-D070F544D39F}.ClientEnd Wind turbune protection model associated with this wind generator type 1 or type 2 model. WindProtectionIEC {3C3632FA-BE2B-49dd-88C8-E46159B964DB}.ClientEnd Wind aerodynamic model associated with this wind generator type 3 model. WindAeroOneDimIEC {0A379016-96C1-4d07-8589-6AE172CD1DA8}.ClientEnd Wind aerodynamic model associated with this wind turbine type 3 model. WindAeroTwoDimIEC {A9340DAA-2D75-4953-8AB2-F705D0EF27D6}.ClientEnd Wind control P type 3 model associated with this wind turbine type 3 model. WindContPType3IEC {1125BB6A-BC13-4945-8BBC-ABB49A1938CE}.ClientEnd Wind control pitch angle model associated with this wind turbine type 3. WindContPitchAngleIEC {6C1D2665-2EAD-48e1-8020-FED105CE3F96}.ClientEnd Wind generator type 3 model associated with this wind turbine type 3 model. WindGenType3IEC {46227D47-50B8-490b-A51B-3E8D8812364C}.ClientEnd Wind mechanical model associated with this wind turbine type 3 model. WindMechIEC {6DFF546C-9D1C-42e3-B137-EB0D010C21D1}.ClientEnd The power electronics connection associated with this wind turbine type 3 or type 4 dynamics model. PowerElectronicsConnection {55DFB003-A30A-4242-A110-1251E461ED28}.SupplierEnd Remote input signal used by these wind turbine type 3 or type 4 models. RemoteInputSignal {6BAC6893-7D0D-407c-903E-4E5F0755C0CE}.SupplierEnd The wind plant with which the wind turbines type 3 or type 4 are associated. WindPlantDynamics {C63D4493-2486-43ff-9F01-3552D8AA93FE}.ClientEnd Wind control Q model associated with this wind turbine type 3 or type 4 model. WIndContQIEC {30981A01-0238-4403-ADC6-906C4187F62A}.ClientEnd Wind control current limitation model associated with this wind turbine type 3 or type 4 model. WindContCurrLimIEC {B15E3709-C78C-4e94-AF81-81277B45B7F1}.ClientEnd Constant Q limitation model associated with this wind generator type 3 or type 4 model. WindContQLimIEC {0017E503-888C-407e-A297-BB307A040C9A}.ClientEnd QP and QU limitation model associated with this wind generator type 3 or type 4 model. WindContQPQULimIEC {B403375C-0F8C-45f3-92A9-700935E21AD2}.ClientEnd Wind turbune protection model associated with this wind generator type 3 or type 4 model. WindProtectionIEC {4FAB4F77-0662-42f6-B383-068B941B8877}.ClientEnd Reference frame rotation model associated with this wind turbine type 3 or type 4 model. WindRefFrameRotIEC {2F7B4345-63FE-4a94-A3A0-0FA22E7F9E64}.ClientEnd Wind generator type 3A model associated with this wind turbine type 4 model. WindGenType3aIEC {CADDE3B0-B9F9-4524-8093-96B4A07DCEB0}.ClientEnd Wind control P type 4A model associated with this wind turbine type 4A model. WindContPType4aIEC {DA5D31C7-93C5-460a-887B-F6F3620C8AB7}.ClientEnd Wind generator type 4 model associated with this wind turbine type 4A model. WindGenType4IEC {11A4D311-CB84-4368-A12C-4259083A726C}.ClientEnd Wind control P type 4B model associated with this wind turbine type 4B model. WindContPType4bIEC {674DEC61-D931-4c8f-95C6-127BDFBD3C9A}.ClientEnd Wind generator type 4 model associated with this wind turbine type 4B model. WindGenType4IEC {CF7D044B-E56E-4d33-ABD3-F06CEB5C6888}.ClientEnd Wind mechanical model associated with this wind turbine type 4B model. WindMechIEC {B31E0647-9F5B-4d5d-91A2-C5F15B48924F}.ClientEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {88DDF410-39C9-46c0-AC56-EC92DA7D9E97}.SupplierEnd Parameter of this proprietary userdefined model. ProprietaryParameterDynamics {7F96DE9C-5421-45cc-A5C5-B8C03C2B4B23}.SupplierEnd FromWinding {85692DA6-1368-431a-B29A-40C8C1AD42B8}.SupplierEnd ToWinding {F014FE41-F5D2-4748-870B-0A78530405BD}.SupplierEnd TransformerObservation {97F8FF5D-183D-4b1c-B364-25B5C98E0F5F}.ClientEnd As of statusDate the leakage reactance measured at the from winding with the to winding shortcircuited and all other windings opencircuited. leakageReactance {B02F7CD4-B6E4-4c25-99AD-E47B4D2E43F2} status {7C859540-4B46-401f-A3F9-4B4358A6FAC9} Per length line parameter associated with this wire assembly. PerLengthLineParameter {07F81D46-A7D6-403d-9687-5A39ABF063FB}.SupplierEnd Wire phase information associated with this wire assembly. WirePhaseInfo {E3D703D3-3A7D-42e4-A77D-C721E2D255F0}.ClientEnd ACLineSegmentPhase {B5F55F86-9C19-4914-99C2-1ACBA0197A2E}.ClientEnd Wire phase information associated with this wire information. WirePhaseInfo {BCFA8491-3B39-46bd-8D33-37BC4F2F5259}.SupplierEnd if there is a different core material Radius of the central core. coreRadius {965E91D6-A32D-4947-9716-E47B628E4569} Geometric mean radius. If we replace the conductor by a thin walled tube of radius GMR then its reactance is identical to the reactance of the actual conductor. gmr {906DF7D6-9FAF-4a39-85BF-B80EFEB2665D} if insulated conductor Material used for insulation. insulationMaterial {07B5CBFF-F12B-4352-8ABB-713BA7EF186B} if insulated conductor Thickness of the insulation. insulationThickness {D6A74A69-23AC-4736-AA86-7450B4629D48} Conductor material. material {111A854C-ED35-40aa-81ED-EC3F0BCA37EE} AC resistance per unit length of the conductor at 25 C. rAC25 {C90C8E7D-13A7-4e41-92B3-F93765F97436} AC resistance per unit length of the conductor at 50 C. rAC50 {804728E3-F54E-4655-91A3-2BDE96A91D5C} AC resistance per unit length of the conductor at 75 C. rAC75 {61931852-3E39-4ad6-BEF3-B8199E448CF7} DC resistance per unit length of the conductor at 20 C. rDC20 {6A3C81F3-B595-4d5d-A45A-39FDFF55105D} Outside radius of the wire. radius {664AAFE3-E0AF-4ce5-B4EA-144630C22698} Current carrying capacity of the wire under stated thermal conditions. ratedCurrent {870797AC-296B-476f-8DFC-B05E8FE8F90A} Wire assembly information using this wire phase information. WireAssemblyInfo {E3D703D3-3A7D-42e4-A77D-C721E2D255F0}.SupplierEnd Wire information contributing to this wire phase information. WireInfo {BCFA8491-3B39-46bd-8D33-37BC4F2F5259}.ClientEnd Wire position with this wire phase information. WirePosition {50E5B6AE-D7FB-4224-829C-5C6DF11ADD61}.ClientEnd Phase information. phaseInfo {266D8E98-246C-48cd-826A-7D0C07C09D8C} Wire phase information for this wire position. WirePhaseInfo {50E5B6AE-D7FB-4224-829C-5C6DF11ADD61}.SupplierEnd Wire spacing data this wire position belongs to. WireSpacingInfo {BC21C0DF-A6A4-48a0-A740-0369DB2A9ECA}.ClientEnd Signed horizontal distance from the wire at this position to a common reference point. xCoord {D8D120C8-F5D4-443d-9956-561B67DB5A4C} Signed vertical distance from the wire at this position above ground positive value or burial depth below ground negative value. yCoord {B0FE6241-691B-4f0b-B8ED-B3FB7916A7C9} The wire segment phases which belong to the wire segment. WireSegmentPhases {0431D530-090C-4821-A609-681E0D77E2EF}.ClientEnd The wire segment to which the phase belongs. WireSegment {0431D530-090C-4821-A609-681E0D77E2EF}.SupplierEnd The phase connection of the wire at both ends. phase {87D543DC-B9E0-4f0d-83F6-B7330796183A} ACLineSegment {F29D4402-D392-434d-9E98-8C35F21BD856}.ClientEnd DuctBank {18C29DE2-77AC-4a90-9E3D-065A8BC002CE}.SupplierEnd Structures {7995689F-9BD5-49e1-BAE8-C986A5446310}.SupplierEnd All positions of single wires phase or neutral making the conductor. WirePositions {BC21C0DF-A6A4-48a0-A740-0369DB2A9ECA}.SupplierEnd Distance between wire subconductors in a symmetrical bundle. phaseWireSpacing {2FAEA954-5307-42ee-8782-30DA4AAF0D8B} Usage of the associated wires. usage {FE991EA9-B3BD-46a6-93EB-DD9AA4599065} All appointments for this work. Appointments {A1F0785E-E4E6-4ce3-8297-16F47D531998}.ClientEnd BusinessCase {9F2397D7-15D3-42a6-9C58-F7D06A58CEAF}.ClientEnd All the customers for which this work is performed. Customers {07E56F99-F27D-4363-90E9-D912F7C8DEC7}.ClientEnd Designs {B42E2297-AE8B-42e0-A3FF-529C6B2C87D8}.ClientEnd ErpProjectAccounting {09AE0E89-9CDA-4e45-9D26-E7A6B10F9B3A}.SupplierEnd All incidents being addressed by this work. Incidents {49B9A841-26C8-423d-94AD-33ADD3293D00}.ClientEnd Project {FD74BD30-960D-447e-B2BA-F87F95FF9001}.SupplierEnd WorkBillingInfo {D0B05EFE-A8D0-4d29-A1FA-53015A22BA40}.ClientEnd WorkCostDetails {D2FB8A1E-45DF-418c-A043-681494BF85D6}.ClientEnd WorkFlowSteps {976229E2-09D8-43d8-95CA-98BF57DBCB3F}.ClientEnd All tasks in this work. WorkTasks {ED65B7F6-9AFD-4fe0-909C-79D02AA238C6}.SupplierEnd Base work that this activity record tracks. BaseWork {916C5FEE-0A53-4844-A34C-EA28BF6FA153}.ClientEnd Estimated percentage of completion of this individual work task or overall work order. percentComplete {700DE45F-5134-4996-A064-363FFE94C67F} CUWorkEquipmentAsset {855EE031-A0C0-4d02-9660-78C8C2427736}.ClientEnd Crew using this work asset. Crew {762660F7-4910-42bc-8748-C7841507E17A}.SupplierEnd CustomerAccount {86A9BD70-A4A7-4530-B205-5F62F9C1C7DB}.ClientEnd ErpLineItems {A0C60390-969D-4a91-B406-83ABE393F0BC}.SupplierEnd Works {D0B05EFE-A8D0-4d29-A1FA-53015A22BA40}.SupplierEnd Estimated cost for work. costEstimate {F8C8B691-3F1E-424b-9846-EB5C21B24526} Amount of price on deposit. deposit {A77E8600-D046-4583-A9B3-B7FD474EC97E} Amount of bill. workPrice {3D621E83-F3CE-4f1b-9D19-54ED66CD1AFC} ContractorItems {96CD6C4B-B625-48f2-823B-F52CD16FCC1F}.SupplierEnd CostType {5446E847-F2C9-4006-ABE5-5682B880301D}.ClientEnd Design {80D53051-C6F7-4c80-B186-FF6AFCC33A66}.ClientEnd ErpProjectAccounting {4005B7A5-5B74-4c65-921E-9254AAD5A266}.SupplierEnd LaborItems {955B011F-CCEE-4126-A607-513F05388ADE}.ClientEnd MiscCostItems {D3D92A8C-C7B5-4a95-B1BF-113EA20D2A57}.ClientEnd OverheadCost {C5ADCDD4-2638-408f-9377-13A155EB81D7}.ClientEnd PropertyUnits {A4CC1ED7-99AE-40a3-8386-8274E4C431D9}.SupplierEnd WorkCostSummary {850D5F1D-AAAC-4e12-8DCC-C3750ED1C33E}.SupplierEnd WorkTask {7F10B6C7-082B-4d2d-B95B-E5DF634041D3}.SupplierEnd Works {D2FB8A1E-45DF-418c-A043-681494BF85D6}.SupplierEnd Amount in designated currency for work either a total or an individual element. As defined in the attribute type multiple instances are applicable to each work for planned cost actual cost authorized cost budgeted cost forecasted cost other. amount {D5667FFB-6C42-4ee0-A4F6-888B57A3E00D} WorkCostDetail {850D5F1D-AAAC-4e12-8DCC-C3750ED1C33E}.ClientEnd Work {976229E2-09D8-43d8-95CA-98BF57DBCB3F}.SupplierEnd WorkTasks {C76E630D-24B2-45f0-8B97-801F51060C44}.SupplierEnd status {6C297E5A-2A72-46bc-82B5-CBEFD34D4467} All workstasks at this location. BaseWorks {4674DC66-FC6D-4b4e-B78A-2BA63838F75D}.ClientEnd DesignLocations {A50D6CAA-AFDC-4c79-A4FF-B15AE7381D4F}.ClientEnd OneCallRequest {ECA7D24D-E18E-412d-BD83-31B1B68A4448}.SupplierEnd All assets on which this nonreplacement work task is performed. Assets {7D2E82EC-1CC5-4b1b-8FF3-DFA1835C7E49}.SupplierEnd All crews participating in this work task. Crews {D3920004-AE6C-439a-9CED-543CFED22657}.SupplierEnd MaterialItems {BFEEB8FC-4560-4027-829D-304562ADB795}.SupplierEnd Old asset replaced by this work task. OldAsset {DEDB052F-30DA-4503-94F8-99F03155CB7F}.SupplierEnd Procedure data set associated with this work task. ProcedureDataSet {78EB6E9E-9B0C-466e-B813-E041B622EF3D}.ClientEnd Switching plan executed by this work task. SwitchingPlan {1B1B92E7-633C-4e30-BCDE-9C62496BE1E8}.ClientEnd TroubleOrder {0C2AE19D-0F46-483f-BA2C-8AFA95A466F6}.SupplierEnd Work this task belongs to. Work {ED65B7F6-9AFD-4fe0-909C-79D02AA238C6}.ClientEnd Total contractor costs associated with the work task. contractorCost {096BB856-397D-4299-904E-22B047F523E3} Total labor costs associated with the work task. laborCost {77174F8A-39D7-4eea-B1B5-FFBBABE95B0C} Hours of labor expended under work task. laborHours {215CD2C9-2733-44e2-A029-378B553D8A9C} Total material costs associated with the work task. materiallCost {25935B2D-841E-4212-9977-5CC1A72F0BA1} Kind of work. taskKind {FC77B89B-160A-4b34-A904-FBE58286E2DD} Total tool costs associated with the work task. toolCost {24C72508-3BC3-48ed-81FF-03888AA03695} Time schedule for this work or work task. BaseWork {43F7FE4D-DD21-436e-B70A-E2FCDD0B6928}.ClientEnd Kind of this work schedule. kind {A628C0AD-7505-49dc-91CA-79B391A9B325} Actual work time schedule. actual {4A7DDC08-A33B-496a-8109-F9DEDDED28BD} Earliest work time schedule. earliest {D71C72B0-9ADF-4a16-98E1-633DC4710A26} Estimate work time schedule. estimate {B3081235-198B-47da-8187-C425BA576FDE} ??. immediate {486D7F9D-18E4-4630-9AAA-7659CDD82270} Latest work time schedule. latest {BF0E733C-C6F7-4251-988E-7C83746A2957} Request work time schedule. request {EA40C9ED-10B3-4898-B316-F6ABB82C3AD6} Kind of this zone. kind {D30C2170-B38E-4bdd-83FD-B530C63C59A2} Number of valves in the converter. Used in loss calculations. numberOfValves {AC44001F-F907-400d-A44D-BE0A7598F930} The connected status is related to a busbranch model and the topological node to terminal relation. True implies the terminal is connected to the related topological node and false implies it is not. In a busbranch model the connected status is used to tell if equipment is disconnected without having to change the connectivity described by the topological node to terminal relation. A valid case is that conducting equipment can be connected in one end and open in the other. In particular for an AC line segment where the reactive line charging can be significant this is a relevant case. connected {C97C0B38-C62F-4f03-A3DE-A67F29A6C6DB} The orientation of the terminal connections for a multiple terminal conducting equipment. The sequence numbering starts with 1 and additional terminals should follow in increasing order. The first terminal is the starting point for a two terminal branch. sequenceNumber {7C7195D3-DFCD-487f-BF92-F359BBE7AFD0} Number designation for this line segment phase. Each line segment phase within a line segment should have a unique sequence number. This is useful for unbalanced modelling to bind the mathematical model PhaseImpedanceData of PerLengthPhaseImpedance with the connectivity model this class and the physical model WirePosition without tight coupling. sequenceNumber {ACC3476D-8979-46f3-A071-224D1BF4D7DD} The start of the time interval for which requirement is defined. intervalStartTime {1DD465A4-D2D9-477f-9D94-80BA3A7DC1BC} Date and time the asset was last tested using the type of test and yielding the current status in success attribute. dateTime {4FFD9786-EEFF-4620-AE9B-9D17639880AF} True if asset has passed acceptance test and may be placed in or is in service. It is set to false if asset is removed from service and is required to be tested again before being placed back in service possibly in a new location. Since asset may go through multiple tests during its lifecycle the date of each acceptance test may be recorded in Asset.ActivityRecord.status.dateTime. success {FB62E81E-63EF-4f9c-A355-6F288D9A581E} Type of test or group of tests that was conducted on dateTime. type {0FEE3FD2-7D70-4ee4-8264-CFF85F657565} Permit application number that is used by municipality state province etc. applicationNumber {638E86A6-F326-4891-9820-734B3C29E3E0} Date that permit became official. effectiveDate {23C8867D-3537-4ce8-AD94-24B52A542A03} Permit expiration date. expirationDate {8C159495-EDF9-470e-B98C-77196502DDF1} Permit identifier. permitID {C463DA91-790E-4181-A1D8-4F60DCEC46B8} Date and time when the creditdebit transaction was performed. dateTime {D0D262E8-C251-4552-8F93-7BBDA4AD410E} Reason for creditdebit transaction on an account. Example payment receivedarrears interest levied. reason {646CDE04-FEFD-411f-898E-99C1E725D1BE} customerNotificationType {E31C32A9-6C3E-4cbe-9FE4-47D5532BEDE1} methodType {F529C151-5EB1-423d-B977-50109A986953} note {7A8608D2-F76A-4199-98B0-453D3F56A324} time {97B57200-C543-4c9f-AAA4-10DF8FE318F5} Value expressed in applicable units. value {6A47AA12-0575-4d16-BAF8-F4CE2E654209} Normal value range maximum for any of the MeasurementValue.values. Used for scaling e.g. in bar graphs or of telemetered raw values. maxValue {7C9AE84F-6621-4dae-9591-C303B417B3B3} The value to supervise against. The value is positive. value {C965BF25-FBC7-4cec-B39F-CC8CDD3CD272} The value to supervise. The value is positive. value {14D2EFFB-6096-4cde-9CF3-02655CBB9C5A} The coded type of an ACE tariff. type {32E9FECB-0B8B-4475-AB18-395F6FCFF767} value {133597D7-9050-4335-B968-86AF7E16558C} value {9AC71195-FE05-4022-805D-524DFF496593} value {4A5E6FCF-E14C-413e-A596-5EA78FA133AB} value {358E511C-E364-4c9f-BB02-83A1E5F56D53} Date and time this activity record has been created different from the status.dateTime which is the time of a status change of the associated object if applicable. createdDateTime {6F7593D9-FC41-4433-8F90-A5A84FE358A5} Reason for event resulting in this activity record typically supplied when user initiated. reason {AD0CAFF7-7E64-4631-8F4C-8B76E7158CE4} Severity level of event resulting in this activity record. severity {07741B27-D453-4dea-80B0-7ADE4E72D9F2} Type of event resulting in this activity record. type {C48CB2C9-BE6B-4cd8-A666-75BE5D047A78} Loss percentage lossPercentage {B1883E0B-026C-4ff7-BF30-14B10E88E33F} value {BC1D6C27-8993-488f-BD6F-E0AD0C4FB6A8} Processing Order for AS selfprovisions for this region. The priority of this attribute directs the awards of any resource that resides in overlapping regions. The regions are processed in priority manner. qualifASOrder {90FE8C49-0ACA-4f26-A45C-EFAC1E87AB8C} Date this agreement was consummated among associated persons andor organisations. signDate {461C5BAD-289C-4d31-8D8E-539470E30A5B} Rating of the CAES air compressor. airCompressorRating {504D5BD8-A892-4fbc-9600-A6E90BE3D29F} The version of the named list of alert types. version {AC598F14-4F3D-4ee8-99D7-FF5D9E3345AB} intervalStartTime {4B38B663-CA9A-4c0d-9A83-2B6DBA87F560} updateTimeStamp {AF94F466-B0CE-4eb5-B240-DC456C2CE0F4} updateUser {76E870E7-3A82-46e5-95E0-894823AC4C28} 1 Detail2 Aggregate by Market service type in which case the AllocationEnergyType field will not be filled3 Aggregate by AllocationEnergyType in which case MarketServiceType will not be filled. aggregateType {66B1BD07-4C8C-4f88-8F29-F092E5572C08} allocationMwHour {74E47F30-E3A2-4739-B8EE-7038835EA041} allocationPrice {8BA67A40-9EC3-4a9a-BC7B-9B5DD8072ED6} energyTypeCode {426CE882-051B-4ea0-BEFF-5DF239659D15} Choices are ME Market Energy Capacity SR Spinning Reserve Capacity NR NonSpinning Reserve Capacity DAC Day Ahead Capacity DEC Derate Capacity marketServiceType {B1371B63-8BAD-4f4b-9EF5-18A9C9B3938D} Priority of a measurement usage. Lower numbers have first priority. priority {A30AB6E8-0C11-4b5e-A030-8E3A69991E1D} Priority of a measurement usage. Lower numbers have first priority. priority {E7365964-FC6E-4f3c-83E9-CF4A6AB953C2} Normal value range maximum for any of the MeasurementValue.values. Used for scaling e.g. in bar graphs or of telemetered raw values. maxValue {82692D33-57C7-408c-86B0-29998C3189F9} Normal value range minimum for any of the MeasurementValue.values. Used for scaling e.g. in bar graphs or of telemetered raw values. minValue {E3279DF2-4529-48c9-9820-A1B69188431D} Normal measurement value e.g. used for percentage calculations. normalValue {F093581C-DE48-4c14-963A-34C739750A61} If true then this measurement is an active power reactive power or current with the convention that a positive value measured at the Terminal means power is flowing into the related PowerSystemResource. positiveFlowIn {25855E61-5D6B-4b06-A221-C580AF35A5D5} Normal value range maximum for any of the Control.value. Used for scaling e.g. in bar graphs. maxValue {0E31E9A4-3EF8-48cc-AF43-93B68C8F87BC} Normal value range minimum for any of the Control.value. Used for scaling e.g. in bar graphs. minValue {B703E8A4-DB01-4e17-BD8F-69B24966EB57} The value to supervise against. value {095EE989-237B-444f-88E6-78DD83F64E72} The quality code for the given Analog Value. scadaQualityCode {E6C4FFA1-E8D5-4d92-8FC9-1516439C6642} The value to supervise. value {833E2600-DFEE-47d8-BF8D-13A23E5031B1} Value that indicates best possible numeric value. bestValue {63E9A77F-F0DA-4f43-849B-D027BFF23496} Value that indicates worst possible numeric value. worstValue {E6E4B735-6DE7-4346-A296-8758122F1E47} Timestamp of when the score was calculated. calculationDateTime {FCBF2F60-C576-4a77-B610-A91925ACE5C9} Datetime for when the score applies. effectiveDateTime {FD394C10-1CFE-48ec-94B4-28E94182ABAD} Asset health score value. value {6AEDFCE0-E9ED-41ff-80D6-46CDA5857E37} value {8C467CE2-6EA5-4aed-810B-32597261DB61} value {08CB4299-C5CB-4f08-810B-C8DD2ADB26DA} value {FEE24CD4-5876-4e4c-B179-AEAA3E11B738} True if requested to call customer when someone is about to arrive at their premises. callAhead {75D9D80A-694C-4110-B834-9FB7F53C2429} value {E8C2C47C-6308-4c7e-BA6A-D38EF8BB0DA9} The Demand Bid Megawatt for the area case. Attribute Usage This is Scheduled demand MW in Day Ahead demandBidMW {5F41DF1F-597A-4b0d-865B-A2428C6A552E} Description of the object or instance. Description {9BF662CF-2D9B-4972-8A6E-BB268C6018B5} Condition of asset at last baseline. Examples include new rebuilt overhaul required other. Refer to inspection data for information on the most current condition of the asset. baselineCondition {4E64DF01-9197-4bf2-8326-BE492F6EB5EA} True if asset is considered critical for some reason for example a pole with critical attachments. critical {C20AB687-5B9D-4140-8BEC-40B09E070FCC} Lot number for this asset. Even for the same model and version number many assets are manufactured in lots. lotNumber {DD5288CC-AFD7-4e0c-9A5A-B458256B1E43} Position of asset or asset component. May often be in relation to other assets or components. position {6E7B8B82-4B2C-40ea-8286-39EB60824436} Serial number of this asset. serialNumber {38BCF463-9045-45f3-A63E-FCB96998A392} Utilityspecific classification of Asset and its subtypes according to their corporate standards practices and existing IT systems e.g. for management of assets maintenance work outage customers etc.. type {430B0352-10C7-4708-8348-0C28F4B227CB} Uniquely tracked commodity UTC number. utcNumber {EB657D28-EC57-4cef-8ADD-D8FB40CA2C55} Detection limit of related analog value if different from detection limit of test standard or if there is no test standard. The detection limit also known as lower limit of detection or limit of detection LOD is the lowest quantity of a substance that can be distinguished from the absence of that substance a blank value within a stated confidence limit generally 1. detectionLimit {B296FEE6-A24A-4a6a-9E9B-DD594660185B} Precision of related analog value if different from precision of test standard or if there is no test standard. Precision is a measure of how closely individual measurements agree with one another. Expressed as plus or minus the value of this attribute. precision {1382B91D-DB7A-46b0-B589-10301C17FE2A} Likelihood of asset failure on a scale of 1low to 100 high. likelihoodOfFailure {FD7B3163-8B17-4661-852F-781785047B9C} Configuration specified for this function. configID {20C4F516-9032-481c-B217-8C7A20A54CA6} Firmware version. firmwareID {959DAD9B-DB45-48e8-B4DF-D106B51609CD} Hardware version. hardwareID {FFA0EE8C-88E7-4378-A382-1C59122AD090} Password needed to access this function. password {142745A0-00EA-415a-8DE5-3EEC3A15711E} Name of program. programID {C6816BDF-8DBD-4a3b-92D1-16CD48E4C4A7} Recommendation for action. actionRecommendation {F54E17E8-8CB8-4857-83F6-B606A38380AA} Time horizon for action. actionTimeline {ED7A149B-0858-4be4-8F4C-0AE5A6DF345D} The date and time when the event is effective. effectiveDateTime {2A874A3E-1E10-4dac-8352-D575F026E687} Indicates whether the machine is a converter fed drive. Used for short circuit data exchange according to IEC 60909. converterFedDrive {2D0ABFAD-5524-4839-992E-427EDB49569A} Ratio of lockedrotor current to the rated current of the motor IaIr. Used for short circuit data exchange according to IEC 60909. iaIrRatio {6B830706-4F9D-40d7-BB25-9CB32BE5982F} Number of pole pairs of stator. Used for short circuit data exchange according to IEC 60909. polePairNumber {C2D7D457-6BD4-436b-8F2A-17AD64AC94CB} Indicates for converter drive motors if the power can be reversible. Used for short circuit data exchange according to IEC 60909. reversible {D064CD3B-17AA-4a0e-9F52-2C43776FC32F} Locked rotor ratio RX. Used for short circuit data exchange according to IEC 60909. rxLockedRotorRatio {CF346A15-5379-44bf-B21A-3AFD391B6F47} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {D230A2B6-5733-4cfe-B4B0-7796CC5A035F} The identification of the formal name of an attribute. attribute {0FBD59EE-F566-44c4-9C0B-8E10CD91E05E} The instance value of the attribute. attributeValue {AAE2E2E8-DABD-4ba1-83AE-F05F2DAB5035} A sequential value representing a relative sequence number. position {C1CB23A1-89A8-4168-8F92-BF147A904503} propertyName {F546BBEA-7A08-4a29-815E-26937877A51A} propertyValue {2C9DB80A-5479-40f6-AFAF-D731CD37C35C} sequence {F578E05F-ABEB-41e6-BBA7-297BC6F756B2} Identification of the method of allocation in an auction. allocationMode {F41CCA4E-22DF-4371-8804-FBD174BC50B2} An indicator that signifies that the auction has been cancelled. cancelled {D8F3C9D9-D21C-4dcd-BD52-698E5F51B682} The product category of an auction. category {903E537E-0A03-4edc-8C08-29339719D70B} The terms which dictate the determination of the bid payment price. paymentTerms {CDA79844-852E-4aa8-814D-E14A2967A31E} The rights of use the transmission capacity acquired in an auction. rights {8FF7990E-BAB0-4736-998C-441D925B1012} The kind of the Auction e.g. implicit explicit .... type {6C33E2C4-D67A-4c0d-8F0F-AD378FAAF82B} The frequency for automatically recurring auxiliary charges where AuxiliaryAccount.initialCharge is recursively added to AuxiliaryAccount.dueCurrent at the start of each auxCycle. For example on a specified date and time hourly daily weekly monthly 3monthly 6monthly 12monthly etc. auxCycle {E0DA06F7-5549-4d2f-BFF9-E2AE281536D1} The coded priority indicating the priority that this auxiliary agreement has above other auxiliary agreements associated with the same customer agreement when it comes to competing for settlement from a payment transaction or token purchase. auxPriorityCode {5484F044-925A-434b-8420-9064729D9C1D} The contractually expected payment frequency by the customer. Examples are adhoc on specified date hourly daily weekly monthly. etc. payCycle {821FDC90-B952-41fc-8B61-3D6D1B6130FA} Subclassification of the inherited type for this AuxiliaryAgreement. subType {A2658DD4-1255-4eab-B60A-BD67E8F03C0C} intervalStartTime {470D6511-3AC4-412e-A8EB-D167CEE223C7} updateTimeStamp {166F39D9-3ACF-4f4f-96EA-42C7AF101791} updateUser {5EBC78B6-7446-456b-BD2E-AF5151869DC1} availUndispatchedQ {4217449A-2958-4da3-834F-1FEC963CC876} incrementalORAvail {27C11241-2C00-42b2-ABC0-52C84AF15BFA} maxExpostCapacity {989EE825-BC10-48c2-93FC-BC99475E2CAF} minExpostCapacity {FDC1CE8D-5672-4e7b-BB61-79639DD4FA03} noLoadCost {C43E5D6E-508D-4853-97CA-DA1233971AFD} startUpCost {B8D50D43-6615-4080-AA6A-DB0A7A1BF19F} Integral gain. integralGain {86CAF110-A86E-47fa-8728-B1385050F139} Pressure setpoint gain adjuster. pressureSetpointGA {C04CC74E-4B09-4010-A0A0-7B4D494D0168} Proportional gain. proportionalGain {E50BF249-B9B4-455a-8590-B42B77C73B02} Constant associated with rod pattern. rodPatternConstant {43F070BE-A56B-4544-8AE4-ED199B6B9920} Bank identifier code as defined in ISO 9362 for use in countries wher IBAN is not yet in operation. bic {581F8A25-DDBD-4192-B445-DCE0AA68491C} International bank account number defined in ISO 13616 for countries where IBAN is not in operation the existing BIC or SWIFT codes may be used instead see ISO 9362. iban {E33D83DF-4B34-4099-8648-A452D1875E5C} Account reference number. accountNumber {5D77174B-D342-43ac-B7DA-D25CA3C181AC} Operational account reference number. accountNumber {1BACCB15-6E84-4b37-83A6-5281BB03EC6A} Name of bank where account is held. bankName {0644F13E-EBDF-4666-A81C-4193E88D631B} Branch of bank where account is held. branchCode {E4659845-6DC8-4933-8048-145F952D2ACE} National identity number or equivalent of account holder. holderID {4C777630-E66F-41bf-AEAE-743296150917} Name of account holder. holderName {A9A26E12-FEF8-4238-B181-FBC14654F047} used only when there are detailed auditing requirements Date and time at which the reading was first delivered to the metering system. reportedDateTime {1EFBADCF-C043-4b42-A958-3E33FEAE424D} System that originally supplied the reading e.g. customer AMI system handheld reading system another enterprise system etc.. source {5E0394BB-E9C4-4292-B470-6DC151E4A3B8} Value of this reading. value {4940C156-BAF1-4ed1-A8E7-BCFE8AF70C33} The time for the first time point. The value can be a time of day not a specific date. startTime {3ACCE58A-16D7-4605-BA2E-BC0F2B4DDC51} Indicates the presenceabsence of energy measurements. bayEnergyMeasFlag {26D3924E-0222-4e9a-9373-CD7D256E9B19} Indicates the presenceabsence of activereactive power measurements. bayPowerMeasFlag {B5F9E0A2-7BE7-4bb1-A035-0F5F849847F0} value {242F2D41-B838-448e-AD36-B197E8CC54CF} Start time and date for which bid applies. startTime {9B636BFE-278E-44a8-8578-BFDDDB2C916C} Stop time and date for which bid is applicable. stopTime {ECEE9946-AADD-458b-80B9-02B88FEBFF23} End of the time interval n which bid is valid yyyymmdd hh24 mi ss timeIntervalEnd {3F4C4676-701C-498e-A801-30BB4FA0B5A0} Start of the time interval in which bid is valid yyyymmdd hh24 mi ss. timeIntervalStart {68EE68BA-1417-4f66-84E3-B1AB53587DE9} componentType {4A1F44CA-1FE5-4b6d-8185-674FEEF955EE} hour wihthin the bid for which the error applies endTime {7423F6F6-A703-4aba-A18E-6A165481DC0C} error message errMessage {BFCEDCA1-4371-42ea-A6EA-031A8DD538A6} Priority number for the error message errPriority {23E14325-6FCA-47d0-BC5F-AE08FF252A9E} logTimeStamp {02D675B1-0369-4b16-A7FD-D8391D728A15} msgLevel {11349151-38B6-4cb8-B79D-40820B167F94} ruleID {5BC0BF99-3D21-43d2-85FD-DF7DBA8714B3} hour wihthin the bid for which the error applies startTime {DFE2A0D2-E2F2-4a0e-B254-E4B696747888} Contains the PriceTaker ExistingTransmissionContract TransmissionOwnershipRights pumping self schedule quantity. If this value is not null then the unit is in pumping mode. pumpSelfSchedMw {84453304-3979-4192-84DD-E0A90EDEE1D9} Self scheduled value selfSchedMw {49885581-F2BE-4b65-B54A-70AB538C594F} Price Taker Export Self Sched Support Resource selfSchedSptResource {55136132-5356-4862-86A3-C8D9DAF3FC54} A unique identifier of a wheeling transaction. A wheeling transaction is a balanced Energy exchange among Supply and Demand Resources. wheelingTransactionReference {9BD74639-7B69-4bf3-ACC0-1E7B2629699A} Indication that the values in the period are considered as a whole. They cannot be changed or subdivided. blockBid {E8885A93-9691-4cb4-80D5-7128403E2259} The coded identification of the energy flow. direction {17AB2D1C-2A3B-428f-8CE5-F7C6ACD747C3} An indication whether or not each element of the bid may be partially accepted or not. divisible {2043AB91-F00F-4448-B423-9585AA7A6BC2} Unique identification associated with all linked tenders.The identification of a set of tenders that are linked together signifying that only one can be accepted. This identification is defined by the tenderer and must be unique for a given auction. exclusiveBidsIdentification {61A81A96-9463-43b0-B2D6-57E6D3E68A7B} Unique identification associated with all linked bids. linkedBidsIdentification {DA90E89E-A3A4-42fb-A53C-E814F3B600D6} The minimum quantity of energy that can be activated at a given time interval. minimumActivationQuantity {C0873E69-A736-4659-AF41-9AFDB31878D2} The numeric local priority given to a bid. Lower numeric values will have higher priority. priority {CFA75F08-D88C-48ed-BFF0-D06E01F92D3E} The information about the status of the bid such as shared restricted ... status {B890EAF9-0541-499e-BD70-5E97FB5F254B} The minimum increment that can be applied for an increase in an activation request. stepIncrementQuantity {C5941D40-E5CA-483b-8656-B10D04D9E1E7} Maximum curtailment time in number of trading intervals curtailTimeMax {1FA08F52-372C-4ae4-BD60-E11B726EEB3A} Minimum curtailment time in number of trading intervals curtailTimeMin {DB1038AC-B30D-47db-B55C-44900B2BDFBE} Market type defaultDADA Day AheadRT Real TimeHA Hour Ahead marketType {290C94D6-B5F4-4c65-8206-C01963A1F2CD} Maximum purchase time in number of trading intervals purchaseTimeMax {4B9F1161-86DA-4c4d-83DB-A9E4C7FE6B5E} Minimum purchase time in number of trading intervals purchaseTimeMin {1E3B746A-9F12-44ce-8FFB-FBFDED59CC34} Transaction scopeInternal defaultExternal scope {459E5791-DCD3-4c2c-A8F0-4492D610AF50} Transaction type default 11 Fixed2 Dispatchable continuous3 Dispatchable blockloading transactionType {2F95D0AF-361F-48f1-8E82-660250BC83D3} Level in charge calculation order. calculationLevel {2A540150-588D-4803-A6AD-1C5BD1D0A571} The version of configuration of calculation logic in the settlement. configVersion {CEBE65AE-7C04-46bf-9B1E-59FBF0EEEE59} deleteStatus {A3C5B4FD-9DE9-4aef-91C6-5B8BF21BAC17} effectiveDate {793F4C87-0F83-4866-AFDD-8E300F10A341} exception {ED997157-812E-4a0b-BA16-AFB558B4394D} factor {ABE551BD-ED20-46b1-951D-A3156D10D16B} frequency {85C35E31-A2E8-40bf-B99E-0E78B1CEF978} Number of intervals of bill determiant in trade day e.g. 300 for five minute intervals. numberInterval {48CEEAE8-9642-4920-9366-390D60AB6CBA} offset {DBA1638E-C286-47aa-BD94-9CAF9CDB41AE} The level of precision in the current value. precisionLevel {1260821F-91EE-4d35-8A73-847E0FBBC149} primaryYN {FAD57C3E-C6A8-4e2b-B47D-78B662E85168} referenceFlag {884B6063-6A84-4016-88C9-1936D07D9B50} reportable {481E6F8A-CAEF-48f1-98A1-99D8D23468CA} roundOff {EF9E4AA7-6C4C-4d48-9F71-A2144886022C} source {A2ED9E99-708E-4c2c-AF99-72A3AEF8E6FB} terminationDate {F877E939-8182-431f-8405-0374E8F9B749} The UOM for the current value of the Bill Determinant. unitOfMeasure {9956AABB-127E-452c-9E00-747B3132D3E4} sequence {DC07156D-FEE4-45f2-A26A-916CB539ADA6} The Load Dump Rating for the branch loadDumpRating {AB9608F9-FE22-4ac7-9AC3-D376DF6E71C4} The Long Term Rating for the branch longTermRating {57A835EC-E024-4485-A93D-C68462D68213} The MVAR flow on the branch Attribute Usage Reactive power flow at the series device transformer phase shifter or line end mVARFlow {B09566DA-DC18-41c4-9907-763674C31C18} The MW flow on the branch Attribute Usage Active power flow at the series device transformer phase shifter or line end mwFlow {EFC4B5AA-CE62-4feb-A6DA-E30D21AA2544} The Normal Rating for the branch normalRating {FA049830-FF5A-4060-AD80-727201ECAA92} The Short Term Rating for the branch shortTermRating {E6A911FE-8B0D-48f3-890C-1158F3DA4880} Monitor the active power flow. monitorActivePower {054412F1-EA7D-48f3-A946-73FB2A9AC5AC} Monitor the reactive power flow. monitorReactivePower {3CCD93AD-E066-4429-93CF-4A75307DAAD3} The flow into the terminal is summed if set true. The flow out of the terminal is summed if set false. positiveFlowIn {B8475766-314D-41cf-9DA0-61DF5D14D2A6} Priority of bus name marker for use as topology bus name. Use 0 for do not care. Use 1 for highest priority. Use 2 as priority is less than 1 and so on. priority {42DD7D7D-947F-400f-94F2-BE2C04827C64} A codified representation of the business case i.e. codes for highway relocation replace substation transformers etc.. corporateCode {68010FA4-340E-4cfb-B2F9-4C9B3EC0333D} Classification by utilitys corporate standards and practices. type {843AA391-E6A1-4cd6-884E-3570B77E4E3C} labelID an ID for a set of apnodespnodes used in a CRR market labelID {8C8D1C56-9CA3-4b5c-BC2E-D00C877BE090} segment end date time endDateTime {817345BB-E920-4120-86D6-7B12B5A0179D} The MW amount associated with the CRR quantity {56B83640-6685-4642-B194-18F40D7BB5B6} segment start date time startDateTime {EB4CB545-26E9-4a9f-A5A7-B30B91D4799B} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {E13E8CFF-168A-41a6-9266-D8B4D20D580B} Activity code identifies a specific and distinguishable unit of work. activityCode {9E695683-C2CF-426a-955E-C3A8E1454D32} Labor code. code {A6F667B5-330C-4455-AB85-11311DE53FDA} Activity code identifies a specific and distinguishable unit of work. activityCode {201FC700-3AA1-49c1-BF25-803B60D383F0} Code for material. corporateCode {B5ABD970-4E73-4d49-B3A0-D2B047BA2341} The equipment type code. equipCode {0F4A6BE8-8FEC-4a76-B358-486194C88A66} True if wire strands are extruded in a way to fill the voids in the cable. isStrandFill {B3CE6228-F6AE-4e51-8275-3B7C2FDA37BA} True if sheath shield is used as a neutral i.e. bonded. sheathAsNeutral {97DFC3D1-475C-49fb-B050-2FA7C58CAA02} Order of the statistical calculation method within the calculation method hierarchy. order {080044BD-D480-40cd-86AD-3FFDBC56F751} Capability performance factor. performanceFactor {242F3279-F71B-4ae2-ADE5-B1DEBFBE700D} Classification by utilitys work management standards and practices. type {C1A9E5F1-2B82-4989-8599-4B942ED46472} value {DD5CA50E-8CF4-4d9d-B637-E3028CDD0DC8} value {D86CCBDD-AB37-4d35-8A40-24064DEA2769} Name of account holder. accountHolderName {4C0BB750-D65F-42a9-B758-74B5FCD3C1DE} The card verification number. cvNumber {D70FA221-259E-4c6f-A5FD-EBC8B62F4DC7} The date when this card expires. expiryDate {BE63D46B-9ABA-446a-AFB8-11FB7EEC8697} The primary account number. pan {2AC0085A-CF44-4e60-B81F-41FA24DA1ADD} True if item is a stock item default. stockItem {94B89383-850C-47ed-BC41-A1105D18D166} Description of type of asset. type {069D3729-A67C-4573-8A70-00C84CED59A9} If true the data is being calculated by an enterprise system rather than metered directly. isVirtual {71DF17F0-D8B0-47ac-9A03-0062B4868F8C} deleteStatus {FAFC0BF4-DEAC-49e2-9D86-14FFDD70F270} effectiveDate {7FA4D357-539A-442a-B3B0-A937EBD2FA4C} equation {E79261B7-BE9D-42e3-994C-4FAF67A1D89C} message {FEDD52B7-AB53-4940-9170-906404584146} roundOff {D4C0965A-E2F8-483c-977C-54418D15EC4C} sum {CCD643C1-A078-4c50-AB7B-BF999CAEF7C3} terminationDate {82341A8E-D54C-49d8-A7D5-286333C49B6A} type {69095778-68FE-40dc-AD17-74A54A10065A} effectiveDate {3E947F8F-3C53-4bf9-B78A-40A5045C50B5} marketCode {1D6AE503-978B-4b4b-A59B-6269A25C1736} terminationDate {D7A5841A-7539-4d10-B6B3-8C199F15C101} The calculation frequency daily or monthly. frequency {543A1D72-47E5-4bb4-B003-A388EA582FE6} The number of intervals in the profile data. numberInterval {5724E16E-4C51-449c-81FE-2C70C65B9732} The type of profile. It could be amount price or quantity. type {2A8F4C98-A1A7-44ea-B725-5D9DBBB50EF6} The unit of measure applied to the value attribute of the profile data. unitOfMeasure {61638093-C8EC-4657-BBB2-EA5DBA8A4D62} The sequence number of the profile. sequence {EC051423-ABBE-415a-B5F3-A41E84467218} The date and time of an interval. timeStamp {0D55F42D-A6CB-4f2c-8F2E-3D5FE4B71CFD} The value of an interval given a profile type amount price or quantity subject to the UOM. value {5EF16AAA-B95B-4673-ACF9-BA85C08F0362} chargeOrder {EF0BAC78-4548-4ea4-A2F7-0D5219BB0E59} chargeVersion {4E6687A3-13FA-4543-9D0A-3BB9F796C455} effectiveDate {94BC39EB-6CF6-44e6-8568-C7E814337E02} factor {1283AF97-6B0B-44e5-8489-FB0ACFA67B70} frequencyType {5647123F-04F4-4200-9116-26AB6F355D31} terminationDate {760CCC7D-1D43-4365-AF3A-8C1B2A266562} totalInterval {BC782E70-8365-4ad0-AD4C-C71F9CA85949} Cheque reference number as printed on the cheque. chequeNumber {34CB8AB7-59FE-4c69-A5AB-83A55DBC6219} Date when cheque becomes valid. date {C3450A5F-DBBC-46da-9B1E-F82835F709AC} The magnetic ink character recognition number printed on the cheque. micrNumber {2505F1E1-6FE3-4429-95D2-808B196B1740} value {5C094F69-3827-4a03-AB0F-98BA656396E9} If true the equipment must be deenergised. mustBeDeenergised {8102C6B9-BFDF-4102-8071-C547C8984D08} If true the equipment must be grounded. mustBeGrounded {4C096287-27B6-4481-B59D-9418396B80FB} Used to calculate participation of Cnode in an AggregateNode factor {4A18D416-D28B-4da1-B201-A88BD1C7FA97} Point of delivery loss factor podLossFactor {9CE7F1FC-2A68-4545-84D8-CADE161C0A22} The high pressure steam sendout. cogenHPSendoutRating {58364926-2356-49f2-8FEB-BFBE60CB258A} The high pressure steam rating. cogenHPSteamRating {962F4362-7444-4925-B187-B995011FEDF2} The low pressure steam sendout. cogenLPSendoutRating {577F0232-FE4A-4ed8-A5C0-3586A290D6FD} The low pressure steam rating. cogenLPSteamRating {144D8B2A-3B7B-47a6-A0B1-5AAD86233E0C} Communication ID number e.g. serial number IP address telephone number etc. of the AMR module which serves this meter. amrAddress {770410B7-727A-49bd-A3A1-7907D402462B} Communication ID number e.g. port number serial number data collector ID etc. of the parent device associated to this AMR module. amrRouter {06F3A500-BB20-4f3c-939D-FEDF9B4FBD85} Automated meter reading AMR system communicating with this com module. amrSystem {9BF887D3-7B0F-4e62-B1C6-79CA35E81A37} If true autonomous daylight saving time DST function is supported. supportsAutonomousDst {6229BFBD-910D-4752-B6CD-31F879525811} Whether Combined Cycle Plant can be shutdown in this Configuration? ShutdownFlag {54B14599-FD05-429f-9C50-BC6EC9E73AB1} Whether Combined Cycle Plant can be started in this Logical Configuration? StartupFlag {BF6C9458-37EB-47aa-8836-53EBADD33626} Whether this CombinedCycleConfiguration is the primary configuration in the associated Logical configuration? primaryConfiguration {04A6423D-C5DF-4b31-827E-1EA76565DF80} primary configuration. primary {CF280400-93E0-4912-89E4-58771817B8AB} Steam plant. steam {3EA9BDFD-5FAE-49f8-A8EF-B8C4C75D5C8E} Flag indicating whether this is an UP transition.If not it is a DOWN transition. upTransition {12749A12-D195-4c11-821F-E47B9AA0C531} Flag that is set to true if the combustion turbine is associated with a heat recovery boiler. heatRecoveryFlag {1415519E-2DBF-47d8-9B1E-DACCEB57F065} Normal value for Control.value e.g. used for percentage scaling. normalValue {437D2D11-A2B3-49b4-9609-7210BA175EA5} The value representing the actuator output. value {29976C5A-6DB4-4916-B523-50F7858960A8} Total cost associated with changing the status of the resource. instructionCost {578EFA4E-7FD0-45b0-A6B8-57A748F87C5A} End time for the commitment period. This will be on an interval boundary. intervalEndTime {50556AF7-DC96-4147-8C7A-FDA9AA4D4017} Start time for the commitment period. This will be on an interval boundary. intervalStartTime {90E388DC-A26F-4245-8B10-5725AB7D9637} SCUC commitment period startup time. Calculated start up time based on the StartUpTimeCurve provided with the Bid.This is a combination of StartUp time bid and Unit down time. Units is minutes minStatusChangeTime {2819E1D6-C130-4a97-AC21-BFE4762100EE} Unit no load cost in case of energy commodity noLoadCost {B053BC2D-C61E-4d09-A9E2-537C58F83F3F} updateTimeStamp {5BE94617-C528-4f99-A3F9-625EA54FD721} updateUser {0D607B81-5F53-49fa-B225-567AD187BDCF} The price of the Commodity expressed as a floating point value with the currency and unit of measure defined in the associated CommodityDefinition class. value {0B6F7B9D-133A-426e-98C0-D150700FC78F} The quantity unit of measure and multiplier at the CU level that applies to the materials. quantity {84C74AD9-B462-4a74-AC12-66784AA8E5F9} The deadline for compliance. deadline {6DF556D7-D4BC-475c-8399-31E6CD2BA271} An alphanumeric code that can be used as a reference to extra information such as the description of the interlocking scheme if any. compositeSwitchType {97E05A7E-4259-438b-8705-00D60DB068EF} True if multiphase switch controls all phases concurrently. ganged {15E93293-031E-4cc3-8990-81B19133B945} Initial operating mode with the following values Automatic Manual. initOpMode {0336A72B-92DB-4f39-9EED-2CE15DAEB7A0} Supported number of phases typically 0 1 or 3. phaseCount {93078995-1B47-47cf-8635-FAC6669633E2} True if device is capable of being operated by remote control. remote {7C276369-05F5-4fd2-9D29-835C41C17C92} Number of switch states represented by the composite switch. switchStateCount {56E37B5A-CCB1-4747-A847-450647A90857} Number of concentric neutral strands. neutralStrandCount {CB711D44-7BA3-4b53-A6D7-7D68C70C922D} The actual value of the condition factor such as labor flat fee or percentage. cfValue {60BF8DF2-B00A-4b78-AA80-DF484A82D05A} value {A37F340D-8291-465f-8A0A-FF87B2676B0E} value {F819D02A-9432-4aa9-B3F5-077392D77154} Date and time this event has or will become effective. effectiveDateTime {64824EF1-3465-4c34-A0D9-943BA218B43B} Sourceinitiator of modification. modifiedBy {31F52668-C2CC-4ef6-BAF7-1826A90450BB} Free text remarks. remark {DD01E9CE-D519-4aa5-8F2D-C0C3BCA37101} Segment of the CRR described in the current record. tradeSliceID {BCB88400-1E7C-4670-B48C-CA6460FC1852} Running cumulative count of connect or disconnect events for the lifetime of this function or until the value is cleared. eventCount {B6A5E2F9-1D95-4fc1-A087-393446A8F880} True if this function is in the connected state. isConnected {25518075-8A12-4e4d-9CDF-25AE11648382} If set true the switch may disconnect the service at the end of a specified time delay after the disconnect signal has been given. If set false the switch may disconnect the service immediately after the disconnect signal has been given. This is typically the case for over current circuitbreakers which are classified as either instantaneous or slow acting. isDelayedDiscon {7DBD3A29-99F7-48c7-B885-BE4144F67C8B} If set true and if disconnection can be operated locally the operation happens automatically. Otherwise it happens manually. isLocalAutoDisconOp {CA9E0CBF-7504-4f90-9B16-493A45E40DEC} If set true and if reconnection can be operated locally then the operation happens automatically. Otherwise it happens manually. isLocalAutoReconOp {45731B3D-65FD-49d1-8C6F-6168EB0403CE} If set true and if disconnection can be operated remotely then the operation happens automatically. If set false and if disconnection can be operated remotely then the operation happens manually. isRemoteAutoDisconOp {43279BC9-6A77-479a-AA77-DF30DA8387C9} If set true and if reconnection can be operated remotely then the operation happens automatically. If set false and if reconnection can be operated remotely then the operation happens manually. isRemoteAutoReconOp {5EAF4B18-51E5-4025-9760-308042A302BB} The duration of the constraint. duration {7D03DFAB-432A-4f58-B1D4-21B2027964E5} The type of the constraint. type {96234AD7-9E0E-41df-A2D3-75E5E1411700} This value is determined in DA and RTM. The SCUC optimization ensures that the MW flow on the Branch Group will not exceed this limit in the relevant direction. BGLimit {3A1E590C-CFFE-4bbf-B83F-3251034E8B28} Branch Group TR Reservation Capacity This value is determined in DA and RTM. It is the amount of spare transmission capacity that is left for the TR holder to use. BGTRResCap {5F933B83-A2DE-4a8a-A195-D4E0E4549E7A} Branch base Power Flow. baseFlow {B223B1CC-02DB-4d9a-B9A8-23DB6AEBD44F} MW Limit. bindingLimit {53A935FA-6BE8-4d3c-8FB8-FC963D41F508} Cleared MW. clearedValue {567BBBA7-A602-468b-860D-63A52C8D4973} Transmission overload MW. overloadMW {2D0D8023-0663-49e5-AF0E-BA2FBAD73B4D} Actual MW flow as percent of limit. percentMW {8B4BDB13-A064-4273-A921-1B6E157ACCF7} Shadow Price MW for the commodity. Shadow price for the corresponding constraint. shadowPrice {38DCCFC5-8DBC-4d3b-B9E9-90A373D05135} Update time stamp. updateTimeStamp {B79B6C6B-BFF6-4a52-9773-A2ECF7006751} Updated user. updateUser {C49E6203-93E8-40a8-94B8-E6C4493721DB} factor {A3332EE4-CECA-4487-A550-30BBDC62F99F} The function is an enumerated value that can be active reactive or VA to indicate the type of flow. function {A6751AF4-2737-4b1e-AF05-B0542253CBA9} A sequential reference that defines the identity of this interval and its relative position with respect to other intervals in a sequence of intervals. sequenceNumber {13BC3024-CED2-41bc-9BF6-2AD075B8F4C3} The lowest level of consumption that defines the starting point of this interval. The interval extends to the start of the next interval or until it is reset to the start of the first interval by TariffProfile.tariffCycle. startValue {C9B4159D-FD48-4f08-81A5-2C715F675CD8} Set true if must study this contingency. mustStudy {1006D019-9EA0-4068-BBE8-7DD65C0C9E67} MW value that this resource provides to the overall contract. factor {B91798E0-DDA9-4618-A849-C7E96A209A90} When used in conjunction with a Transmission Right contract chain this is the precedence for the contracts. chainOrder {1FE814D3-9CC5-43ed-99C5-F1EE87D780D8} MW value of the contract contractMW {D4C2E876-9A57-4158-8538-E9E2E7945630} Priority for the contract. This should be unique amoung all contracts for a specific resource. This value is the directive for the SCUC algorithm on the order to satisfycut contracts. contractPriority {8B4A477C-88E5-4829-8F65-DD4F5FDE0F70} Contract status contractStatus {57879043-AB9C-4296-9DFE-F0107063427B} Estimated Fuel Adder fuelAdder {4E86FA44-61A5-462e-8ADC-F951EFAE9331} This indicates the latest schedule minutes e.g. t xx that this resource can be notified to respond. This attribute is only used if the market type is not supplied. latestSchedMinutes {3DAAD7FC-8821-4919-ACB3-9F7BF8CFB9CC} Maximum Net Dependable Capacity maxNetDependableCapacity {897F5B07-A24C-411a-A5FF-92974D196008} Maximum schedule MW quantity maximumScheduleQuantity {9E96222F-F142-468a-A0BA-C53BF2577A58} Maximum service hours maximumServiceHours {DB6A03D9-CD14-419e-B95A-8E80AFBCB823} Maximum startups maximumStartups {CD042392-070A-45ff-AEED-A165D28FB7A2} Minimum Load minimumLoad {D5D4A6CF-C570-4f9a-9597-0E3975D84BE9} Minimum schedule quanity minimumScheduleQuantity {D254C0AE-F31D-4c96-B7B9-A6F367B63FD9} Start up lead time startupLeadTime {FE9455D5-F58B-45ec-8D37-390124E0C24A} Activity code identifies a specific and distinguishable unit of work. activityCode {724DFDC6-1877-41fd-86E6-1D32A63B98A3} Specifies the type of Control e.g. BreakerOnOff GeneratorVoltageSetPoint TieLineFlow etc. The ControlType.name shall be unique among all specified types and describe the type. controlType {6AFDC59F-2A6A-41ab-9987-323A1C1CF331} Indicates that a client is currently sending control commands that has not completed. operationInProgress {DC617446-9739-4c4f-8104-988D373E6B60} The last time a control output was sent. timeStamp {019300D3-C764-4818-AA31-EE00F8FB2886} The analog value used for the analog control the raiselower control and the set point control analogValue {8AF9ACFF-9BCF-448c-A2C1-E2E293F700F7} The integer value used for the command or the accumulator reset. discreteValue {9FC1AB85-0AD0-4300-8927-62A216B594C0} Pool MW Interchange Attribute Usage The active power interchange of the pool solvedInterchange {4CFE232C-7651-4654-B5D7-69B00F0A9B62} Pool Losses MW Attribute Usage The active power losses of the pool in MW solvedLosses {0A30D1ED-41B5-44a2-B882-C25954D40D4E} True if the appliance is an electric vehicle. isElectricVehicle {AB22ECAF-6616-4845-A49D-81A1CC4A7684} True if the appliance is exterior lighting. isExteriorLighting {ECC061BA-09EC-4336-85CC-D3611DA1680C} True if the appliance is a generation system. isGenerationSystem {CE3CDA23-E4F1-4c95-AD6F-B80BD1308A58} True if the appliance is HVAC compressor or furnace. isHvacCompressorOrFurnace {F58DAD5C-5903-40c4-8441-C43F41051997} True if the appliance is interior lighting. isInteriorLighting {5680776E-9981-422f-84E7-EE0F459E167E} True if the appliance is an irrigation pump. isIrrigationPump {C61BF63B-609E-4594-A933-E2959F80CF0B} True if the appliance is managed commercial or industrial load. isManagedCommercialIndustrialLoad {7715CEF9-9EDC-4551-8715-AEEC59EBC1F4} True if the appliance is a pool pump spa or jacuzzi. isPoolPumpSpaJacuzzi {08C353AF-4C0B-4487-B50D-D51EC1DA4ED3} True if the appliance is a simple miscellaneous load. isSimpleMiscLoad {67F0C49B-1B4C-4f86-A4E5-8CB1A215C437} True if the appliance is a smart appliance. isSmartAppliance {67F103F1-967C-4c06-8AA7-DFCD5DBFD80A} True if the appliance is a stip or baseboard heater. isStripAndBaseboardHeater {A12278C6-BC53-48d6-A36B-A795C5AA06F7} True if the appliance is a water heater. isWaterHeater {01CDCE80-C542-410c-97DA-5A549815D0B9} Stage of cooling and associated power rating. stage {00A22567-01EF-4081-9A80-BAF75B02327F} A Uniform Resource Name URN for the coordinate reference system crs used to define Location.PositionPoints.An example would be the European Petroleum Survey Group EPSG code for a coordinate reference system defined in URN under the Open Geospatial Consortium OGC namespace as urnogcdefcrsEPSGXXXX where XXXX is an EPSG code a full list of codes can be found at the EPSG Registry web site httpwww.epsgregistry.org. To define the coordinate system as being WGS84 latitude longitude using an EPSG OGC this attribute would be urnogcdefcrsEPSG4236.A profile should limit this code to a set of allowed URNs agreed to by all sending and receiving parties. crsUrn {961FC72C-29B9-4d09-B575-0140E5585552} value {FE8D36F6-50A2-4391-B9FB-5B12267F7608} value {DEC55B23-344E-41a7-A8FA-8E21A6305E14} value {CBA262DB-1A7B-4562-813C-16E939256A67} value {D4BDBA35-032E-4aa0-AA21-7B4E4694BAE3} True if an amount can be assigned to the resource element e.g. building in service transmission plant software development capital false otherwise e.g. internal labor material components. amountAssignable {E18872D1-1F16-4033-96D3-3E454041BCB5} A codified representation of the resource element. code {66003815-729C-4ace-B437-0441F73684EE} The level of the resource element in the hierarchy of resource elements recursive relationship. level {89764D37-FE17-4e94-834B-E0A23E4BD94B} The stage for which this costType applies estimated design estimated actual or actual actual. stage {5F794B8E-0443-41c3-A22E-CE12ED456C3C} Classification by utilitys work mangement standards and practices. type {EC4D9877-70D5-4366-8DB0-0D650B39E801} Net tie MW. These are three entries the current emergency schedule interchange and the two future schedules if they exist. emergencyScheduleMW {B53EB58A-2509-455c-AD80-18A8BC0C9A1C} Ramp time the ramping time for a schedule. This is calculated as the remaining time to ramp if a schedule is ramping. Measured in seconds but can be negattive. emergencyScheduleRampTime {CEAA82DA-77AD-4b8d-B70A-9CE53FB1EB63} Net tie time the start time for a schedule. This is calculated as the current time if a schedule is ramping. emergencyScheduleStartTime {E060B453-0DE3-429f-BD35-27223E05C8A2} value {83BDDC04-3689-432d-BF6E-0712C32CE504} Set true if the current relay has inverse time characteristic. inverseTimeFlag {7499121A-8A2C-48db-985D-971ADE0D1B62} Current control area net tie MW the sum of the tie line flows i.e the sum of flows into and out of the control area the current instantaneous scheduled interchange. currentNetTieMW {F52B6E46-0018-400b-9011-F7DB4A2C2A7A} Use Emergency Schedule Attribute Usage Emergency use indicator false Emergency Schedular OFF true Emergency Schedular ON. useEmergencySchedule {8A820CCE-E30E-4414-98F0-1A518292E03E} CT accuracy classification. accuracyClass {82552632-7502-4d65-BBB1-8E6A067F4873} CT classification i.e. class 10P. ctClass {80E77345-5BB0-40b8-B123-5DCB928951D2} Intended usage of the CT i.e. metering protection. usage {56466CE3-6700-41c3-B756-DB92CB062BEF} CT accuracy classification. accuracyClass {BBE29588-E564-4049-9BC1-3BEF60AEFEFA} Number of cores. coreCount {A3439D96-56FC-4203-BCA4-72F08DF7E63A} ctClass {9706AC2D-13CB-421c-AB8D-0D3D4D150139} Usage eg. metering protection etc. usage {48BD9430-4FFB-4cdc-9019-FEC9036835F3} The data value of the Xaxis variable depending on the Xaxis units. xvalue {25202638-FF67-4a74-9190-EFB0B473BAAB} The data value of the first Yaxis variable depending on the Yaxis units. y1value {5BE57251-18BF-4e7f-A02D-3B42C9DC1222} The data value of the second Yaxis variable if present depending on the Yaxis units. y2value {88D16D6F-312D-4a45-B322-E742A16DDB3F} The data value of the third Yaxis variable if present depending on the Yaxis units. y3value {53A1221F-D9D4-4ade-8918-ADB189907ABD} Locale designating language to use in communications with this customer. locale {6C272E71-959E-4d69-B143-6DC49AB2A0D5} if applicable Public utilities commission PUC identification number. pucNumber {4044CC00-B628-44a1-BCB3-5864B96E66ED} True if customer organisation has special service needs such as life support hospitals etc. specialNeed {DC524344-393C-44d5-849C-B2B08481B7A9} deprecated use priority instead True if this is an important customer. Importance is for matters different than those in specialNeed attribute. vip {EDA95871-C80E-4d3c-AFEA-79575780E2FE} Cycle day on which the associated customer account will normally be billed used to determine when to produce the billing. billingCycle {71DC2D6E-AF5F-4b99-BD52-6452CEA27F8C} Budget bill code. budgetBill {789C5B33-25FB-4e44-B978-FEBDBFCE7AE5} If true the customer is a prepay customer for the specified service. isPrePay {83C54792-A73E-42c0-89BF-2704EB0CFCB6} Load management code. loadMgmt {15CE1E0E-9A95-48ba-B098-11C89F09061F} Final date and time the service will be billed to the previous customer. shutOffDateTime {8FD31051-3798-4023-8527-6B57A4DC49D8} Business date designated for the billing run which produced this CustomerBillingInfo. billingDate {12D186DD-95FD-4517-842D-385342B64506} Calculated date upon which a customer billing amount is due used in the invoicing process to determine when a Customers Payment is delinquent. It takes into consideration the regulatory criteria and the Customers requested due date. In the absence of a Customer requested due date the due date is typically calculated from the regulated number of days and the billingDate. dueDate {CA7C613F-F1BC-4b31-A039-A3B5D07E146F} Date of the last payment received from the customer. It is retained in the Customer Billing system although the details of each payment are tracked in the ERP system. lastPaymentDate {44E5BD4D-16FB-47e3-A7BC-D9986E8114C7} Type of payment plan. pymtPlanType {8DF9572D-F773-4178-8496-ECF4F5EAF471} Type of contact e.g. phone email etc.. contactType {88B92073-B229-40ae-A4ED-B9C6B5D11AEF} Value of contact type e.g. phone number email address etc.. contactValue {48BFCAF6-872E-48a0-9BC4-571637693AA3} Earliest date time to call the customer. earliestDateTimeToCall {F26E31AA-5C85-45d0-AEB0-8016C070FE01} Latest date time to call the customer. latestDateTimeToCall {BFC1B4D2-0ED1-44b4-B29B-35BAC89EF480} Wind Force as classified on the Beaufort Scale 012 during the time interval. windForce {205F3C8E-F5CE-432e-A904-67EE2E7D36F1} intervalNumber {2CEA5B0D-5C22-4005-8809-EF81B2368CA7} maxYValue {457C948A-86B7-47c7-AF69-AE9CCE1A78E7} minYValue {286AB868-27C0-490e-BDC6-614D0CA50C95} nominalYValue {49E8C08F-F968-474d-A937-C3BB832D73C0} timeStamp {F27D2492-4951-4870-9EEF-03B787335ADA} connectDisconnect {038AB681-95CA-4260-B164-C05028A458A7} frequencyWattCurveFunction {0D3690F5-90F9-4eba-AE52-160BD143AD87} maxRealPowerLimiting {378EE0AC-39F7-4b4a-AB8B-052E946C50A5} rampRateControl {C13BA408-60AF-472c-80B4-EF70955EA44F} reactivePowerDispatch {6FE87DDE-CAF6-44da-92B0-11B3464031D4} realPowerDispatch {89B5111F-4C71-48e4-AF53-A32C16D4B7C0} voltVarCurveFunction {CC717899-83B4-4919-AE5E-F766AF4293EB} voltWattCurveFunction {4CF3A52F-1D86-426d-95D6-A992782F29D8} voltageRegulation {14F7BDCA-3C1A-41d0-AD01-F2F5409FEEBC} The timestamp for when a prediction was created predictionCreationDate {41C4E067-0F3F-4a40-9FBC-BFE14BB0FB23} yUnitInstalledMax {518E0D95-7456-405b-BF96-2D507A5D3DE7} yUnitInstalledMin {55B20B63-082A-4779-8A64-D61E73057059} value {0F8AB6DB-14D2-4ff4-8F9D-04C8EE513931} The description is a free human readable text describing or naming the object. It may be non unique and may not correlate to a naming hierarchy. description {14F272FF-25AE-4d6a-9BFE-FF46458C9848} Master resource identifier issued by a model authority. The mRID is unique within an exchange context. Global uniqueness is easily achieved by using a UUID as specified in RFC 4122 for the mRID. The use of UUID is strongly recommended.For CIMXML data files in RDF syntax conforming to IEC 61970552 Edition 1 the mRID is mapped to rdfID or rdfabout attributes that identify CIM object elements. mRID {38079BA5-9C66-4e27-9C98-D6221A666E31} The name is any free human readable and possibly non unique text naming the object. name {4DFBBA72-867F-4d84-8F39-69AFECF9990E} Date as yyyymmdd which conforms with ISO 8601 date {AB78A7E6-4326-47df-BDD7-19020BFD7955} Time as hhmmss.sssZ which conforms with ISO 8601. time {D47B6165-A270-4a65-80DB-C64BDF3384EB} End date of this interval. end {339CEC7A-2AAE-4b35-A4F0-D99489647814} Start date of this interval. start {E4C6879F-771E-45e8-8ABB-77B9C038EECC} End date and time of this interval. The end date and time where the interval is defined up to but excluded. end {55C5DBB1-2BC7-4ff6-9AE1-5D9BD2F9C376} Start date and time of this interval. The start date and time is included in the defined interval. start {6B83DB52-1642-4a44-8CCC-C20165ABEF2D} Value of this quantity. value {10B7E679-825E-4a69-B100-0BDB78764BE4} To indicate a type used for a default energy bid curve such as LMP cost or consultative based. curveType {21406AC0-4224-43cb-860E-F9D10BFE2A15} Type of demand response program examples are CPP criticalpeak pricing RTP realtime pricing DLC direct load control DBP demand bidding program BIP base interruptible program. Note that possible types change a lot and it would be impossible to enumerate them all. type {73995657-2421-4621-BAA7-4C3A392F9D45} Date and time asset most recently put in service. inServiceDate {74B6735C-750A-4691-A153-43D9FA159702} Date and time asset most recently installed. installedDate {47DC0F80-8D6E-431c-A4E7-3493FD1D87A0} Date and time of asset deployment transition to not yet installed. notYetInstalledDate {2DD37832-4235-44cc-8AB3-85D18F40C5F8} Date and time asset most recently taken out of service. outOfServiceDate {57ECC0B7-29A0-43da-91E6-2DA5883C308A} Date and time asset most recently removed. removedDate {53B5359B-5F55-48f2-AD8A-BF0DCD623ABE} A code that helps direct accounting capital expense or accounting treatment. cuAccount {3E3F4920-E49F-47be-89D6-7F354CFE0215} As the same CU can be used for different purposes and accounting purposes usage must be specified. Examples include distribution transmission substation. cuUsage {336A65BC-7340-4e6d-8D1A-DAF39EE828FB} Year when a CU that represents an asset is removed. removalDate {94B1A40C-D493-4d9f-B798-C1BEBEC495EC} True if associated electrical equipment is intended to be energized while work is being performed. toBeEnergised {AB1BE96D-4FEB-4790-B605-3E761438F03D} Effect of problem. effect {9D24B977-2916-419b-AEB0-C992DFB2E3D8} Failuer mode for example Failure to Insulate Failure to conduct Failure to contain oil Failure to provide ground plane Other. failureMode {20867EBB-0B64-4e42-8BD7-5C35EB325E4C} Cause of problem determined during diagnosis. finalCause {F733F1CC-263D-474c-BEB0-968985A3B5A5} Code for diagnosed probem type. finalCode {FFC539E2-1CD0-42c5-AF27-00B0E505E143} Origin of problem determined during diagnosis. finalOrigin {CAFBD581-3686-485b-97DD-919B0936E4A1} Remarks pertaining to findings during problem diagnosis. finalRemark {DD8F1982-C0F0-4614-B85B-8F6C1C86EE32} Code for problem type determined during preliminary assessment. preliminaryCode {82B6D5BE-5A23-4de6-918A-6AF05ED4FFC7} Date and time preliminary assessment of problem was performed. preliminaryDateTime {BCC48BA2-EB9C-4997-BDE1-AF0E28B50110} Remarks pertaining to preliminary assessment of problem. preliminaryRemark {F53CA5FA-DA56-4cc5-BDE5-E759CD257D66} Root cause of problem determined during diagnosis. rootCause {283B037A-8BA2-4354-AC49-449DD43A7EFB} Root origin of problem determined during diagnosis. rootOrigin {A0A688A9-EA41-415a-A095-F4BB99F03134} Remarks pertaining to root cause findings during problem diagnosis. rootRemark {F2028E43-700A-4139-B392-299371B11E17} X coordinate of the first corner of the initial view. x1InitialView {C3E7979E-7009-4acc-BEFD-4EE6C76AC48B} X coordinate of the second corner of the initial view. x2InitialView {8D98579B-5D7F-44a7-B694-6ADA4287C5AB} Y coordinate of the first corner of the initial view. y1InitialView {F9ED2529-E452-4556-ACAD-C33EA342768B} Y coordinate of the second corner of the initial view. y2InitialView {FC6220EE-D6C6-4c8c-A6AF-02463B048936} The drawing order of this element. The higher the number the later the element is drawn in sequence. This is used to ensure that elements that overlap are rendered in the correct order. drawingOrder {9C8F08EF-6539-4118-BEA5-1E00C412E809} Defines whether or not the diagram objects points define the boundaries of a polygon or the routing of a polyline. If this value is true then a receiving application should consider the first and last points to be connected. isPolygon {E105F67A-F735-40c8-828B-50637B38AEBC} The offset in the X direction. This is used for defining the offset from centre for rendering an icon the default is that a single point specifies the centre of the icon.The offset is in perunit with 0 indicating there is no offset from the horizontal centre of the icon. 0.5 indicates it is offset by 50 to the left and 0.5 indicates an offset of 50 to the right. offsetX {9E1EABB6-8384-40b8-B97D-CAC2F81D25CC} The offset in the Y direction. This is used for defining the offset from centre for rendering an icon the default is that a single point specifies the centre of the icon.The offset is in perunit with 0 indicating there is no offset from the vertical centre of the icon. The offset direction is dependent on the orientation of the diagram with 0.5 and 0.5 indicating an offset of 50 on the vertical axis. offsetY {10731F3A-76D6-488f-8C14-CC488A1F8B2D} The sequence position of the point used for defining the order of points for diagram objects acting as a polyline or polygon with more than one point. The attribute shall be a positive value. sequenceNumber {DD5337A3-21F0-414c-B772-EC69C25CB9C0} The X coordinate of this point. xPosition {A3590665-8EB6-420f-B38D-80EDBB9A2879} The Y coordinate of this point. yPosition {997CF101-75B1-45e4-9EEE-974A5021B21A} The Z coordinate of this point. zPosition {DD934E69-A026-4e5c-8806-B82F21273BEE} A description of the orientation of the object relative to the dimensions. As an example a vault may have northsouth orientation for the sizeLength measurement and sizeDepth may be the height of the vault. orientation {A79BC47D-365C-4c49-801D-CDE794D7BB1D} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {E6E3C01A-8E9E-43d4-9557-EC69B205A70E} Normal value range maximum for any of the MeasurementValue.values. Used for scaling e.g. in bar graphs or of telemetered raw values. maxValue {01F2E304-8F1E-411f-8E9E-F7ABE6EBFDF9} Normal value range minimum for any of the MeasurementValue.values. Used for scaling e.g. in bar graphs or of telemetered raw values. minValue {B037804B-F711-402b-B970-3783F39F5D39} Normal measurement value e.g. used for percentage calculations. normalValue {C5F7B7AF-8F82-4817-AE28-E89B438AC440} Switch Manual Replace Indicator. Flag indicating that the switch is manual replace. manualReplaceIndicator {0F5EB050-1945-4087-B917-F1386235174A} Removed From Operation Indicator. Flag indicating that the switch is removed from operation. removeFromOperationIndicator {8FA4980E-4422-4dcc-A6A9-281639701434} The value to supervise. value {8BEDF964-90B8-4560-85C4-AB072DA60F17} The Subject DN is the X509 Certificate Subject DN. This is the essentially the certificate name presented by the client. In the case of ADS Certificates this will be the user name. It may be from an API Client or the MP Client GUI.The Subject ID normally includes more than just the user name Common Name it can also contain information such as City Company ID etc. certificationName {2F0BD8D9-3850-45cf-8064-E713769E503F} The target datetime for the received instruction. instructionTime {DF69EF06-AD72-4e42-BA97-13EFB9885E8E} instruction typecommitmentout of sequencedispatch instructionType {BB8F257E-A6B7-4383-90DC-48575D271573} Timestamp indicating the time at which the instruction was received. receivedTime {01352FBA-1FA8-409b-AF74-AD7249F13B92} start time startTime {60B3E187-DD10-4762-A31A-8E31E5668E25} Used to specify the number of intervals when requesting a forecast or a dispatch. numberOfIntervals {7CF4BD27-56D1-44f1-939B-97AE671F3FAB} The start time of the first interval in the dispatch schedule startTime {D59461F4-D44A-4a43-8B0F-19108BE7B8E7} The length of time for each interval in the dispatch schedule. timeIntervalDuration {26ECA103-D7A2-4e84-BC4C-4F2BA77FF543} value {46E3485A-62DB-425a-B900-3AA4DF718F14} The end of the time interval for which requirement is defined. intervalEndTime {CF797456-529F-4a87-AF1F-10970741A498} The start of the time interval for which requirement is defined. intervalStartTime {923A6AEA-D882-4741-B721-4D9953096F26} Name of the author of this document. authorName {3CAF8786-CCB2-4aac-9223-4099DBF0A5AF} Free text comment. comment {A754AC3E-62CC-4559-8275-82B3391ACEC4} Date and time that this document was created. createdDateTime {2AADF13C-3746-4a53-9569-4D4F32C28CF4} Date and time this document was last modified. Documents may potentially be modified many times during their lifetime. lastModifiedDateTime {779D509D-F4F0-4279-8E0D-CA2FC2B461C9} Revision number for this document. revisionNumber {BB9A66A5-1F53-423b-B1D7-328BB2D64C84} Document subject. subject {9876F55E-396A-4b45-969E-5EF24A46DAB0} Document title. title {D5DB91DF-E1E6-4d77-A2D8-D070A03B9422} Utilityspecific classification of this document according to its corporate standards practices and existing IT systems e.g. for management of assets maintenance work outage customers etc.. type {6A6BC1C9-8818-43ca-BFB0-A1A43EFAAD20} A value used to establish priority of the DOP when plotting. This is only applicable when two DOPs exist for the same time but with different MW values. E.g. when indicating a step in the curve. Its used to determine if the curve steps up or down. plotPriority {D15D423F-AFDC-4b55-A01D-6BC69AE3B85D} DOP time stamp timestampDOP {37C842F5-E920-4aed-BB71-C52EBC28C159} updateTimeStamp {42FB380E-784A-47b9-9029-726B8C1879CB} updateUser {7BD0DDD2-C99C-4955-A471-0F9902D3EBDC} Dispatch operating target value. DOT {C924C44A-2BE0-421f-916C-41AC7FF43AEB} Actual ramp rate. actualRampRate {AABFDE8F-AAF6-45a5-84D7-43DD87AC0215} Economic Max Limit override for unit this value is null if it is not this value overrides the Energy column value. Allows dispatcher to override the units energy value. economicMaxOverride {8AE849EC-4989-4c51-9746-44C9D17B8DCC} Expected energy. expectedEnergy {0D1B3ECD-85B8-40c0-853A-D3AAF1A18DEC} The Degree of Generator Performance DGP used for the unit. Measure of how a generator responds to raise lower signals. Calculated every five minutes. generatorPerformanceDegree {81D47F65-2C70-4e6e-BCD7-C849FBEAD6BD} HASP results. hourAheadSchedEnergy {5A6B1B79-E227-47b8-9448-B9580C8EF722} Hourly Schedule DA Energy Schedule. hourlySchedule {9621C54A-2600-45a1-B43A-2A0C9675C2D7} The datetime for the instruction. instructionTime {B65905A1-FF98-40f5-AA15-228D4B9FDAD2} True if maximum emergency limit activated false otherwise. If unit is requested to move up to its max emergency limit. this flag is set to true. maximumEmergencyInd {5644A1D9-6F4B-4572-8207-B27916EDF715} Meter Sub System Load Following. meterLoadFollowing {C21B8592-E424-4c8f-910C-E40E238C92EA} Desired MW that is not ramp restricted. If no ramp rate limit existed for the unit this is the MW value tha t the unit was requested to move to. nonRampRestrictedMW {51695684-7F17-453d-801E-EE2D5652715B} Non Spin Reserve used to procure energy. nonSpinReserve {F9CECFCC-FD28-48fd-8FBC-269AD59281BE} Timestamp when the previous DOT value was issued. previousDOTTimeStamp {B1382EAF-343E-49d2-8BFB-2C9548C745B8} The ramp rate limit for the unit in MWs per minute. Participant bidding data. rampRateLimit {E1BAF5D7-4C43-4846-9C6A-D5D148BF5E93} Spin Reserve used to procure energy. spinReserve {6BB3E8FB-4AE7-4c5e-BFCA-EA9D11BEE54E} Standard ramping energy MWH. standardRampEnergy {F9988408-3BE0-4b86-A66B-A9117F354493} Supplemental Energy procure by Real Time Dispatch. supplementalEnergy {552B8DCB-414D-4b36-A94E-09FAE594628F} Output results from the case identifying the reason the unit was committed by the software. unitStatus {84754C00-5BFA-4f3b-B1EB-644A35A8AC9F} Rating of drum boiler in steam units. drumBoilerRating {5696E189-9278-4faa-8681-EE8497E8F3F7} Number of circuits in duct bank. Refer to associations between a duct ConductorAsset and an ACLineSegment to understand which circuits are in which ducts. circuitCount {5A3C628A-5B05-46f0-9F6F-06903BD764AC} Dynamic schedule sign reversal required truefalse dynSchedSignRev {BAAD951E-ECBF-4aa7-9C88-F4D718FAB2B5} The active or inactive status of the dynamic schedule dynSchedStatus {AD2F2B96-E195-4c52-A1DD-008C6CA0663E} Function block used indicator.true use of function block is enabledfalse use of function block is disabled. enabled {CEE5F07B-8F7C-4f2b-A690-D0D7F0511216} The intensity of the earthquake as defined by the Modified Mercalli Intensity MMI scale. Possible values are 112 corresponding to IXII. intensity {550A759C-5DB8-4be8-9477-6792BF21F02F} The magnitude of the earthquake as defined on the Moment Magnitude Msubwsub scale which measures the size of earthquakes in terms of the energy released. Must be greater than zero. magnitude {D19FDDEE-5DB4-48df-8B6E-254B7510B1E8} Primary email address. email1 {DA76BEA2-70FF-49a9-8FE0-15F027685F54} Alternate email address. email2 {A93BB320-542C-411e-A25F-7175F8506C96} Address on local area network. lan {BA953C4D-C5E3-455c-9CFE-3071857ABE3C} MAC Media Access Control address. mac {75AD5365-618B-43ab-B105-C665EA975D92} Password needed to log in. password {9A958851-98D3-49d3-851E-D8A30C44B656} Radio address. radio {E8017C5C-0A76-4cf9-A9C2-77CB35B22A30} User ID needed to log in which can be for an individual person an organisation a location etc. userID {50656270-0E10-4914-9FB1-8907617F90AC} World wide web address. web {19B00DDF-F9E2-4a65-816A-12BE13228934} value {C8D2EF5E-4C31-4971-A8F8-4E180EE01040} Flag is set to true when output is expressed in net active power. isNetGrossP {BAB97F88-4F02-4068-BB50-28A0A7E67206} Automated meter reading AMR or other communication system responsible for communications to this end device. amrSystem {BF5942B2-10FF-4829-8C33-C5E109FBA558} Installation code. installCode {1367671F-A0FE-433c-B6E9-6B1CA6E65938} If true this is a premises area network PAN device. isPan {480AB23B-6622-4119-B5D0-A02C35F00C8C} isSmartInverter {76E8FF63-8F1A-4236-B7A5-43CD378113EE} If true there is no physical device. As an example a virtual meter can be defined to aggregate the consumption for two or more physical meters. Otherwise this is a physical hardware device. isVirtual {6F065A0C-6D76-4504-B9C1-5283A9DBE66F} Command text. command {44A9E4CF-C396-4026-8450-AAF899F4A721} True if the action of this control is indefinite. durationIndefinite {8F9B70BB-94C3-4385-B8C3-3C60289302C0} Start date and time for action of this control. startDateTime {C5A321BE-7FE7-4aca-8A41-175F04BE09A3} True if autonomous DST daylight saving time function is supported. autonomousDst {D0621056-7652-4d68-ACF8-25D481D8AA2A} True if communication function is supported. communication {9D60E799-5170-4611-B07D-37D2994DF2EC} True if connect and disconnect function is supported. connectDisconnect {483B73C3-A187-47fd-B3C2-9C20C84A41DB} True if demand response function is supported. demandResponse {F405AC35-8DF7-483a-A400-B1201584F6F0} True if electric metering function is supported. electricMetering {752479A9-387B-4d4c-818A-D526CA02A0E8} True if gas metering function is supported. gasMetering {A0A35A59-2C2B-42bf-9B7F-983DAA57824E} True if metrology function is supported. metrology {B585026D-DBE1-4a14-A4E3-D8112BB36AAD} True if on request read function is supported. onRequestRead {3D8EB7C8-D6EB-429a-9379-76710C454E16} True if outage history function is supported. outageHistory {9902B7C2-3D23-441f-BB6A-2221AEED6E52} True if device performs pressure compensation for metered quantities. pressureCompensation {9E1822BD-C9E5-43d5-8104-CE2022588589} True if pricing information is supported. pricingInfo {81151227-D1EB-407c-9660-96B986D50C1D} True if device produces pulse outputs. pulseOutput {73778C03-44E6-433e-ABFC-65130DE1A3B2} True if relays programming function is supported. relaysProgramming {947EBE17-818A-4f43-B7C2-E4971E97C99B} True if reverse flow function is supported. reverseFlow {5463F168-5EEC-4fc1-A707-BFF3CDB3705F} True if device performs super compressibility compensation for metered quantities. superCompressibilityCompensation {D44EC7D9-7D26-4b20-9C4D-ECDDE08BF695} True if device performs temperature compensation for metered quantities. temperatureCompensation {C3092EB3-05F6-41c8-9A18-A703A334532E} True if the displaying of text messages is supported. textMessage {FD453833-A43F-4252-8577-AFA52682E318} True if water metering function is supported. waterMetering {94C5FF37-B19A-4f3d-ABD3-7685CC67D315} Level of a demand response program request where 0emergency. Note Attribute is not defined on DemandResponseProgram as it is not its inherent property it serves to control it. drProgramLevel {361DFF6B-9249-489f-A4EC-B1CCF50D5E7E} Whether a demand response program request is mandatory. Note Attribute is not defined on DemandResponseProgram as it is not its inherent property it serves to control it. drProgramMandatory {5DAB80A8-2513-4627-BC23-91A8A3307404} Unique identifier of the business entity originating an end device control. issuerID {BD9B9B7E-8A1A-4029-AC56-42F901B96AF4} Identifier assigned by the initiator e.g. retail electric provider of an end device control action to uniquely identify the demand response event text message or other subject of the control action. Can be used when cancelling an event or text message request or to identify the originating event or text message in a consequential end device event. issuerTrackingID {B16A2CDD-7E27-4af6-825D-6C8F5A452D7F} Reason for the control action that allows to determine how to continue processing. For example disconnect meter command may require different processing by the receiving system if it has been issued for a networkrelated reason protection or for a paymentrelated reason. reason {21FFC655-460E-4328-9665-50D149C15358} Highlevel nature of the control. domain {0F5F0BE5-F400-4f90-9719-3E9F85437851} The most specific part of this control type. It is mainly in the form of a verb that gives action to the control that just occurred. eventOrAction {C95D1B0C-B29D-4165-A70A-CAFA8E888FE3} More specific nature of the control as a further subcategorisation of domain. subDomain {035EDA6F-4BFB-4beb-AC32-107DF7A0564C} Type of physical device from which the control was created. A value of zero 0 can be used when the source is unknown. type {A990244D-143A-4d58-AF5C-155EC002B101} Unique identifier of the business entity originating an end device control. issuerID {8EC275B9-0B82-45ef-A8DE-33671CAB9CA7} Identifier assigned by the initiator e.g. retail electric provider of an end device control action to uniquely identify the demand response event text message or other subject of the control action. Can be used when cancelling an event or text message request or to identify the originating event or text message in a consequential end device event. issuerTrackingID {14ECC181-8099-44bf-B053-44609BAB463D} if user initiated ID of user who initiated this end device event. userID {9F85911C-8623-4bc5-8CB8-5C58A3E54AF8} Name. name {DC69156D-AAD3-4a56-A300-E88DE10E42F4} Highlevel nature of the event. By properly classifying events by a small set of domain codes a system can more easily run reports based on the types of events that have occurred or been received. domain {253EAC1A-20A2-4f76-B1CF-B2E3AB768C64} The most specific part of this event type. It is mainly in the form of a verb that gives action to the event that just occurred. eventOrAction {50325D8B-DBA3-4df6-9378-35C2605E660A} More specific nature of the event as a further subcategorisation of domain. subDomain {DC206603-1A13-45fb-9DF3-BAC39935408F} Type of physical device from which the event was created. A value of zero 0 can be used when the source is unknown. type {D13065E2-EB45-4b24-9CB7-89FB99F5FC41} True if the function is enabled. enabled {390D762D-C7F9-4c1f-9707-0B03BA5A9C46} Type of this group. type {D0A63F4A-0346-4e67-9E5A-68C9C30CF910} If true this is a solid state end device as opposed to a mechanical or electromechanical device. isSolidState {A6ABA5DD-8711-4727-946F-C84C017BB613} Number of potential phases the end device supports typically 0 1 or 3. phaseCount {FCFAC8D1-C036-4864-9911-9E981B524FCE} True if duration is indefinite. durationIndefinite {EBE804B8-225F-489a-8A00-CEFD415DB073} Number of individual customers represented by this demand. customerCount {EEA34371-CAE6-49b7-A544-81DD3192C676} Used for Yn and Zn connections. True if the neutral is solidly grounded. grounded {56A0DAAA-8C90-4e10-B63E-47E544C63EF6} isSlack {3B16B23D-6571-45c6-BC1E-B5D5988511F4} Energy price index energyPriceIndex {3ED23352-20AF-45bf-8D79-908955BAD239} Time updated lastModified {65049BD1-5CAA-46ad-B1F4-F4BDD86C12B6} Interchange capacity flag. When the flag is set to true it indicates a transaction is capacity backed. capacityBacked {F10E101F-E3AE-4b94-AF86-AC4298D02921} Firm interchange flag indicates whether or not this energy transaction can be changed without potential financial consequences. firmInterchangeFlag {DD6E78AE-2C4F-48a6-80F2-6DA9181EAE28} Willing to Pay congestion flag payCongestion {17D8EF73-8AD9-487d-B63C-792A4005D5EB} Reason for energy transaction. reason {0970CD30-651A-40ab-994C-996C98539603} The type of the issued alert which is drawn from the specified alert type list. alertType {B61476BB-A5C4-4c7a-9687-1EFE4D54BE36} Time and date alert cancelled. Used only if alert is cancelled before it expires. cancelledDateTime {61671C52-30AE-42c2-B8AC-9BC22BD30B4B} An abbreviated textual description of the alert issued. Note the full text of the alert appears in the .description attribute inherited from IdentifiedObject. headline {1F4FA496-48C2-485c-8047-A750DD962298} The timestamp of when the forecast was created created {3888907A-F121-4e27-BA62-81FFD19899EF} Whether this station is currently reporting using daylight saving time. Intended to aid a utility Weather Service in interpreting information coming from a station and has no direct relationship to the manner in which time is expressed in EnvironmentalValueSet. dstObserved {7CEFCF49-C763-419b-BE8A-32BD900163DD} Indication that station is part of a network of stations used to monitor weather phenomena covering a large geographical area. isNetworked {7E6E7AB8-C39C-499c-92CD-275E5A3E09B6} The aggregate flag provides an alternative way of representing an aggregated equivalent element. It is applicable in cases when the dedicated classes for equivalent equipment do not have all of the attributes necessary to represent the required level of detail. In case the flag is set to true the single instance of equipment represents multiple pieces of equipment that have been modelled together as an aggregate equivalent obtained by a network reduction procedure. Examples would be power transformers or synchronous machines operating in parallel modelled as a single aggregate power transformer or aggregate synchronous machine. The attribute is not used for EquivalentBranch EquivalentShunt and EquivalentInjection. aggregate {3C000D48-C67D-4cc3-89D6-5F336420B325} Specifies the availability of the equipment. True means the equipment is available for topology processing which determines if the equipment is energized or not. False means that the equipment is treated by network applications as if it is not in the model. inService {84B66A12-0723-4edf-BC0E-5CD2F4034CC3} The equipment is enabled to participate in network analysis. If unspecified the value is assumed to be true. networkAnalysisEnabled {0B1D0D20-436A-42a0-AD04-DECFCE5CFCF3} Specifies the availability of the equipment under normal operating conditions. True means the equipment is available for topology processing which determines if the equipment is energized or not. False means that the equipment is treated by network applications as if it is not in the model. normallyInService {410CEA04-CA77-46d9-A093-019230A2DE17} Specifies whether or not the EquivalentInjection has the capability to regulate the local voltage. If true the EquivalentInjection can regulate. If false the EquivalentInjection cannot regulate. ReactiveCapabilityCurve can only be associated with EquivalentInjection if the flag is true. regulationCapability {8D94C9DC-F706-4810-96B0-1A08EE8837E4} Specifies the regulation status of the EquivalentInjection. True is regulating. False is not regulating. regulationStatus {79E03A9B-2B54-4de5-BAFE-20735F747738} Bank ABA. bankABA {B2CD78D6-65B3-4528-9B8E-2D5632E820A2} Calculated date upon which the Invoice amount is due. dueDate {8D53F7AD-8126-4a9d-BA88-01D1C21DE4D4} Date on which the customer billing statementinvoice was printedmailed. mailedDate {6731C31D-BCC0-415c-BE70-90D1132C8F6D} True if payment is to be paid by a Customer to accept a particular ErpQuote with associated Design and have work initiated at which time an associated ErpInvoice should automatically be generated. EprPayment.subjectStatus satisfies terms specificed in the ErpQuote. proForma {46430F95-9874-40ab-AF17-32BD0B096923} Number of an invoice to be reference by this invoice. referenceNumber {6382F970-EA3A-4a65-AEE8-46A16C131BDB} Date and time when the invoice is issued. transactionDateTime {54176B4E-F7F5-44df-82EB-58FFBC1BEED7} Type of invoice transfer. transferType {9409F692-8ECA-4d7f-8020-CFECCAB1C8C0} General Ledger account code must be a valid combination. glAccount {82B95CE9-1295-473d-BC59-57671A05A86F} Date and time line item will be posted to the General Ledger. glDateTime {C7BEA464-8250-48a9-B1F8-47070D26243D} Amount due for this line item. lineAmount {BFE467E3-7E55-4804-881D-64E6DA0D592F} Line item number on invoice statement. lineNumber {766920A0-DCEB-464f-873E-0411625AB8E6} Version number of the bill run. lineVersion {26DAA334-4B56-4af3-A53D-86BF6D28936A} Net line item charge amount. netAmount {5114E10D-48ED-43e2-B733-998F0D693226} Previous line item charge amount. previousAmount {3C420DC9-B031-4cbb-9D98-5E24F829A56D} Account identifier for this entry. accountID {4E2C82C7-38D9-41e6-A7D0-35B699198F03} Date and time this entry is to be posted to the ledger. postingDateTime {3311876C-79F6-4bb9-8A20-2DB7707D9D4B} The identifer of the source for this entry. sourceID {73504C54-0C17-47a9-B7BA-398BE859DDB2} Date and time journal entry was recorded. transactionDateTime {4FCB3458-4FCE-44fb-B57B-DE561EFFAA2E} Account identifier for this entry. accountID {77AC00FD-7727-4d42-A2FB-9612FF099467} Date and time this entry was posted to the ledger. postedDateTime {8012748C-8D8E-4d25-9544-20EFEFB243FF} Date and time journal entry was recorded. transactionDateTime {5259D4D8-49FF-4593-82AE-A15FB31065AA} Payment terms e.g. net 30. termsPayment {6C9E4485-78AC-4e69-A7F6-CB9CD83315CB} code {8CE8A9A5-20DE-4aba-B505-75DA469D089E} deliveryDate {A539A33F-06C0-4f01-AEC9-808F8B685FDD} Quantity of item requisitioned. quantity {A92FBA8F-90CB-46f3-B6F1-858AB8ADDDFE} estimated time the outage will be restored ert {E8CD10EA-E4A7-4741-A408-3D7D30252659} defines the source that provided the ERT value. ertSource {70933541-7619-40b4-AF9E-7C9EFE8C7362} EHV MW losses in the company Attribute Usage Information purposes Output of LPA engine. ehvLossMW {AD826022-CBD7-4a14-87EF-29F1973E973D} Total MW losses in the company Attribute Usage Information purposes Output of LPA engine. totalLossMW {E0672466-2D05-44ee-9A3E-508463002D94} exPostClearedPrice {E4CBF494-EF98-4790-9F72-F33048E11A1F} market energy price energyPrice {2FAF176F-93C5-4247-B315-F1B66D444DE1} Congestion component of Location Marginal Price LMP in monetary units per MW congestion component of the hourly LMP at a specific pricing node Attribute Usage Result of the Security Pricing and DispatchSPDSimultaneous Feasibility TestSFT software and denotes the hourly congestion component of LMP for each pricing node. congestLMP {AFBD1903-D336-437c-827F-2BD08F9A06B3} 5 min weighted average LMP the Location Marginal Price of the Pnode for which price calculation is carried out. Attribute Usage 5 min weighted average LMP to be displayed on UI lmp {BDC4DBA7-243C-42b8-9BE6-333A29FD494A} Loss component of Location Marginal Price LMP in monetary units per MW loss component of the hourly LMP at a specific pricing node Attribute Usage Result of the Security Pricing and DispatchSPDSimultaneous Feasibility TestSFT software and denotes the hourly loss component of LMP for each pricing node. lossLMP {2BE2B4DD-E47C-47a4-B979-3BB5AF3418AD} LMP component in USD deprecated congestionLMP {D028013A-DEDC-464a-A60E-40D69F0AA0A2} Desired output of unit desiredMW {DBFA9DF0-1342-485c-B818-3923EFB6A2E9} Unit Dispatch rate from real time unit dispatch. dispatchRate {84D0E387-0130-475e-BFFB-FE746462CEA0} LMP Local Marginal Price in USD at the equipment deprecated lmp {09338D77-2444-4dac-89D2-A5A85208496F} loss lmp deprecated lossLMP {9A3E5E51-4A35-46af-8BEE-844C1346EC69} Economic Maximum MW maxEconomicMW {81C7F0DF-A9DE-4699-975A-76330B319D97} Economic Minimum MW minEconomicMW {31A905CF-5127-4469-8DB2-597E958D6EFD} Current MW output of the equipment Attribute Usage Information purposes Information purposes Output of LPA engine. resourceMW {68ED1489-3FA2-4838-86E0-A562397AE2A5} Indicates if both HV gate and LV gate are active iHVLVgatesi.true gates are usedfalse gates are not used.Typical value true. hvlvgates {971A1448-AAAD-46fa-8EBF-298B11A7A9E5} Exciter saturation function value at the corresponding exciter voltage iVeiisub1subi back of commutating reactance iSeVeiisub1subiii gt 0. Typical value 01. seve1 {48C7B76B-CF2C-4e80-84DA-5E247986CB84} Exciter saturation function value at the corresponding exciter voltage iVeiisub2subi back of commutating reactance iSeVeiisub2subiii gt 0. Typical value 003. seve2 {6574DA42-482B-4b08-8FFE-D705FABC0DDF} Indicates if HV gate is active iHVgatei.true gate is usedfalse gate is not used.Typical value true. hvgate {F4BCA4B2-83CA-479e-83E1-FEDDE079349E} Indicates if LV gate is active iLVgatei.true gate is usedfalse gate is not used.Typical value true. lvgate {88575ABD-CDFA-429d-990B-90A7612C7C95} Exciter saturation function value at the corresponding exciter voltage iVeiisub1subi back of commutating reactance iSeVeiisub1subiii gt 0. Typical value 0037. seve1 {F7FA3472-2117-473a-BB79-CFB3218910FD} Exciter saturation function value at the corresponding exciter voltage iVeiisub2subi back of commutating reactance iSeVeiisub2subiii gt 0. Typical value 0012. seve2 {EE2FA498-B7B2-498a-BFE0-418C67E8A765} Exciter saturation function value at the corresponding exciter voltage iVeiisub1subi back of commutating reactance iSeVeiisub1subiii gt 0. Typical value 1143. seve1 {5CB74FC7-AF77-4b20-9074-E7F8FE157DC2} Exciter saturation function value at the corresponding exciter voltage iVeiisub2subi back of commutating reactance iSeVeiisub2subiii gt 0. Typical value 01. seve2 {ACA2A09A-1C95-43b6-B5FF-A1B323F100F8} Coefficient to allow different usage of the model iai. Typical value 1. a {245D492E-2BDB-4a07-B200-F100F94E836B} Exciter saturation function value at the corresponding exciter voltage iEfdiisub1subi iSeEfdiisub1subiii gt 0. Typical value 086. seefd1 {3B09F8F3-E5DC-4163-97AF-44BFEF672094} Exciter saturation function value at the corresponding exciter voltage iEfdiisub2subi iSeEfdiisub2subiii gt 0. Typical value 05. seefd2 {57F952A9-AF49-478e-96F6-51B6C7A73F16} Exciter saturation function value at the corresponding exciter voltage iVeiisub1subi back of commutating reactance iSeVeiisub1subiii gt 0. Typical value 0214. seve1 {8866B5A1-66BC-47d3-8F9C-178E10F15C04} Exciter saturation function value at the corresponding exciter voltage iVeiisub2subi back of commutating reactance iSeVeiisub2subiii gt 0. Typical value 0044. seve2 {0BF9F6DD-A0F8-49b3-AD30-5396A4303A8D} Input limiter indicator.true input limiter iVimaxi and iVimini is consideredfalse input limiter iVimax iand iVimini is not considered.Typical value true. inlim {845B6E20-74AB-4c4b-9D22-3C5AD3734A64} PID limiter indicator.true input limiter iVpidmaxi and iVpidmini is consideredfalse input limiter iVpidmaxi and iVpidmini is not considered.Typical value true. pidlim {AD029846-B4B3-4d47-81FA-AE0E8356FF51} Exciter saturation function value at the corresponding exciter voltage iVeiisub1subi back of commutating reactance iSeVeiisub1subiii gt 0. Typical value 03. seve1 {C0289295-1816-4510-9AA6-C9280FB932AB} Exciter saturation function value at the corresponding exciter voltage iVeiisub2subi back of commutating reactance iSeVeiisub2subiii gt 0. Typical value 3. seve2 {FFBDEE11-E9DD-49c0-A1FD-AFC00D71072A} Selector for the limiter on the block i1sTei. See diagram for meaning of true and false.Typical value false. telim {FE8039D3-B35C-44ac-844E-EE09AA5C0C36} Multiply by generators terminal voltage indicator.true the limits iVrmaxi and iVrmini are multiplied by the generators terminal voltage to represent a thyristor power stage fed from the generator terminalsfalse limits are not multiplied by generators terminal voltage. Typical value false. vtmult {C3AA0638-EA16-4a96-B9D7-BF8B1FDFC9B2} Governor control flag iBLINTi. 0 leadlag regulator1 proportional integral regulator.Typical value 0. blint {ADB7C7AB-BAB8-4939-8BCC-65373511D8A3} Exciter gain iKiisub2subi. Typical value 20. k2 {4252EB5F-C096-44e9-9410-1415D9E9A08C} AVR gain iKiisub3subi. Typical value 1000. k3 {4AA45B50-82F8-417d-99C0-6400339A1A54} Ceiling factor iKiisubCEsubi. Typical value 1. kce {3751B80B-1CE2-4675-9A09-366C211231C4} Feedback enabling iKiisubRVECCsubi. 0 open loop control1 closed loop control.Typical value 1. krvecc {5EA3BE96-E79F-4ce4-826E-B869FCFC0419} Rate feedback signal flag iKiisubVFIFsubi. 0 output voltage of the exciter1 exciter field current.Typical value 0. kvfif {C758EBEA-BE53-4256-9599-1823CFA566B7} AVR gain iKiisubAsubi. Typical value 500. ka {23A81F36-7918-4c5a-80F3-DACDBBFAA90D} Rate feedback gain iKiisubFsubi. Typical value 012. kf {A66FC96A-D837-4839-9AAC-6D2307C5361B} Saturation factor at iEiisub1subi iSEiisub1subiii. Typical value 01. se1 {A450D456-D29D-4f13-AB1D-B782A6308442} Saturation factor at iEiisub2subi iSEiisub2subiii. Typical value 003. se2 {560B7978-D976-43dd-A565-80DB7807A657} AVR gain iKiisubAsubi. Typical value 500. ka {C7E4A97A-F8EA-4888-BD2B-0678C608D911} Rate feedback gain iKiisubFsubi. Typical value 012. kf {06B712E0-FF45-456b-828C-391E11F7305E} Saturation factor at iEiisub1subi iSEiisub1subiii. Typical value 0.1. se1 {79FF18E7-66C0-471a-B91E-4749C5307CFB} Saturation factor at iEiisub2subi iSEiisub2subiii. Typical value 003. se2 {3014A25E-F6AF-41b4-8CFF-72D86F8FBE8B} AVR gain iKiisubAsubi. Typical value 100. ka {476AE42A-60AA-4542-96B5-3BAFC6417E08} Saturation factor at iEiisub1subii iiSEiisub1subiii. Typical value 01. se1 {16A35A8B-249F-4d5c-99B7-4D3B1D5A59A9} Saturation factor at iEiisub2subii iiSEiisub2subiii. Typical value 003. se2 {0E067215-432D-4be0-9606-2C80DC19B5A5} AVR output voltage dependency selector iIiisubMULsubi.true selector is connectedfalse selector is not connected.Typical value true. imul {A83D1C80-58C3-49d2-A414-0C5997E9B8D3} AVR gain iKiisubAsubi. Typical value 300. ka {5173E778-715B-4e8a-BABB-9F6F08A5FFB9} Exciter gain iKiisubEsubiii. Typical value 1. ke {7AE9490D-26A4-4579-A9B7-264B12B135AA} Exciter internal reactance iKiisubIFsubi. Typical value 0. kif {1A8FE213-DE3A-42cd-8B7B-8FD0E16B62FC} Supplementary signal routing selector iswitchi.true iVsi connected to 3rd summing pointfalse iVsi connected to 1st summing point see diagram.Typical value false. switch {9B8B51F4-9197-4d15-893F-0FC6B7D0F1B1} iexclimi. IEEE standard is ambiguous about lower limit on exciter output. true a lower limit of zero is applied to integrator outputfalse a lower limit of zero is not applied to integrator output.Typical value true. exclim {F6772296-58D3-4ad8-B03D-A4A0DB9616B3} Exciter saturation function value at the corresponding exciter voltage iEfdiisub1subi iSeEefdiisub1subiii gt 0. Typical value 033. seefd1 {BA09D802-A2C4-4154-91E0-ED8AE32BDE1F} Exciter saturation function value at the corresponding exciter voltage iEfdiisub2subi iSeEefdiisub2subiii gt 0. Typical value 01. seefd2 {561A08D3-A350-4080-B4AD-FF3876C84E90} iexclimi. IEEE standard is ambiguous about lower limit on exciter output.true a lower limit of zero is applied to integrator outputfalse a lower limit of zero is not applied to integrator output.Typical value true. exclim {74E2E48F-7952-4980-BC83-5ED53BC081F6} Exciter saturation function value at the corresponding exciter voltage iEfdiisub1subi iSeEfdiisub1subiii gt 0. Typical value 0279. seefd1 {C2018CA0-F49E-4309-BB81-B0FD0704E212} Exciter saturation function value at the corresponding exciter voltage iEfdiisub2subi iSeEfdiisub2subiii gt 0. Typical value 0117. seefd2 {F82E7AE4-4FE7-4e2e-B858-2B124C50CEA4} iVtlimi.true limiter at the block iKa 1 sTai is dependent on iVt ifalse limiter at the block is not dependent on iVti.Typical value true. vtlim {56A88055-8164-4405-909A-813E4DF99268} iEfdlimi.true exciter output limiter is activefalse exciter output limiter not active.Typical value true. efdlim {CA5C8CF6-0BA4-4ae2-89B5-EE09ED810C5E} iexclimi. IEEE standard is ambiguous about lower limit on exciter output.true a lower limit of zero is applied to integrator outputfalse a lower limit of zero not applied to integrator output.Typical value true. exclim {493D6B50-A7B6-4a34-87C8-E6EB8EF852D7} Exciter saturation function value at the corresponding exciter voltage iEfdiisub1subi iSeEfdiisub1subiii gt 0. Typical value 01. seefd1 {6FEE3EC7-DDC3-4050-A7CC-24809314D140} Exciter saturation function value at the corresponding exciter voltage iEfdiisub2subi iSeEfdiisub2subiii gt 0. Typical value 035. seefd2 {AD0ADFFE-6FE1-4f86-94A3-AE6B48BB99AE} iexclimi.true lower limit of zero is applied to integrator outputfalse lower limit of zero not applied to integrator output.Typical value true. exclim {67BACD0E-1B5D-4db5-A237-A3AD470B1062} Vb limiter indicator.true exciter iVbmaxi limiter is activefalse iVb1maxi is active. Typical value true. vblim {0643055E-27A0-4822-8B53-22E4DD461AEB} Voltage base conversion constant iKei. Typical value 4666. ke {5769BF55-A790-4a7d-83E4-9D52CF3F298E} Current base conversion constant iKii. Typical value 021428. ki {5248F81B-1D48-41df-B9CC-2A6964B0D8E8} Exciter saturation function value at the corresponding exciter voltage iViisubE1subi back of commutating reactance iSiisubEsubiiViisubE1subiii gt 0. Typical value 01. seve1 {DB8EE451-F00D-4345-91DF-76788471A867} Exciter saturation function value at the corresponding exciter voltage iViisubE2subi back of commutating reactance iSiisubEsubiiViisubE2subiii gt 0. Typical value 003. seve2 {5040884C-91CA-483b-92C1-764CCEEBFDF7} Exciter saturation function value at the corresponding exciter voltage iViisubE1subi back of commutating reactance iSiisubEsubiiViisubE1subiii gt 0. Typical value 0037. seve1 {59780752-CD47-4dc3-B4EA-1F4D2D2CD00F} Exciter saturation function value at the corresponding exciter voltage iViisubE2subi back of commutating reactance iSiisubEsubiiViisubE2subiii gt 0. Typical value 0012. seve2 {60F3E03D-A073-4b83-840B-16AAE273EFC8} Exciter saturation function value at the corresponding exciter voltage iViisubE1subi back of commutating reactance iSiisubEsubiiViisubE1subiii gt 0. Typical value 1143. seve1 {857CF7D9-4D69-403b-A1E0-899D707C3502} Exciter saturation function value at the corresponding exciter voltage iViisubE2subi back of commutating reactance iSiisubEsubiiViisubE2subiii gt 0. Typical value 01. seve2 {BAE75C79-8F63-444f-9486-863933DD29E5} Exciter saturation function value at the corresponding exciter voltage iEiisubFD1subi iSiisubEsubiiEiisubFD1subiii gt 0. Typical value 086. seefd1 {995A78B6-48C1-40eb-940A-25CC88B46269} Exciter saturation function value at the corresponding exciter voltage iEiisubFD2subi iSiisubEsubiiEiisubFD2subiii gt 0. Typical value 05. seefd2 {1DD0B8D0-600F-4aac-97F6-109B41CB13D7} Exciter saturation function value at the corresponding exciter voltage iViisubE1subi back of commutating reactance iSiisubEsubiiViisubE1subiii gt 0. Typical value 0214. seve1 {127B17E2-19AA-461a-A6F5-B1ACB71A79E6} Exciter saturation function value at the corresponding exciter voltage iViisubE2subi back of commutating reactance iSiisubEsubiiViisubE2subiii gt 0. Typical value 0044. seve2 {950BA46D-7147-421d-BBD0-24D9F2AC43BE} Exciter saturation function value at the corresponding exciter voltage iViisubE1subi back of commutating reactance iSiisubEsubiiViisubE1subiii gt 0. Typical value 044. seve1 {63F1D856-9A79-4dcb-9C02-63EAB30A0476} Exciter saturation function value at the corresponding exciter voltage iViisubE2subi back of commutating reactance iSiisubEsubiiViisubE2subiii gt 0. Typical value 0075. seve2 {90A8F4BB-CE36-45fd-9E5E-B44A9A27A86A} Exciter saturation function value at the corresponding exciter voltage iViisubE1subi back of commutating reactance iSiisubEsubiiViisubE1subiii gt 0. Typical value 03. seve1 {DBFC6806-485A-4944-9461-9327CEDD05A3} Exciter saturation function value at the corresponding exciter voltage iViisubE2subi back of commutating reactance iSiisubEsubiiViisubE2subiii gt 0. Typical value 3. seve2 {9C345CC4-84DE-4110-9D73-9BE657FD1D4F} iexclimi. IEEE standard is ambiguous about lower limit on exciter output.true a lower limit of zero is applied to integrator outputfalse a lower limit of zero is not applied to integrator output.Typical value true. exclim {A8CC72E6-B221-4df6-8512-901EC73B106A} Exciter saturation function value at the corresponding exciter voltage iEiisubFD1subi iSiisubEsubiiEiisubFD1subiii gt 0. Typical value 0.33. seefd1 {AE072325-5BB2-4520-A1C0-F4363CDCD38D} Exciter saturation function value at the corresponding exciter voltage iEiisubFD2subi iSiisubEsubiiEiisubFD2subiii gt 0. Typical value 01. seefd2 {81E0A29E-4BA0-413c-9FA3-319426FC5108} UEL input iuelini.true input is connected to the HV gatefalse input connects to the error signal.Typical value true. uelin {0AD26100-3CFD-475e-87ED-6056BB10D2AB} Exciter saturation function value at the corresponding exciter voltage iEiisubFD1subi iSiisubEsubiiEiisubFD1subiii gt 0. Typical value 0279. seefd1 {9443FE9C-EAFA-4c69-8C4B-3E99C652452A} Exciter saturation function value at the corresponding exciter voltage iEiisubFD2subi iSiisubEsubiiEiisubFD2subiii gt 0. Typical value 0117. seefd2 {DE1FE73D-137A-4921-9264-ABBC8A97BF29} UEL input iuelini.true input is connected to the HV gatefalse input connects to the error signal.Typical value true. uelin {4DD79FCA-E438-4659-81AB-6ED216F18A4F} iexclimi. IEEE standard is ambiguous about lower limit on exciter output.true a lower limit of zero is applied to integrator outputfalse a lower limit of zero is not applied to integrator output.Typical value true. exclim {EE0498C2-5761-48f8-AA0B-F9F0683C01D4} Exciter saturation function value at the corresponding exciter voltage iEiisubFD1subi iSiisubEsubiiEiisubFD1subiii gt 0. Typical value 0267. seefd1 {286AA295-1129-4000-A7C3-AAA2704AC8BD} Exciter saturation function value at the corresponding exciter voltage iEiisubFD2subi iSiisubEsubiiEiisubFD2subiii gt 0. Typical value 0068. seefd2 {90CD7D02-3C97-4c68-A207-2760D27A71F9} OEL input iOELini.true LV gatefalse subtract from error signal.Typical value true. oelin {46880FA6-779F-4a87-8C9D-5C7C4A815C57} Exciter saturation function value at the corresponding exciter voltage iEiisubFD1subi iSiisubEsubiiEiisubFD1subiii gt 0. Typical value 008. seefd1 {F0F5A5BC-EB93-40cf-B4CB-4DE77B1150CD} Exciter saturation function value at the corresponding exciter voltage iEiisubFD2subi iSiisubEsubiiEiisubFD2subiii gt 0. Typical value 027. seefd2 {F35D1879-5442-4788-A966-A36335426B77} UEL input iUELini.true HV gatefalse add to error signal.Typical value true. uelin {DC53D240-059A-40ef-9337-8FF898F1B149} Selector of the Power System Stabilizer PSS input iPSSini.true PSS input iVsi added to error signalfalse PSS input iVsi added to voltage regulator output.Typical value true. pssin {1333FCED-55F2-41e7-A961-E87D72843546} UEL input iUELini.true HV gatefalse add to error signal.Typical value true. uelin {51994929-6954-4bf6-85C1-E955187B5E15} Fed by selector iBusFedSelectori. true bus fed switch is closedfalse solid fed switch is open.Typical value true. busFedSelector {E92EC7AE-D456-4ac3-9CC9-CCC8F5EA7206} Voltage reference input gain iKi0i. Typical value 127. ki0 {B493D123-40C6-4d54-BB37-324D37E7B58B} Voltage input gain iKi1i. Typical value 168. ki1 {CF8C5BF0-C0EC-4814-98A4-5F62A3959B5E} OEL input gain iKLIRi. Typical value 1213. klir {3B7C47BD-BD93-4e54-849D-F3830B065933} Limiter gain iKLUSi. Typical value 50. klus {AAB000CA-5586-42ea-B9B3-99DA20A8A415} Power source switch iCswitchi.true fixed voltage of 1.0 PUfalse generator terminal voltage. cswitch {C074CB80-072C-4e94-8549-61A422EBE381} Ratio of field discharge resistance to field winding resistance irc rfdi. Typical value 0. rcrfd {E9A327DF-C4C7-4b09-B83B-EB1B93D47B0F} Gain reduction ratio of laglead element iTai iTbi. The parameter iTai is not defined explicitly. Typical value 0.1. tatb {AEFE1FBC-C9AE-4337-AF1D-0781DF8EE7DC} Gain reduction ratio of laglead element iTa Tbi. Typical value 01. tatb {4AE50BB0-88B8-4bdf-BE88-73A4B6115B9F} Secondary voltage control state iQconoffi.true secondary voltage control is onfalse secondary voltage control is off.Typical value false. qconoff {FF19F789-1DF6-45e7-8865-1B0014A41D0F} Selector to apply automatic calculation in secondary controller model iremotei.true automatic calculation is activatedfalse manual set is active the use of desired value of reactive power iQzi is required.Typical value true. remote {7C164CD6-B160-4ec5-8EA4-34D336810E57} UEL input iUELini.true HV gatefalse add to error signal.Typical value false. uelin {D4130127-D1FA-4c62-963B-70591D41EDD9} Selector iLVGatei.true iLVGatei is part of the block diagramfalse iLVGatei is not part of the block diagram. Typical value false. lvgate {9BBCC5A0-EBCB-4bd2-9C87-4B2685723C6B} Selector iUELi.true iUELi is part of block diagramfalse iUELi is not part of block diagram. Typical value false. uel {68A6C837-3C9A-4693-94A1-516F54D3C8F8} Selector iK1i.true feedback is from iIfdifalse feedback is not from iIfdi.Typical value true. k1 {CACE10C1-DF79-4632-87D5-7C61DD6EA942} Selector iVilimi.true iViminiiVimaxi limiter is activefalse iViminiiVimaxi limiter is not active.Typical value true. vilim {A4DEC66C-1034-467d-B0C7-B1884D6D9CE1} Selector ivmulti.true multiply regulator output by terminal voltagefalse do not multiply regulator output by terminal voltage. Typical value true. vmult {1C4E0B4F-40A8-4a21-A44A-1F7945DE6EB7} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {86F95A3E-DDC1-4785-B0E4-926F616635BD} intervalStartTime {4BF0246B-5735-4a23-998F-E56F8D907327} updateTimeStamp {13007307-4778-4028-BE29-8050780E6B64} updateUser {56736E2C-5D60-4d27-B52E-8B1FBE4E14D6} energyTypeCode {5B44E17B-9EB8-44e9-A30C-6C99649DD2DC} expectedMwh {FEAF95C4-FFE7-4026-9A71-939329F66292} extName {2424595E-296B-4c62-991F-9F00CF7E6B50} extType {8D63A655-FF51-4598-8DD0-B744700BB701} extValue {9E51695E-B885-4386-A558-626EC7909BB3} Indicates whether initial symmetrical shortcircuit current and power have been calculated according to IEC Ik. Used only if short circuit calculations are done according to superposition method. ikSecond {8CE33CA0-BF90-4ffb-8094-3E13248C294D} Maximum ratio of zero sequence resistance of Network Feeder to its zero sequence reactance R0X0 max. Used for short circuit data exchange according to IEC 60909. maxR0ToX0Ratio {DEEA4970-8179-4c0c-835B-448F523182C6} Maximum ratio of positive sequence resistance of Network Feeder to its positive sequence reactance R1X1 max. Used for short circuit data exchange according to IEC 60909. maxR1ToX1Ratio {38290CCA-41EE-43e1-A7C4-FC39CFB33C7C} Maximum ratio of zero sequence impedance to its positive sequence impedance Z0Z1 max. Used for short circuit data exchange according to IEC 60909. maxZ0ToZ1Ratio {FC3C5788-3C3E-41a9-B90F-01C842E72DEE} Indicates whether initial symmetrical shortcircuit current and power have been calculated according to IEC Ik. Used for short circuit data exchange according to IEC 6090. minR0ToX0Ratio {BCD7177E-8D88-4797-949C-3068CE234417} Minimum ratio of positive sequence resistance of Network Feeder to its positive sequence reactance R1X1 min. Used for short circuit data exchange according to IEC 60909. minR1ToX1Ratio {A2644704-DF87-4b44-8C4D-F4D202095BB0} Minimum ratio of zero sequence impedance to its positive sequence impedance Z0Z1 min. Used for short circuit data exchange according to IEC 60909. minZ0ToZ1Ratio {224FEA10-D384-4c38-87D8-5B84DA49BD3F} Priority of unit for use as powerflow voltage phase angle reference bus selection. 0 don t care default 1 highest priority. 2 is less than 1 and so on. referencePriority {FFD18DCF-6376-4723-B60B-AC8A81B4F137} Buy Sell action {9BD3A6B7-999D-4ab7-995D-6EFA5D957B0C} Peak Offpeak 24hour class {3CEB668B-EB29-4356-BA7E-AE996421A421} Type of rights being offered product allowed to be auctioned option obligation. ftrType {716C38B8-9A57-4a96-BB17-514ACB08D40A} Fixed covers reconfiguration grandfathering or Optimized up for salepurchase optimized {FA4480C9-2B55-47f0-9F12-FC173A0FD439} Kind of this facility. kind {FF15BEF0-DD46-40e7-A1E3-C4045F50C87A} Code for asset failure. corporateCode {BC0A1588-289A-48d2-8DC3-1ECA185AF1C9} Time and date of asset failure. failureDateTime {05ED4F1E-5A60-45f5-924A-40000EF40685} The method used for locating the faulted part of the asset. For example cable options include Cap DischargeThumping Bridge Method Visual Inspection Other. faultLocatingMethod {544149E0-9B4A-4baf-8374-8E6A6A08A2BE} Failure location on an object. location {5B5B0023-5670-4f17-89BF-BB3C4161A05B} Root cause of asset failure. rootCause {664D7023-3674-4b41-AB44-9CA0A37A0592} The date and time at which the fault occurred. occurredDateTime {A564D5B3-A502-4507-A8B7-8134E17FDA4E} The date and time at which the dispatch status occurred. occurredDateTime {38688B4D-E353-4dad-9FF7-7543D70D491F} freeform comments related to the dispatch to perform field work. remarks {35E22BA8-BF26-4fba-9CBE-395DB4BFB660} The sequence number of the field dispatch step within the field dispatch history. Begins with 1 and increments up. sequenceNumber {C88B525A-CB47-4781-8FF9-C1F15B82F353} The account to which this actual material item is charged. account {5E65F3EF-B411-4420-9BF2-7CA3553D2A28} Description of the cost. costDescription {DAFA0F90-F985-4d9d-9F37-5388AC176999} Type of cost to which this Material Item belongs. costType {57680149-B42B-4c6a-8B78-D88A6FD1842D} Date and time assets financial value was put in plant for regulatory accounting purposes e.g. for rate base calculations. This is sometime referred to as the inservice date. plantTransferDateTime {98C87236-3163-4be6-A3D1-8C04C10343E0} Date and time asset was purchased. purchaseDateTime {7BC01C58-833F-457f-8340-877E574D71DF} Purchase order identifier. purchaseOrderNumber {F6E01293-2490-46cb-AC01-4A687C9115F2} Date and time at which the financial value was last established. valueDateTime {9B3F8DAC-2349-455a-ADE8-D2D7D451C356} Date and time warranty on asset expires. warrantyEndDateTime {3BF06345-071E-4850-A331-E589FA670BDF} intervalStartTime {360A3631-84DB-495f-ABCD-3B521D40BB53} updateTimeStamp {3B07678A-2E49-40b4-92DF-FA6FE6C0B07A} updateUser {BC79ADAA-69D4-41ed-9371-100CA07F2ED4} Value of this quantity. value {5E8E552B-F83E-4980-805D-4D158E4E97CA} The coded identification of the direction of energy flow. direction {F3B42A18-C9A0-4e82-9363-68D5FBEFA898} DateTime when record becomes effective Used to determine when a record becomes effective. effectiveDate {672DB5BF-19A6-4de7-AB36-754894803108} Energy Flow level that should be maintained according to the TLR rules as specified by the IDC. For Realtime Markets use in dispatch to control constraints under TLR and calculate unconstrained market flows idcTargetMktFlow {684CE646-566D-433c-B71A-8AF2713EDFC8} DateTime when record is no longer effective Used to determine when a record is no longer effective terminateDate {1C6D40BE-BF3F-4c23-A7DC-EF5815300B96} Limit for Economic Dispatch priority 6 energy flow on the specified flowgate for the specified time period. economicDispatchLimit {8579296C-5600-4731-BF1D-10BA1FD50096} DateTime when record becomes effective Used to determine when a record becomes effective effectiveDate {D30DAB67-7DBD-4a7c-BA37-9FE57DB2A1C2} Limit for firm flow on the specified flowgate for the specified time period. The amount of energy flow over a specifed flowgate due to generation in the market which can be classified as Firm Network priority. firmNetworkLimit {066A7B63-FEE8-4ec0-A39E-CFFCC5FA1B85} The amount of energy flow over a specifed flowgate due to generation in the market. mktFlow {CBF555DE-AD61-49e4-A3EC-D24CFAFEF509} Net Energy flow in flowgate for the associated FlowgatePartner netFirmNetworkLimit {DE1F7658-1D49-4f7d-BB15-E5E9A87C4D55} Time to cross the forbidden region in minutes. crossTime {37663C0E-0AC7-4b37-A26A-EB6CD191F457} Cost associated with crossing the forbidden region crossingCost {3BF0D02C-CE07-4bb9-9AFA-8F1664D740A4} High end of the region definition highMW {2B24B12B-69CB-4120-ABE4-C0B0CFE55542} Low end of the region definition. lowMW {9372EFA9-7C28-4e74-86EE-5146FCA6E049} The amount of heat per weight or volume of the given type of fuel. fuelHeatContent {015BCC20-6735-4f96-98F8-3F76D09FF7EE} Active power error bias ratio. controlErrorBiasP {2465489F-93F1-4e03-B147-7AEB3BCB4C3D} Integral constant. controlIC {F6ECDB33-EC5C-4331-8CAF-CB4FA1E0DDC2} Proportional constant. controlPC {3E31C8E3-D0E1-4470-AC21-AECEFAA587D3} Pressure error bias ratio. controlPEB {877704D3-C236-44cd-838B-340F3046F472} Time constant. controlTC {C8CEC5DB-3D44-432a-88D8-6DBE23594E7B} Feedwater integral gain ratio. feedWaterIG {D367B901-4670-482b-8B8E-7B4F6C967BD8} Feedwater proportional gain ratio. feedWaterPG {EF2F8E46-83D2-42da-AB4D-2A1CAC5E0ECC} Active power maximum error rate limit. maxErrorRateP {123B3594-1A16-4554-B4AE-4ACCAA5D07BC} Active power minimum error rate limit. minErrorRateP {8E5CE183-191F-492f-86B4-BF8640C2CFBB} Pressure control derivative gain ratio. pressureCtrlDG {D6F0B17C-8414-4eed-8EDE-E5DA08EDCC11} Pressure control integral gain ratio. pressureCtrlIG {4CAC03F1-364F-402f-8A36-2E683685E7BF} Pressure control proportional gain ratio. pressureCtrlPG {5ACE586A-890A-4fb8-AB1A-388B934C263B} Pressure feedback indicator. pressureFeedback {1097FA75-EB4A-400a-8C63-0B94B18D1159} Drumprimary superheater capacity. superHeater1Capacity {1E936ADE-3C2D-4635-8005-685C2CEDBD46} Secondary superheater capacity. superHeater2Capacity {9D1898CD-0EEC-4747-A935-FF6D01F6C12D} Superheater pipe pressure drop constant. superHeaterPipePD {56E7A7FA-CEF9-411e-849C-84119FE62329} value {1CC12D60-90B2-4e21-BD77-F209F6F728FF} The end time and date of the fuel allocation schedule. fuelAllocationEndDate {9FC1D7F8-69D8-4f17-995B-B54C93AA1350} The start time and date of the fuel allocation schedule. fuelAllocationStartDate {B12E17BB-85DD-4456-A819-3EEC89BDAB05} The maximum amount of fuel that is allocated for consumption for the scheduled time period. maxFuelAllocation {0EC3CD8C-365E-4192-9BDA-152C02D056CC} The minimum amount of fuel that is allocated for consumption for the scheduled time period e.g. based on a takeorpay contract. minFuelAllocation {EE916503-410E-4bb2-9251-20DE555D98DC} The type of fuel region fuelRegionType {AF55DD4A-C4F6-4585-8D74-7E732C876C78} Time of last update lastModified {2ACCB12D-341D-4aac-A4C6-6957D1D561CA} The average natural gas price at a defined fuel region. gasPriceIndex {8A1ED58F-C713-486a-82E5-F90AADF15C02} If true use the absolute value for compare.. absoluteValue {FCD69B93-BD2B-42c1-8FFC-14CAA4F0FDBD} Invertnegate the result of the compare. negate {57662A74-7AB0-464d-9C1C-4E735E89E55B} The threshold value that should be used for compare with the input value. thresholdValue {59CA253A-1EE5-4192-A27F-388F80703FA9} Used to calculate generation participation of an individual pnond in an AggregatePnode. factor {2FC84093-36C6-4bcf-A247-E0C98E852B19} Flag is set to true when output is expressed in net active power. isNetGrossP {8EFD6391-C73C-45f1-A334-721A9B751FC3} Amount of load in the control zone Attribute Usage hourly load value for the specific area totalLoad {E2E858F3-E1B6-461c-8ADA-0CF28847876E} Amount of interchange for the control zone Attribute Usage hourly interchange value for the specific area totalNetInterchange {60E7974B-B192-463e-8055-5A325884D009} Will indicate if the unit is part of a CC offer or not combinedCycleUnitOffer {57ACBC9F-9C37-4ce6-B886-4E59E342D585} Maximum down time. downTimeMax {0859DD24-BADD-4189-BA08-4C0D925E8866} Installed Capacity value installedCapacity {C9A06448-BE92-4f1c-83EB-18CE43655B2E} Maximum high economic MW limit that should not exceed the maximum operating MW limit maximumEconomicMW {D938C2FF-5DCE-43ba-9524-0C8FA9EE818F} Low economic MW limit that shall be greater than or equal to the minimum operating MW limit minimumEconomicMW {E6EFC602-CD7E-4dbe-9903-0F4491A89B7F} Resource fixed no load cost. noLoadCost {41F39618-2E9C-45ab-A74F-6ACB2E00150E} Time required for crew notification prior to start up of the unit. notificationTime {FE1017DB-8365-4465-BB5A-986B2A3B2F6F} Bid operating mode C cycling F fixed M must run U unavailable operatingMode {AEEC8F5C-4664-433f-A6DD-591863E95FB0} Ramp curve type0 Fixed ramp rate independent of rate function unit MW output1 Static ramp rates as a function of unit MW output only 2 Dynamic ramp rates as a function of unit MW output and ramping time rampCurveType {BA84B0DF-C164-4878-B947-16C593E9A7A1} Resource startup type1 Fixed startup time and fixed startup cost2 Startup time as a function of down time and fixed startup cost3 Startup cost as a function of down time startUpType {D041FD53-9267-494a-A6BF-0DD69AE770B2} Startup costprice startupCost {85767EF9-0AD6-436a-A1D0-2F5B5D1E4692} Maximum up time. upTimeMax {1A7DE6C7-EDC8-46cb-BED4-7AB384081DC2} Generating unit long term economic participation factor. longPF {814E1820-70AE-4773-8776-0D3AA9728977} Generating unit economic participation factor. The sum of the participation factors across generating units does not have to sum to one. It is used for representing distributed slack participation factor. The attribute shall be a positive value or zero. normalPF {5C5B950D-8DCC-4ec0-A054-5B1A1F99B724} Defined as 1 1 Incremental Transmission Loss with the Incremental Transmission Loss expressed as a plus or minus value. The typical range of penalty factors is 0.9 to 1.1. penaltyFactor {75B099B9-2375-42c3-AD10-F54FBBCAA4FA} Generating unit short term economic participation factor. shortPF {EFD06B26-999F-492d-B482-C8EE20F3AF6E} Generating unit economic participation factor. tieLinePF {B0D4B4E5-5975-493b-9401-7F13F1D6A824} Loss Factor lossFactor {1EC86402-55A6-46c9-9D2E-BF650BAC5019} Unit reactive power generation in MVAR mVAR {FA1C8DF2-7CCB-4828-98CA-BA3935B261DD} The maximum active power generation of the unit in MW maximumMW {CC2F56E7-B1E0-4754-99CF-CA5B7F0F85D3} The minimum active power generation of the unit in MW minimumMW {9359A3E7-53B8-4e04-B0EC-985E08960789} Unit active power generation in MW mw {2226A9AA-18B1-4f2b-AD72-8C70A25ED01A} Unit sencivity factor. The distribution factors DFAX for the unit sensitivity {119B4D4D-96AE-4539-AD6A-B559878BAA9E} Interval End Time intervalEndTime {7A90559E-067F-41d5-9470-0558AF10403D} Interval Start Time intervalStartTime {6CCC99B1-BE6B-4c55-9E78-F4985231F26F} Maximum Limit MW maxLimit {C661D952-3810-4239-9DD3-AF9290D014C2} Minimum Limit MW minLimit {2A7DE582-F470-4056-AADC-210EAF5A0D82} The universal CIM version name describing a consistent set of packages. majorVersion {C95DF1AC-45B6-4749-BB5F-0780762CB7FE} Describe minor updates and error corrections. minorVersion {FFFB2C42-020B-4561-81D8-93A831D4AC7F} The date when the complete CIM canonical model is published and made available for use After the publication the major version and name space are updated. published {D1602C8A-0004-4edc-A797-1A4F32BF4905} Acceleration limiter setpoint iAseti. Unit PU s. Typical value 001. aset {257C6F96-A6F6-4c69-BC2C-2419DCACE098} Minimum valve closing rate iRclosei. Unit PU s. Typical value 01. rclose {0A646A3E-1697-4f53-B21C-131243FEDA8C} Maximum valve opening rate iRopeni. Unit PU s. Typical value 0.10. ropen {6DC5228C-7937-4a96-8B05-BB465F1E0FC1} Switch for fuel source characteristic to recognize that fuel flow for a given fuel valve stroke can be proportional to engine speed iWfspdi.true fuel flow proportional to speed for some gas turbines and diesel engines with positive displacement fuel injectorsfalse fuel control system keeps fuel flow independent of engine speed.Typical value true. wfspd {7E83B056-E060-4256-B604-86D1AD1A5671} Acceleration limiter setpoint iAseti. Unit PU s. Typical value 10. aset {0291153F-DCB6-4fc1-A0AD-45B0F5B5FB2B} Minimum valve closing rate iRclosei. Unit PU s. Typical value 99. rclose {A1C2BDBB-7631-4069-851F-B95E834D0F46} Maximum valve opening rate iRopeni. Unit PU s. Typical value 99. ropen {7FD30DB6-2FDD-42b7-B62F-009C719D3FD6} Switch for fuel source characteristic to recognize that fuel flow for a given fuel valve stroke can be proportional to engine speed iWfspdi.true fuel flow proportional to speed for some gas turbines and diesel engines with positive displacement fuel injectorsfalse fuel control system keeps fuel flow independent of engine speed.Typical value false. wfspd {A09DFA99-5733-4aa0-8CF8-393EEF97F285} Turbine power time constant numerator scale factor iai. Typical value 08. a {4B713CC1-D1B2-4a2e-99CA-747ABD7FC3E9} Turbine power time constant denominator scale factor ibi gt0. Typical value 1. b {EF7FF898-4236-4cec-B099-944E149DC713} Maximum long term fuel valve opening rate iLtratei. Typical value 002. ltrate {63E96E0F-CB6D-4751-8A0B-E8FA22DE56E8} Maximum fuel valve opening rate iRmaxi. Unit PU s. Typical value 1. rmax {1B70A83E-B1A6-4655-B605-56C76F224921} Valve positioner iAi. a {DBC6215C-807D-4448-960E-AB70C2E9DE6F} Valve positioner iBi. b {54D6EFA9-E20A-47e3-A9D1-7ACBB2C87C94} Valve positioner iCi. c {88EFB7C5-48FC-4404-8AAA-6502D736DFEE} Governor mode iZi.1 droop0 isochronous. z {F7F03573-6CBF-4934-AC1C-54DA8CE00587} Acceleration limit setpoint iBcai. Unit 1s. Typical value 001. bca {B3E6B32D-9443-4f94-B541-CAE1EA41296A} Fuel system feedback iKiisubACsubi. Typical value 0. kac {24F8C5F9-6D46-4f68-B52F-7FC4C5B92D06} Acceleration control integral gain iKcai. Unit 1s. Typical value 100. kca {2B4CB294-3052-43eb-A8BB-025B2114C42A} Gain of radiation shield iKsii. Typical value 08. ksi {F3A38C97-B132-4192-A8EA-35C7B1D717EC} Coefficient of transfer function of fuel valve positioner iKyi. Typical value 1. ky {8E14F5CB-7D84-4b69-B4F0-4A4B250EC553} Valve positioner iAi. a {E9B2E67F-148B-45f5-A20F-290EAC2978B6} Valve positioner iBi. b {E1B8747C-D70F-4508-8F4B-E1DF1E2C7281} Valve positioner iCi. c {96C07468-DA80-4933-A3E9-A775511108A5} Maximum gate velocity iVlemi gt 0. Typical value 02. velm {DE782CB5-7653-4c66-A929-C9019477CF51} Maximum gate closing velocity iUci lt 0. Unit PU s. Typical value 01. uc {C616225F-12E9-47d2-B938-09291EB15658} Maximum gate opening velocity iUoi. Unit PU s. Typical value 01. uo {B16FFD3B-ED67-4351-A07F-1EAD0985F168} Governor control flag iCflagi.true PID control is activefalse double derivative control is active.Typical value true. governorControl {23B04075-EE03-4759-AC44-A5B6F96E177A} Maximum gate closing velocity iVelcli. Unit PU s. Typical value 02. velcl {EDB42260-2AFB-498f-B0D9-2FD449839F3D} Maximum gate opening velocity iVelopi. Unit PU s. Typical value 02. velop {5542A86A-E2FE-410e-B01A-CE4805A7EAD8} Maximum blade adjustment factor iBmaxi 0 for simple 0 for FrancisPelton. Typical value for Kaplan 11276. bmax {BE809A7F-1B77-40be-B908-230D1288AD6E} Max gate closing velocity iUci. Typical value 02. uc {2F511A10-938D-4c28-BD41-6A175D8D353C} Max gate opening velocity iUoi. Typical value 02. uo {ED6AEE7C-0928-4df9-86D1-0BBB70F8EBE1} Input signal switch iFlagi. true iPei input is usedfalse feedback is received from iCVi.iFlagi is normally dependent on iTti. If iTti is zero iFlagi is set to false. If iTti is not zero iFlagi is set to true. Typical value true. inputSignal {84EF753B-18AE-4768-B2F2-944C15ACF1D4} Maximum gate closing velocity iVelcli. Unit PU s. Typical value 014. velcl {8DC31A74-2994-4696-8C23-85607752AF54} Maximum gate opening velocity iVelopi. Unit PU s. Typical value 009. velop {A251DF5C-DB9A-47e5-8224-DFFB430A4ACF} Maximum gate opening velocity iVai. Unit PU s. Typical value 006. va {8E8B42A3-F36E-4033-BCD0-25FD73EA7E4D} Maximum gate closing velocity iVci. Unit PU s. Typical value 006. vc {C6F820A3-5A3B-4b57-9F16-6D270EFD9075} Water tunnel and surge chamber simulation iTflagi.true enable of water tunnel and surge chamber simulationfalse inhibit of water tunnel and surge chamber simulation.Typical value false. waterTunnelSurgeChamberSimulation {6AD46094-5EBE-414c-96BC-971D89B26E73} Maximum gate closing velocity iUci lt0. Typical value 01. uc {26862ED2-6564-4d4c-8794-672739DE0392} Maximum gate opening velocity iUoi. Unit PU s. Typical value 01. uo {70A05529-828D-4681-9705-8AFC36908C9F} Input signal switch iFlagi. true iPei input is usedfalse feedback is received from iCVi.iFlagi is normally dependent on iTti. If iTt iis zero iFlagi is set to false. If iTti is not zero iFlagi is set to true. Typical value true. inputSignal {5AE17F32-8F81-4822-BBDC-5F45412566B7} Maximum gate closing velocity iVelcli. Unit PU s. Typical value 014. velcl {9D53A441-55A1-4806-A44B-A839A5721E2F} Maximum gate opening velocity iVelopi. Unit PU s. Typical value 009. velop {EE997207-A1BD-4914-BDBA-8F95023051C6} Feedback signal type flag iFlagi.true use gate position feedback signalfalse use Pe. feedbackSignal {41E39C0C-EEB8-4203-B7C2-40BC9A8CD8F4} Reset gain iKii. Unit PUs. Typical value 0. ki {F22CA9F8-7D61-4bee-BC68-D3835435D1B9} Maximum gate opening velocity iVelmaxi lt GovHydroPID2.velmin. Unit PU s. Typical value 0. velmax {D95288EB-2146-4052-A86E-8160C4F701EB} Maximum gate closing velocity iVelmini gt GovHydroPID2.velmax. Unit PU s. Typical value 0. velmin {1284640F-7608-447b-BA32-5E66033AA822} Simplified Pelton model simulation iSflagi.true enable of simplified Pelton model simulationfalse enable of complete Pelton model simulation nonlinear gain.Typical value true. simplifiedPelton {B7D78B57-709E-4b07-8398-E2AE570EC996} Static compensating characteristic iCflagi. It should be true if simplifiedPelton false.true enable of static compensating characteristic false inhibit of static compensating characteristic.Typical value false. staticCompensating {B8704167-B5F7-4c5f-8499-3BDC556EDC93} Maximum gate opening velocity iVai. Unit PU s. Typical value 006. va {78BE03AB-2862-4f50-8D74-6CF9B251D4D1} Maximum gate closing velocity iVci. Unit PU s. Typical value 006. vc {47822E94-14FA-4526-8188-230BFC165A5B} Water tunnel and surge chamber simulation iTflagi.true enable of water tunnel and surge chamber simulationfalse inhibit of water tunnel and surge chamber simulation.Typical value false. waterTunnelSurgeChamberSimulation {AF5B673E-82D7-4268-9087-6909A72307A0} Input signal switch iFlagi.true iPei input is usedfalse feedback is received from iCVi.iFlagi is normally dependent on iTti. If iTt iis zero iFlagi is set to false. If iTti is not zero iFlagi is set to true. Typical value true. inputSignal {F4312C37-EAFA-45e0-9D3E-8F64425214E9} Maximum gate closing velocity iVelcli. Unit PU s. Typical value 02. velcl {F59B8D7E-0EA9-488d-9F26-AE1D97AD5BC4} Maximum gate opening velocity iVelopi. Unit PU s. Typical value 02. velop {DF4D6038-DE4A-403e-B7AC-70E46154F9B3} Feedback signal selection iSwi.true PID output if iRPermGate i droop and iRPermPe i 0false electrical power if iRPermGate i 0 and iRPermPe i droop orfalse gate position if RiPermGate i droop and iRPermPe i 0.Typical value false. feedbackSignal {45D2E866-1186-4fb8-BF62-1585CD9BC0D4} Permanent droop for governor output feedback iRPermGatei. rpg {11CBC264-5B9B-4599-A392-A773EEAF7D4A} Permanent droop for electrical power feedback iRPermPei. rpp {C0DD6E76-9A4E-457e-9706-E99B8A5082C5} Fraction of HP shaft power after first boiler pass iK1i. Typical value 02. k1 {7ED4BFDC-8F10-4e4f-A768-CCA8E3753436} Fraction of LP shaft power after first boiler pass iK2i. Typical value 0. k2 {9DF83AD1-E200-4aa8-BF02-AD1EAAAC6236} Fraction of HP shaft power after second boiler pass iK3i. Typical value 03. k3 {A1E70CF0-8353-4c85-A3D4-F82DE2F12277} Fraction of LP shaft power after second boiler pass iK4i. Typical value 0. k4 {38A9D6DC-7C4D-4ffe-A311-2C65038B5B01} Fraction of HP shaft power after third boiler pass iK5i. Typical value 05. k5 {95468D3F-CBC7-42cc-B868-BEF15C392002} Fraction of LP shaft power after third boiler pass iK6i. Typical value 0. k6 {B523EDAD-56A3-40ce-88CF-C45ECF58D405} Fraction of HP shaft power after fourth boiler pass iK7i. Typical value 0. k7 {FB5B049C-0DFA-4109-943F-4976AF2064B4} Fraction of LP shaft power after fourth boiler pass iK8i. Typical value 0. k8 {BFA4E602-372D-4e58-BE79-9B13A674339D} Intentional deadband indicator.true intentional deadband is appliedfalse intentional deadband is not applied.Typical value true. sdb1 {A7B34ECC-72F8-4ccb-9B16-253E5760D64D} Unintentional deadband location.true intentional deadband is applied before point Afalse intentional deadband is applied after point A.Typical value true. sdb2 {550A9C48-19D3-4d38-9DEA-57E5558C9F38} Maximum valve closing velocity iUci lt 0. Unit PU s. Typical value 10. uc {7BB46CBF-5834-469b-B5E8-BB03F6779E8E} Maximum valve opening velocity iUoi gt 0. Unit PU s. Typical value 1. uo {2C8ABBF9-1054-4638-959B-C3EA5576430A} Nonlinear valve characteristic.true nonlinear valve characteristic is usedfalse nonlinear valve characteristic is not used.Typical value true. valve {D01C182E-8057-4b88-ACA9-1635208668DB} Governor gain reciprocal of droop iKi. Typical value 20. k {C03A97C6-5301-4113-A23F-65754161A639} Electric power input selection Peflag. true electric power inputfalse feedback signal.Typical value false. peflag {EB307DE6-D498-45e4-A85A-7246C3BA0938} Control valves rate closing limit iChci. Unit PU s. Typical value 33. chc {DEF590D4-75E3-45dc-869C-9D534C324C59} Control valves rate opening limit iChoi. Unit PU s. Typical value 017. cho {2F6B20C0-095F-44ab-B486-E8EA79C896FB} Maximum valve closing velocity iUci. Unit PU s. Typical value 1. uc {8A7D8783-C393-4b18-9C08-CD70CE5B7225} Maximum valve opening velocity iUoi. Unit PU s. Typical value 01. uo {62FFF2FC-E43F-4c08-9042-3A63B4EF0636} Maximum regulator gate closing velocity iSvmni. Typical value 00333. svmn {931BE282-21CA-40ec-8FA4-6AE8ACF31304} Maximum regulator gate opening velocity iSvmxi. Typical value 00333. svmx {86D59C44-E403-42c7-B871-3F5DA29ED25C} Fraction of HP shaft power after first boiler pass iK1i. Typical value 02. k1 {A060B705-473C-4759-8722-F969343AE905} Fraction of LP shaft power after first boiler pass iK2i. Typical value 0. k2 {B0B3C600-89FE-49dd-8BE5-0329DB19BED2} Fraction of HP shaft power after second boiler pass iK3i. Typical value 03. k3 {C1E03DCC-834D-48ff-BF02-C4A6BD824048} Fraction of LP shaft power after second boiler pass iK4i. Typical value 0. k4 {A8101D28-E0EF-46ae-98F5-8971B0A67A9F} Fraction of HP shaft power after third boiler pass iK5i. Typical value 05. k5 {9C327305-9C97-4c50-8F82-4588422553FF} Fraction of LP shaft power after third boiler pass iK6i. Typical value 0. k6 {685AB351-306B-47f2-A371-2600CB4EB8EC} Fraction of HP shaft power after fourth boiler pass iK7i. Typical value 0. k7 {8CD0911F-2504-4fd2-8D74-ABC801E1D654} Fraction of LP shaft power after fourth boiler pass iK8i. Typical value 0. k8 {6B1B64DE-7290-41e6-9585-F82E0BF93C3E} Maximum valve closing velocity iUci lt 0. Unit PU s. Typical value 10. uc {84320485-7039-4a2a-BCCC-AEC25896CF5B} Maximum valve opening velocity iUoi gt 0. Unit PU s. Typical value 1. uo {9FE36435-360D-4cee-9774-BBBBAC457B3C} input {45EF945B-44C7-46e7-8EE1-8A6EB2EF4198} output {4FA08DCF-D7DC-4d76-9F7E-6D3373F63AEB} sequence {9C227FE9-4D64-4872-A897-33D950B968D7} Type of this hazard. type {D614E68B-37A0-4459-8A19-317F9727F63F} Flag is set to true when output is expressed in net active power. isNetGrossP {8BCB6AC1-048F-4c69-ACBE-DA212B529872} value {850F6606-EA94-47e5-8B66-D1FF8A0A4EFA} Flag is set to true when output is expressed in net active power. isNetGrossP {27662118-95E1-44c3-93E7-76E793CB3DD7} The steam supply rating in kilopounds per hour if dual pressure boiler. steamSupplyRating2 {18166755-4BEE-4852-AC00-FB70A422C8F6} The control areas frequency bias factor in MW0.1 Hz for automatic generation control AGC frequencyBiasFactor {F9138327-D4A1-4d5d-8994-FC32942062A3} Flag defining that for this hour in the resource bid the resource shall have an hourly predispatch. value {4958C881-4C68-4f97-B98C-482B57F0F22D} value {42EFC868-753D-41ef-B4ED-C116231492E3} The hurricanes category during the time interval using SaffirSimpson Hurricane Wind Scale a 1 to 5 rating based on a hurricanes sustained wind speed. category {C67D6897-B00D-4e7f-8CD6-BE602E0C79F1} Type and configuration of hydro plant penstocks. penstockType {9FE6046A-C52A-40b1-B7B7-B3A5820CCE7D} A code describing the type or absence of surge tank that is associated with the hydro power plant. surgeTankCode {5C9A5E8A-FBF5-428e-B3F1-60A2F8A0E8F4} Gate rate limit. gateRateLimit {5AF1C0E3-9138-4929-8CB3-D173A308732F} The Local Reference attribute specifies a value agreed upon between sender and receiver of the Information Message. It further identifies the Information Message. localReference {A2962A38-643E-4dc6-8012-24927484F35B} Used to indicate if the Provider is responsible for initiating the TASE.2 connection. If the value is TRUE the provider is responsible for establishing the association. If the value is FALSE the peer provider of the Bilateral Table will need to establish the association. calling {F4CE1A53-F799-4391-91CD-F8C19396E808} If True the value indicates that the entity represented by the bilateral table is capable of issuing requests and responding to request e.g. bidirectional support of ICCP requests.If False this indicates that a calling entity e.g. calling True will not be able to respond to ICCP requests. If False and callingFalse this indicates that the entity will only respond to ICCP requests and not issue ICCP requests. clientAndServer {570D1089-9BB0-4011-B47A-7D5C0E9B4949} Specifies the fastest update interval that can be provided for integrity information and Transfer Set creation. The value is in seconds. minimumUpdateInterval {91145068-4973-4b2d-AE1F-8F5C348D9A31} Specifies the ICC scope name that the remote can use to access the information in the Bilateral Table if the information is not VCC scoped. This value may not be null. nameOfLocalICC {B42B35C8-D080-4ef0-9B2A-053AF8117B35} Per IEC 608706702 If true indicates support for basic services. Must always be true. supportForBlock1 {4328CCAD-0A37-4216-A47B-E5C8AC1BA630} Per IEC 608706702 If true indicates support for extended conditions. supportForBlock2 {126521CA-0970-404a-8284-77C77058CCAD} Per IEC 608706702 If true indicates support for blocked transfers. supportForBlock3 {309E572B-4263-4007-BC03-1768B7E7C6B0} Per IEC 608706702 If true indicates support for information messages. supportForBlock4 {577F16A1-A20D-4b49-808C-D7ABB8330DE9} Per IEC 608706702 If true indicates support for device control. supportForBlock5 {9D232F12-EB25-4348-A274-14E06E2DE03F} Per IEC 608706702 If true indicates support for accounts. The use of this block was deprecated in Edition 3. supportForDepriciatedBlock8 {0C33DBCA-53F5-4a87-83AC-FD164CD45BD1} If true then transport level security as specified by IEC 623516 is required. transportSecurityRequirement {515BDDFD-3CA7-4b93-AF9F-6950FFEBB9A8} const20161031 Form is YYYYMMDD for example for January 5 2009 it is 20090105. date {353BDA8B-E1C1-4e55-BE22-8BF6A658E355} constIEC61968CIM13v09 Form is IEC61968CIMXXvYY where XX is the major CIM package version and the YY is the minor version. For example IEC61968CIM10v17. version {4FE5B579-CDEC-42c6-87FE-65797A3E9E03} Form is YYYYMMDD for example for January 5 2009 it is 20090105. date {8DADB97F-283D-40c7-A25A-D75E4C0D8507} Form is IEC61970CIMXXvYY where XX is the major CIM package version and the YY is the minor version. For example IEC61970CIM13v18. version {B4E0B1B6-8794-406a-A4C6-CBB395E37A52} Form is YYYYMMDD for example for January 5 2009 it is 20090105. date {A832713E-4991-478c-A9F3-950E5D26380C} Form is IEC62325CIMXXvYY where XX is the major CIM package version and the YY is the minor version. For example IEC62325CIM10v03. version {324CBD5B-D3C6-4c9d-94DD-3E78DDB5DDDA} Is the dotted decimal IP Address resolve the IP address. The format is controlled by the value of the addressType. address {3797024E-6F8F-4970-835B-5AA4EF50678E} Is the dotted decimal IPAddress of the first hop router. Format is controlled by the addressType. gateway {285AB90D-ED6D-45b3-B5E6-57240966F56F} This is the IP subnet mask which controls the local vs nonlocal routing. subnet {7081E6FF-D824-4f51-B9FC-CA3102C2EB7D} Is part of the Application Entity addressing as specified by ISO Addressing. aeInvoke {45125E3E-D2B8-455d-9355-E74DB6923601} Is the AE qualifier and represents further application level addressing information. aeQual {0270C184-02E5-424b-A75C-B5D31A9FDE3E} Is a further application level OSI addressing parameter. apInvoke {BF45760D-20B5-4f8b-8235-F2D820EE5B81} Is a sequence of integer strings separated by .. The value in conjunction with other application addressing attributes e.g. other APs are used to select a specific application e.g. the ICCP application entity per the OSI reference model. The sequence and its values represent a namespace whose values are governed by ISOIEC 74983. apTitle {7E7E4F69-3FA8-43be-8616-47490338F236} Is the addressing selector for OSI presentation addressing. osiPsel {14C1B232-15B4-4d3c-87CA-338FB7CACF8A} Is the OSI session layer addressing information. osiSsel {63DAE666-97E7-4397-BFEB-8E51A1BD956A} Is the OSI Transport Layer addressing information. osiTsel {97BA7C1A-D88B-436a-88C6-251FBDDBEC8A} The aliasName is free text human readable name of the object alternative to IdentifiedObject.name. It may be non unique and may not correlate to a naming hierarchy.The attribute aliasName is retained because of backwards compatibility between CIM relases. It is however recommended to replace aliasName with the Name class as aliasName is planned for retirement at a future time. aliasName {D4F8B75D-CDAD-4440-8092-1425101E5ABC} The description is a free human readable text describing or naming the object. It may be non unique and may not correlate to a naming hierarchy. description {13104BE9-CB1E-4dde-9A52-D7EE95DF7B65} Master resource identifier issued by a model authority. The mRID is unique within an exchange context. Global uniqueness is easily achieved by using a UUID as specified in RFC 4122 for the mRID. The use of UUID is strongly recommended.For CIMXML data files in RDF syntax conforming to IEC 61970552 the mRID is mapped to rdfID or rdfabout attributes that identify CIM object elements. mRID {C775F80A-A23D-4f38-AB9D-49D1FA882337} The name is any free human readable and possibly non unique text naming the object. name {870F033B-EDA6-4a32-A5AD-47DCBBFE2997} value {6C71F109-A754-41ed-88E0-B9DA18EAF543} Date asset was most recently put in use. inUseDate {D327CF70-AF93-4e42-A189-E3BA4E75A296} Date of most recent asset transition to not ready for use state. notReadyForUseDate {E4F9187C-A1AD-4454-AED9-08AD9D09780B} Date of most recent asset transition to ready for use state. readyForUseDate {47F58F13-B8BC-4c05-8E37-C571EF36AD07} Cause of this incident. cause {D9CF34B1-42FB-4ecd-82C0-C3E1215408E9} Flag is set to true when output is expressed in net active power. isNetGrossP {6658D33F-5901-4068-B659-F851F517ECEE} value {83AE2102-F0CF-4ab8-BBB6-03E5262DCC86} value {165B20CD-D566-4ac4-83F9-2989DE99DEFA} Answer to question. answer {FE348524-99F6-4474-9E30-BABBFA11AE53} The date and time the quesiton was answered. answerDateTime {9B797A64-7291-496e-A711-ACD22E1A90A8} Remarks to qualify the answer. answerRemark {8191AB2B-7DE1-4b7a-A685-BEF3E8232062} The question code. If blank refer to questionText. questionCode {26212987-0976-4ce1-B780-0CAE0DD29B88} Remarks to qualify the question in this situation. questionRemark {A7B4B038-382E-4290-9BAE-5C388ED2F458} For noncoded questions the question is provided here. questionText {00576FB3-D1F0-4c51-AB5A-18B6EF4E6CCC} The type of the question. questionType {88C3EDC6-0737-4b4d-9835-E980D6501AFD} Description of the conditions of the location where the asset resides. locationCondition {B3236466-AC6B-4534-8403-BBB1462D89EE} Binding dispatch operating delta provides a relative delta to be applied. Typically used in demand response instructions. The bindingfont color0f0f0fDOD instructions are cumulative in other words a second DOD instruction does not replace the previous DOD instead the second DOD adds to the previous DODs.font bindingDOD {3AB5BB18-5183-45d4-BF5F-241E98B4EF37} bindingDOT {2E51D0DF-8686-4a85-BBD4-1418C326C160} Total cost associated with changing the status of the resource. instructionCost {67446729-30BA-4692-8A0E-7D87C31B8C3D} Time the resource should be at Pmin for start ups.Time the resource is off line. instructionStartTime {605A5BE0-8122-4f62-8ED9-BD85AFCEABA9} Minimum start up time required to bring the unit online minutes.SCUC commitment period startup time. Calculated start up time based on the StartUpTimeCurve provided with the Bid.This is a combination of StartUp time bid and Unit down time. Units is minutes minStatusChangeTime {2DD8AD83-AE4F-4179-B4D9-56720958F4A5} updateTimeStamp {075653C8-07C1-4d10-895C-EC4986611FAC} updateUser {E72345ED-0308-41bf-AFF3-408D6934896C} The default method by which interchange schedules are to be integrated to obtain hourly MWh schedules for accounting. Method 1 is to integrate the instantaneous schedule between the hourly boundaries. Method 2 compensates for any updown ramping that occurs across the hourly boundary this is called block accounting. defaultIntegrationMethod {CC6D1262-0B43-480a-9087-4DE8AB5BC36D} Value of this quantity. value {9ECF56CF-5869-4003-A850-3C3787F6EBE1} The minimum hourly block for an InterTie Resource supplied within the bid. minHourlyBlock {9BB13447-77B1-47a3-8BBB-EE2897D8F6F0} The accepted mw amount by the responder. aka response mw. acceptMW {8E3039DF-A092-4726-99FA-A244F1705A07} MW amount associated with instruction. For 5 minute binding dispatches this is the Goto MW or DOT clearedMW {A64B5344-FA77-46a1-824F-B90729BFFECA} Part of the Composite key that downstream app uses to match the instruction startTime {A3D44154-1EC5-42e7-9E9E-63196451FB66} Net Actual MW Flow baseMW {D2959287-9D99-4945-B626-3274BD9C231D} Net Dispatched MW clearedValue {3B6DEFDA-0D3B-435b-B7AD-48AA876E7E14} Existing transmission contract number contractNumber {8813C172-1C8D-453d-8B7F-45B450343A00} Existing transmission contract usage MW value usageMW {7502733E-5CB2-4372-9925-739821215502} Interval length. intervalLength {2536EA51-AAFD-4901-A2D7-4B782F0808E1} Operating date hour. operatingDate {D9EC6FFA-D2A4-47a7-BCA5-B5FAABE58C78} To indicate an outofmarket OOM schedule. outOfMarketType {866CCB87-449D-4004-87AE-CD21EDE940C3} Wheeling CounterResource ID required when Schedule TypeWheel. wcrID {0AA198B8-F5F0-463d-BAB1-6BDE904EE4F6} Indicates whether a resource is eligible for PIRP program for a given hour eligibilityStatus {21CE1352-7DFA-47a9-854A-B547BDF1A2B2} Name of building where location is. buildingName {EBC7D706-D38B-4ddc-95A3-ACA29F530142} Number of building where location is. buildingNumber {BA96D88C-B729-4609-9168-ED4B4BE39C34} Floor of location. floor {00BA84BE-DA16-4867-B0F3-61958AECCA7A} Room number of location. roomNumber {764EC990-0E59-4475-8D97-41358E8E65DC} The first value at the time. The meaning of the value is defined by the derived type of the associated schedule. value1 {9D8B5A55-35E1-40b2-ADE8-4DF725D136CC} The second value at the time. The meaning of the value is defined by the derived type of the associated schedule. value2 {5577A9F6-8B29-43dd-9885-64909F799BEE} The type of insulation around the joint classified according to the utilitys asset management standards and practices. insulation {0B0DED74-3F20-41f7-8778-9097C59CF268} value {5B27F433-ED87-49d6-81BB-ECFEA60B9979} Conclusion drawn from test results. conclusion {5B0BDE26-6A56-46eb-85F5-D815D2BA7AFB} Description of confidence in conclusion. conclusionConfidence {CD575F21-6875-48fe-97CB-0CF30E48E370} Identity of lab equipment used to perform test. testEquipmentID {87810D30-C5B2-4f09-8C90-B99E2ABB4C66} Activity code identifies a specific and distinguishable unit of work. activityCode {5F50A5A9-4B07-4e4a-ACA3-4EE97920081E} Reference allocated by the governing organisation such as municipality to this piece of land that has a formal reference to Surveyor Generals records. The governing organisation is specified in associated Organisation. externalRecordReference {6C3D6DE5-C0AE-41d1-B19B-BA09389A098F} value {C594A615-29EA-4d24-8984-B8844EE042B2} Date current installation was completed which may not be the same as the inservice date. Asset may have been installed at other locations previously. Ignored if asset is 1 not currently installed e.g. stored in a depot or 2 not intended to be installed e.g. vehicle tool. installationDate {569B7CC2-79C1-422c-B4C3-6551377163D0} Date the asset was manufactured. manufacturedDate {4C5A0697-6497-44c6-B167-21833EA42DCD} Date the asset was purchased. Note that even though an asset may have been purchased it may not have been received into inventory at the time of purchase. purchaseDate {DAFA856B-5B25-408f-A57C-E2B5B3676D49} Date the asset was received and first placed into inventory. receivedDate {A5EC1B77-3011-45cb-AF41-30C1C33ECC64} Date when the asset was last removed from service. Ignored if 1 not intended to be in service or 2 currently in service. removalDate {73ADF6AC-F535-4131-A7F1-8F28B1CB8BF3} Date the asset is permanently retired from service and may be scheduled for disposal. Ignored if asset is 1 currently in service or 2 permanently removed from service. retiredDate {86EFDA3A-F38C-4fa6-8F1E-8BA6D002730B} The polarity of the strike with T meaning negative. About 90 of all lightning strokes are negative strokes meaning that they were initiated by a large concentration of negative charge in the cloudbase this tends to induce an area of positive charge on the ground. negativePolarity {750A6414-900E-4457-9818-8BDFE53A671F} Tells if the limit values are in percentage of normalValue or the specified Unit for Measurements and Controls. isPercentageLimits {47BA45BD-55DC-4051-9C7F-BAAF73825DB3} Date and time when this line was created in the application process. dateTime {B5193FB2-406B-43fc-9A24-90A84FB8C7C9} Free format note relevant to this line. note {0D4BF5CB-FDCC-4204-BFE8-939EDCD08EAF} load reduction initiation time loadRedInitiationTime {44DF6703-0B98-45be-A442-89150C27BDC2} The date represents the NextMarketDate for which the load response bids apply to. marketDate {ED808F87-0F39-4810-83CC-AEAF62A9A1CC} Flag indicated that the load reduction is metered. See aboveIf priceSetting and meteredValue both equal 1 then the facility is eligible to set LMP in the real time market. meteredValue {AE9763D2-72E8-4ece-9D3F-E13409CA2623} Shortest period load reduction shall be maintained before load can be restored to normal levels. minLoadReductionInterval {79E7CD7E-0A40-4f6a-8105-16BE49D34B4C} Shortest time that load shall be left at normal levels before a new load reduction. minTimeBetLoadRed {EBEC1A15-18D3-4cc9-ADDB-285D864FBC45} Flag to indicate that the facility can set LMP Works in tandem with Metered Value. Greater chance of this being dynamic than the Metered Value however it is requested that Price Setting and Metered Value stay at the same source. Currently no customers have implemented the metering capability but if this option is implemented then Price Setting could become dynamic. However Metered Value will remain static. priceSetting {3A410659-A1FB-4737-874A-C4BB0BF2F974} Time period that is required from an order to reduce a load to the time that it takes to get to the minimum load reduction. reqNoticeTime {E4C7252C-35AD-4ca9-AA76-8703572A9F2A} Active loadfrequency dependence index dynamic iEpfdi. Typical value 15. epfd {F7B947C0-C3A0-45f7-9796-DF787FDF4153} Active loadfrequency dependence index static iEpfsi. Typical value 15. epfs {8429D43B-EF51-432a-A02E-2A886600565D} Active loadvoltage dependence index dynamic iEpvdi. Typical value 07. epvd {D0A50971-317E-43d8-BD56-92601F29B460} Active loadvoltage dependence index static iEpvsi. Typical value 07. epvs {4990BD89-41F5-4423-A4A0-4E134AB1BD6E} Reactive loadfrequency dependence index dynamic iEqfdi. Typical value 0. eqfd {D4C07CDA-B8E2-4b7f-9415-004DC64B7CC8} Reactive loadfrequency dependence index static iEqfsi. Typical value 0. eqfs {23148A82-CAB9-4c08-8851-EB5BE690A005} Reactive loadvoltage dependence index dynamic iEqvdi. Typical value 2. eqvd {099E8689-45D8-4b63-ACAA-FEBFA57DF54B} Reactive loadvoltage dependence index static iEqvsi. Typical value 2. eqvs {94C533E5-0B86-4612-A4BB-D42DBC0B3AFD} Loading factor iLiisubfacsubi. The ratio of initial iPi to motor MVA base. Typical value 08. lfac {4D80F496-63A7-4b13-B587-E9DF6A486523} Fraction of constantpower load to be represented by this motor model iPiisubFRACsubi gt 00 and lt 10. Typical value 05. pfrac {2D8FAD05-749B-4f96-B2D2-4CE5BF50469D} Real power MW load distribution factor pDistFactor {4E402FD4-06EF-426b-9E4F-040F305571F4} Reactive power MVAr load distribution factor qDistFactor {FEE98F42-6694-4caa-9E09-46589EBDB0C1} Instruction End Time endTime {1DEAC45A-BDCB-4218-A478-C0EB5FAB79EF} Load Following MW Positive for followup and negative for followdown loadFollowingMW {FB0807D3-5970-4049-B9B9-63A6C32A8805} Unique instruction id per instruction assigned by the SC and provided to ADS. ADS passes through. mssInstructionID {727926DE-DCB8-45d0-8EA7-1D5F81397861} Instruction Start Time startTime {EAB6EB68-19F5-4829-B50F-4D949CC8AE77} Time the data entry was performed dataEntryTimeStamp {7DD72623-EDA0-4d8f-B6D7-321F1D582C8E} temporarily manually entered LFD capacity tempLoadFollowingDownManualCap {604BC411-AB8D-4586-889E-2D68B6F5841E} temporarily manually entered LFU capacity. tempLoadFollowingUpManualCap {15C3EF08-CE3F-4e07-A2C0-D8A7CF7CBDF6} updateTimeStamp {CD6F520D-318A-47e2-B8B3-48A166DA6A05} updateUser {5BF75C1F-B679-4fd2-949D-96382466125A} Steady state voltage index for reactive power iBSi. bs {38F9B935-2DA2-4f51-B985-6E8239F697EF} Transient voltage index for reactive power iBTi. bt {C96066B4-E411-4037-9394-1055CAB38285} Steady state voltage index for active power iLSi. ls {6F1D546B-2FD9-4f5b-9A29-A987724FECB5} Transient voltage index for active power iLTi. lt {6E434EE1-6562-4740-98B5-2588E480C1C7} Damping factor iDi. Unit delta iPidelta speed. Typical value 2. d {E924980F-8F48-4fbd-A0F0-F1D6AFD10A3D} Loading factor iLfaci. The ratio of initial iPi to motor MVA base. Typical value 08. lfac {7B55D1AF-F5B6-4c9b-85AC-44A71019BDCD} Fraction of constantpower load to be represented by this motor model iPfraci gt 00 and lt 10. Typical value 03. pfrac {1D8468A9-BB75-439b-9CDD-031979BEDDAD} Interval End Time intervalEndTime {E8ADFD1D-9964-47f2-B1A4-8E363B48380F} Interval Start Time intervalStartTime {7B8FB69D-0BA5-41f7-90AA-537A9F5E7BF6} type of the curve Possible values are but not limited toMax Min loadReductionTimeCurveType {1487FFFA-AAF3-4c6c-BEEB-FCAAEB6EDCA1} Indicates the exponential voltage dependency model is to be used. If false the coefficient model is to be used.The exponential voltage dependency model consist of the attributes pVoltageExponent qVoltageExponent pFrequencyExponent qFrequencyExponent.The coefficient model consist of the attributes pConstantImpedance pConstantCurrent pConstantPower qConstantImpedance qConstantCurrent qConstantPower.The sum of pConstantImpedance pConstantCurrent and pConstantPower shall equal 1.The sum of qConstantImpedance qConstantCurrent and qConstantPower shall equal 1. exponentModel {167B72F6-0FB5-4c24-AD5B-E7D5CEAAFB08} Portion of active power load modelled as constant current. pConstantCurrent {8173030F-BA74-4d14-9EAF-5BB596D214B2} Portion of active power load modelled as constant impedance. pConstantImpedance {2BA696F5-28B3-47b8-9C5A-312BDD6C4325} Portion of active power load modelled as constant power. pConstantPower {8FBB39E5-76EE-4c10-8312-F7C95EAE8DFF} Exponent of per unit frequency effecting active power. pFrequencyExponent {239AEC84-9D6C-48ae-B39A-E727E8011266} Exponent of per unit voltage effecting real power. pVoltageExponent {0D189BB7-C047-44b2-897B-43C9F90554A4} Portion of reactive power load modelled as constant current. qConstantCurrent {13BEED75-919E-4609-9FBC-560293500E7C} Portion of reactive power load modelled as constant impedance. qConstantImpedance {7D1D30A6-9C72-42de-991C-EC9D1D5742B1} Portion of reactive power load modelled as constant power. qConstantPower {DB0D438A-33C3-4390-B6AA-B32EBC7EE187} Exponent of per unit frequency effecting reactive power. qFrequencyExponent {197ADE9E-E59C-444f-9761-15E420D25F3C} Exponent of per unit voltage effecting reactive power. qVoltageExponent {E22F1B76-3348-468a-98F3-9D31182229EE} First term voltage exponent for active power iEp1i. Used only when .staticLoadModelType exponential. ep1 {73B18F54-8825-4761-A56E-32F4CD464919} Second term voltage exponent for active power iEp2i. Used only when .staticLoadModelType exponential. ep2 {23188E52-1D97-44c9-A401-6E9F96E2AFE5} Third term voltage exponent for active power iEp3i. Used only when .staticLoadModelType exponential. ep3 {123F8B72-CD85-4540-B740-66F8BEFAF909} First term voltage exponent for reactive power iEq1i. Used only when .staticLoadModelType exponential. eq1 {49E45725-736B-4a44-9ACA-B6679F6A6221} Second term voltage exponent for reactive power iEq2i. Used only when .staticLoadModelType exponential. eq2 {52436692-2C04-4383-A16C-22EDA77F0530} Third term voltage exponent for reactive power iEq3i. Used only when .staticLoadModelType exponential. eq3 {C81902D0-C3DE-48ac-8AD8-E8FA2D09857C} First term voltage coefficient for active power iKiisubp1subi. Not used when .staticLoadModelType constantZ. kp1 {B0997870-4CE1-4c52-8B8B-8A05325F3EF8} Second term voltage coefficient for active power iKiisubp2subi. Not used when .staticLoadModelType constantZ. kp2 {C5468FFC-CD8B-4e7f-8210-C93CF03DF0F2} Third term voltage coefficient for active power iKiisubp3subi. Not used when .staticLoadModelType constantZ. kp3 {9395A751-7826-4baf-8BB8-768E22CE36C8} Frequency coefficient for active power iKiisubp4subi not 0 if .staticLoadModelType zIP2. Used only when .staticLoadModelType zIP2. kp4 {4BD6EDD0-E320-49e0-B917-05BFA105B04C} Frequency deviation coefficient for active power iKiisubpfsubi. Not used when .staticLoadModelType constantZ. kpf {974F0B03-584D-4eb6-A780-A32CABA4CCC6} First term voltage coefficient for reactive power iKiisubq1subi. Not used when .staticLoadModelType constantZ. kq1 {2CB965D6-070E-4acf-A8FA-3C1681EA10A8} Second term voltage coefficient for reactive power iKiisubq2subi. Not used when .staticLoadModelType constantZ. kq2 {3CBEC0C5-AB09-427f-955C-A40A04776E93} Third term voltage coefficient for reactive power iKiisubq3subi. Not used when .staticLoadModelType constantZ. kq3 {F183074D-6CF6-401b-828E-D61137B18790} Frequency coefficient for reactive power iKiisubq4subi not 0 when .staticLoadModelType zIP2. Used only when .staticLoadModelType zIP2. kq4 {17E983C0-DF7D-4b45-B0C7-FC8E4BB19902} Frequency deviation coefficient for reactive power iKiisubqfsubi. Not used when .staticLoadModelType constantZ. kqf {2D2BCF88-86DD-49f3-9DA0-9819749FA6BA} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {B8FC77A3-E9FD-41af-8CB8-029281C34232} if applicable Direction that allows field crews to quickly find a given asset. For a given location such as a street address this is the relative direction in which to find the asset. For example a streetlight may be located at the NW northwest corner of the customers site or a usage point may be located on the second floor of an apartment building. direction {08837BC4-44DA-4af5-A8CA-D2158DB60CCB} if applicable Reference to geographical information source often external to the utility. geoInfoReference {42D25DB2-D892-4511-8D66-5ADC0654C723} Classification by utilitys corporate standards and practices relative to the location itself e.g. geographical functional accounting etc. not a given property that happens to exist at that location. type {55804064-3AA5-48ce-99BE-ECF43B41B5B0} Property related information that describes the Grants land parcel. For example it may be a deed book number deed book page number and parcel number. propertyData {3BA672F3-86AB-4ed4-B5C2-433470DA443C} lossMW {728052D0-FCB5-4f4b-8B8B-626FBF0F3EBF} Loss penalty factor.Defined as 1 1 Incremental Transmission Loss with the Incremental Transmission Loss expressed as a plus or minus value. The typical range of penalty factors is 09 to 11. lossFactor {F1B7C014-7A9C-4fa0-93EA-8BAC43B57BCA} Interval Test StatusN not applicable resourceStatus {6895CBD1-8389-46c0-A844-942678CF96A8} This is the default loss factor for the Metered SubSystem MSS zone. The actual losses are calculated during the RT market. lossFactor {53FC00D7-3D53-4e43-A46D-ED010B3CC736} value {E8A9ED0E-4D87-4afc-A1CB-3C23D7DDED5F} Condition of asset just following maintenance procedure. conditionAfter {B3307F5D-715C-455b-A5AF-1FD7E6611009} Description of the condition of the asset just prior to maintenance being performed. conditionBefore {92EC2BB3-EB9C-446a-BD14-BB0D622C1D53} Code for the type of maintenance performed. maintCode {FC04C0ED-F5F4-405f-8DE7-4A98F48C26D6} if applicable Name identifier or description of the block in which work is to occur. block {77B96DCC-5721-42ae-B49A-08A48556669E} if applicable Name identifier or description of the lot in which work is to occur. lot {561DB6D9-CD00-40da-AE4B-3C804080B5B3} The names of streets at the nearest intersection to work area. nearestIntersection {910A4B46-7E76-47b1-A080-EDD2D3872C36} if applicable Name identifier or description of the subdivision in which work is to occur. subdivision {EC4D823B-C339-4deb-ADC3-F178E2F520D9} effectiveDate {E1E5967C-8BCA-40ae-BF34-1ABABC6A700A} frequencyType {1BE1D957-5AF6-4b0d-ACBD-FADF5B0F0BC8} invoiceType {6967ABC2-C756-4094-BA48-E58D2AFB26FE} requireAutorun {2EE8DCD0-9C42-4b28-B77B-FECF821BB17A} Revision number for the major charge group revisionNumber {BAF4FAD2-1760-441e-AF96-7EC3BDC95814} runType {D62A757F-1D92-4f6c-A194-7D19226899A3} runVersion {B6BCBCA1-DA35-4b46-BF75-7DD4E50D77DA} terminationDate {D4FAE52A-CD79-469a-86D7-B607DAD0C0BF} Market ending time actual market end actualEnd {5E69C5D3-9B77-440e-BC5B-03248540EFEF} Market starting time actual market start actualStart {DE6A61B9-9E34-4acc-86E1-54634576C1C9} True if daylight savings time DST is in effect. dst {3462AFA4-12A0-4713-9BAD-6149AEB3433A} Market end time. end {B30ABEA5-4045-4217-A804-D2B53BD7D85E} Local time zone. localTimeZone {D1088F71-0BDD-41f9-ADD0-222D3824A932} Market start time. start {1D932894-E217-4d3f-8122-41EEA157D324} Market Status OPEN CLOSED CLEARED BLOCKED status {FCFC14B3-2619-440e-B2DE-7B6B25D9D19A} Trading time interval length. timeIntervalLength {229C9B4E-8A30-4b95-8533-719D42806F0C} Market trading date tradingDay {168F6324-8FA5-40a4-8F74-5736BA86BE71} Trading period that describes the market possibilities could be for an Energy MarketDayHourFor a CRR MarketYearMonthSeason tradingPeriod {F939EABE-2AB9-42cc-8FE2-8C5082A6F698} Free format comments for the event for any purpose needed. eventComments {7C23371D-ECA0-43f1-B5B9-2719C6D853F4} End time of the event. eventEndTime {AACC9B84-5395-40d2-AADE-C9A14FA9B366} Start time of the event. eventStartTime {252EBB54-4830-4fa2-8914-E132CC882EDE} Actual event type. eventType {131C3E2A-F3F7-48bf-8649-EDFB4E14653D} Settlement periodDA BidinDA ReliabilityDA Amp1DA Amp2RT ExAnteRT ExPostRT Amp1RT Amp2 caseType {43C85EDF-E36F-48af-B1A0-25916F39127E} Last time and date clearing results were manually modified. modifiedDate {81DC6EB4-7448-46fb-8C65-117A54E825BA} Bid clearing results posted time and date. postedDate {0391B073-3FAF-4f72-B258-B848F3776771} The end of the time interval for which requirement is defined. intervalEndTime {4B41CD8F-9D59-49bc-9FB3-7A24007E872D} The start of the time interval for which requirement is defined. intervalStartTime {E07A9E3B-3BC0-4638-9AA0-30E71AA02895} Calculated date upon which the Invoice amount is due. dueDate {CDB725A4-15F8-4e96-A034-2643E5BF1D5F} Date on which the customer billing statementinvoice was printedmailed. mailedDate {C887903F-0AEA-4775-9535-C3F683C0B50D} True if payment is to be paid by a Customer to accept a particular ErpQuote with associated Design and have work initiated at which time an associated ErpInvoice should automatically be generated. EprPayment.subjectStatus satisfies terms specificed in the ErpQuote. proForma {0E523839-D815-4c8c-8645-FD50B511800A} Number of an invoice to be reference by this invoice. referenceNumber {CA3010DE-8C4A-4ae7-A7F0-631000A394B0} Date and time when the invoice is issued. transactionDateTime {0B15CFDB-BBC7-4f49-9DDB-3600604F1562} Type of invoice transfer. transferType {7514BE8F-8225-4c93-9BAB-BC374CA108E1} General Ledger account code shall be a valid combination. glAccount {E326FB4C-743B-42a6-9491-5BABA475213D} Date and time line item will be posted to the General Ledger. glDateTime {3DD89411-A3D2-4ddd-A386-4F5BAC511919} Amount due for this line item. lineAmount {C0B0FAAB-EF7C-46a0-90BF-FF32C761FF17} Line item number on invoice statement. lineNumber {BB462B2E-8C6B-4265-9D30-EA52C5E47E6D} Version number of the bill run. lineVersion {DB7E1220-E2D3-4dac-929F-5725D3427BFF} Net line item charge amount. netAmount {E2179F12-4D81-4b32-818A-95ADCF9315E6} Previous line item charge amount. previousAmount {C8DE6B1C-4FB8-425c-9F45-8172DD571D6F} Account identifier for this entry. accountID {18499FF2-16DA-4401-8397-1DBB08CB66ED} Date and time this entry was posted to the ledger. postedDateTime {D7312FA1-69F9-4ac6-952A-BF5DFDDC4D9D} Date and time journal entry was recorded. transactionDateTime {4014604C-A551-4901-AA51-E11108BF5A07} The coded condition or position of an object with regard to its standing. status {AD08B171-672D-4d8c-9A29-0F14BA1F3D32} Category of this person relative to utility operations classified according to the utilitys corporate standards and practices. Examples include employee contractor agent not affiliated etc.This field is not used to indicate whether this person is a customer of the utility. Often an employee or contractor is also a customer. Customer information is gained with relationship to Organisation and CustomerData. In similar fashion this field does not indicate the various roles this person may fill as part of utility operations. category {7BCEE6E0-F6F7-4928-A356-A872C3F8A0F7} Persons first name. firstName {31E8C736-2EC6-4217-A190-F63C60057364} Unique identifier for person relative to its governing authority for example a federal tax identifier such as a Social Security number in the United States. governmentID {1436A65F-1030-4d31-BDC0-81FE8A0C7079} Persons last family sir name. lastName {B3B5308E-447F-4445-B69A-BFBB4A0F3488} Middle names or initials. mName {97B95DF8-6AEF-431a-81B1-8065D585A887} A prefix or title for the persons name such as Miss Mister Doctor etc. prefix {1FA68757-F994-483f-8820-12E58DBDBFB1} Special service needs for the person contact are described examples include life support etc. specialNeed {CAD05567-3E3F-4df5-905E-DFC4976F2075} A suffix for the persons name such as II III etc. suffix {D11C1FA8-CCA3-4680-86F5-A8CE377B9D56} The user name for the person required to log in. userID {A15386B0-9163-40fc-A686-E574F9044E47} Planned market trading day. tradingDay {DDC70E68-8F3F-4f76-9A6B-B4C5339BE387} Ramping time interval for the specific market product type specified by marketProductType attribute. For example if marketProductType EN from enumeration MarketProductType then the rampInterval is the ramping time interval for Energy. rampInterval {49419B5B-D158-451a-A8BD-9D4D00507DE8} Effective date of the privilege terminate date of the privilege or effective date of the application for the organization effectiveDate {4DA620F2-C8AD-480e-94CE-42F37F6F1A8F} This is the terminate date of the application for the organizationThe specific organization can no longer access the application as of the terminate date expirationDate {5875BA62-6112-4008-B4AE-ACA780836AF6} Qualification identifier. qualificationID {033EC4B6-F2CC-4f6a-BD29-44EC9534A00D} The status of the privilege. Shows the status of the users qualification. The current statuses are 1New 2Active 3Refused 4Terminated 5Withdrawnand it is subject to update. status {7FED54E8-547D-42db-8002-A270CC9CB456} This is the name of the status of the qualification and is used to display the status of the users or organizations status. statusType {C00EADDA-1FC5-466e-B929-DBA8BD180EDD} Cleared generation Value in MW. For AS this value is clearedMW AS Total. For AS clearedMW selfScheduleMW AS Procured clearedMW {24C7A0FA-0099-4a68-AB84-64EE9E2535C6} Marginal Price MW for the commodity Energy Regulation Up Regulation Down Spinning Reserve or Nonspinning reserve based on the pricing run. clearedPrice {7E9DBD3E-3AF3-4125-A2DB-B0199A830C8B} Dispatchable MW for Combustion units. dispatchCtMW {A344528E-383F-4d88-A07C-7D9358D4905E} Dispatchable MW for Hydro units. dispatchHydroMW {A702307B-BFF0-422d-93D8-236ED6E880C0} Dispatch rate in MWminutes. dispatchRate {25D395B3-4702-430e-B5A9-058CD17E44E2} Dispatchable MW for Steam units. dispatchSteamMW {E1016103-42B0-4c9f-BF31-00A36F835F23} Imbalance Energy Bias MW by Time Period 5 only imbalanceEnergyBias {6CC211E5-2A47-41c3-8251-824CC81CBF26} Region requirement maximum limit maxSufficiencyIndex {30AED1ED-3238-4812-A1DC-5BF2554F5BBC} Region requirement minimum limit minSufficiencyIndex {94BD8526-FC6C-4885-B9B1-C8A992135E96} Region requirement maximum limit reqMaxMW {C8EF162F-1D48-4084-8EBE-BAB8EF680B16} Region requirement minimum limit reqMinMW {839A065C-5B33-46b9-9E69-69083FF68309} Aof AS selfScheduleMW AS SelfProvided selfScheduleMW {7E5D8D82-E6FE-427c-9C6F-D1319FDCACB6} Total AS Cost i.e. payment over the time horizon ancillarySvcCost {1E276D77-8818-4fa8-AE97-AAEB28D68694} Total Energy Cost over the time horizon energyCost {11393337-7C11-49f2-9495-2AEF77184896} Total Minimum Load Cost over the time horizon minimumLoadCost {4DC46E2E-29BE-4b0e-A537-365E6622E197} Total Startup Cost over the time horizon startUpCost {E42CCD79-C084-42c5-B08B-1653B04891ED} Total Cost Energy AS cost by over the time horizon totalCost {6AE93F37-6546-451a-8C86-33F8068766D1} The total RUC capacity cost for this interval totalRucCost {81E513DF-FF20-45d8-A4AB-4B4900406229} The kind of market roles that can be played by parties for given domains within the electricity market. Types are flexible using dataType of string for freeentry of role types. type {C624FDB0-F4CE-4af4-8DA9-D43058F1A060} Approved time for case. Identifies the time that the dispatcher approved a specific real time unit dispatch case marketApprovalTime {87818354-2F6C-4b3c-8737-6FC915C357BE} Set to true when the plan is approved by authority and becomes the official plan for the day ahead market. Identifies the approved case for the market for the specified time interval. marketApprovedStatus {938FA2A6-4C8A-49e3-A6F7-23A86F263DF2} The end time defined as the end of the market market end time. marketEndTime {B608D398-38F3-4ae6-BE72-E316CDE1A715} The start time defined as the beginning of the market market start time. marketStartTime {9CB9CFB6-521F-4ad6-8874-F4DFBAEE0431} This is the state of market run activity as reported by market systems to the market definition services. reportedState {110876DD-36F9-411e-8A82-AB4A698B49C6} This is the state controlled by market defintion service.Possible values could be but not limited by Open Close. runState {5BA76CDA-BFAC-4df0-8773-899BB1BA8DFD} Category of scheduled event. category {3F067C62-1AD8-433b-A62F-E682FC4E6B05} Date and time the skill became effective. effectiveDateTime {40E49FFB-94D3-4393-A310-8B2D2077C257} Level of skill for a Craft. level {6F157A53-C185-4fe4-BF59-E0B7CEC82F47} The end of a bill period. end {302FE5A3-B3B3-4260-959D-B7D64CE3FAA8} The version number of previous statement in the case of true up. referenceNumber {82ADA027-0F38-4aa2-BFB6-2AA7C01D7CED} The start of a bill period. start {08140298-C4B7-4edd-892F-DDB042BA8855} The date of which Settlement is run. tradeDate {5003BA23-3D99-4466-A24A-A42F9A0B2ECC} The date of which this statement is issued. transactionDate {5FDBB629-85E6-417b-B2C1-E72AC476F597} Current settlement amount. currentAmount {BDDF2867-9EC5-477e-8BFB-E2F9D59C6877} Current ISO settlement amount. currentISOAmount {4F460E72-9F8F-49fc-A42B-FF9A98EC3BD0} Current ISO settlement quantity. currentISOQuantity {68931B37-2D63-4617-A22B-5BBA420F4709} Current settlement price. currentPrice {4ACFF648-1B93-4951-82F6-4E692DE41ACA} Current settlement quantity subject to the UOM. currentQuantity {EC738BC7-F731-4bbd-9C5C-19B141C2DD9D} The date of which the settlement is run. intervalDate {C6A2CCF9-67E5-4b69-90C1-3915D4CA189A} The number of intervals. intervalNumber {2B5C2956-E730-494b-BCB6-692BCE493746} Net settlement amount. netAmount {0D9D46C5-2F86-4c99-9CAC-443296C03E0A} Net ISO settlement amount. netISOAmount {5207A915-2570-4bf7-9FBD-56084A46BD4D} Net ISO settlement quantity. netISOQuantity {23350D3D-E34A-4c8e-9325-118A1BF98869} Net settlement price. netPrice {28BBE022-060A-45d8-A295-54A39B134D04} Net settlement quantity subject to the UOM. netQuantity {F19A6001-57E4-4943-B40D-0F2A76FCABD1} Previous settlement amount. previousAmount {0B33E2A5-517A-4aa7-9270-858E28E25321} Previous ISO settlement amount. previousISOAmount {789BC974-2D5C-42ba-B918-88EAAA6743FB} Previous ISO settlement quantity. previousISOQuantity {48CE3DFC-3D35-4efb-91D0-BEC05E8A8017} Previous settlement price. previousPrice {C39D279F-9250-4d48-ADAB-E796D1E86F49} Previous settlement quantity subject to the UOM. previousQuantity {3327EB68-75A0-4766-B6A8-DF360B855E59} The unit of measure for the quantity element of the line item. quantityUOM {8C9B3E5D-5D0F-4b2a-BD85-12C27C5F8BB4} value {2B34EA04-ECD7-45ae-A68A-43F2B5164237} Specifies the type of measurement. For example this specifies if the measurement represents an indoor temperature outdoor temperature bus voltage line flow etc.When the measurementType is set to Specialization the type of Measurement is defined in more detail by the specialized class which inherits from Measurement. measurementType {A0E1519B-5C0C-40ba-8596-0A94D2FE4BAB} If true use the absolute value for the calculation. absoluteValue {3BA7323C-2D42-4400-95BE-56B7D3F1A274} Positive number that defines the order of the operant in the calculation. 0 default. The order is not relevant e.g. summation. order {3E9966B5-7592-4933-A194-6736927F9CAE} The time when the value was last updated. timeStamp {DB94617E-83D2-4cd4-A38F-64B0524D28DF} Speed squared coefficient iai. a {0EA5ECA8-93B7-41a9-9A55-E9CDEC8C3335} Speed coefficient ibi. b {71E0F9DB-3021-483f-A1FF-1DF3BB404200} Speed to the exponent coefficient idi. d {BEE3D939-4A13-47f4-9A1B-0927DAAFCD3D} Exponent iei. e {C84BE72A-27FF-428d-8E10-C34F58BF5291} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {56223F2E-6860-4700-99BB-0305AAD03A60} A code used to specify the connection category e.g. low voltage where the meter operates. connectionCategory {622874D1-2F3A-4826-99F7-A77EFAD997CD} Meter form designation per ANSI C12.10 or other applicable standard. An alphanumeric designation denoting the circuit arrangement for which the meter is applicable and its specific terminal arrangement. formNumber {7F31FDC5-A964-4bd8-808F-F5FD797C0672} Multiplier value. value {ABB08FC7-3402-4506-85A4-ED18B95832D7} If true this meter reading is the meter reading for which other coincident meter readings are requested or provided. isCoincidentTrigger {DAB53223-CC2D-4d57-B0C3-02C4E285778B} value {1356BE21-6F87-4337-A03B-CC647C105BBD} This drives the accounting treatment for this misc. item. account {E02A8A65-D385-4851-B440-3E92DE69F111} The cost type for accounting such as material labor vehicle contractor equipment overhead. costType {43AF93E4-2C39-4642-A2E9-C0F60FB07CD0} External reference identifier e.g. purchase order number serial number . externalRefID {BE90DAC9-DD62-4e5b-B470-AC8EBD69F540} intervalStartTime {FDC17CBA-1DE0-4932-AE99-75CF9C65A1BD} Mitigated bid segment MW value segmentMW {5C57DAD8-1C0C-4a5e-91BF-A3B131A4658E} Mitigated Bid Segment Number segmentNumber {B38A9950-E0E9-4b50-A80C-AA070D5EE47D} thresholdType {FEE5BD2A-0F32-446d-8935-D2787A06D062} true if limit exceeded exceededLimit {0D3EF607-DF9A-4105-99B7-630A59D53FC4} Rating set numbers ratingSet {60E291BE-E5FD-4bd3-9722-6E1F4CACC2EA} load change flag Flag that indicates whether load rollover and load pickup should be processed for this contingency loadRolloverFlag {9A7D4774-1D64-4156-A4A0-0FFA5EAE1BB6} ltc enable flag Flag that indicates if LTCs regulate voltage during the solution of the contingency ltcControlFlag {18416467-0816-44fd-A590-F7C1D3A1474D} Participation Factor flag An indication which set of generator participation factors should be used to reallocate generation in this contingency participationFactorSet {F90FB99D-8C1A-49be-8302-4CEA475CFFEA} sceening flag for outage Flag that indicated whether screening is bypassed for the contingency screeningFlag {60C3E6E1-DFA0-4386-B854-107B46AE2D97} The coded type of a power system resource. psrType {8E95C8F7-1EFB-4522-8AD7-189D6F3BF99C} Sequence number within a operation sequence lower is first. Normally starts with 1. sequenceNumber {FCE1226B-AD80-4464-9FF7-89C1FFD68D74} The sequence number of the argument in an operation. Argument entries are considered in numerical order where the operation requires an ordering. sequenceNumber {83B9E792-F08C-4ee5-B00E-94FBA8273296} The maximum multiplicity of the instance arguments that should be supplied for a single operation. Use 1 to indicate unlimited. multiplicityMaximum {C7915124-BD8D-469e-859A-A662FD28656B} The minimum multiplicity of the instance arguments that should be supplied for a single operation. Use zero to indicate optional. multiplicityMinimum {73ECB561-CD30-479e-B6C3-00C9BDB82D88} value {FD1C5A68-05E0-448a-9515-88FB188D1A41} End time of this interval. end {33539151-664A-4d98-95A1-991B84C84CF9} Start time of this interval. start {87DA0F8E-0F49-4525-A5CC-52843D7C4420} Any free text that name the object. name {A2162B14-022E-4cda-AC84-B9D32A0C6C00} Description of the name type. description {B831899F-A8DB-470e-B41E-AE8F085A6225} Name of the name type. name {EEC57734-55A8-4d7d-BCBB-44785732CBD8} Description of the name type authority. description {90C20513-82B6-4090-89AE-2FE6E6F81954} Name of the name type authority. name {3D2A9B24-AB04-454f-BD8E-01ECCEAE4103} A user provided comment describing the changes in this version from the previous version. comment {D93C941F-9EAD-40bb-901E-645D477E89B6} The datetime the change set is included in the model. effectiveDateTime {AE2C8158-C22D-49ab-852C-CF13BF73C3F1} The datetime this version was finalized and thus made immutable. timeStamp {21DDF9F4-9D82-4353-A476-4B36BBA53017} closed {2F264EB1-7E6B-437c-86C9-A61E23D4ADDF} created {3CAEDC22-9EDC-45bd-911E-7640F075658D} updated {6C78A04A-879B-42d1-9F8B-72EF2A2DF4BB} version {A4691763-AA51-409c-ADC6-C2B7B8DFD94D} changesetVersion {FD18FAD7-404B-453e-ADF5-A64D64E9FF85} commissionedDate {2E5A9062-F9F9-43bd-B8F8-6D7D2805F2CE} plannedCommissionedDate {8E3B8F90-E8A5-4f88-86EA-E6AA2957201F} The number of the section. sectionNumber {2B3AA796-1811-4a0b-BD0B-1D16B11F8912} The number of the section. sectionNumber {3039EC90-899C-4381-9C73-A62F7CEF9854} The average oil price at a defined fuel region. oilPriceIndex {36B36062-3CF2-4c20-9D33-20D565AEF352} Classification by utilitys work management standards and practices. type {F8946D8D-3171-49ea-913D-3D1767888EA8} Utilityspecific classification for this person according to the utilitys corporate standards and practices. Examples include employee contractor agent not affiliated etc.Note that this field is not used to indicate whether this person is a customer of the utility. Often an employee or contractor is also a customer. Customer information is gained with relationship to Organisation and CustomerData. In similar fashion this field does not indicate the various roles this person may fill as part of utility operations. type {071CC7DD-F6F9-4317-A122-8698E58225AA} True if switch has load breaking capabiity. Unless specified false this is always assumed to be true for breakers and reclosers. loadBreak {E42360AB-9249-4102-98A5-90E11E09C893} Number of poles i.e. of current carrying conductors that are switched. poleCount {8EAE3E37-CA67-465b-A35E-D7D27A7EDDFC} True if device is capable of being operated by remote control. remote {5F56AAC8-C2A9-42cb-B01A-3C1FD4CCD075} True if explosives have been or are planned to be used. explosivesUsed {E4B30714-6356-4429-8240-29CEEFE194C3} True if work location has been marked for example for a dig area. markedIndicator {7F2BD3BC-5419-4bde-8729-CD9F58BFF915} Instructions for marking a dig area if applicable. markingInstruction {7EA3F5C0-FA84-4af7-A55A-1FA9D80137C1} Tap step number for the energised end of the test pair. energisedEndStep {5D7088AD-AC3B-4992-8C06-D2DF4A72753E} Tap step number for the open end of the test pair. openEndStep {5FFDF198-9498-42b9-8210-1294F1D3C914} value {47172EC0-3F6B-4b0d-8139-FAA801CD58FB} Defines if the operational limit type has infinite duration. If true the limit has infinite duration. If false the limit has definite duration which is defined by the attribute acceptableDuration. isInfiniteDuration {B23A3007-13C1-4330-983F-08B81F130AF9} Type of operational updated rating e.g. a derate a rerate or a return to normal. changeType {6DE4EB71-00FF-41fc-919D-49BA3D755AD1} Identifiers of the organisation held by another organisation such as a government agency federal state province city county financial institution Dun and Bradstreet etc. clientID {3A3EE3F2-0A0B-4ef3-980D-BEF5EBC84E8C} a name to denote the community this could be a name or a code of some kind. communityDescriptor {8C38F9E5-6C87-4c4f-9880-51186D05090F} number of customers that have been restored in the area. customersRestored {96EC7A1B-7F86-4742-A6DE-DAB1E3BA1ED2} The updated number of meters affected by the outage as reported by the OMS within the utility. It is assumed this number will be updated repeatedly until the full outage is resolved. metersAffected {5793A622-95C4-41c3-B43A-075FBD01DCC4} the total number of customers that are served in the area both outaged and not outaged. originalCustomersServed {81471418-91EA-4a7a-BF26-04C830755313} The original number of meters that were affected as reported by the OMS within the utility. That is this is the total number of meters that were out at the beginning of the outage. originalMetersAffected {831EAA33-59E8-45c6-A7E0-AD1E0F65E806} This contains an disclaimers the utility would like to place on the data provided to any stakeholder. This may be different for different stakeholders. This should possibly be an attribute under the Organization class but it is placed here for now. utilityDisclaimer {B8DD462E-CD50-45dd-B640-C2E9C0D7A292} This is the reported time of the first outage report earliestReportedTime {12A02525-DF1B-499c-872E-47D57B49845E} defines the number of meters served in the defined area. metersServed {BA8C464B-7AF0-4565-92FF-C4121EC8CC6B} Freeform comment associated with the outage order comment {951491DA-3948-4521-B621-2FF848323433} The date and time the outage plan was approved approvedDateTime {97729C42-A9A2-495e-9ED3-60F05F77EB55} Date and Time the planned outage was canceled. cancelledDateTime {DEA72F1F-9BAF-48d7-B194-94075F7F99C1} Purpose of this outage plan such as whether it is to replace equipment or perform maintenance or repairs or to reconfigure network topology. purpose {529D7F19-8F50-4a43-A14F-12D99A20C4E7} OEL ramped limit rate iKiisubRAMPsubi. Unit PU s. Typical value 10. kramp {FB5970BD-9979-43d3-B60F-094FE6B44F87} imi.true IFD limitingfalse EFD limiting. m {374FB821-28AC-4eef-B9C6-491FE7E5E856} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {37E442B3-4EDC-4687-BA37-499BEC0D9B11} Overhead code. code {D1AF82EF-D512-4926-B426-BC351D15F20B} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {33D2A381-E3EB-4831-B4D7-C2B57B2FCD9A} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {74ACE0E0-24AD-42bc-8B8F-02283355F675} Overexcitation Flag iOVEXitrue overexcitedfalse underexcited. ovex {C06CD261-159D-4913-9750-5FB80F5283AF} PF controller deadband iViisubPFCBWsubi. Typical value 005. vpfcbw {05BFA2E1-613F-4b7f-93B5-37E90009E587} Var controller deadband iViisubVARCBWsubi. Typical value 002. vvarcbw {6996BD76-2761-4a50-BD8B-F71F46A56AA1} Selector iJi.true control mode for reactive powerfalse control mode for power factor. j {1847D74E-8220-4456-AF87-04375CE3FC87} Overexcitation or under excitation flag iEXLONitrue 1 not in the overexcitation or underexcitation state integral action is activefalse 0 in the overexcitation or underexcitation state so integral action is disabled to allow the limiter to play its role. exlon {BF1C0E34-219E-4a3e-B171-E0D30C9ED234} Generator sensing voltage iViisubSsubi. vs {F4E5148F-7C59-4f6f-9454-9E43266808B5} Overexcitation or under excitation flag iEXLONitrue 1 not in the overexcitation or underexcitation state integral action is activefalse 0 in the overexcitation or underexcitation state so integral action is disabled to allow the limiter to play its role. exlon {7BBD8676-15AE-4ce5-9EF7-4A90B6479CFC} Generator sensing voltage iViisubSsubi. vs {8A63948E-CB60-4fc9-9C14-1F6F4AC38EDA} value {9E5F92B8-7F02-49bd-BC52-81240FB30E84} Date of last change to the main package dependencies in format YYYYMMDD. This is updated when the version attribute is updated. date {020082B1-54FC-44dc-8ECA-9AFF7F0B882F} The version of the main subpackages of the combined CIM model. The format is simply an integer. The version and date initial values should be updated any time the dependencies in the model change and require an actual change to the diagrams within this package. version {533F205D-A518-4746-807D-8C7D6BC58718} Encoding of cancel control. cancelControlMode {53C0B772-C6B2-48da-82BF-FA2CEE179C97} Timestamp when a canceling of the event is scheduled to start. cancelDateTime {73EB7715-9F21-4074-98DA-89ED1F2E1272} If true a canceling of the event should start immediately. cancelNow {D44316CF-6D36-41b0-9420-653BFCE0764B} Level of criticality for the action of this control. The action taken by load control devices for an event can be solely based on this value or in combination with other load control event fields supported by the device. criticalityLevel {C85BFB13-6B5E-43ff-8CC3-18AF2446AB1D} Provides a mechanism to direct load control actions to groups of PAN devices. It can be used in conjunction with the PAN device types. enrollmentGroup {07E0C79E-A170-47d5-95E1-22BB2534FA33} If true the requesting entity e.g. retail electric provider requires confirmation of the successful display of the text message. confirmationRequired {890832AF-EDE6-46dc-9F25-24D3C7CDFEA6} Priority associated with the text message to be displayed. priority {56BD00B5-72C6-474e-8DB7-1F927917725A} Text to be displayed by a PAN device. textMessage {8376A101-FA49-42bd-BF79-9DC66B1CF89C} Unique identifier for the commodity provider. providerID {8CB87BDC-F600-4908-926F-9140B0A9C178} Alternative measure of the cost of the energy consumed. An example might be the emissions of CO2 for each kWh of electricity consumed providing a measure of the environmental cost. alternateCostDelivered {9D4DB9F1-C034-44c6-89C9-79F8E35A7CC0} Cost unit for the alternate cost delivered field. One example is kg of CO2 per unit of measure. alternateCostUnit {CB63AE4C-4C47-4204-8B0A-BA8DC72F0C12} Current time as determined by a PAN device. currentTimeDate {1677916F-6193-4c1f-A208-5037F37C955A} Ratio of generationPrice to the normal price chosen by the commodity provider. generationPriceRatio {FD0A8465-6939-4f4c-A8DE-8EFCDF4DEBA5} Ratio of price to the normal price chosen by the commodity provider. priceRatio {8CC62802-7EBB-44eb-A70B-B1DFD02524BE} Pricing tier as chosen by the commodity provider. priceTier {F4791193-717A-4821-939F-CFC00AA0E854} Maximum number of price tiers available. priceTierCount {559203C2-BEAB-4d88-923F-230B11E3B950} Label for price tier. priceTierLabel {F15298A0-41D1-4d82-B77E-BA38B62BC457} Label of the current billing rate specified by commodity provider. rateLabel {384028DF-4158-404e-B6CD-F9AF42D4C597} Register tier accumulating usage information. registerTier {4729FC25-48EF-48e5-A056-B4EE905219E3} Defines commodity as well as its base unit of measure. unitOfMeasure {FBDAC539-8B49-4cd1-ADD4-666004F092DC} Used to calculate participation of Pnode in an AggregatePnode. For example for regulation region this factor is 1 and total sum of all factors for a specific regulation region does not have to be 1. For pricing zone the total sum of all factors has to be 1. factor {E80A70B9-85CD-46a9-9FEB-75166CFA021D} value {EA0BFAA8-C6F6-4267-938E-9F60DD6BD30F} Bill period end date billEnd {33129B09-36F9-4209-BA06-761C2906BF84} The settlement run type for example prelim final and rerun. billRunType {7F7ED7F0-F6DD-4510-A60F-F21BB5532291} Bill period start date billStart {5A6452BC-D3D1-4c8a-B3EC-9E2A0F8110CF} The company to which the PTB transaction is billed. billedTo {11AF0C88-C01F-49f1-B235-4E4F30CF6DBC} The effective date of the transaction effectiveDate {A5B03725-29E8-4602-99EF-5D6B017CDC61} Disputed transaction indicator isDisputed {87FFEBCE-7D8A-43e9-B86A-9CAE1A7C9ED5} A flag indicating whether there is a profile data associated with the PTB. isProfiled {0043A2F2-0C11-4dde-AAE2-4FBFE8FFCB11} The company to which the PTB transaction is paid. paidTo {A2F93159-F7AE-49f5-B728-499D67E8D909} The previous bill period end date previousEnd {93B19D45-DB6F-441d-8037-22AB6AA9DB2A} The previous bill period start date previousStart {24584977-F3F7-4322-8337-DDE69F0B9863} The product identifier for determining the charge type of the transaction. productCode {946D6460-AA13-4fd1-9C14-FB2C4F0136F0} The company by which the PTB transaction service is provided. providedBy {BCA57DAF-B80D-43fe-9833-5B679A5924D0} The end date of service provided if periodic. serviceEnd {5ACC3A68-0553-44ce-AEE1-F887DC3C1A6E} The start date of service provided if periodic. serviceStart {A75B85E5-9173-4c00-9E35-1FDB45B8BEB0} The company to which the PTB transaction is sold. soldTo {018309D3-D3E4-4b53-A1E5-1A59148FF7A8} The time zone code timeZone {703AE722-EBA1-4181-A63A-2137BF1D86F3} The trade date tradeDate {BED316C1-0279-45c5-9CD6-13885D681E47} The date the transaction occurs. transactionDate {3373C7E9-541F-4d9e-B528-41659363E0BD} The type of transaction. For example charge customer bill customer matching ARAP or bill determinant transactionType {74C3F782-FFCF-4b21-AF40-993488E13AA1} Whether scalars should be applied before adding the offset. multiplyBeforeAdd {83C1E126-7DDD-4e2e-85AF-78085F9723B2} if applicable Offset to be added as well as multiplication using scalars. offset {EA7A005C-CC97-4edd-8D97-74A85EC5886C} if scalar is rational number When IntervalReading.value is multiplied by scalarNumerator and divided by this value it causes a unit of measure conversion to occur resulting in the ReadingType.unit. scalarDenominator {C1A0458B-7A3D-4f62-993F-38E046631ED5} if scalar is floating number When multiplied with IntervalReading.value it causes a unit of measure conversion to occur according to the ReadingType.unit. scalarFloat {2EEB0DE4-0F59-4edb-B66B-FB396D661124} if scalar is integer or rational number When the scalar is a simple integer and this attribute is presented alone and multiplied with IntervalReading.value it causes a unit of measure conversion to occur resulting in the ReadingType.unit. It is never used in conjunction with scalarFloat only with scalarDenominator. scalarNumerator {B46284FF-68CC-4b35-B805-E3951AC0FF64} Normally 0 to 100 on a defined base. value {3F3F1095-2284-438d-89FF-699BCA187532} Number of phase neutral and other wires retained. Constrains the number of matrix elements and the phase codes that can be used with this matrix. conductorCount {B1A3AD9B-B326-480a-AA6F-4905351CDB64} The number of units of time that compose an individual step within a period. resolution {C59B0D48-250B-476c-8861-BAA72529975E} Number of units of calculationIntervalUnit in the calculation interval. calculationIntervalMagnitude {8758B1AC-AAAC-4206-850C-762A4813E787} Persons first name. firstName {77ACE572-5BDF-44e9-86AF-2CD6B7F00B2C} Persons last family sir name. lastName {6008933E-3372-4111-A607-3913A72D8718} Middle names or initials. mName {BFBB68F0-9442-494c-9869-E5405B24DF65} A prefix or title for the persons name such as Miss Mister Doctor etc. prefix {3D223B70-2955-4e74-BE3B-0A1D5431442E} Special service needs for the person contact are described examples include life support etc. specialNeed {F0CB10E7-4D38-4338-9446-B7674F165FCD} A suffix for the persons name such as II III etc. suffix {F373226B-344D-4a68-941F-34FC1B8F696E} Identifiers of the person held by an organisation such as a government agency federal state province city county financial institutions etc. clientID {D6AB28EF-C4BC-4e52-BA86-C7503E3CF3A9} The matrix elements column number in the range 1 to row. Only the lower triangle needs to be stored. This column number matches ACLineSegmentPhase.sequenceNumber. column {CB6694A0-F76F-4b69-A8A9-C9CF26E64C78} The matrix elements row number in the range 1 to PerLengthPhaseImpedance.conductorCount. Only the lower triangle needs to be stored. This row number matches ACLineSegmentPhase.sequenceNumber. row {F247BE15-2165-4832-A1D5-8B27BFA58C2B} Market end time. marketEndTime {C29815A2-6145-4da0-82D4-0ADADBAA561D} Market start time. marketStartTime {83BFFE49-8403-4c46-985E-E97F6AB4F438} Planned event type. eventType {CAD4EB97-87C1-4e51-BB3D-276655328AB7} This is relative time so that this attribute can be used by more than one planned market. For example the bid submission is 10am everyday. plannedTime {72D70C55-CDFB-45f1-B022-D90F7749F6CF} The reason for the planned outage. reason {D3D3D4BC-E73E-4ed6-92E8-F8B34CB83F0D} If true this Pnode is public prices are published for DART and FTR markets otherwise it is private location is not usable by market for biddingFTRstransactions. isPublic {FCD2A273-D0AE-4f09-AD5C-518647CC1B46} Used to calculate participation of Pnode in an AggregatePnode. For example for regulation region this factor is 1 and total sum of all factors for a specific regulation region does not have to be 1. For pricing zone the total sum of all factors has to be 1. factor {6D45DB67-9BC8-4616-8785-C5DA2ED3C57A} Point of delivery loss factor podLossFactor {7E2A5978-D690-4c48-B58A-5172333C6EC9} Congestion component of Location Marginal Price LMP in monetary units per MW. congestLMP {10E2DDBC-3BE0-41c0-9D08-F72122EE2A46} Cost component of Locational Marginal Pricing LMP in monetary units per MW. costLMP {5CA45BDE-B3EE-445d-B09A-38C869DEDC50} Loss component of Location Marginal Price LMP in monetary units per MW. lossLMP {2A53042F-9FFE-482b-9540-07A923FA390E} Locational Marginal Price LMP MWh marginalClearingPrice {25A6BE2B-6BD5-4ceb-9061-670622A4DAD7} total MW schedule at the pnode scheduledMW {DFF61D74-0457-42b9-A4DD-DA9D29EE7948} updateTimeStamp {F67728DD-C968-43ed-9A18-71E32E8BC0F7} updateUser {5544800D-9E3A-4659-8499-6986D1B0338F} A sequential value representing the relative position within a given time interval. position {C0718C4B-0FC2-4f02-8F55-3C94CEC4FCA4} The quality of the information being provided. This quality may be estimated not available as provided etc. quality {6A1D771D-37FC-423d-9E77-E9187116DE69} Principal quantity identified for a point. quantity {21FE2306-1C79-43fe-BBF7-76B1C8FBF2B9} Secondary quantity identified for a point. secondaryQuantity {021826F6-FB21-4bee-8635-4F7E9AA94FA6} Local description for where this point of sale is physically located. location {5D2A71D2-A4AC-4e84-979D-13685AA51641} True if a block of material has been attached to base of pole in ground for stability. This technique is used primarily when anchors can not be used. breastBlock {30AFAE49-2B0A-47b7-9328-BD428DB18008} Pole class 1 2 3 4 5 6 7 H1 H2 Other Unknown. classification {BAB4B7EB-930D-44fd-A589-B10DCC774D48} The framing structure mounted on the pole. construction {3EF6E50E-8DEE-4fe4-B964-D1682D76405B} Joint pole agreement reference number. jpaReference {06F77118-1E08-4d94-BC09-89FA617E262C} Pole species. Aluminum Aluminum Davit Concrete Fiberglass Galvanized Davit Galvanized Steel Davit Primed Steel Davit Steel Standard Primed Steel Truncated WoodTreated WoodHard WoodSalt Treated WoodSoft Wood Other Unknown. speciesType {A3A888A4-81E0-4180-83EA-5F6B9F225CBD} Date and time pole was last treated with preservative. treatedDateTime {412A87B4-E7EF-4bd7-B3C5-EF21FFEBB774} Zerorelative sequence number of this group within a series of points used when there is a need to express disjoint groups of points that are considered to be part of a single location. groupNumber {A6E3E73C-A099-4fc2-87EF-CB70E39C88C2} Zerorelative sequence number of this point within a series of points. sequenceNumber {9C1FA17F-EC70-452a-9BD5-2F5E29234B28} X axis position. xPosition {2C06CBF6-1564-417b-98DF-24B9E0040DCC} Y axis position. yPosition {150622F9-462B-4479-9DC4-F9035E140110} if applicable Z axis position. zPosition {A0537144-D5D9-4a24-805C-D4478E98690C} PT accuracy classification. accuracyClass {1C83085C-B00F-4a08-84C9-31F4F8983620} Nominal ratio between the primary and secondary voltage. nominalRatio {D4188CEB-ABD3-4b22-B141-1014ED802DC2} Potential transformer PT classification covering burden. ptClass {C62F1ED6-7467-491d-B29E-5F1B02510E10} accuracyClass {8C1D4658-31A4-4086-92CE-6A4DC77A9842} ptClass {DCA7C549-ADFB-4652-B4F6-46DF54FCC43E} Threshold minimum power factor for this PricingStructure specified in instances where a special charge is levied if the actual power factor for a Service falls below the value specified here. powerFactorMin {70E9676C-0AF2-4361-BFE8-9B16613AF154} Value of uninterrupted service Cost per active power. valueUninterruptedServiceP {4971A693-EAA2-4b1e-99C6-28DD55F41187} Voltage imbalance violation cost Cost per unit Voltage. voltImbalanceViolCost {961C47D2-CA85-43a3-B68C-6517C5CFD16D} Voltage limit violation cost Cost per unit Voltage. voltLimitViolCost {BD023A28-FD65-4e2f-9B29-14182FA848AF} The date the Power System Project is in cancelled stage. cancelled {150F5E1E-AFD4-435f-B79F-AE23D38D4BB3} The date Power System Project is in committed stage. committed {D6AFD0AA-BB96-4c65-A593-7C64982EE70B} The date Power System Project is in build stage. inBuild {D405B545-9121-4e8d-8DF6-0EFE787B1093} The date Power System Project is in planning stage. inPlan {A18B0A36-51D2-4823-85A1-2C9901BF89AE} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {2CF58DB7-BDAE-4e11-91A1-0651D6E514E3} Indicates whether the machine is part of a power station unit. Used for short circuit data exchange according to IEC 60909. It has an impact on how the correction factors are calculated for transformers since the transformer is not necessarily part of a synchronous machine and generating unit. It is not always possible to derive this information from the model. This is why the attribute is necessary. isPartOfGeneratorUnit {90536F90-2FEE-4023-A72F-58DACED054DC} It is used to define if the data other attributes related to short circuit data exchange defines long term operational conditions or not. Used for short circuit data exchange according to IEC 60909. operationalValuesConsidered {48CE1171-4EB3-4eb0-981D-28AE7ABB7F49} Vector group of the transformer for protective relaying e.g. Dyn1. For unbalanced transformers this may not be simply determined from the constituent winding connections and phase angle displacements.The vectorGroup string consists of the following components in the order listed high voltage winding connection mid voltage winding connection for three winding transformers phase displacement clock number from 0 to 11 low voltage winding connection phase displacement clock number from 0 to 11. The winding connections are D delta Y wye YN wye with neutral Z zigzag ZN zigzag with neutral A auto transformer. Upper case means the high voltage lower case mid or low. The high voltage winding always has clock position 0 and is not included in the vector group string. Some examples YNy0 two winding wye to wye with no phase displacement YNd11 two winding wye to delta with 330 degrees phase displacement YNyn0d5 three winding transformer wye with neutral high voltage wye with neutral mid voltage and no phase displacement delta low voltage with 150 degrees displacement.Phase displacement is defined as the angular difference between the phasors representing the voltages between the neutral point real or imaginary and the corresponding terminals of two windings a positive sequence voltage system being applied to the highvoltage terminals following each other in alphabetical sequence if they are lettered or in numerical sequence if they are numbered the phasors are assumed to rotate in a counterclockwise sense. vectorGroup {5A4A0AC2-AE76-4849-9563-015909DD9F2F} Terminal voltage phase angle displacement where 360 degrees are represented with clock hours. The valid values are 0 to 11. For example for the secondary side end of a transformer with vector group code of Dyn11 specify the connection kind as wye with neutral and specify the phase angle of the clock as 11. The clock value of the transformer end number specified as 1 is assumed to be zero. Note the transformer end number is not assumed to be the same as the terminal sequence number. phaseAngleClock {D2BA85F8-D4BC-4f1a-824A-2B7E701EC65B} value {E6D105E4-B62D-456f-B72A-2A29D839F0F6} A number of monetary units specified in a unit of currency. amount {093D3CF7-93B1-400b-9426-362029D0D0CA} The category of a price to be used in a price calculation. The price category is mutually agreed between System Operators. category {2969A791-6AF1-4569-BD54-318627ED9BF0} The direction indicates whether a System Operator pays the Market Parties or inverse. direction {B0A2D49B-B8F9-485a-891E-6C2C6F5D63E4} Unique userallocated key for this pricing structure used by company representatives to identify the correct price structure for allocating to a customer. For rate schedules it is often prefixed by a state code. code {D69394C5-9254-4968-8624-BC4F0A8239D9} Absolute maximum valid nondemand usage quantity used in validating a customers billed nondemand usage. dailyCeilingUsage {537108AF-E92B-4120-8500-6FB730ED517F} Used in place of actual computed estimated average when history of usage is not available and typically manually entered by customer accounting. dailyEstimatedUsage {147D3D24-7AA8-4bda-902C-28857A29E5D5} Absolute minimum valid nondemand usage quantity used in validating a customers billed nondemand usage. dailyFloorUsage {BB53179E-E177-4bed-81E1-1D2A773910A0} True if this pricing structure is not taxable. taxExemption {CD9823BB-8C78-4484-802F-E0335505EE26} Rating of prime mover. primeMoverRating {EE52178E-A51A-4d21-A4D8-6AFEE994F9BE} Justification for rank. justification {E98CF76B-FE70-427f-8547-BC61CF0E318A} Priority level usually lower number means high priority but the details are provided in type. rank {34AE2D85-7350-43ef-A7E5-D918200CF4B3} Type describing rank e.g. high emergency etc. type {8699FBAF-4C60-449d-92AA-F4FB4C3FB0D1} Textual description of this procedure. instruction {1A4ED9AF-6B28-41a2-A64E-A74330234D06} Sequence number in a sequence of procedures being performed. sequenceNumber {C176AD36-9F60-4752-AAE9-81D507A41D14} Date and time procedure was completed. completedDateTime {AD226C7F-6B32-415b-83A2-B560CDB67DF9} The classification mechanism used to group a set of objects together within a business process. The grouping may be of a detailed or a summary nature. classificationType {61387D64-75FE-465e-AE65-F9434CE76E10} The kind of business process. processType {12B4C7F6-B24F-4264-8F27-F6E29F1654A2} Catalogue number for asset model. catalogueNumber {EE84D526-AF29-4f56-9971-17AFD121273B} Drawing number for asset model. drawingNumber {F79043A4-2C5B-49b3-A559-892C475DE663} Reference manual or instruction book for this asset model. instructionManual {5711572B-2381-4651-9992-19951B55C9EB} Manufacturers model number. modelNumber {9F9D99E2-BF4E-480c-9F36-DF6232678DEA} Version number for product model which indicates vintage of the product. modelVersion {76499278-B021-4ccb-B94F-2C4908D322D3} Style number of asset model. styleNumber {5F872A8E-C74B-4058-A791-716B9882F1C0} Bid price associated with contract bidPrice {4AA91973-E36C-4ae3-9451-383F39170A32} Minimum MW value of contract minimumLevel {A210469E-9305-4eab-8768-B792209F6735} Sequence to provide item numbering for the profile. greater than or equal to 1 sequenceNumber {DFBD0BCA-7A15-428b-8CAA-C0071658D5A8} Start datetime for this profile. startDateTime {9A0143AA-454E-43a7-8B4F-02E8451D11D4} Stop datetime for this profile. stopDateTime {EC1FE564-537B-457b-901F-3A1768B35980} A code that identifies appropriate type of property accounts such as distribution streetlgihts communications. accountingUsage {F42341DB-C87A-4945-85EE-1D388CA6FEED} Used for property record accounting. For example in the USA this would be a FERC account. propertyAccount {D29FBA1B-4BB1-41a0-8C1A-B3B23AD2BC15} Boolean parameter value. If this attribute is populated integerParameterValue and floatParameterValue will not be. booleanParameterValue {0E61FD56-554E-465d-9AE4-9B289A8647BD} Floating point parameter value. If this attribute is populated booleanParameterValue and integerParameterValue will not be. floatParameterValue {12110E5F-7A18-491a-A9E1-3A586ED32A40} Integer parameter value. If this attribute is populated booleanParameterValue and floatParameterValue will not be. integerParameterValue {A49DE176-514B-4da0-9F0A-5B915A3AAB6C} Sequence number of the parameter among the set of parameters associated with the related proprietary userdefined model. parameterNumber {0CC89B5C-41AC-4172-B1E6-4036410F4512} The maximum allowable value. highLimit {F305239C-BFB2-4371-8720-1F5DE2E09469} The minimum allowable value. lowLimit {0CC901DB-A2AB-42e4-9447-8FEA31CFCC0F} Direction same as positive active power flow value. powerDirectionFlag {AE7BDAEB-F6E5-4730-8A14-A04B9717DC86} The status of the class set by operation or by signal. Optional field that will override other status fields. enabled {D865239A-5B6F-4ce9-85AE-7E6B5A7A96A3} The defaultnormal value used when other active signalvalues are missing. normalEnabled {28D90BA4-7AA1-4abd-A99F-84AB484195BD} The adjustment is given in value of the active value. byValue {BE83ED67-773A-4e17-A1A4-29722A57B41C} If true the adjusted value is an reduction. Other wise it is an increase in the value. reduce {FB86C37D-8228-4030-B4E2-11825871E2BA} The adjustment is given by a new active value. setValue {67AC81F0-98D9-47c1-A1E3-123A05600F46} If true the equipment is put inservice otherwise outofservice. inService {21446F33-36FE-4e95-AC9C-E7CDCD153031} If true the regulator is put inservice otherwise outofservice no regulation. isRegulating {A38F654D-B5D9-4af7-BC01-CA61BB93F59F} The target value specified the new case input for the regulator. The value has the units appropriate to the mode attribute. The protective action does not change the mode attribute. targetValue {EE438BF0-AC2B-470b-8920-399AA23443FB} Frequency power input gain iKiisubFsubi. Typical value 5. kf {2378BC64-904B-4742-968C-88B7B0DE0F57} Shaft speed power input gain iKiisubomegasubi. Typical value 0. komega {7B6FCB6C-182B-4019-99E6-FFDCA615C6C1} Electric power input gain iKiisubPEsubi. Typical value 03. kpe {64AB48CF-15BC-479e-B61C-58A7E0889E4C} PSS gain iKsi. Typical value 1. ks {6D525B2C-F8A2-470f-A668-591EA55636C8} font color0f0f0fSignal selector iViisubADATsubi.fontfont color0f0f0ftrue closed generator power is greater than iPminifontfont color0f0f0ffalse open iPei is smaller than iPmini.fontfont color0f0f0fTypical value true.font vadat {AA0C65C3-4C07-4991-BC6C-2C4ABA6A7F8F} Selector iKdi. true esupsTdelaysup usedfalse esupsTdelaysup not used. kd {D55E3AF3-A9FB-42bc-B9B9-4C0D464475FA} Numerator constant iai. Typical value 1. a {B7B33888-E2AF-45a6-B135-551B74F620DE} Denominator order of ramp tracking filter imi. Typical value 5. m {717D2A5F-F7A9-4e1b-A6CF-344B5F3E957B} Order of ramp tracking filter ini. Typical value 1. n {803DB770-5743-45ce-8C20-834DD902F433} Selector for second washout enabling iCiisubTW2subi.true second washout filter is bypassedfalse second washout filter in use.Typical value true. ctw2 {77ABA1A5-FA04-4b6e-B43C-90B89FCB7A2A} Selector for frequencyshaft speed input iisFreqi.true speed same meaning as InputSignaKind.rotorSpeedfalse frequency same meaning as InputSignalKind.busFrequency.Typical value true same meaning as InputSignalKind.rotorSpeed. isfreq {9F8F44E6-304A-4c39-8C82-21430BA6C20D} Frequencyshaft speed input gain iKiisubFsubi. Typical value 5. kf {CDE15429-27DD-4cc9-B8D7-6ED31D5C5A9A} Electric power input gain iKiisubPEsubi. Typical value 03. kpe {777561DD-FD01-42dd-BB60-913009CC641A} PSS gain iKiisubPSSsubi. Typical value 1. kpss {4D072C18-30BD-47a1-9B59-8E3C6D1E470A} font color0f0f0fSignal selector iViisubadAttsubi.fontfont color0f0f0ftrue closed generator power is greater than iPminifontfont color0f0f0ffalse open iPei is smaller than iPmini.fontfont color0f0f0fTypical value true.font vadat {E97A15BF-11CB-48e4-ADB1-42C3481B5971} Denominator order of ramp tracking filter iMi. Typical value 5. m {B93F120F-4EF0-4a41-BE52-ADA74DB90957} Order of ramp tracking filter iNi. Typical value 1. n {CA27CFE3-AE81-41b1-A261-6E1387F96DFF} Notch filter 1 highfrequency band three dB bandwidth iBiisubwisubi. bwh1 {2675EA1B-FBB9-4735-8B95-407C9E7B3A1A} Notch filter 2 highfrequency band three dB bandwidth iBiisubwisubi. bwh2 {615AFDA6-AFB3-4fb3-9625-718C8690F956} Notch filter 1 lowfrequency band three dB bandwidth iBiisubwisubi. bwl1 {7DFB80FD-07F1-4bc0-B931-215326B06667} Notch filter 2 lowfrequency band three dB bandwidth iBiisubwisubi. bwl2 {F11DF8B0-D827-4b3d-9647-55148EFA678B} Notch filter 1 highfrequency band filter frequency iomegaiisubnisubi. omeganh1 {4DB867AF-870F-470b-9059-4A32463B5CDC} Notch filter 2 highfrequency band filter frequency iomegaiisubnisubi. omeganh2 {2A16CB89-49A7-4ad9-9089-C4482587A4BB} Notch filter 1 lowfrequency band filter frequency iomegaiisubnisubi. omeganl1 {BD409892-68E8-4297-9520-F5A83D9EB42E} Notch filter 2 lowfrequency band filter frequency iomegaiisubnisubi. omeganl2 {59E9B850-DEEE-45ab-9B6E-DFCD93F14A26} Digitalanalogue output switch iIswi.true produce analogue outputfalse convert to digital output using tap selection table. isw {C27FA3BA-6B34-46dc-B36E-55A47DA1FC69} Number of control outputs to average iNAVi 1 lt iNAVi lt 16. Typical value 4. nav {31B5D989-CCF9-49a6-AFDD-6AB512001E52} Number of counts at limit to active limit function iNCLi gt 0. ncl {6C9B718F-90B1-48af-86C8-580085DA9144} Number of counts until reset after limit function is triggered iNCRi. ncr {65B58BB6-AE01-46ba-A795-F48E009059B9} Lead lag gain iKDPMi. Typical value 0185. kdpm {66542AFA-D5FB-4dfc-99CF-9F4D42F1D8AD} Speed input gain iKi2i. Typical value 343. ki2 {AAC42C70-DBCC-4c70-9825-1DB568FE8022} Electrical power input gain iKi3i. Typical value 1145. ki3 {ABC6F786-28E7-4906-9560-E1C864D0D463} Mechanical power input gain iKi4i. Typical value 1186. ki4 {D68ED8AF-6E44-4d4a-94B7-8BB572908985} Represents the CA that issued the certificate. Defined to be per X.509. issuerName {F6EDACBE-9EC1-40a4-80CD-D45D3E4FE9E8} Is the serial number of the certificate per X.509 definition. serialNumber {A498CF92-3F35-4b46-802D-A4D028FD45A4} value {CE3523DF-2923-4c23-91A5-845194FD296B} value {E705B485-9C6E-487a-9192-A0D14EAC36FF} value {4E4ADD0A-674C-4e87-9434-5DF76BFA57D8} Qualification identifier. qualificationID {5E9C902C-045D-48a6-B432-756B5D6D2A1C} Measurement value may be incorrect due to a reference being out of calibration. badReference {582D1BE5-8C79-448e-83AE-473834C0380C} Value has been replaced by State Estimator. estimatorReplaced is not an IEC61850 quality bit but has been put in this class for convenience. estimatorReplaced {11CA6A0B-FEAC-41a0-AF45-AE159D352461} This identifier indicates that a supervision function has detected an internal or external failure e.g. communication failure. failure {2B640DD0-57EC-4c03-BF9A-B40906336431} Measurement value is old and possibly invalid as it has not been successfully updated during a specified time interval. oldData {4E74DF87-D586-4fdb-AFBC-968BDCC024A1} Measurement value is blocked and hence unavailable for transmission. operatorBlocked {2686EF18-BE9A-4037-8A3F-032FBE4AADD0} To prevent some overload of the communication it is sensible to detect and suppress oscillating fast changing binary inputs. If a signal changes in a defined time twice in the same direction from 0 to 1 or from 1 to 0 then oscillation is detected and the detail quality identifier oscillatory is set. If it is detected a configured numbers of transient changes could be passed by. In this time the validity status questionable is set. If after this defined numbers of changes the signal is still in the oscillating state the value shall be set either to the opposite state of the previous stable value or to a defined default value. In this case the validity status questionable is reset and invalid is set as long as the signal is oscillating. If it is configured such that no transient changes should be passed by then the validity status invalid is set immediately in addition to the detail quality identifier oscillatory used for status information only. oscillatory {5785D8A1-BB09-466c-AF85-CB88C54AD5DC} Measurement value is beyond a predefined range of value. outOfRange {36E6C225-3F42-446f-873B-7CBAB71DE307} Measurement value is beyond the capability of being represented properly. For example a counter value overflows from maximum count back to a value of zero. overFlow {35920B57-826D-4b5d-A0CE-82526D3C7610} A correlation function has detected that the value is not consistent with other values. Typically set by a network State Estimator. suspect {F925B417-2665-40e7-89ED-F22698B8207E} Measurement value is transmitted for test purposes. test {7EA53CA3-B88B-4fd4-9AF5-E19B4AEF968F} The quality of the information being provided. This quality may be estimated not available as provided etc. quality {774A9E73-1211-41ac-9FA3-84A021D961B6} The description of the type of the quantity. type {3FD8967F-3245-42da-AA04-74A591D8C6BB} The lower of the original predispatch or the AC run schedule Also known as the RMR Reguirement becomes the predispatch value. manuallySchedRMRMw {A2808980-CA85-4214-93B7-9B7A14DD9390} updateTimeStamp {5B402505-B4A2-4efe-9D55-4C2F1584727A} updateUser {02D681C8-3711-4db3-9E3A-2D2711133823} The RUC Award of a resource is the portion of the RUC Capacity that is not under RA or RMR contracts. The RUC Award of a resource is the portion of the RUC Capacity that is eligible for RUC Availability payment. RUCAward {71BE92A8-A6C5-48dd-B61E-36949755A7E3} The RUC Capacity of a resource is the difference between i the RUC Schedule and ii the higher of the DA Schedule and the Minimum Load. RUCCapacity {A2D6DE99-A9AF-4fcb-9236-61917FC1B04D} The RUC Schedule of a resource is its output level that balances the load forecast used in RUC. The RUC Schedule in RUC is similar to the DA Schedule in DAM. RUCSchedule {9E6AF283-3DFB-4b39-8901-F1E959B507AE} Marginal Price MW for the commodity Regulation Up Regulation Down Spinning Reserve or Nonspinning reserve for pricing run. clearedPrice {2F105D8E-3556-4cff-9B40-4402DD0A4003} updateTimeStamp {8DA426EB-C242-4ee0-8E31-BF5E091E032E} updateUser {3AF4D1F8-78EF-471b-A419-C380C928168E} The part of a fraction that is below the line and that functions as the divisor of the numerator. denominator {A4EB68EF-AC41-4b3b-9CF6-C2CF14199F79} The part of a fraction that is above the line and signifies the number to be divided by the denominator. numerator {36E8CBA1-3ED7-4c9f-9581-27EE38B0548A} Denominator. Value 1 indicates the number is a simple integer. denominator {145A5952-26F7-4fd2-9E3E-2176EC9E136E} Numerator. numerator {FDE93DE3-8CB5-447a-8501-F904B30B9C93} value {1010C898-C3A2-45b0-BF5D-C0DEDEBA27CC} value {7CA4EC71-C6F8-4e22-96E2-19908B0F8533} value {4AEEBF1D-260E-4615-95F2-8219EA8B0AC9} A sequential value representing the relative position within a given time interval. position {9FF69212-92EE-40eb-9A7A-4755584F2062} The indication of whether or not the quantity of this reading is missing. valueMissing {87C7729A-76FC-44d1-9036-A16C057BA3AC} Interharmonic denominator. Value 0 means not applicable. Value 2 is used in combination with numerator1 to represent interharmonic 12. Finally value 1 indicates the harmonic of the order specified with numerator. denominator {49AC48A8-C21C-4f72-A178-D6F5B3ED0F43} Interharmonic numerator. Value 0 means not applicable. Value 1 is used in combination with denominator2 to represent interharmonic 12 and with denominator1 it represents fundamental frequency. Finally values greater than 1 indicate the harmonic of that order e.g. numerator5 is the fifth harmonic. numerator {7742BFFE-803C-4bbf-B91F-FE668C04F2A2} Elaboration on the quality code. comment {70A62C61-5CCF-4dfa-AEC3-F2DB1C8B9FCE} System acting as the source of the quality code. source {35498F43-1567-4243-841C-F5B36900D0BC} Date and time at which the quality code was assigned or ascertained. timeStamp {7C91965E-E991-46ba-9581-AB42B2D25ED2} Highlevel nature of the reading value quality. category {9D0C1E50-B838-4a7f-BA20-80BC82A0EAE1} More specific nature of the reading value quality as a further subcategorisation of category. subCategory {8A882F61-9C1B-4509-A272-B3F0B4FC1B35} Identification of the system which has declared the issue with the data or provided commentary on the data. systemId {30D4236C-A6CA-4da6-838F-E93C16488524} In case of common flatrate pricing for power in which all purchases are at a given rate consumptionTier0. Otherwise the value indicates the consumption tier which can be used in conjunction with TOU or CPP pricing.Consumption tier pricing refers to the method of billing in which a certain block of energy is purchasedsold at one price after which the next block of energy is purchased at another price and so on all throughout a defined period. At the start of the defined period consumption is initially zero and any usage is measured against the first consumption tier consumptionTier1. If this block of energy is consumed before the end of the period energy consumption moves to be reconed against the second consumption tier consumptionTier2 and so on. At the end of the defined period the consumption accumulator is reset and usage within the consumptionTier1 restarts. consumptionTier {D3DFD4F3-FBD6-4571-8EBE-16EA045C41B4} Critical peak period CPP bucket the reading value is attributed to. Value 0 means not applicable. Even though CPP is usually considered a specialised form of time of use tou this attribute is defined explicitly for flexibility. cpp {C90C5422-85AD-4377-A645-13F05385F2DD} Time of use TOU bucket the reading value is attributed to. Value 0 means not applicable. tou {6162A0BD-1069-4a6a-950C-3357F81CAC99} value {2E378A28-DBB2-43ee-8264-7E45516E19A6} The motivation of an act in coded form. code {FA6537D4-73E8-4c30-A0C3-97EECD3B4E0F} The textual explanation corresponding to the reason code. text {495E50E9-E07A-4efc-9BC6-33E038B922A8} True if this receipted payment is manually bankable otherwise it is an electronic funds transfer. isBankable {F4F0A1B0-D6E4-47c9-9CC4-FB8068A6A1B1} Indicates the ordinal position of the reclose step relative to other steps in the sequence. recloseStep {033893EA-F93E-47ab-94D1-44CA5A3A9B3E} True if device has ground trip capability. groundTripCapable {CA6614F0-C969-4936-8DC9-0ABB40F4FC67} True if normal status of ground trip is enabled. groundTripNormalEnabled {2A70FE76-7BA5-4fee-A631-C63A925D146C} Total number of phase reclose operations. recloseLockoutCount {198AD782-D482-4539-9247-444F63DAC611} Date and time this reconditioning or a major overhaul has been performed. dateTime {3CF26758-DE94-4d2c-8CCD-B17805B8B735} If true the data it produces is calculated or measured by a device other than a physical end devicemeter. Otherwise any data streams it produces are measured by the hardware of the end devicemeter itself. isVirtual {CF6AB1A8-2466-441b-B0CD-5A13A1C96F18} Number of digits dials on a mechanical meter to the left of the decimal place default is normally 5. leftDigitCount {0C46D2F4-7F7D-4a85-9181-639F99A65B64} Number of digits dials on a mechanical meter to the right of the decimal place. rightDigitCount {82C8EB70-469E-40ef-AF09-9F6F894F8B7C} Name used for the time of use tier also known as bin or bucket. For example peak offpeak TOU Category A etc. touTierName {32DEC698-03EA-4e54-8CE4-F17B3B0DEED9} Maximum Deployment time seconds maxDeploymentTime {B382B0B7-51E3-4950-8687-2B6CF311FC6B} Maximum Number of Daily Load Curtailments maxLoadRedTimesPerDay {E674CF02-214F-43da-9D38-65E1C1CD5802} Maxiimum Load Reduction Time min per Participating Load Resource maxReductionTime {EB7D903B-8CA2-40f2-A072-0D141306182D} Maximum weekly deployments maxWeeklyDeployment {4B24096C-A269-473e-9B4C-85C8368605EB} Shortest period load reduction shall be maintained before load can be restored to normal levels.This attribute may be used also in the LoadBid class. The reason that the attribute is also modeled in this class is that it is resource attribute and needs to be persistently stored. minLoadReductionInterval {C8DAD1E4-E0F9-4229-BB1C-8600DB1ED3A7} Minimum Load Reduction Time min per Participating Load Resource minReductionTime {91BDAD99-21F3-4469-8FB0-74C9C925AC3A} Shortest time that load shall be left at normal levels before a new load reduction.This attribute may be used also in the LoadBid class. The reason that the attribute is also modeled in this class is that it is resource attribute and needs to be persistently stored. minTimeBetLoadRed {0226735F-400B-493e-A677-B903D7D9A44F} Time period that is required from an order to reduce a load to the time that it takes to get to the minimum load reduction.This attribute may be used also in the LoadBid class. The reason that the attribute is also modeled in this class is that it is resource attribute and needs to be persistently stored. reqNoticeTime {0F7AAB35-BDF0-4789-AD7C-07C6263CCF50} The type of resource. Examples include fuel cell flywheel photovoltaic microturbine CHP combined heat power V2G vehicle to grid DES distributed energy storage and others. distributedResourceType {3770DAEC-B840-42bc-8683-D8D066430891} Cold start time. coldStartTime {55DADDB4-933C-4a86-A544-9FCD2CA48A5B} Combined Cycle operating mode. combinedCycleOperatingMode {6C4CDF5B-6F78-424b-B261-BC591BC28AAA} commericialOperationDate {575F85C6-CB48-4afb-9162-7E5DDDEE4597} Hottointermediate time Seasonal hotIntTime {671490F2-F524-4f1b-A324-CE1C3A22D844} Hot start time. hotStartTime {7BA1B678-5518-48e3-980F-8ADB910F538A} Intermediatetocold time Seasonal intColdTime {3E621176-FEEA-4dfe-8B87-61BA584EC297} Intermediate start time. intStartTime {0D984EBD-23EF-420b-9A92-B551BCB95B2A} Maximum time this device can be shut down. maxShutdownTime {41C3CAA0-F9ED-4350-80C3-A9FBB0A869EA} maximum start ups per day maxStartUpsPerDay {43C52424-21B1-4eac-A46D-CBB8C58FA214} Maximum weekly Energy Seasonal maxWeeklyEnergy {EF663956-1740-4c10-9C6E-5FD57EBC15A3} Maximum weekly starts seasonal parameter maxWeeklyStarts {63EFF7D9-B987-40cd-9AB4-A595A971CCF6} The minimum down time for the pump in a pump storage unit. pumpMinDownTime {C3675AC0-83FD-4fc7-A697-7460E98F2350} The minimum up time aspect for the pump in a pump storage unit pumpMinUpTime {6D1D0FE7-CD49-421c-9C67-8A67B578F16F} The cost to shutdown a pump during the pump aspect of a pump storage unit. pumpShutdownCost {7C3DA9D2-0B67-4f08-8358-91C0865EBA3B} The shutdown time minutes of the pump aspect of a pump storage unit. pumpShutdownTime {0E6008BD-3F09-4fb0-A4A3-BDB33A785952} Pumping factor for pump storage units conversion factor between generating and pumping. pumpingFactor {85DD50DF-7E72-4c12-8CFB-94D0AB67387C} Unit sub type used by Settlements or scheduling application. Application use of the unit sub type may define the necessary types as applicable. resourceSubType {DFD2F0AB-1EC2-4a4f-BF3C-C7517FF6B7BA} River System the Resource is tied to. riverSystem {FDA2AAAD-2687-4c40-B5A8-3E867E1FB114} The registered upper bound of minimum hourly block for an InterTie Resource. minHourlyBlockLimit {579E27F1-EBCA-4136-838A-7079038B27E6} Emergency operating procedure Flag to indicate that the Resource is Block Load pseudo resource. blockLoadTransfer {D80F0D1D-7B48-4f6d-817C-381D56650C1B} Flag to indicate that a Load Resource is part of a DSR Load dynamicallyScheduledLoadResource {C7EDCE9D-6572-4374-BF92-15DCFFA76779} Qualification status used for DSR qualification. dynamicallyScheduledQualification {8DCCFA7B-9490-4f7a-85EF-F3563FC8FC10} Resource Commercial Operation Date. commercialOpDate {2FDEC1B4-8E91-484e-B928-840F66A0E464} Dispatchable indicates whether the resource is dispatchable. This implies that the resource intends to submit Energy bidsoffers or Ancillary Services bidsoffers or selfprovided schedules. dispatchable {F6634618-C613-4d63-A779-A43466A8A2EA} Indication of the last time this item was modifiedversioned. lastModified {85FE9965-750B-4bc6-8892-7925D53FB7DA} Maximum base self schedule quantity. maxBaseSelfSchedQty {CFAE5BB4-CC53-40d3-B79C-8DAFD6471B3D} Maximum on time after start up. maxOnTime {90FA8FE0-BBF5-4999-8DE0-70A1ABE1C277} Minimum off time after shut down. minOffTime {2CCCFAE5-2140-4752-B889-41975A150FD4} Minimum on time after start up. minOnTime {9A51BD09-304A-4402-83AA-A354109614B7} The time for the last time point. The value can be a time of day not a specific date. endTime {61C25045-8C8B-4bb8-82A6-5BCDA64CC9E9} The position of the regular time point in the sequence. Note that time points dont have to be sequential i.e. time points may be omitted. The actual time for a RegularTimePoint is computed by multiplying the associated regular interval schedules time step with the regular time point sequence number and adding the associated schedules start time. To specify values for the start time use sequence number 0. The sequence number cannot be negative. sequenceNumber {D417E462-D31A-4df8-9912-76A29BFACE60} The first value at the time. The meaning of the value is defined by the derived type of the associated schedule. value1 {DD725FB3-91EB-480f-A9B0-355AEBE4CD7D} The second value at the time. The meaning of the value is defined by the derived type of the associated schedule. value2 {CD812D5E-3799-4584-A7DC-4EBBB72838A2} Specifies the regulation status of the equipment. True is regulating false is not regulating. controlEnabled {59FD3220-4AC6-4fe5-ADDE-2317ACD8F701} The regulation is performed in a discrete mode. This applies to equipment with discrete controls e.g. tap changers and shunt compensators. discrete {402FA12A-ED05-4ef2-812F-3C26BB27936D} The flag tells if regulation is enabled. enabled {BB18638D-6DC9-43a9-8631-380ED5BF18B6} Maximum allowed target value RegulatingControl.targetValue. maxAllowedTargetValue {2417F359-3B33-4d71-B942-17654980DAEB} Minimum allowed target value RegulatingControl.targetValue. minAllowedTargetValue {B5AC0B65-B094-4d23-AB5D-FA9F1CF06D2D} This is a deadband used with discrete control to avoid excessive update of controls like tap changers and shunt compensator banks while regulating. The units of those appropriate for the mode. The attribute shall be a positive value or zero. If RegulatingControl.discrete is set to false the RegulatingControl.targetDeadband is to be ignored.Note that for instance if the targetValue is 100 kV and the targetDeadband is 2 kV the range is from 99 to 101 kV. targetDeadband {646962B2-3D10-4e78-AA89-12D0A41BB43B} The target value specified for case input. This value can be used for the target value without the use of schedules. The value has the units appropriate to the mode attribute. targetValue {9827F679-5CE0-4b9e-A7B4-219CE46E466E} External reference to regulation if applicable. referenceNumber {E8BF8D7C-52A6-44f5-94F6-813D4E29DFAF} The status of the class set by operation or by signal. Optional field that will override other status fields. armed {58ABBE6F-7A04-4f65-AD37-59F30A3EAE25} The defaultnormal value used when other active signalvalues are missing. normalArmed {2827FCA9-9331-4e93-B76E-64863E83F1BE} Start date and time to accumulate energy for energy usage limiting. energyUsageStartDateTime {F216C778-14EB-4a6b-9849-48FF9D3134DC} True if the RCD switch has to be armed before a connect action can be initiated. isArmConnect {769AA1A6-92ED-433b-9656-55D6CCFEBBEC} True if the RCD switch has to be armed before a disconnect action can be initiated. isArmDisconnect {C3EEB2B3-7543-4772-9D3B-A74F816E14AF} True if the energy usage is limited and the customer will be disconnected if they go over the limit. isEnergyLimiting {04D0341F-B9A4-45ad-BBE8-E0D248CAD27E} True if load limit has to be checked to issue an immediate disconnect after a connect if load is over the limit. needsPowerLimitCheck {98D652DA-9D08-4295-96AC-42032A79EED0} True if voltage limit has to be checked to prevent connect if voltage is over the limit. needsVoltageLimitCheck {41E919E1-537B-4949-96DE-FFED2398781F} True if pushbutton has to be used for connect. usePushbutton {4AA773BF-F3A0-405b-98D0-924F2EF833B0} The maximum set point value accepted by the remote control point. actuatorMaximum {9C84D7FF-1A6A-4b41-8F8E-D374F4363CF5} The minimum set point value accepted by the remote control point. actuatorMinimum {10CD0F3E-58E3-4bf1-BB58-7A366E82D25F} Set to true if the actuator is remotely controlled. remoteControlled {FA37D934-7FD5-42d3-A3E1-0555712A3E28} The smallest change in value to be reported. deadband {BAE984E8-5AEC-4b3e-9F90-D74CB4BFC16D} The maximum value the telemetry item can return. sensorMaximum {4A4526F8-4FB1-43e3-B075-01846E1D7CB4} The minimum value the telemetry item can return. sensorMinimum {446E8C3F-540A-4d66-B8FD-6E6C80778117} Repair work is emergency. emergency {8105B867-4116-4fa0-8FD3-2A26CD2D1908} Number of units of time making up reporting period. reportingIntervalPeriod {D89FAACB-360E-4e4b-8B4A-1F1D663BED88} Region requirement maximum limit reqMaxMW {9B957A18-FA2C-4e5b-89B2-04F0F9CBF0AB} The reservoirs energy storage rating in energy for given head conditions. energyStorageRating {1D2BE652-8A84-4e0e-90BF-6F21AFAB9A43} River outlet works for riparian right releases or other purposes. riverOutletWorks {7EBFA889-4712-41d3-B241-79E6305E7F5C} Type of spillway gate including parameters. spillWayGateType {AB355717-E841-4fab-A383-63221736524B} The flow capacity of the spillway in cubic meters per second. spillwayCapacity {6CB37874-BA9F-402a-8347-B283B4018E42} value {CFCFA1A2-5401-4f99-81B4-5B5441697F60} value {E4ECE412-83A1-4181-9E29-DE88C54FB005} For DA Energy Not Applicable For DA AS DA AS market award For RT Energy Not Applicable For RT AS RT AS market award excluding DA AS market or selfproviison awards awardMW {DDF5155C-7ADB-4765-9F4D-79D446AA3E15} For DA Energy Total Schedule DA market schedule DA selfschedule award For DA AS DA Ancillary Service Awards DA AS market award DA AS selfprovision award For RT Energy Total Schedule RT market schedule RT selfschedule award For RT AS RT Ancillary Service Awards RT AS selfprovision award RT AS market award DA AS market award DA AS selfprovision award clearedMW {F1EF86CD-0F8C-4bf0-9598-9A2E5839A8DF} Marginal Price MW for the commodity Regulation Up Regulation Down Spinning Reserve or Nonspinning reserve for pricing run. clearedPrice {3C4B6A18-98AF-44e6-ACD2-E0E33BA5F454} Congestion component of Location Marginal Price LMP in monetary units per MW. congestLMP {1ACC24CD-B067-48ea-BF42-D0F3E60E2AAA} Cost component of Locational Marginal Pricing LMP in monetary units per MW. costLMP {EF90FDB3-6B4F-4211-9032-A5260C2CE544} The tier2 mw added by dispatcher action Market results of the synchronized reserve market dispatcherAddedMW {4589CF1B-6953-4fd6-A105-94B8591615FD} Unit max output for dispatch bid in economic maximum economicMax {3865BBAC-DCEE-4491-AFDE-78A85BEAFCF0} Unit min output for dispatch bid in economic minimum economicMin {5233C78D-D315-4fab-8FEC-26CE3FABB2BB} Effective Regulation Down Limit MW effRegulationDownLimit {22C31833-2561-4c7c-B3EA-89C1887C0D3F} Effective Regulation Up Limit effRegulationUpLimit {362F41FC-F626-4618-9DA9-277C1893D45E} Locational marginal price value lmp {FB783ECF-8292-41c6-894E-3F08E8C34352} Loss component of Location Marginal Price LMP in monetary units per MW. lossLMP {0100A689-A0BD-43b8-98B5-4D4C6E9A744B} Identifes if the unit was set to must run by the market participant responsible for bidding in the unit mustRunInd {CE54EA35-91CE-4164-8386-6CD7677B396D} Unit noload cost in case of energy commodity noLoadCost {0E84CFF5-BC9F-4ab1-980C-284BA4094975} Optimal Bid cost optimalBidCost {52A9E0B8-201C-4bec-AFCD-D84970F19B1B} Optimal Bid production payment based on LMP optimalBidPay {49138345-8B7D-42fc-832B-FD520990A380} Optimal Bid production margin optimalMargin {4427C4F6-B930-4200-BA27-3838EA614C3C} Time the manual data entry occured. overrideTimeStamp {248A703B-93F7-4efe-9677-AE0719CBEAAF} Provides the ability for the grid operator to override items such as spin capacity requirements prior to running the algorithm. This value is market product based spin nonspin reg up reg down or RUC. overrideValue {13C37DBA-DFBE-4ac9-B6B9-01E577C1C48A} For DA Energy DA total selfschedule award For DA AS DA AS selfprovision award For RT Energy RT total selfschedule award For RT AS RT AS selfprovision award excluding DA AS market or selfprovision awards selfSchedMW {AE99FBCA-3164-4617-846D-3AE4E37D95DF} Unit start up cost in case of energy commodity startUpCost {2118CDF6-D1DC-4fb6-AC62-ED6C99D388CB} In or out status of resource status {5FC8CE0E-5BBC-4e32-96CF-6FD600EE7E46} Total bid revenue startupcost noloadcost bidpay totalRevenue {5EFDBD3B-8BBC-4a90-BE3C-FA6B7ED2FAB8} updateTimeStamp {D698BA1F-C17D-4b3a-810B-188C939FFBA3} updateUser {51EC4729-6EE5-46a1-BB01-BEBCD7AB9FC8} Aggregation flag 0 individual resource level1 Aggregated node location2 Aggregated price location aggregationFlag {ADCA44B4-F70B-4cf1-99D9-4DC77D16C58A} bidStatus {FF7D5213-9A5C-4e42-B4CB-602B14231EB9} Energy product commodity typeEn EnergyRu Regulation UpRd Regulation DnSr Spinning ReserveNr NonSpinning ReserveOr Operating Reserve commodityType {2A4E8B9E-09B9-4ab5-AD3C-824B273E244C} Maximum amount of energy per day which can be produced during the trading period in MWh energyMaxDay {F7C84694-DB91-4eb1-82C4-AD1F1E694754} Minimum amount of energy per day which has to be produced during the trading period in MWh energyMinDay {615993D8-50ED-4b05-81CC-1FC8920F7F7E} Market Separation FlagY Enforce market separation constraints for this bid N Dont enforce market separation constraints for this bid. marketSepFlag {5FEBDCB4-33ED-4e5d-8B5D-5123E4D42D0C} minimum number of consecutive hours a resource shall be dispatched if bid is accepted minDispatchTime {82365FB4-2245-460d-AC6F-AF51E20AC6CC} Resource loading curve type1 stepwise continuous loading2 piecewise linear continuous loading3 block loading resourceLoadingType {E1EA6B39-8FCD-4ca6-AEB3-4E94CC2BA39D} Maximum number of shutdowns per day. shutDownsMaxDay {FD4FA6A5-B41D-4f40-BF5A-6F73264A5351} Maximum number of shutdowns per week. shutDownsMaxWeek {ECA28A83-21C7-4374-BCFF-A2E0EBB0C5AE} Maximum number of startups per day. startUpsMaxDay {1A5E0B1D-1F7B-45ec-AD37-9486A5DAE136} Maximum number of startups per week. startUpsMaxWeek {A2C524DD-3E89-4ee6-A3F3-EE04391BAE00} True if bid is virtual. Bid is assumed to be nonvirtual if attribute is absent virtual {98F6EA70-2C46-4f1e-9C33-1E15BF19A672} default capacity defaultCapacity {C2275FAB-0D52-42e4-A22C-B4F01D679FC9} maximum capacity maximumCapacity {BEC12E36-9DD8-4453-A2E3-ECF2BE7B809B} minimum capacity minimumCapacity {96DABEB7-8FA8-4024-86D1-0A373E197A65} certifiedNonspinDAMMw {6E426F03-5FF9-49e2-A8CC-772C1AB6CACD} certifiedNonspinRTMMw {3EEB6939-937D-4e80-971F-700A2705810F} certifiedRegulationMw {683A2BDB-72E0-4fb5-A4B4-630B3330583D} certifiedSpinMw {59B16A92-7E6F-4262-BD9B-BF243E9CC8CF} Commenst to explain why the acceptance status. For example to explain why a request is accepted only partially instead of fully. acceptComments {071472A2-95C2-4487-BEA5-36B81DA0EA14} Status of the resource for this deployment. Values include full compliance partial compliance optout etc. acceptStatus {74B3E3A5-8518-460d-A811-A29A5EA0DAE2} The MW amount the resource can contribute for this deployment. This is from the DR provider as a response? Or actual? Does this belong in settlement? Discuss more. resourceResponseMW {BB9F2DF9-A29D-4b23-B704-ADDA3368D33C} Blocked Dispatch Indicator YesNo blockedDispatch {F45560E7-C484-4d1c-8442-D6425F9892FB} Block sending DOP to ADS YN blockedPublishDOP {88AC4A3E-72EA-4c21-A33D-FEFD90EA6C57} indicate which limit is the constraints limitIndicator {AA50B2D0-8923-4cd8-9429-A7D14A634B68} resource energy ramping lower limit lowerLimit {9C7BABEC-986F-421d-AF6E-6B3125993011} maximum ramp rate maxRampRate {F1C7971F-A992-47b2-8F90-61CC230005EF} The upper operating limit incorporating any derate used by the RTD for the Binding Interval. operatingLimitHigh {1988C90A-D81F-4a7c-B4E6-85926DD9958C} The lower operating limit incorporating any derate used by the RTD for the Binding Interval. operatingLimitLow {445A99E4-58EB-4f71-A8B6-3B1F3878DE32} The upper regulating limit incorporating any derate used by the RTD for the Binding Interval. regulatingLimitHigh {5E47AAEE-B818-4566-BEE3-5AA342C03186} The lower regulating limit incorporating any derate used by the RTD for the Binding Interval. regulatingLimitLow {59894E81-264B-4e51-8021-B3C866860399} Unit Commitment Status OnOffStarting resourceStatus {E769D448-0F9E-4692-AF68-37EF2A390125} Resource total upward schedule. total schedule En all AS per resource per interval totalSchedule {B49A640A-567A-48a0-9311-3BFE7E9D520D} updateTimeStamp {830328A6-BFCA-44c7-B15A-F7B020B2CF22} updateUser {18985560-A22C-4af8-924A-51128A1A107E} resource energy ramping upper limit upperLimit {B9E153D6-DE03-48d7-8FB6-6092A296706D} Type of this group. type {0700679C-348D-4223-95FA-6F09D0F33822} weighted average for RTPD and RTCD and same for RTID calcLoadFollowingMW {AF0EA6D5-8552-4efe-8E78-898FA26C784A} dispWindowHighLimt {F770DB06-A853-49ca-8E7B-9A20A6D70761} dispWindowLowLimt {6C95510E-A69C-461a-B3FC-A8AFEC15CF6D} Unique instruction id per instruction assigned by the SC and provided to ADS. ADS passes through. instructionID {E84B0DD5-1BF5-496c-AE29-1D68FE6213CB} The start of the time interval for which requirement is defined. intervalStartTime {9A521D60-DD0F-4952-9DC3-615DA76AA593} Verifiable OampM Cost Cold Startup omCostColdStartup {192181D3-5752-4176-B9AB-C6302A3718C5} Verifiable OampM Cost Hot Startup omCostHotStartup {8DFEECE8-B042-475e-990B-72239D26F922} Verifiable OampM Cost Intermediate Startup omCostIntermediateStartup {2664C4FC-E547-4560-AE20-8BAD0B351540} Verifiable OampM Cost MWh LSL omCostLowSustainedLimit {7041420E-BF06-43f3-A6BC-CEFF49297FD2} effectiveEndTime {7FD9D769-A9D2-4a2b-A613-6037499A8EA3} effectiveStartTime {8D8E2D4C-45E4-4137-80AF-C97E8C59F783} Description of the performance evaluation e.g. the rating classification used any is allowed why the evaluation was performed anything that describes the demand response performance evaluation. evaluationDescription {06147450-AB8F-4d4c-95F9-7DB957E38F03} The value of the performance. as a String any rating scheme is supported e.g. 123 or low medium high. The rating scheme is described in the performanceValueDescription attribute. evaluationValue {A2968EE8-F705-4159-B2B2-3D6400EE0CDD} Description name of the property factor. factorDescription {EF857CC6-C883-4932-95E3-24170CA6F026} Value of the property factor. factorValue {6A7FFF8B-D38A-42a9-879B-753D3EA7EF97} starting date time that the rating is valid for effectiveEndTime {C60BBE60-37A8-44f7-ABA1-6757B5B5A81D} ending date time that the rating is valid for effectiveStartTime {20A6C9E3-1013-4169-A977-7E546A121FD1} the resources demand response rating description ratingDescription {BF37DE31-A90A-427f-BF6C-18DC0345ED41} the type of performance rating e.g. which market or product the rating is for ratingType {507F1297-FEA1-492a-B1BC-202A2823C377} the resources demand response rating ratingValue {AB1B47CB-4A31-4075-9D20-5F66F2E158A5} Type of the time series data e.g. baseline data meter read data computed performance data. timeSeriesDataType {BE982C80-8088-4d8c-90E4-9A0AB614CB3C} Optional description of the time series data e.g. baseline data meter read data computed performance data. timeSeriesDescription {C1E10AC6-1873-4410-BE43-9272E11DABCC} Description for the value1 contained within the TimeSeriesFactor. value1Description {69E44D0D-778E-4bc2-AE74-5889B34EDF93} Description for the value2 contained within the TimeSeriesFactor. value2Description {1C8CBF64-452D-4e3b-A419-FE070A275E55} Verifiable Cold Start Up Fuel MMBtu per start fuelColdStartup {AAB81330-0690-437e-AC43-34D7ECC143A5} Verifiable Hot Start Up Fuel MMBtu per start fuelHotStartup {0497A286-D1FE-4e14-9F32-3FEDC9F2C7A7} Verifiable Intermediate Start Up Fuel MMBtu per start fuelIntermediateStartup {E291E0BD-C737-4cf6-B834-4576FEB6F50D} MinimumEnergy fuel MMBtuMWh fuelLowSustainedLimit {D92E6E6E-749A-4214-A715-D5E23AE0FE07} The active power value for the demand adjustment type. This supports requests to be made to a resource for some amount of active power provided by a particular response method as specified by the method attribute e.g. lighting HVAC wall mounted air conditioners etc.. activePower {5D0D596E-8538-4e65-872B-D9902186B04A} The unit of measure of active power e.g. kiloWatts kW megaWatts mW etc. activePowerUOM {0761A6BD-9504-4e76-95A0-9678E09FDE6B} The response method e.g. lighting HVAC wall mounted air conditioners etc.. method {4D5252AC-BF4D-49f4-AC51-C4E8C0640FC5} This value provides for scaling of a response methods active power. For example a response method of air conditioning could utilize a small amount of active power from each air conditioning unit e.g. 0.1 kiloWatt but the site multiplier could be used to produce a the total active power adjustment by multiplying the response method active power by this value e.g. a building with 100 window air conditioning units so 100 0.1 kW 10 kW. siteMultiplier {0214AFA0-EFD1-41c8-9164-F77472B5C51F} Property related information that describes the ROWs land parcel. For example it may be a deed book number deed book page number and parcel number. propertyData {604852F3-7580-458f-91B1-8CDFD9C5FA41} Type of role. type {660E0D6C-4274-4184-995D-F8932685CE1F} Power factor nameplate data. It is primarily used for short circuit data exchange according to IEC 60909. The attribute cannot be a negative value. ratedPowerFactor {B5179363-B1D6-44bc-949C-449AA1934ACE} Damping torque coefficient iDi gt 0. A proportionality constant that when multiplied by the angular velocity of the rotor poles with respect to the magnetic field frequency results in the damping torque. This value is often zero when the sources of damping torques generator damper windings load damping effects etc. are modelled in detail. Typical value 0. damping {5F801ECC-E3CF-481c-B5F9-FED2D71F679A} Saturation factor at rated terminal voltage iS1i gt 0. Not used by simplified model. Defined by defined by iSiiE1i in the SynchronousMachineSaturationParameters diagram. Typical value 002. saturationFactor {43DE8A9C-88A1-48c1-BC53-2022481FD579} Saturation factor at 120 of rated terminal voltage iS12i gt RotatingMachineDynamics.saturationFactor. Not used by the simplified model defined by iSiiE2i in the SynchronousMachineSaturationParameters diagram. Typical value 012. saturationFactor120 {E4937370-1EC7-4358-8FC2-3A6D3AF17808} value {F2A70238-8D27-4b54-AD10-EFF7F53201E5} Classification by utilitys work management standards and practices. type {6395BDEB-FCB9-4ca0-887F-421AEC4670C7} time of the update from SCADA timeStamp {EB683575-E93D-479b-B554-A049DEEE7532} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {5B9A28EC-586A-4768-891D-DBDDAA0D77EC} Date and time this safety document has been issued. issuedDateTime {06B39557-E213-45e4-BA87-EF6E23458375} Date and time this safety document has been released. releasedDateTime {05643D1D-FFC2-43e3-AB97-CAB50A908FC3} Type of scheduled event. type {3D337F25-5696-49d0-B177-2B94C8334173} Date that the scheduling coordinator becomes creditworthy. creditStartEffectiveDate {E44244BC-3803-48ae-B89B-84AAEB0B1C42} Indication of the last time this scheduling coordinator information was modified. lastModified {76262E08-0E04-42c8-832D-8E266B21627B} Scheduling coordinator qualification status Qualified Not Qualified or Disqualified. qualificationStatus {B5262D45-86D2-4a65-B8E9-2009F29AFDE5} This is the short name or Scheduling Coordinator ID field. scid {C4D2624D-4A48-4e2a-942C-5356A5C4698B} Login ID loginID {275B03D3-A5AA-480b-9E87-413EBEF0C254} Assigned roles these are roles with either Read or ReadWrite privileges on different Market Systems loginRole {38B2006F-13D7-4551-89A5-E5AD85D63D1F} Date and time this seal has been applied. appliedDateTime {A2FD6612-ADAA-4307-8A3C-2631F6043775} reserved word Seal number. sealNumber {6E885028-ED9A-4f37-8506-47A175C98E7A} Date season ends. endDate {863F06C3-15B4-4292-833B-3CF72A8ABD23} Date season starts. startDate {4F960CB2-0438-48dd-A134-A7398B3C4C61} Time in seconds value {EC69405D-C44E-4c12-BAD5-58A3C1375649} Cleared value for the specific self schedule type listed. selfSchedMW {7EC71EF8-D79C-4388-BE1A-52B515050DB3} The date of the last update related to this market object. lastUpdateDate {7339EBC4-5F86-443f-8660-36CE0867DE4E} Type of method used in the business process related to this Series e.g. metering method. methodType {6632E2EB-70AC-4a2b-B5EA-E60B71B42405} For a market object the date of registration of a contract e.g. the date of change of supplier for a customer. registrationDate {BFF04E36-FA5F-4d20-BFD9-8371780D3E36} Describe if a metal oxide varistor mov for over voltage protection is configured in parallel with the series compensator. It is used for short circuit calculations. varistorPresent {7D1BDB14-3258-4f63-B2B4-D55EEB08EC07} True if utility must autmatically pay the specified amount whenever the condition is not satisified otherwise customer must make a claim to receive payment. automaticPay {3E0521F2-073D-4ba0-96E2-4C1B9AA26DB2} Explanation of the requirement and conditions for satisfying it. serviceRequirement {44E73159-6BF7-4772-B2ED-7B85FCBE995D} Method for the service person to access this service location. For example a description of where to obtain a key if the facility is unmanned and secured. accessMethod {0037D380-8BCE-443a-A471-2A60AA36271F} True if inspection is needed of facilities at this service location. This could be requested by a customer due to suspected tampering environmental concerns e.g. a fire in the vicinity or to correct incompatible data. needsInspection {6C778C83-6FED-4a77-A515-E082EBA483E9} Problems previously encountered when visiting or performing work on this location. Examples include bad dog violent customer verbally abusive occupant obstructions safety hazards etc. siteAccessProblem {F391522D-EBB4-4e50-84FB-B5E100C93CC3} Multiplier value. value {40BB2D3D-FD5F-4ebb-B1FF-5D681F893D7B} Number of critical service delivery points affected by an outage. criticalCount {55AD8E4F-0658-4eaa-9A4B-E2B5A530B8C1} Number of all service delivery points affected by an outage. totalCount {931644DD-C199-4b7c-9996-298AD5ED0DA9} Unique transaction reference prefix number issued to an entity by the International Organization for Standardization for the purpose of tagging onto electronic financial transactions as defined in ISOIEC 78121 and ISOIEC 78122. issuerIdentificationNumber {D918C8B9-0BE2-4ee0-B63A-9D41CB71DA99} Normal value for Control.value e.g. used for percentage scaling. normalValue {7261D276-52C2-49df-9B88-2C69F225F21B} The value representing the actuator output. value {F73DC098-9B6A-4c02-AF7D-7CE330617A2C} The trade date on which the settlement is run. tradeDate {E891CF3D-DB7E-41db-9377-ABAE81190BB6} Type of assignement intended to be worked on this shift for example temporary standard etc. assignmentType {6E42A146-AF71-4f6f-99C5-C0F9B779EA1F} Number of cycles for a temporary shift. cycleCount {0C848437-B6CA-4eb8-BC34-7E84C3BB3D23} Tap step number for the energised end of the test pair. energisedEndStep {48C771BA-9E75-448d-A4BF-FEF94FE9B915} Tap step number for the grounded end of the test pair. groundedEndStep {5F1796F7-DB42-4572-95A8-207DF6A5655B} Used for Yn and Zn connections. True if the neutral is solidly grounded. grounded {819FDD3F-56BC-4323-A11A-0E3DF06D929D} The maximum number of sections that may be switched in. maximumSections {A38AEF78-95E1-44c8-B060-2ABC1D8C921E} The normal number of sections switched in. The value shall be between zero and ShuntCompensator.maximumSections. normalSections {98B74E3C-2205-4981-9E38-8E394C2A4D79} Shunt compensator sections in use. Starting value for steady state solution. The attribute shall be a positive value or zero. Non integer values are allowed to support continuous variables. The reasons for continuous value are to support study cases where no discrete shunt compensators has yet been designed a solutions where a narrow voltage band force the sections to oscillate or accommodate for a continuous solution as input. For LinearShuntConpensator the value shall be between zero and ShuntCompensator.maximumSections. At value zero the shunt compensator conductance and admittance is zero. Linear interpolation of conductance and admittance between the previous and next integer section is applied in case of noninteger values.For NonlinearShuntCompensators shall only be set to one of the NonlinearShuntCompenstorPoint.sectionNumber. There is no interpolation between NonlinearShuntCompenstorPoints. sections {092847A7-BC7D-4682-BA72-84E03733C148} The switch on count since the capacitor count was last reset or initialized. switchOnCount {29F942BE-335A-4233-88AA-8F66D2BA8E58} The date and time when the capacitor bank was last switched on. switchOnDate {8D542910-E6DF-4244-A561-DC898FCF6924} For VAR amp or power factor locally controlled shunt impedances the flow direction in out. branchDirect {AD002C5C-C511-43e2-BC31-528C5951E9D3} Upper control setting. localOffLevel {3BBC36D1-37C7-4d45-9F4F-48A81B33BFB9} Lower control setting. localOnLevel {18873C57-44E9-4a74-9D59-84EDEE8E85EB} True if the locally controlled capacitor has voltage override capability. localOverride {5171389C-7C1C-4394-9292-CD966A29A7EF} IdmsShuntImpedanceData.maxNumSwitchOps. maxSwitchOperationCount {2E839DBA-2073-40e0-BBDC-18053EC6E0DE} True if open is normal status for a fixed capacitor bank otherwise normal status is closed. normalOpen {A9E80E20-6FD9-47d7-9675-EF01177947BD} For VAR amp or power factor locally controlled shunt impedances the index of the regulation branch. regBranch {150E560D-D77A-45bc-875D-B7C22F7231B4} For VAR amp or power factor locally controlled shunt impedances the end of the branch that is regulated. The field has the following values from side to side and tertiary only if the branch is a transformer. regBranchEnd {044D2971-4EDC-46db-8180-A2A5E9B71AD8} True if regulated voltages are measured line to line otherwise they are measured line to ground. vRegLineLine {996F55D3-DD71-454b-97D6-2E1FBBE2F6EF} The current status for the Voltage Control Capacitor 1 Connected 0 Disconnected connectionStatus {07A334F1-C745-4457-887E-83257096DA0A} The desired voltage for the Voltage Control Capacitor desiredVoltage {379F7D91-2F72-4f4b-A12A-B1E06BDFD9CE} The injection of reactive power of the filter bank in the NA solution or VCS reactive power production mVARInjection {6EAC6FDA-32A7-4dc2-AC22-49EC6628FD30} Voltage control capacitor step position stepPosition {1AF0C71D-B59A-48ba-A432-78B22B2F9AE4} Indicator if the voltage control this is regulating True Yes False No voltageRegulationStatus {385D588C-9282-4282-AD4B-4DF20A7BBA92} The maximum number of sections that may be switched in for this phase. maximumSections {2C99794B-45D6-49f5-A824-9C28E00B58DD} For the capacitor phase the normal number of sections switched in. The value shall be between zero and ShuntCompensatorPhase.maximumSections. normalSections {F758CEC8-481C-4189-BDBE-93C124F74BF5} Shunt compensator sections in use. Starting value for steady state solution. The attribute shall be a positive value or zero. Non integer values are allowed to support continuous variables. The reasons for continuous value are to support study cases where no discrete shunt compensators has yet been designed a solutions where a narrow voltage band force the sections to oscillate or accommodate for a continuous solution as input.For LinearShuntConpensator the value shall be between zero and ShuntCompensatorPhase.maximumSections. At value zero the shunt compensator conductance and admittance is zero. Linear interpolation of conductance and admittance between the previous and next integer section is applied in case of noninteger values.For NonlinearShuntCompensators shall only be set to one of the NonlinearShuntCompenstorPhasePoint.sectionNumber. There is no interpolation between NonlinearShuntCompenstorPhasePoints. sections {3BA39BCB-56D3-4739-B4E8-CB34290BF25C} The date and time of the most recent generating unit shutdown. shutdownDate {C495CFA2-919C-4cec-975C-F8DC926A91E6} Date and time the skill became effective. effectiveDateTime {E6E3DB2B-AE0E-450a-BE66-13C6315E9C0A} Identifier of specimen used in inspection or test. specimenID {3AC42772-D031-4b9b-A365-F68F5EF6A25D} Date and time sample specimen taken. specimenSampleDateTime {5ACA13EE-9821-4079-BDA2-EEDDCE035E4C} Date and time the specimen was received by the lab. specimenToLabDateTime {C9BF41F1-26E4-4455-824D-CB5A0944F13F} value {E21F1358-2DFC-4a4c-8D74-FB69C43FAF00} The priority of the stage. 0 don t care default 1 highest priority. 2 is less than 1 and so on. A stage with higher priority needs be activated before a lower stage can be activated. priority {9BC3DCEC-B6A2-4426-8DB0-A499DFAE0A57} The status of the class set by operation or by signal. Optional field that will override other status fields. armed {9BF4B5C0-18A5-475b-BF28-BC017FE2734E} The defaultnormal value used when other active signalvalues are missing. normalArmed {8404B97F-2B87-4fef-B6DB-558AF99BE4B8} Priority of trigger. 0 don t care default 1 highest priority. 2 is less than 1 and so on. A trigger with the highest priority will trigger first. priority {4A46F23C-C9A3-4c78-A813-C74143B6A3D1} Standard alphanumeric code assigned to a particular productservice within an industry. code {0CEB6E97-7E3B-47cd-B2B6-C70AAA067269} The date and time of the most recent generating unit startup. startupDate {0EEE810A-ACC6-4abb-9343-B79416836876} Startup priority within control area where lower numbers indicate higher priorities. More than one unit in an area may be assigned the same priority. startupPriority {78E0F1CC-90AC-4129-B39E-B5E0B33ED065} Date and time for which status value applies. dateTime {F75CAF5C-DCC0-40fc-A2AF-D10354C0E735} Reason code or explanation for why an object went to the current status value. reason {BF4685AC-F0E0-40f0-87F2-5D4714B1D11F} Pertinent information regarding the current value as free form text. remark {BD8B05D0-CEC7-4f60-8CC3-7C88DA03505F} Status value at dateTime prior status changes may have been kept in instances of activity records associated with the object to which this status applies. value {7BAA985C-D13D-4282-91ED-90FBCF326D6B} Rating of steam supply. steamSupplyRating {3DB026F2-5780-43ac-B301-9177CE31217B} Fraction of power from shaft 1 high pressure turbine output. shaft1PowerHP {30AED556-D03A-48d7-A08B-64476C4F5889} Fraction of power from shaft 1 intermediate pressure turbine output. shaft1PowerIP {0AB4FE34-3498-4bd9-AA6A-958BBFB49718} Fraction of power from shaft 1 first low pressure turbine output. shaft1PowerLP1 {E28C564F-EBEC-4ad8-83F2-F5CB91054B08} Fraction of power from shaft 1 second low pressure turbine output. shaft1PowerLP2 {8D4D447A-65BF-4f6d-B711-5F38C56CCE3C} Fraction of power from shaft 2 high pressure turbine output. shaft2PowerHP {2AD424EA-6398-4f48-A710-5ADF501FA834} Fraction of power from shaft 2 intermediate pressure turbine output. shaft2PowerIP {17DC375F-3B1C-43e4-9630-1CBFB6EFEB6A} Fraction of power from shaft 2 first low pressure turbine output. shaft2PowerLP1 {CDB649BB-9A07-4918-90C5-ED4A86AF1C2A} Fraction of power from shaft 2 second low pressure turbine output. shaft2PowerLP2 {33C256C1-2AD1-44e9-B41D-9C2517ECBDA7} The language in which the address is specified using ISO 6391 two digit language code. language {7BD40FC3-3D5F-4229-ADAF-7CFC1AC97F0B} Post office box. poBox {AE33800A-1AD9-45e6-8415-1B9FB3A789C8} Postal code for the address. postalCode {8F962EBC-8805-4e03-8051-45E7382F0649} First line of a free form address or some additional address information for example a mail stop. addressGeneral {5CE3C56A-A8CB-4d17-8F13-B1D56813F9B0} if applicable Second line of a free form address. addressGeneral2 {DC974BBD-371B-400a-BECB-7D8F8A5C58E2} if applicable Third line of a free form address. addressGeneral3 {07C70D18-5538-4645-B13D-BBD72DE32C97} if applicable In certain cases the physical location of the place of interest does not have a direct point of entry from the street but may be located inside a larger structure such as a building complex office block apartment etc. buildingName {7537B883-F71B-4189-B0C4-036277339DEF} if applicable Utilities often make use of external reference systems such as those of the townplanners department or surveyor generals mapping system that allocate global reference codes to streets. code {9C44FAD9-C465-4c6b-A403-E6F1E66D9BE1} The identification by name or number expressed as text of the floor in the building as part of this address. floorIdentification {24B16BCA-4094-43e8-9867-BC2E9EDC5D04} Name of the street. name {CFEA2CAE-B7AA-4efd-ADCA-844A71759BFD} Designator of the specific location on the street. number {DF4B02A3-F827-403b-AF42-3EDF7C5AB26E} Prefix to the street name. For example North South East West. prefix {C0D97DAC-BB35-430e-B7F4-8C9FFBBED05D} Suffix to the street name. For example North South East West. suffix {E00200CA-8258-41be-8D82-475C894ECD59} Number of the apartment or suite. suiteNumber {2292B0DB-9622-4f91-A86B-C8067BCB34DF} Type of street. Examples include street circle boulevard avenue road drive etc. type {C1813D47-8834-4076-8C7D-A2A86410A073} True if this street is within the legal geographical boundaries of the specified town default. withinTownLimits {9B131882-C1C7-4ecc-B52A-FC25C2AFFCC7} The value to supervise. value {CD179EE2-08E0-422c-8DC7-22CC8ADDDE71} Value of this quantity. value {BAD170CB-1619-4202-A717-0253140C6495} Date fumigant was last applied. fumigantAppliedDate {A7EC168D-91A7-4adf-A262-BC18CE2751C0} Name of fumigant. fumigantName {5A990EE4-A247-4d51-8292-6BCA67D5E453} True if weeds are to be removed around asset. removeWeed {BF6DDC13-711A-4566-B0A2-8165E35443DD} Date weed were last removed. weedRemovedDate {AE7A7236-019E-4b3d-864A-4E7FB0964870} if anchor Number of rods used. anchorRodCount {B4BB2EBE-65EF-401a-8056-77F44A804ABA} Size of this support structure. size {D9811D22-A4FC-431e-9F62-7B3A9C4F130F} Market area short name which is the regulation zone. It references AGC regulation zone name. areaShortName {4517C598-1961-4006-98F4-FC065361BF0B} Loss estimate constant coefficient constantCoefficient {79D175AA-21A5-4785-B269-2482FF00AFE4} Loss estimate linear coefficient linearCoefficient {870F1DA9-9DA3-49d7-BD70-7BF15012DD0F} Maximum amount of self schedule MWs allowed for an embedded control area. maxSelfSchedMW {FEC5C00B-AFE1-4826-BADF-2D57AC7D2ADC} Minimum amount of self schedule MW allowed for an embedded control area. minSelfSchedMW {CE49DB13-6706-46de-A03E-AE06B3A7FE36} Loss estimate quadratic coefficient quadraticCoefficient {F36C7A04-A9EF-4148-913C-A59B9C08DE1D} An indicator of the order a resource should be substituted. The lower the number the higher the precedence. precedence {8876BA44-ADEC-45a3-A12E-814357D6A651} If true the arrester has a polymer housing porcelain otherwise. isPolymer {03584C79-2C6E-42c3-9ABE-B78C1CC4A8A5} Determines the arrester energy discharge capability. Choices are limited to 0 none through 5 highest by IEC 60099. Classes 1..3 require a 10kA nominal discharge current. Classes 4..5 require a 20kA nominal discharge current. Lower nominal discharge currents must use class 0. lineDischargeClass {7267083E-E1D5-44c1-8A6D-294C43C55410} value {5AB38FF3-6ED0-4479-947D-CB7B7FF06765} value {194691F2-4589-4c33-904D-5FC9FE41AC3A} The number of sections in service as a continuous variable. The attribute shall be a positive value or zero. To get integer value scale with ShuntCompensator.bPerSection. sections {9CF2E84D-246A-4e10-9289-A42B1F563EBB} The in service status as a result of topology processing. It indicates if the equipment is considered as energized by the power flow. It reflects if the equipment is connected within a solvable island. It does not necessarily reflect whether or not the island was solved by the power flow. inService {4031A324-BC7D-46da-A4F8-F5FF3AD7C480} The attribute tells if the computed state of the switch is considered open. open {B4297F1E-EA65-4837-8A2C-65C5DA1D97FF} The floating point tap position. This is not the tap ratio but rather the tap step position as defined by the related tap changer model and normally is constrained to be within the range of minimum and maximum tap positions. position {640BC88B-D310-47fc-85CA-893FE11565EB} If true the switch is locked. The resulting switch state is a combination of locked and Switch.open attributes as followsullilockedtrue and Switch.opentrue. The resulting state is open and lockedlililockedfalse and Switch.opentrue. The resulting state is openlililockedfalse and Switch.openfalse. The resulting state is closed.liul locked {D72B9A82-CD67-425e-AF36-802920CFAF3F} The attribute is used in cases when no Measurement for the status value is present. If the Switch has a status measurement the Discrete.normalValue is expected to match with the Switch.normalOpen. normalOpen {42C10E32-018C-4f7d-81E1-3687F5A7FCFD} The attribute tells if the switch is considered open when used as input to topology processing. open {7FC100AA-9641-4d45-AC84-8B90D9FC4D3F} Branch is retained in the topological solution. The flow through retained switches will normally be calculated in power flow. retained {5E9C873C-F052-49f6-9247-D7274CDA570A} The switch on count since the switch was last reset or initialized. switchOnCount {0FA70685-F30F-4d40-9CA6-65C5C7AC0543} The date and time when the switch was last switched on. switchOnDate {49CABBEB-6179-48ca-A1D3-4D45B67C7058} If true it is a single phase switch. isSinglePhase {276BEA3A-30B0-4c6e-8043-1E7126732BEF} If true the switch is not ganged i.e. a switch phase may be operated separately from other phases. isUnganged {597B5D6F-3228-4ad0-980D-ABD0E86453E3} Total breaker fault operations to date. lifetimeFaultOperations {450D7639-E96E-4e6b-8DF9-B932FC6773AB} Total motor starts to date. lifetimeMotorStarts {EB698254-E589-4355-BA41-E254D98A0B59} Total breaker operations to date including fault and nonfault. lifetimeTotalOperations {81CE57DF-7742-40b1-8BC7-86505B49FE93} Date of most recent breaker fault operation. mostRecentFaultOperationDate {F1C596A3-3B98-49fb-80C1-9D61D0E50DD2} Date of most recent motor start. mostRecentMotorStartDate {53267D18-2883-4622-8F8B-F6C8C64C642B} Date of most recent breaker operation fault or nonfault. mostRecentOperationDate {37512992-7096-45bc-86CD-1CE4D2B10623} The attribute tells if the switch is considered closed when used as input to topology processing. closed {2D74FA7E-B474-49c0-9048-99DC144552C0} Used in cases when no Measurement for the status value is present. If the SwitchPhase has a status measurement the Discrete.normalValue is expected to match with this value. normalOpen {3EB97B9C-9596-4407-931B-BE4479584302} Free text description of this activity. description {36196D20-DADC-4f10-9DC0-624BA20C3EA7} Actual date and time of this switching step. executedDateTime {58C40B93-BF37-447f-B1D4-432EFB3E149A} Date and time when the crew was given the instruction to execute the action not applicable if the action is performed by operator remote control. issuedDateTime {A84B8EC5-9192-4165-B659-B7586A377D0F} Planned date and time of this switching step. plannedDateTime {D13229D6-80A4-4bfa-94B0-A8E0295D18AD} Freeform comment associated with the switching order. comment {490032F6-F824-4c73-BB3B-ADD2B11F1225} The date and time the switching plan was approved approvedDateTime {F6C5D9C3-6B86-4667-B16A-A96D45F764D3} Date and Time the switching plan was cancelled. cancelledDateTime {7540C913-2836-43e3-9DAF-7E81A8DD0B5E} Purpose of this plan such as whether it is to move the state from normal to some abnormal condition or to restore the normal state after an abnormal condition or to perform some kind of optimisation such as correction of overload voltage control etc. purpose {1FDFFB30-E37C-4c09-9813-A53FBB508F22} Ranking in comparison to other switching plans. rank {6BBFA369-C2F2-49fb-A2F1-085E8B077A87} Freeform text to describe the request comment {808357BB-3C46-4159-A535-A615C38F8022} freeform list of the equipment to be isolated by the switching equipmentToBeIsolated {58E8F603-D85A-4983-9037-640F0D8D2FD4} freeform list of equipment to be grounded or other actions to be taken in order to accomplish the required grounding. groundingPoints {F60F677C-D37F-40f9-B5B1-0E37DEACBF56} freeform description of the area to be isolated by the switching isolationArea {312AEED1-5F56-47b8-9A2F-4A7AC8812FAA} freeform list of equipment to be operated or other actions to be taken in order to accomplish the required isolation. isolationPoints {7AB55350-D4E8-4305-9491-041737EFB40D} purpose {2DEAA8AD-4456-4d11-81DA-53395F86D1BE} switchingRequestDetails {3D05C75D-9C26-4865-B9D0-444F4584276B} For a step if isFreeSequence is set to false or is not specified all of the steps in the group must be executed in the order defined by the sequenceNumber attribute. The sequenceNumber for a step has a different meaning when there are two or more sequential steps that have the isFreeSequence attribute set to true. Execution must still be performed in sequenceNumber order until a set of two or more steps that have isFreeSequence set to true is encountered. In this case these steps can be executed in any sequence until a step is encountered that has isFreeSequence set to false. All of the steps preceding this step must be executed before the step can be executed. isFreeSequence {1EE398A0-47B4-4f51-B249-80E644EE189E} Order of this activity in the sequence of activities within the switching plan. sequenceNumber {4444250A-B1C3-43e3-87D5-EF82219CFCDA} Supports compound switching steps that are made up of several sub steps. subStepSequenceNumber {BDE538C9-4FDC-4707-969B-5F43B204FC3B} Descriptive information concerning the switching step group. description {20AD671A-E578-4c4a-8066-00556F2235FC} If true the sequence number serves for presentation purposes only and the activity itself may be executed at any time. isFreeSequence {E4FC0A13-BC40-4de5-B042-726F6BE56827} Describes the overall purpose of the steps in this switching step group. purpose {69B7E904-C2ED-4643-BF74-843C42E1502D} Order of this activity in the sequence of activities within the switching plan. sequenceNumber {5988977E-1E7B-4aef-A4E5-AC5455C25A7B} Temperature or pressure of coolant medium. coolantCondition {6CFFB946-1FF7-413e-84A5-A1C6FD614BB1} Indicates whether or not the generator is earthed. Used for short circuit data exchange according to IEC 60909. earthing {F7C4DAB6-7373-4bab-B049-98CFFFE863F3} Factor to calculate the breaking current Section 4.5.2.1 in IEC 609090.Used only for single fed short circuit on a generator Section 4.3.4.2. in IEC 609090. mu {848A6DD0-9E82-42fa-B11B-8532CB3D9AA3} Priority of unit for use as powerflow voltage phase angle reference bus selection. 0 don t care default 1 highest priority. 2 is less than 1 and so on. referencePriority {9B59DCCE-EF9D-498c-90AC-A8582AB555DC} Ratio exciter voltagegenerator voltage of iEfdi bases of exciter and generator models gt 0. Typical value 1. efdBaseRatio {0D3770BC-CA73-4aec-B343-6AC5121A3AB7} Quadratureaxis saturation factor at 120 of rated terminal voltage iS12qi gt SynchonousMachineDetailed.saturationFactorQAxis. Typical value 012. saturationFactor120QAxis {4E010EA3-912C-48d6-A50E-764BB9052160} Quadratureaxis saturation factor at rated terminal voltage iS1qi gt 0. Typical value 002. saturationFactorQAxis {9C4E1B77-7803-463e-8B11-207491E7C7DE} Saturation loading correction factor iKsi gt 0. Used only by type J model. Typical value 0. ks {D2444614-9B84-4a35-ABD1-835F24796268} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {6A3B8AD0-3274-4018-A07C-62DBC203F7F5} Used to calculate load participation of a connectivity node in an host control area factor {43BDB0E2-9F3B-4b47-8EF1-F03C449274A4} Specifies the version of the Bilateral Table configuration that is being exchanged. bilateralTableID {53A10B69-153E-4f4c-8AAD-639A5F384816} The Version attribute identifies a unique version of the Bilateral Table. If any changes are made to a Bilateral Table then a new unique value for this attribute shall be generated. bilateralTableVersion {CC710D6D-F752-420e-B60D-82C3719D1A4D} Specifies the version of the TASE.2 that is needed to access the Bilateral Table information via TASE.2.In order for a link to be established both sides must have the same value. tase2version {B4023E17-82AB-402a-B0F4-C4CF717BBCEC} Indicates the default interval at which TCP will check if the TCP connection is still valid. keepAliveTime {BB1D9F2A-3E25-4a11-A4C8-4EF1F9C6CEC5} This value is only needed to be specified for called nodes e.g. those that respond to a TCP.Open request.This value specifies the TCP port to be used. Well known and registered ports are preferred and can be found at httpwww.iana.orgassignmentsservicenamesportnumbersservicenamesportnumbers.xhtmlFor IEC 608706 TASE.2 e.g. ICCP and IEC 61850 the value used shall be 102 for nonTLS protected exchanges. The value shall be 3782 for TLS transported ICCP and 61850 exchanges. port {13836426-DFB7-43df-B5CC-6C71D7A73B26} The entitlement entitlement {F2CD4524-777A-40b8-B6CE-625A5ED6CD1A} Operating date and hour when the entitlement applies startOperatingDate {A1081BC1-7AB1-45b5-8445-F50D2164439A} Specifies the regulation status of the equipment. True is regulating false is not regulating. controlEnabled {1BF7B544-61DC-4fd7-9325-E938A8C364C7} Highest possible tap step position advance from neutral.The attribute shall be greater than lowStep. highStep {F3D83CC1-3BD4-4c27-9782-7FB0DDBAED1F} Lowest possible tap step position retard from neutral. lowStep {E72756C9-A9EA-41fb-9523-A9E5EC65C109} Specifies whether or not a TapChanger has load tap changing capabilities. ltcFlag {DA8B32CA-3C0B-4913-8EED-F08BF2818AFD} The neutral tap step position for this winding.The attribute shall be equal to or greater than lowStep and equal or less than highStep.It is the step position where the voltage is neutralU when the other terminals of the transformer are at the ratedU. If there are other tap changers on the transformer those taps are kept constant at their neutralStep. neutralStep {AEF6801E-342A-4a1f-ADC6-C7DAFFED61BC} The tap step position used in normal network operation for this winding. For a Fixed tap changer indicates the current physical tap setting.The attribute shall be equal to or greater than lowStep and equal to or less than highStep. normalStep {A0388C6D-808F-4546-A960-9D73692E7B0B} Tap changer position.Starting step for a steady state solution. Non integer values are allowed to support continuous tap variables. The reasons for continuous value are to support study cases where no discrete tap changer has yet been designed a solution where a narrow voltage band forces the tap step to oscillate or to accommodate for a continuous solution as input.The attribute shall be equal to or greater than lowStep and equal to or less than highStep. step {2FA251C7-BB3A-4cf7-9BC7-316171AED7CB} If true the line drop compensation is to be applied. lineDropCompensation {0DFB1938-959E-4ede-BF20-0A418D722484} True means the phase shifter is regulating. angleRegulationStatus {FA7CF8BD-B9C3-41ef-BADE-2CC155A01E7B} Phase Shifter Desired MW. The active power regulation setpoint of the phase shifter desiredMW {DF5330AC-6500-460c-B474-427660D824E8} The desired voltage for the LTC desiredVoltage {8E552FAA-07A2-4b82-88C0-C64886B9AD9A} The maximum phase angle shift of the phase shifter maximumAngle {5EBED356-6785-46d3-AC96-27E5E21D8FB2} The minimum phase angle shift of the phase shifter minimumAngle {33DEA165-128F-4f6a-A27E-E23E5CEF636B} Phase Shifter Angle. The solved phase angle shift of the phase shifter solvedAngle {2351EEC4-4AD9-4f36-BE81-2A126FEFF7DA} Tap position of the phase shifter highside tap position of the transformer or lowside tap position of the transformer tapPosition {E078E113-C900-4782-8EDD-50449B1041CE} Indicator if the LTC transformer is regulating True Yes False No voltageRegulationStatus {3BEE90DE-E994-4710-90BA-C42DD46CCB41} Builtin current transducer ratio. ctRatio {F4A05AC3-06F3-4817-AD7C-F3EA93FAA940} Highest possible tap step position advance from neutral. highStep {3196F11C-6B90-44f7-851B-DBE27C48DC5F} Whether this tap changer has under load tap changing capabilities. isTcul {6D8ACE93-71C4-4aa0-9A47-C6DD6FC5AD61} Lowest possible tap step position retard from neutral. lowStep {2A9864D7-C700-4bf0-BDA1-38B07F621DB4} The neutral tap step position for the winding. neutralStep {EA6B0312-1800-4534-8A47-A6C0B7AE3A8A} Builtin voltage transducer ratio. ptRatio {E47AC4C5-DB70-462e-9B02-23D31BF05BD3} The voltage at the tap step divided by rated voltage of the transformer end having the tap changer. Hence this is a value close to one.For example if the ratio at step 1 is 1.01 and the rated voltage of the transformer end is 110kV then the voltage obtained by setting the tap changer to step 1 to is 111.1kV. ratio {4357132D-9216-46a0-A5B0-6C3F0DCC7876} The tap step. step {4941A374-B3BD-4b4e-9F28-C44B88440D16} if tariff became inactive Date tariff was terminated. endDate {BEE38839-574C-4cde-A93D-246F790EC64D} Date tariff was activated. startDate {C9A669A4-0863-441b-A382-DC8ED7C8AA2C} The frequency at which the tariff charge schedule is repeated. Examples are once off on a specified date and time hourly daily weekly monthly 3monthly 6monthly 12monthly etc. At the end of each cycle the business rules are reset to start from the beginning again. tariffCycle {85CE711E-41B2-4dba-969E-FEA5AC0A61DE} if applicable Area or region code. areaCode {C0F15152-9E3A-448e-941F-1352D0609D30} City code. cityCode {5EECBD36-B275-4c05-83A1-4CFC5763E23E} Country code. countryCode {B5A53069-6F98-4057-9C4C-13B658EF4D8B} if applicable Dial out code for instance to call outside an enterprise. dialOut {DB70B0A2-0520-408d-B14D-91C330CBFC63} if applicable Extension for this telephone number. extension {A9F4D146-3D47-464f-B051-0C623B097B2D} if applicable Prefix used when calling an international number. internationalPrefix {28A12A3C-F864-414c-B886-52B31BE3671B} Phone number according to ITU E.164. ituPhone {2B1FD4FF-40C1-40ac-A218-94641E8F4470} Main local part of this telephone number. localNumber {06880FBC-0A6F-410c-A423-AF24CF7901A7} value {7716E759-D73B-4c62-81B9-898473941C90} The polinomial coefficent of power 0. coefficient0 {1A13C0D8-F106-4922-90CE-3FA57AFB74D1} The polinomial coefficent of power 1. coefficient1 {4E7AF97F-B59F-40bc-BB30-2F232A4B2D21} The polinomial coefficent of power 2. coefficient2 {446EE933-E3D8-4e88-BE6A-D126B0EA8099} The polinomial coefficent of power 3. coefficient3 {8643F736-D0FF-40c7-83B7-2E7431A9EF9C} The polinomial coefficent of power 4. coefficient4 {72AD515D-7174-40ff-8AD4-49769E70F9EC} intervalStartTime {C91B1BB5-FBCC-424c-BF7A-3109D7919E4A} updateTimeStamp {35DFD7D8-C40F-4e0b-90E5-52021EFDF956} updateUser {9EF51A88-6737-47c6-AA13-D2B0BFE67280} Conclusion drawn from test results. conclusion {BE9FFE6F-B09A-49d0-B9DB-3A1FBA978A85} Identifier of specimen used in inspection or test. specimenID {5D931E29-F9B4-42a6-ABCB-7A739DE568B2} Date and time the specimen was received by the lab. specimenToLabDateTime {93A24278-F558-4ca7-BFE9-81B4EF2A87B9} The text that is displayed by this text diagram object. text {CE3AEAE4-F12B-4049-97ED-61BF9EDEB14E} Specifies the sign of the tie flow associated with a control area. True if positive flow into the terminal load convention is also positive flow into the control area. See the description of ControlArea for further explanation of how TieFlow.positiveFlowIn is used. positiveFlowIn {61B84897-30DD-424d-9ED1-0FBF9923D8D1} End time of this interval. end {15C2B131-A184-4578-8C4A-ECC84D5F9EBF} Start time of this interval. start {AD4CB2DE-357C-4097-B9C6-C778CC7C75CA} Absolute date and time for this time point. For calendarbased time point it is typically manually entered while for intervalbased or sequencebased time point it is derived. dateTime {91DE3B9C-7E60-4211-873B-6878A6AE5B41} if sequencebased Relative sequence number for this time point. sequenceNumber {047CFBED-95A9-468f-A172-F1C2372117D7} True if this schedule is deactivated disabled. disabled {47A134AD-2457-4a49-9265-765803BD63F8} Interval at which the scheduled action repeats e.g. first Monday of every month last day of the month etc.. recurrencePattern {8E6FC68B-16DB-4b9c-A1AA-D3B73E1200AA} The identification of the nature of the time series. businessType {5AD2DBE0-1DF3-43fa-B574-1CF51A9DF1B0} An indicator stating that the TimeSeries identified by the mRID is cancelled as well as all the values sent in a previous version of the TimeSeries in a previous document. cancelledTS {AE336DA4-75D3-45d7-9A6A-EB94972BE279} The coded representation of the type of curve being described. curveType {5FA13D83-B105-4de7-91BF-47E6117C4F26} Identification of the object that is the common denominator used to aggregate a time series. objectAggregation {B75C88DE-DD66-4bd1-8174-8BE3A0283814} The type of the product such as Power energy reactive power transport capacity that is the subject of the time series. product {4FA59194-C37D-4bae-8C7A-235C9D6C1E20} Version of the time series. version {656F68BE-E261-41fd-81AC-FE26C6151C1B} A sequential reference that defines the identity of this interval and its relative position with respect to other intervals in a sequence of intervals. sequenceNumber {DFC6559A-3CB3-4550-9FAA-DECC6C92280B} A real time marker that defines the starting time typically it is the time of day for this interval. The interval extends to the start of the next interval or until it is reset to the start of the first interval by TariffProfile.tariffCycle. startTime {A077A349-C8CE-4fda-A4F5-D4EC2B1BFB33} if applicable Date the tool was last calibrated. lastCalibrationDate {4CCDDD58-04E9-41ed-BB08-98230DBFF109} Town code. code {7435FA35-FEF2-44b0-96AC-8F11789C1AF9} Name of the country. country {ACD16500-AC2D-464f-AD2C-5F78BDB8C8A1} Town name. name {D21D8A7E-6B52-42de-BBC4-5A334BE6FC3B} Town section. For example it is common for there to be 36 sections per township. section {D3BABCE4-BCC6-4352-838F-CE2D37898326} Name of the state or province. stateOrProvince {54BE5603-B97E-4fa8-9398-1AE6FE1A7538} The validated and current market accepted trade amount of a physical energy trade. adjustedTradeQuantity {1CE523A5-FE56-4bfc-97C7-F097556A5B93} MW quantity submitted by counter SC for the same trade counterTradeQuantity {3EC4C06E-B94A-424c-9468-EE626DD15CAB} The Depend On IST Name points to the unique IST Name in the chain of physical energy trades. dependOnTradeName {9B51DE89-A691-428f-A06A-013BCBC854FF} Time and date the trade was last modified. lastModified {20FAFB3F-BC44-45e9-900E-E32F04D1A054} Start time and date for which trade applies. startTime {98D0940C-68D5-4d12-AADA-8472ABE65E9D} Stop time and date for which trade is applicable. stopTime {E52B6C3B-0FC7-4749-96ED-9A53F99ADDD8} Timestamp of submittal of submit From Scheduling Coordinator Trade to Market Participant Bid Submittal submitFromTimeStamp {A52454D0-D735-4b73-BF6E-1AC3538BB7A2} Userid of the submit From Scheduling Coordinator trade submitFromUser {5A576126-E23D-4d50-AAB7-AB7EE291CEBA} Timestamp of submittal of submit To Scheduling Coordinator Trade to Market Participant Bid Submittal submitToTimeStamp {E445B6E6-6ED4-4567-80D3-E3DE0C9BE2DE} Userid of the submit To Scheduling Coordinator trade submitToUser {2D84A73F-1099-4d2c-A648-AE64A0E51D3A} tradeQuantity If tradeType IST The amount of an Energy Trade. If tradeType AST The amount of an Ancillary Service Obligation Trade. If tradeType UCT The amount of a Unit Commitment Obligation Trade. tradeQuantity {925B6058-C190-4228-B5CA-659D979F37B1} Resulting status of the trade following the rule engine processing. tradeStatus {5075FF4C-A069-46d1-AB6C-E588C5FE45F9} updateTimeStamp {095362AA-12F7-4278-9A93-F0CE7E927D03} updateUser {4B9C6AF9-74ED-4a5f-B801-BBFA6943347D} hour wihthin the trade for which the error applies endTime {947F8B26-8EDD-4ac6-8D5D-CC1CE1125CEF} error message errMessage {831A0328-A38C-406b-874B-6E6BE083C18A} Priority number for the error message errPriority {F6E4E3C2-D0D3-42f5-BD4E-218F00B05442} Timestamp of logged errorwarning message logTimeStamp {EB4ABF18-503F-4d2d-B05F-560B99178741} Rule identifier which triggered the errorwarning message ruleID {39B265DA-4FB6-466d-88D8-DC62D62D1E83} hour wihthin the trade for which the error applies startTime {E7523572-E3C9-41bb-9CD0-D2E31B35012D} PHY Physical Energy Trade APN Energy Trades at Aggregated Pricing Nodes CPT Converted Physical Energy Trade RUT Regulation Up Trade RDT Regulation Down Trade SRT Spinning Reserve Trade NRT NonSpinning Reserve Trade tradeProductType {E126223A-DFDF-4de0-A4AE-C26A01E55549} intervalStartTime {04704CEF-AB95-41a6-9462-B80A82A1AE6D} updateTimeStamp {648653CB-831D-490c-AB39-B8AD5656654F} updateUser {8AB44A38-A24A-41a4-84E5-C25B21B6B573} Utilizes the Market type. For DA the price is hourly. For RTM the price is a 5 minute price. price {D01C765D-9650-4d9a-8EE6-CD310A89AB34} Formal reference for use with diverse payment traffic fine for example. diverseReference {7FC27DD1-EBB7-4da4-BF67-AD2E597A399B} Reference to the entity that is the source of amount for example customer for token purchase or supplier for free issue token. donorReference {35DA1D74-B576-41d9-BB85-4ADEEA9AD05E} Reference to the entity that is the recipient of amount for example supplier for service charge payment or tax receiver for VAT. receiverReference {99461FE6-36A8-440b-82A0-4E463F9348D4} if kind is transactionReversal Reference to the original transaction that is being reversed by this transaction. reversedId {98EABBF6-1112-403a-9757-AD7DDD752266} Set true if this is a demand transaction. demandTransaction {4F17AD78-4DED-4aa5-A138-FD36182EC0B9} Set true if this is a dispatchable transaction. dispatchable {78534BBC-7997-4428-B88C-210EB0F5E9F6} Set true if this is a willing to pay transaction. This flag is used to determine whether a schedule is willingtopaycongestion or not. payCongestion {A217B41F-50B0-4303-8F21-0E2ADC4033B9} The market transaction megawatt clearedMW {D20BBD85-7BE1-4867-93DF-5E9364C0C804} The price of the market transaction clearedPrice {03CE725D-4B2C-40eb-B19F-37C1E6BE6F00} The margin for the interface interfaceMargin {7148BE39-9BE2-4a9e-A50A-384F97126BCE} Post Transfer MW for step postTransferMW {36435E6E-5A75-4338-86A3-802A1E3CF87F} Transfer Interface Limit Attribute Usage The absoloute of the maximum flow on the transfer interface. This is a positive MW value. transferLimit {47FAF506-922B-48a6-AFF8-1B664C2C1900} Number for this transformer end corresponding to the ends order in the power transformer vector group or phase angle clock number. Highest voltage winding should be 1. Each end within a power transformer should have a unique subsequent end number. Note the transformer end number need not match the terminal sequence number. endNumber {6822B571-71B1-4ce5-AEFB-1B41C19076AF} for Yn and Zn connections True if the neutral is solidly grounded. grounded {AF0E90AF-70E5-4620-9474-F9DD0E9C4DB2} Number for this transformer end corresponding to the ends order in the PowerTransformer.vectorGroup attribute. Highest voltage winding should be 1. endNumber {003A8DC4-2E56-49b8-A5F4-33EA9E65FF13} Winding phase angle where 360 degrees are represented with clock hours so the valid values are 0 ... 11. For example to express the second winding in code Dyn11 set attributes as follows endNumber2 connectionKind Yn and phaseAngleClock 11. phaseAngleClock {F4141924-9719-4edc-B632-11CF34FC372D} Dissolved Gas Analysis. Typical values are Acceptable Overheating Corona Sparking Arcing. dga {154CCF3B-B56F-4e17-9319-F5B0EC0B5C6D} Frequency Response Analysis. Typical values are acceptable slight movement significant movement failed near failure. A graphic of the response diagram which is a type of document may be associated with this analysis through the recursive document relationship of the ProcedureDataSet. freqResp {64D3AD87-2070-4907-87F7-46BAF30F555F} Overall measure of furfural in oil and mechanical strength of paper. DP the degree of polymerization is the strength of the paper. Furfural is a measure of furfural compounds often expressed in parts per million. furfuralDP {4B575838-E6D0-465a-87CF-296B56087C94} Oil Quality AnalysisColor. oilColor {89F296B8-5D8C-4a6c-BC08-5AA70B9BDE44} Oil Quality Analysis inter facial tension IFT numberDynesCM. oilIFT {35225156-B22A-4f12-A30E-5269369B1AD7} The level of oil in the transformer. oilLevel {C39558C9-99F9-45e1-BE4C-05F4979AC7A3} Oil Quality AnalysisNeutralization Number Number Mg KOH. oilNeutralizationNumber {C1B4550B-5771-4dfe-B4FD-06C1FB21DDEC} Pump vibration with typical values being nominal high. pumpVibration {AEF1D76A-6AF1-41f0-A530-148507CD3E76} Water Content expressed in parts per million. waterContent {A64BC954-F0B3-4e78-AE94-3B629D64AB66} The Operational Transmission Capacity OTC 15 minute Emergency Limit OTC15min_emergency {FF409639-6927-405e-AA9B-7D067E351D4E} The Operational Transmission Capacity OTC Emergency Limit. OTCemergency {C5419437-8442-4d7f-9518-A70B52270FD0} point of delivery POD {E13EBD4D-3B78-4982-89B6-1B592F26059D} point of receipt POR {3DCDBDED-0C71-4eb2-95B3-0096AF898CF3} Capacity Benefit Margin CBM is used by Markets to calculate the transmission interface limits. This number could be manually or procedurally determined. The CBM is defined per transmission interface branch group. capacityBenefitMargin {C2A2B075-F0B9-4071-A88E-920011C5BAFA} The Operational Transmission Capacity OTC is the transmission capacity under the operating condition during a specific time period incorporating the effects of derates and current settings of operation controls. The OTCs for all transmission interface branch group are always provided regardless of outage or switching conditions. operationalTransmissionCapacity {FD10E531-44CD-4d10-9ADD-23D147154E27} Operating date amp hour when the entitlement applies startOperatingDate {787FB4A8-7DC2-479f-B4CA-63EC927BB3D6} Total Transmission Capacity totalTransmissionCapacity {6D1CD983-C6A5-4ede-91CB-19ED5275294E} point of delivery POD {75635FA8-DBDF-494a-BF93-06BAB90E1206} point of receipt POR {923698C3-BE86-412c-87C0-146BA9E29856} the entitlement entitlement {1B68C582-6833-4c32-A869-7594E5F13D52} Operating date and hour when the entitlement applies startOperatingDate {04DB74F7-CA94-494c-A102-D6A19F20FCCE} Flag which indicates if the transmission path is also a designated interconnection parallel path. parallelPathFlag {5D84D934-FF7C-4168-9A64-AA832E8F9825} Type of the transmission product. This could be a transmission service class firm total transmission capability or nonfirm transmission service period onpeak fullperiod offpeak transmission service increments yearly extended hourly fixed monthly sliding etc. transmission service type network available transmission capability or pointtopoint or a transmission service window fixed hourly sliding weekly extended monthly etc.. transmissionProductType {CE73DE13-FCEF-4636-8943-0C8ED7EA0237} Strength of tropical cyclone during the time interval based on Australian Bureau of Meteorology Category System where1 tropical cyclone with typical gusts over flat land 90125 kmh2 tropical cyclone with typical gusts over flat land 125164 kmh3 severe tropical cyclone with typical gusts over flat land 165224 kmh4 severe tropical cyclone with typical gusts over flat land 225279 kmh5 severe tropical cyclone with typical gusts over flat land greater than 280 kmh. category {1D4017E0-04CA-40db-9AAF-7985CE3A5103} Freeform comment associated with the trouble order. comment {DAB0A2E8-48FB-45e5-A8CF-B7D88FCDB254} Freeform comment associated with the trouble call for example customer reported a large flash etc. comment {50382B04-C162-42db-B641-0484ABBCE37C} Date and time the trouble has been reported. dateTimeOfReport {07C3932F-AF4B-451f-B61A-A1B2C3A7A74A} Indicates whether the first responder such as police fire department etc.has been notified and whether they are on site or en route. firstResponderStatus {3C2B70BF-FF28-4ead-A57D-915DF069F40F} Set to true if the outage report indicated that other neighbors are also out of power. multiplePremises {C3380A11-1A6E-4572-B45D-7FD8282128DE} Date and time this trouble ticket has been resolved. resolvedDateTime {DC1D36C2-4B19-4d76-99F7-ED70DFA4D18A} Trouble code e.g. power down flickering lights partial power etc. troubleCode {6ED450C4-9A26-4a02-9679-F007AB0BCCE6} Tsunami intensity on the PapadopoulosImamura tsunami intensity scale. Possible values are 112 corresponding to IXII. intensity {4ED47FA3-D00E-4713-B28F-222A976CB77A} Tsunami magnitude in the Tsunami Magnitude Scale Mt. Is greater than zero. magnitude {204A9193-E5EF-4f9b-9853-0A1C78A82EBC} Frequency bias flag iFbfi.true enable frequency biasfalse disable frequency bias.Typical value false. fbf {2F246C40-1834-4279-8859-5F571A190ECA} Power controller flag iPbfi.true enable load controllerfalse disable load controller.Typical value false. pbf {F4F97D36-820C-4ff3-AFD2-C1522D80BB7C} Type of turbine governor reference iTypei.true speed reference governorfalse load reference governor.Typical value true. speedReferenceGovernor {C758ED36-CBD9-4b5e-8A6D-1513DB8C160F} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {27F46778-324A-4712-A7BB-F5FCC341F814} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {05DA1339-DD09-43ac-999C-88CA3D4FDEF5} The type of cost to which this Material Item belongs. costType {76B7FF39-9EF0-4c73-9D2F-63C0A7A1CE9F} The value unit of measure and multiplier for the quantity. quantity {D926505E-9258-4992-82AD-02ABAB961683} True if item is a stock item default. stockItem {32D66979-021B-4e23-AC4E-B70187657530} The switch is to be open during the scheduled period. open {C75509C2-7901-4982-B84F-968C36550402} UEL terminal voltage exponent applied to real power input to UEL limit lookup table ik1i. Typical value 2. k1 {638C7C78-559F-4a76-8E57-79914007D7B4} UEL terminal voltage exponent applied to reactive power output from UEL limit lookup table ik2i. Typical value 2. k2 {19B9C704-16B2-43e6-AEE3-FAC9223901D2} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {572825C2-FD3A-4129-8C0B-B0881D893C08} True if vault is ventilating. hasVentilation {38ACDAD7-AFA2-497d-8E75-F2A068C1F0E7} Primary material of underground structure. material {CA5A2649-5188-4d09-AF01-AF3993F02167} Date sealing warranty expires. sealingWarrantyExpiresDate {1FC9A995-8136-497e-AD99-2599816EB50E} The coded representation of the unit. name {EAD9B97C-94E1-4796-BF98-5983B3B1E0C4} Cumulative number of status changes of the resource. cumStatusChanges {9E922C4F-B4BD-4db6-995F-EFFB5FC34FAA} Number of start ups in the Operating Day until the end of previous hour. numberOfStartups {F6290677-89F8-4242-A728-9328A7BBB5FB} true if the GeneratingUnit is currently OnLine onlineStatus {3C9441B0-8BBC-4d9f-947D-863C331A959E} Resource status at the end of previous clearing period0 offline1 online production2 in shutdown process3 in startup process resourceStatus {38727FBE-2336-4c41-B2AB-66D51E5D6291} Time and date for resourceStatus statusDate {826449A7-92F2-4fe5-86CF-C845F657A440} Time in market trading intervals the resource is in the state as of the end of the previous clearing period. timeInStatus {934B73D4-5C99-48ed-B245-3888E08E5EF8} Time interval timeInterval {13739F29-F1FC-4947-9629-2F29B962275B} The cause of this outage. This is the cause that is used to present to external entities. That is the cause is weather equipment failure etc.Note At present this is a free text could be replaced with a separate associated class in case we have multiple causes e.g. OutageCauseType inheriting from IdentifiedObject. cause {9A9D6ECC-E71D-4ffe-B0E0-189ABDD9F9D7} The earliest start time of the Outage as reported by some system or individual reportedStartTime {8EE3C1F7-19A7-462a-AC66-2051A65D4775} True if as a result of an inspection or otherwise there is a reason to suspect that a previous billing may have been performed with erroneous data. Value should be reset once this potential discrepancy has been resolved. checkBilling {DE77B4A2-8577-4794-A6E5-9FF152E87610} A code used to specify the connection category e.g. low voltage or low pressure where the usage point is defined. connectionCategory {A1047581-241C-49d1-8D53-50E0B42F6E87} Is an indication of how the usage point is physically connected or disconnected. disconnectionMethod {DD0D8899-65DB-4258-A2DA-E8FE6465F708} True if grounded. grounded {EAE2E1D6-0B57-4e0a-BBB1-735E2ACF1EE7} If true this usage point is a service delivery point i.e. a usage point where the ownership of the service changes hands. isSdp {947023F0-AAAE-4f68-9287-50DF8A55A4D0} If true this usage point is virtual i.e. no physical location exists in the network where a meter could be located to collect the meter readings. For example one may define a virtual usage point to serve as an aggregation of usage for all of a companys premises distributed widely across the distribution territory. Otherwise the usage point is physical i.e. there is a logical point in the network where a meter could be located to collect meter readings. isVirtual {3691658C-E34F-4fd0-92D4-A055A15072B7} If true minimal or zero usage is expected at this usage point for situations such as premises vacancy logical or physical disconnect. It is used for readings validation and estimation. minimalUsageExpected {08F9C82B-05D1-4ae2-AB07-12B0170ED05B} Outage region in which this usage point is located. outageRegion {F58AEBC9-9D5F-4c50-A440-16103B7DF4EA} Number of potential phases the Usage Point supports typically 0 1 or 3. phaseCount {2DE5C100-2339-41d7-B012-E7C31DFECA21} Cycle day on which the meter for this usage point will normally be read. Usually correlated with the billing cycle. readCycle {832B3B00-C670-40c6-949D-19596F8E59A7} Identifier of the route to which this usage point is assigned for purposes of meter reading. Typically used to configure hand held meter reading systems prior to collection of reads. readRoute {6177C257-3701-48f7-B963-C7EACFBA6A0F} Remarks about this usage point for example the reason for it being rated with a nonnominal priority. serviceDeliveryRemark {66DA89F1-3EE7-4327-A46E-633BF0494BF4} Priority of service for this usage point. Note that usage points at the same service location can have different priorities. servicePriority {056904FD-D8E9-47dc-9613-5072C0990148} Type of this group. type {251458FE-5F8E-4d0d-8D21-4AC014F8BF6D} Method for the service person to access this usage point location. For example a description of where to obtain a key if the facility is unmanned and secured. accessMethod {51B1450D-6E8F-4982-8FCF-447E433AC614} Remarks about this location. remark {4536E6A5-9BEF-4d39-B582-15478E14145A} Problems previously encountered when visiting or performing work at this location. Examples include bad dog violent customer verbally abusive occupant obstructions safety hazards etc. siteAccessProblem {C1F2DB7A-D6C4-4b21-B4B2-77673AC07D69} Name of an attribute. name {61DCC7D8-F3E1-43e0-8580-9BE21EA30F38} Sequence number for this attribute in a list of attributes. sequenceNumber {D0F92F6B-A5E3-43d3-9DCE-D60139E9D9FA} Rate at which output of adjuster changes iADJSLEWi. Unit s PU. Typical value 300. adjslew {E40DC976-74DA-4bd1-BA94-FAFC5867CFB6} Set high to provide a continuous raise or lower iViisubADJFsubi. vadjf {AB5A599F-D369-4b9c-AE39-2FA080357CAE} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {7C1AA2F8-727B-47f0-AA70-28914C61A015} The value that is mapped. value {562A0230-6FE6-41f6-89C5-57E9B98C6DF7} Date and time the last odometer reading was recorded. odometerReadDateTime {C990C069-8ABC-4f81-A6F7-141B33D84E56} If true merchantDebitAmount has been debited from MerchantAccount typically happens at the end of VendorShift when it closes. posted {CC31EC93-9592-4e35-86EE-65A2F8DB649B} freeform description of the condition to be verified verificationCondition {202ED7E9-A314-41a6-AC6B-E62E30281DB7} date of this version date {28057F96-3703-490c-BBF4-3A7113355B20} major release level for this version major {506A5FE7-3B02-46a0-B305-9B971798486B} minor release level for this version minor {1E1F60F9-2F44-4507-A2AB-74DC5AF2823A} revision level for this version revision {67BFB722-9A59-4a41-8651-3F13B7E19EA5} True if limit is enforced. enforced {E664258A-9A77-4787-9D04-BC291766B6D0} The drawing order for this layer. The higher the number the later the layer and the objects within it are rendered. drawingOrder {956B59BC-6351-48b2-8FA2-1C4DE7166D80} value {C86122FF-94E1-4244-975A-BA865D8135BC} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {E9E422A8-FB57-48d2-A7F7-BD93ED90FC77} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {AA098B5D-576E-4c99-8715-958458E897B6} value {B46101E6-5EB2-4dd5-ABC5-B1CB020B9DBA} value {02D7F4E6-03E6-463d-9DD9-1081B43B4961} value {EA19120F-0FA0-4791-9F6D-5D9B7FB8AFF0} The maximum quotient between the AC converter voltage Uc and DC voltage Ud. A factor typically less than 1. It is converters configuration data used in power flow. maxModulationIndex {890DE330-B4CC-41df-B43B-9DA0B7B53C8F} Magnitude of pulsemodulation factor. The attribute shall be a positive value. targetPWMfactor {AAF5738F-29D9-4895-A411-B84AACBD8D17} Power factor target at the AC side at point of common coupling. The attribute shall be a positive value. targetPowerFactorPcc {7BC0C6D9-916B-48a4-90E7-5579B10150E1} value {BC0A86DE-ECF3-4e90-9335-24C90AC029FD} value {56AFFD54-B3F6-4055-BCCA-03433BDE1555} Aerodynamic gain ikiisubasubi. It is a typedependent parameter. ka {4BD5FB0D-082E-447d-9E72-4E1546A5F68A} Limitation of type 3 stator current iMiisubDFSLimsubi. iMiisubDFSLimsubisub sub 1 for wind turbines type 4. It is a typedependent parameter.false total current limitation 0 in the IEC modeltruestator current limitation 1 in the IEC model. mdfslim {C06EF80E-98AC-4cf7-9DBB-484804AD024E} Prioritisation of Q control during UVRT iMiisubqprisubi. It is a projectdependent parameter.true reactive power priority 1 in the IEC modelfalse active power priority 0 in the IEC model. mqpri {9C297019-34D6-41ee-A6E8-DF334616C56F} Enable UVRT power control mode iMiisubpUVRTsubisubsub. It is a projectdependent parameter.true voltage control 1 in the IEC modelfalse reactive power control 0 in the IEC model. mpuvrt {33CE952A-663C-49c4-A3FD-54DA08E29FA4} Coefficient for active drive train damping izetai. It is a typedependent parameter. zeta {DB370774-9D9E-4dc4-A292-DC8A2EBB2C62} Maximum pitch positive ramp rate idthetaiisubmaxsubi gt WindContPitchAngleIEC.dthetamin. It is a typedependent parameter. Unit degrees s. dthetamax {DD5589AE-1698-4aab-A3C7-006D5B259721} Maximum pitch negative ramp rate idthetaiisubminsubiii lt WindContPitchAngleIEC.dthetamax. It is a typedependent parameter. Unit degrees s. dthetamin {E4F76455-9E09-4704-8615-16D6693A3C7D} Filter gain for generator speed measurement iKiisubomegafiltsubi. It is a typedependent parameter. komegafilt {2BEFAC34-6964-4557-AF8E-162F4F97B1F8} Filter gain for power measurement iKiisubpfiltsubi. It is a typedependent parameter. kpfilt {408F4D0F-4DFA-467e-BC4D-212E6B4070E6} Input value ixi for the lookup table function. input {3D0CAC57-B878-46ef-814D-537CC23015D6} Output value iyi for the lookup table function. output {D7130C3D-9647-4dcd-88C0-6C64AB515B91} Sequence numbers of the pairs of the input ixi and the output iyi of the lookup table function. sequence {6759556A-53A0-495d-BFF0-1BB5FED564F8} Current PI controller proportional gain iKiisubPcsubi. It is a typedependent parameter. kpc {87A8E6BB-9BBE-4b87-A537-A6B03D7D0B9F} Crowbar control mode iMiisubWTcwpsubi. It is a casedependent parameter.true 1 in the IEC modelfalse 0 in the IEC model. mwtcwp {A3515688-9988-4bfd-B20A-68A8B55D1901} Plant P controller integral gain iKiisubIWPpsubi. It is a projectdependent parameter. kiwpp {B3D70218-CCB1-4499-BBA2-A7FC4267E495} Plant P controller proportional gain iKiisubPWPpsubi. It is a projectdependent parameter. kpwpp {C2731D0B-83F1-45e7-8D80-84F975843026} Plant Q controller integral gain iKiisubIWPxsubi. It is a projectdependent parameter. kiwpx {3DD6277D-C34D-44db-A688-7E4BEA7D196E} Plant Q controller proportional gain iKiisubPWPxsubi. It is a projectdependent parameter. kpwpx {1A75A19B-D3BD-4adb-AF8E-C6C8E750E3FB} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {D41966C0-1FA9-4300-BA3E-3AC59E20B3F0} Zero crossing measurement mode iMzci. It is a typedependent parameter. true WT protection system uses zero crossings to detect frequency 1 in the IEC modelfalse WT protection system does not use zero crossings to detect frequency 0 in the IEC model. mzc {5DE5FE1A-DDC4-43e1-8976-3F23E5A58256} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {1B240E84-C463-4d23-AA73-477A8429D46A} Behaviour is based on a proprietary model as opposed to a detailed model.true userdefined model is proprietary with behaviour mutually understood by sending and receiving applications and parameters passed as general attributesfalse userdefined model is explicitly defined in terms of control blocks and their input and output signals. proprietary {1E6971EC-178F-43cc-8BCD-A1ADB88FD418} Status of Winding Insulation Power Factor as of statusDate Acceptable Minor Deterioration or Moisture Absorption Major Deterioration or Moisture Absorption Failed. insulationPFStatus {702AD4E8-234B-4feb-A2C4-5927155EBB86} For testType status of Winding Insulation Resistance as of statusDate. Typical values are Acceptable Questionable Failed. insulationResistance {E2216923-4AFE-4715-ACCD-95F397614FB5} if used Number of strands in the steel core. coreStrandCount {70338779-A979-480f-AB0C-0BD4C9C91E5F} True if conductor is insulated. insulated {85C3A0AF-D527-49f9-9DCA-931F50A7D466} Describes the wire gauge or cross section e.g. 40 2 336.5. sizeDescription {18872596-E683-4e8e-8A79-DE2A42BF7309} Number of strands in the conductor. strandCount {377416E1-F3C8-4f1a-8E84-0B4E53FD3583} Numbering for wires on a WireSpacingInfo. Neutrals should be numbered last. sequenceNumber {B39D9122-E640-4ab1-8C3B-CD6F5639F3C6} Number designation for this wire segment phase. Each wire segment phase within a wire segment should have a unique sequence number. sequenceNumber {A0CA13C1-E5B6-47a1-89F2-610E67B4D8B8} If true this spacing data describes a cable. isCable {9907BAFD-0E2F-45ee-B180-B80495E5DABB} Number of wire subconductors in the symmetrical bundle typically between 1 and 4. phaseWireCount {C85C7D02-5737-4811-9213-E14986EC4062} Date and time work was requested. requestDateTime {C729DE88-3CB0-4c8b-9565-CD57BC277DAB} Work order number or other unique identifying information for this work. workOrderNumber {9EFC239F-BA02-4e58-8A64-ED3828584598} Discount from standard price. discount {5D27D938-F07E-41a9-808D-52F833436DB6} Date and time by which payment for bill is expected from client. dueDateTime {ABD64D66-DFCF-4ec8-B878-66CBED859372} Date and time bill was issued to client. issueDateTime {59D59811-6D00-4cf9-99E6-7ACC994AB6AF} Date payment was received from client. receivedDateTime {D4C33DED-E38C-494e-8FFB-BF36FD6899CE} True if amount is a debit false if it is a credit. isDebit {BFB2FE68-FB2A-40e6-9B90-49D995BB53A7} Date and time that amount is posted to the work. transactionDateTime {FE7E2E1F-D451-4259-BF2B-515ED328B598} Used to define dependencies of each work flow step which is for the instance of WorkTask associated with a given instance of WorkFlow. sequenceNumber {E8421B81-A08C-4668-B4BB-B72103B70347} Date and time work task was completed. completedDateTime {4977EADE-2FE8-4978-AB0F-9AC3E4CF3E7E} Estimated time of arrival so that customer or policefire department can be informed when the crew will arrive. crewETA {A4C6BB0D-98DB-4b01-8D96-9EE682980DDA} Time and Date when the work task will be completed. estimatedCompletionTime {F57120CD-4EA2-48a7-9D39-6D9191B04559} Instructions for performing this task. instruction {A4E3668E-F6DB-4a42-B7D0-4E15EE8CCB51} If specified override schedule and perform this task in accordance with instructions specified here. schedOverride {F19422F8-BA4E-42da-B604-CCF2CC7B4E10} Date and time work task was started. startedDateTime {69087946-9C77-49de-9EDB-A6C7748D4718} A unit with valves for three phases together with unit control equipment essential protective and switching devices DC storage capacitors phase reactors and auxiliaries if any used for conversion. ACDCConverter {7BAF3CFD-55A3-4945-B51F-D3117CCB7F89} A DC electrical connection point at the ACDC converter. The ACDC converter is electrically connected also to the AC side. The AC connection is inherited from the AC conducting equipment in the same way as any other AC equipment. The ACDC converter DC terminal is separate from generic DC terminal to restrict the connection with the AC side to ACDC converter and so that no other DC conducting equipment can be connected to the AC side. ACDCConverterDCTerminal {58B81D5E-10FF-4e21-A564-304AD5297BAE} An electrical connection point AC or DC to a piece of conducting equipment. Terminals are connected at physical connection points called connectivity nodes. ACDCTerminal {D37077B9-3B0C-4c16-8F5F-9A6F2C83A7F2} A wire or combination of wires with consistent electrical characteristics building a single electrical system used to carry alternating current between points in the power system.For symmetrical transposed three phase lines it is sufficient to use attributes of the line segment which describe impedances and admittances for the entire length of the segment. Additionally impedances can be computed by using length and associated per length impedances.The BaseVoltage at the two ends of ACLineSegments in a Line shall have the same BaseVoltage.nominalVoltage. However boundary lines may have slightly different BaseVoltage.nominalVoltages and variation is allowed. Larger voltage difference in general requires use of an equivalent branch. ACLineSegment {625BD764-3907-4d65-8497-7FD09708BD8E} Represents a single wire of an alternating current line segment. ACLineSegmentPhase {84627F88-F666-4f07-890A-62622070CD0F} ADSInstructionTypeCommitment {A7302B16-BDEA-44f4-84C3-BB14238B3A89} MINCONSTRAINTMAXCONSTRAINTFIXEDCONSTRAINT ADSInstructionTypeOOS {6B50D9E2-ACFF-4dcd-AA03-2E2F1EF34878} Models Ancillary Service Requirements. Describes interval for which the requirement is applicable. ASRequirements {876735DA-B8B1-43b7-B00A-722B8BB05BD7} Standard published by ASTM ASTM International. ASTMStandard {50546C5D-FFCB-433e-868C-8DC104A32BC3} List of editions of ASTM standards. ASTMStandardEditionKind {6D7494AE-11A2-4d4d-A33F-B9852AF8A498} List of ASTM standards. ASTMStandardKind {0098C082-3C0F-488a-B495-F2338409C1DD} Acceptance test for assets. AcceptanceTest {CEA89CFD-93CD-4599-9940-BCB3369ECF93} A permit is sometimes needed to provide legal access to land or equipment. For example local authority permission for road works. AccessPermit {2EF3EB23-CD98-4c1f-9666-C99E392E8140} Creditdebit movements for an account. AccountMovement {7E314D6D-4B83-48e8-86C9-CCE6BCAB6BFE} Notifications for movein moveout delinquencies etc. AccountNotification {78D31291-F409-42c5-8671-BB2914DE33FB} Unit for accounting use either energyUnit or currencyUnit to specify the unit for value. AccountingUnit {5F0C90B2-8D7F-4468-B553-8A0AC39EA02E} Kind of accumulation behaviour for read measured values from individual end points. AccumulationKind {519F992F-632E-473a-BBC0-582B9734F927} Accumulator represents an accumulated counted Measurement e.g. an energy value. Accumulator {4A66104E-BA5F-446e-A5B6-C9BBAF00E0F3} Limit values for Accumulator measurements. AccumulatorLimit {58445F1F-311A-409e-9B07-F05F6BAACE20} An AccumulatorLimitSet specifies a set of Limits that are associated with an Accumulator measurement. AccumulatorLimitSet {25F6012B-0434-4c9b-8E77-E64E5897923B} This command resets the counter value to zero. AccumulatorReset {4B18D989-2A07-447e-B794-898A1DF10DEC} AccumulatorValue represents an accumulated counted MeasurementValue. AccumulatorValue {EBC302E8-45FB-4cb3-8F17-3CC7387EE297} The Area Control Error tariff type that is applied or used. AceTariffType {155F5F4F-E3DE-4ba2-9B2C-FFE5461E84A0} Action request against an existing Trade. ActionRequest {E7BE52F0-B8A9-4d48-B746-7B06946B50CA} Action type associated with an ActionRequest against a ParticipantInterfacesTrade. ActionType {5FF231B0-DE11-4e32-B970-0E658986ABCD} Product of RMS value of the voltage and the RMS value of the inphase component of the current. ActivePower {E52EDC2D-8972-42c7-A7EB-D8C017E138A4} Rate of change of active power per time. ActivePowerChangeRate {C872CC3E-AEC1-4ea2-93C8-0E51DDC2DA30} Limit on active power flow. ActivePowerLimit {37990C74-B64A-4f62-B6ED-FD6133282C42} Active power variation with current flow. ActivePowerPerCurrentFlow {D0F4E10E-A379-4a83-A452-974B8D2B45AD} Active power variation with frequency. ActivePowerPerFrequency {322D4C26-DEB6-4f9b-98CF-BA06ACD58EF8} Records activity for an entity at a point in time activity may be for an event that has already occurred or for a planned activity. ActivityRecord {53D429E3-8E92-4098-8545-54DEEFC803C9} BASELI NENEGOTIATED AdderType {60F4885F-4176-42fe-BF55-160ACAF74B6F} Groups Adjacent Control Areas. AdjacentCASet {BE7798B5-C117-4bb3-A680-7F58DACC00A2} Ratio of current to voltage. Admittance {30AC6821-E972-456a-8F64-0765D7361767} Kind of aggregation for read measured values from multiple end points. AggregateKind {62D8C9AB-8C4C-4ecf-B14B-7548CF58CFA4} An aggregated node can define a typed grouping further defined by the AnodeType enumeratuion. Types range from System ZoneRegions to Market Energy Regions to Aggregated Loads and Aggregated Generators. AggregateNode {E0B7E648-99FC-46e1-8F74-5A9BD098FE23} An aggregated indicative scoring by an analytic which is based on other analytic scores that can be used to characterize the health of or the risk associated with one or more assets. AggregateScore {BFA64B46-A4E4-424e-BCB9-67BA79DC21DE} An aggregated pricing node is a specialized type of pricing node used to model items such as System Zone Default Price Zone Custom Price Zone Control Area Aggregated Generation Aggregated Particpating Load Aggregated NonParticipating Load Trading Hub Designated Control AreaDCA Zone. AggregatedPnode {175E9723-D1D7-497a-A5BF-82FFBC0CC3D4} Formal agreement between two parties defining the terms and conditions for a set of services. The specifics of the services are in turn defined via one or more service agreements. Agreement {17B1479C-FC7D-4621-AF7F-BBA624EE6037} Combustion turbine air compressor which is an integral part of a compressed air energy storage CAES plant. AirCompressor {3620E654-094D-4422-8417-E50ADEF99CAB} AlarmDisplayType {F5077EC7-2BDC-4bc7-A2EA-652BBFFBA879} A named list of alert types.Note the name of the list is reflected in the .name attribute inherited from IdentifiedObject. AlertTypeList {2A1D60DD-5EE2-4c5d-9C38-3B2A84660EF8} AllocationEnergyTypeCode {E5C1B2E5-D611-46d6-BB83-6B5848E0A360} Models Market clearing results. Indicates market horizon interval based. Used by a market quality system for billing and settlement purposes. AllocationResult {0B5B92EF-D56F-4b91-8CC4-7C4464083896} Models Market clearing results in terms of price and MW values. AllocationResultValues {664E0009-1ADD-4795-A1C4-4C8DE37DCAB8} A prioritized measurement to be used for the generating unit in the control area specification. AltGeneratingUnitMeas {73E925B7-6B4A-45b9-B03E-3EE2FA3C1837} A prioritized measurement to be used for the tie flow as part of the control area specification. AltTieMeas {08FB5259-8BBB-4ca4-B812-541DCFE52997} AlternateModel {EE7CCD9D-C684-4b3d-816F-16343649AE68} AlternateModelGroup {E0956F63-50B6-4390-91B4-2E1194FB9B0D} Lifecycle states of the metering installation at a usage point with respect to readiness for billing via advanced metering infrastructure reads. AmiBillingReadyKind {E31A9764-F65A-4a70-B936-6128A32C0353} Analog represents an analog Measurement. Analog {BBCB109C-256C-42ee-9B78-8B17B54C9668} An analog control used for supervisory control. AnalogControl {EF5C08B7-CB93-438d-B73A-9F7406694697} Limit values for Analog measurements. AnalogLimit {7B8D1296-E9A1-4d2c-87AF-C3DED5FD9463} An AnalogLimitSet specifies a set of Limits that are associated with an Analog measurement. AnalogLimitSet {629BA1E7-A3FB-480f-93A6-0AE81750CC57} Limit type specified for AnalogLimits. AnalogLimitType {5C3BE105-70E4-4789-84FE-B6A1D3FFB5CF} Measurement quality flags for Analog Values. AnalogMeasurementValueQuality {B2F2CD2A-A979-4ce8-ACFC-514875F2F8C2} Categories of analog to digital or logical result comparison. AnalogToDigitalLogicKind {4A652597-C1C1-4ef1-ABB7-A33022ABE056} AnalogValue represents an analog MeasurementValue. AnalogValue {E8AD2B41-94FA-40e5-A1DC-96B7E0A8025C} An algorithm or calculation for making an assessment about an asset or asset grouping for lifecycle decision making. Analytic {827A4D52-94DC-449b-BD6A-4F9BCAEAB145} Possible kinds of analytics. AnalyticKind {A8C5490A-2C86-4fa6-BD75-391A9145E814} An indicative scoring by an analytic that can be used to characterize the health of or the risk associated with one or more assets. The analytic score reflects the results of an execution of an analytic against an asset or group of assets. AnalyticScore {F9FCF4BF-9DF2-47db-9FD7-608D02E3F3C8} Kind of anchor. AnchorKind {C8058D3C-2D3F-4036-8D55-14C034FADE2A} ancillary serivce types AncillaryCommodityType {87DD7832-25B0-456b-808D-8819FF7A4133} Model of results of market clearing with respect to Ancillary Service products. AncillaryServiceClearing {0137CEC6-490C-4189-8727-73C31AA6CE08} Measurement of angle in degrees. AngleDegrees {A633BDC9-A238-4f69-AF1B-FF8A5C2FFCC8} Phase angle in radians. AngleRadians {E491E83D-03A0-4cad-86D4-30A09EF320F3} AnnotatedProjectDependency {03CC228C-C9FF-4ffd-9F8E-760435D9D1C4} Aggregated Nodes Types for exampleulliSYS System ZoneRegion liululliRUC RUC Zone liululliLFZ Load Forecast Zone liululliREG Market EnergyAncillary Service Region liululliAGR Aggregate Generation Resource liululliPOD Point of Delivery liululliALR Aggregate Load Resource liululliLTAC Load TransmissionAccessCharge TAC GroupliululliACA Adjacent Control ArealiululliASR Aggregated System ResourceliululliECA Embedded Control Arealiul AnodeType {24EF2FC5-1D75-417f-881B-C45C0E8DC00C} Aggregate Node Types for exampleAG Aggregated GenerationCPZ Custom Price ZoneDPZ Default Price ZoneLAP Load Aggregation PointTH Trading HubSYS System ZoneCA Control AreaGA generic aggregationEHV 500 kVGH generic hubZN zoneINT InterfaceBUS Bus ApnodeType {7634CAB9-E602-483a-91AC-EF3B8D693A66} Product of the RMS value of the voltage and the RMS value of the current. ApparentPower {95576B4A-D9AC-49fc-82ED-CB6DB2CE8584} Apparent power limit. ApparentPowerLimit {4A84BEAD-A18F-4474-B5D6-471216783A07} Specifies the expected security mechanism per IEC 623514 to be utilized. ApplicationSecurityKind {74D73777-3CA4-4c75-9275-F97BD3AD3097} Meeting time and location. Appointment {C68E73D7-812C-4261-A207-A9781C6DB752} Person who acceptedsigned or rejected the document. Approver {DC3D9F04-D322-4d2d-9033-42C238CAD8B6} Area. Area {BD3D15F2-CB39-41a5-935D-7B8F490ECBF8} Areas present control mode. AreaControlMode {3B815580-37E3-4f7e-A282-D2762848B2C8} Enumeration for the type of area defined e.g. county state parish zipcode etc. AreaKind {F717AA93-4655-4e02-B8A8-1E4E0D83BB6D} AreaLoadBid is not submitted by a market participant into the Markets. Instead it is simply an aggregation of all LoadBids contained wtihin a specific SubControlArea. This entity should inherit from Bid for representation of the timeframe startTime stopTime and the market type. AreaLoadBid {C1523A5D-368D-4b7d-B379-FD344ABE9B5C} Area load curve definition. AreaLoadCurve {B75407FF-3F23-4159-B25E-8F0C6E9BDB1A} The control areas reserve specification. AreaReserveSpec {C493C9B4-DF5E-476c-8EBE-5B14C1E37306} A description for how to assemble model parts for a specific purpose. AssemblyDescription {446D63EB-80BB-405f-A221-B70FF41142A3} A collection of model parts when combined form a case or part of a case. AssemblyManifest {FC8FF3BB-E525-4d7c-A1E4-6B1C3320C6D9} Tangible resource of the utility including power system equipment various end devices cabinets buildings etc. For electrical network equipment the role of the asset is defined through PowerSystemResource and its subclasses defined mainly in the Wires model refer to IEC61970301 and model package IEC61970Wires. Asset description places emphasis on the physical characteristics of the equipment fulfilling that role. Asset {4F4AE641-1576-4f64-BE09-A19143D580F7} Definition of type of analog useful in asset domain. AssetAnalog {E20744C8-D46C-4617-957B-8FC0E2B39179} Asset that is aggregation of other assets such as conductors transformers switchgear land fences buildings equipment vehicles etc. AssetContainer {C871BF41-2266-4e8c-B45A-1534C39F8633} Deployment of asset deployment in a power system resource role. AssetDeployment {D5998006-5A79-4d0d-8E31-D6F88DD4C413} Definition of type of discrete useful in asset domain. AssetDiscrete {7033E036-B936-481d-9868-D636510904E7} Classifications of asset failures. AssetFailureClassification {01057CD3-8D73-4ef5-A952-DBFB54C079E5} What asset has failed to be able to do.Reason for breaker failure.Note This enumeration provides essential information to asset health analytics. The existing list is a starting point and is anticipated to be fleshed out further as requirements are better understood PAB 20160109. AssetFailureMode {45CFD460-7584-4b41-BFBA-619BB3A992CE} Function performed by an asset. AssetFunction {D61C3FF0-8CA9-4806-B99C-92A36C8B1194} A grouping of assets created for a purpose such as fleet analytics inventory or compliance management. AssetGroup {D12CA3E8-532D-46df-A804-131A56F3E56E} Possible kinds of asset groups. AssetGroupKind {61FE121F-F762-4873-96B9-EC5B01DBA4C6} Type of hazard that is posed to asset in this location.Note This enumeration provides essential information to asset health analytics. The existing list is a starting point and is anticipated to be fleshed out further as requirements are better understood PAB 20160109. AssetHazardKind {C1FC4F91-3E73-4782-8B0D-4BB7BDA876B0} An asset healthrelated event that is created by an analytic. The event is a record of a change in asset health. AssetHealthEvent {7F3BB06D-D6E2-42cc-B6ED-A298269A8889} Set of attributes of an asset representing typical datasheet information of a physical device that can be instantiated and shared in different data exchange contexts as attributes of an asset instance installed or in stock as attributes of an asset model product by a manufacturer as attributes of a type asset generic type of an asset as used in designsextension planning. AssetInfo {6D78A817-1BB4-4cb1-8478-11A40AF8F62F} Kinds of assets or asset components. AssetKind {F59B7C24-2676-4627-9CFF-4EA9AC02D336} Lifecycle states an asset can be in.While the possible lifecycle states are standardized the allowed transitions are not they are intended to be defined by the business process requirements of local implementations. AssetLifecycleStateKind {C07287F4-DEF3-481f-8BEE-705D116B6CA3} Potential hazard related to the location of an asset. Examples are trees growing under overhead power lines a park being located by a substation i.e. children climb fence to recover a ball a lake near an overhead distribution line fishing poleline contacting power lines dangerous neighbour etc. AssetLocationHazard {B4AC24E1-04E8-4237-9AE9-A81876210B6E} Catalogue of available types of products and materials that are used to build or install maintain or operate an Asset. Each catalogue item is for a specific product AssetModel available from a specific supplier. AssetModelCatalogue {6453AF51-F9D2-49b8-8FDA-BE5F7D2E96E0} Provides pricing and other relevant information about a specific manufacturers product i.e. AssetModel and its price from a given supplier. A single AssetModel may be availble from multiple suppliers. Note that manufacturer and supplier are both types of organisation which the association is inherited from Document. AssetModelCatalogueItem {0BC94DBD-0BA4-4298-8439-48D9C8EF9CC5} Usage for an asset model. AssetModelUsageKind {A72BDDB7-03B4-4754-8F5E-C1930D7F7923} Role an organisation plays with respect to asset. AssetOrganisationRole {67516A27-FDD6-42da-91E3-3A99CD80A662} Owner of the asset. AssetOwner {780D3A9C-A59A-4516-B7EB-60C24AA5F03B} An Asset Property that is described through curves rather than as a data point. The relationship is to be defined between an independent variable Xaxis and one or two dependent variables Y1axis and Y2axis. AssetPropertyCurve {908D87FF-0DB8-400f-9203-3C586099255A} Definition of type of string useful in asset domain. AssetStringKind {5859D755-5C64-48b5-9CB0-6A4483BE14C3} Definition of type of string measurement useful in asset domain. AssetStringMeasurement {355C200B-C09D-451c-A775-875CA3DC724D} Temperature or pressure type of asset analog. AssetTemperaturePressureAnalog {209F5C9F-32CE-4ac6-9D01-9FAD6305692B} Analogs representing temperatures or pressures related to assets. AssetTemperaturePressureAnalogKind {DD05A091-668C-4592-B797-8A7A81D597FA} Test lab that performs various types of testing related to assets. AssetTestLab {C5648348-94C3-4a7e-840C-430396199E06} Identity of personorganization that took sample. AssetTestSampleTaker {60605479-B20A-41da-B346-408E713B0070} Organisation that is a user of the asset. AssetUser {A64B92C7-CE4E-4fa7-BD95-00DA376237FF} An assignment is given to an ErpPerson Crew Organisation Equipment Item Tool etc. and may be used to perform Work WorkTasks Procedures etc. TimeSchedules may be set up directly for Assignments or indirectly via the associated WorkTask. Note that these associations are all inherited through the recursive relationship on Document. Assignment {DAB328F7-94C5-4470-8228-B5EC63800CD2} A rotating machine whose shaft rotates asynchronously with the electrical field. Also known as an induction machine with no external connection to the rotor windings e.g. squirrelcage induction machine. AsynchronousMachine {EC5FCEFF-1274-4771-9D92-C0FF7A100AB8} Asynchronous machine whose behaviour is described by reference to a standard model expressed in either time constant reactance form or equivalent circuit form font color0f0f0for by definition of a userdefined model.fontParameter detailsolliAsynchronous machine parameters such as iXl Xsi etc. are actually used as inductances in the model but are commonly referred to as reactances since at nominal frequency the PU values are the same. However some references use the symbol iLi instead of iXi.liol AsynchronousMachineDynamics {3459C70D-B2B9-4da0-93C9-AEC975B7B46C} The electrical equations of all variations of the asynchronous model are based on the AsynchronousEquivalentCircuit diagram for the direct and quadrature axes with two equivalent rotor windings in each axis. Equations for conversion between equivalent circuit and time constant reactance formsiXsi iXmi iXliiXi iXli iXmi x iXlr1 i iXm i iXlr1iiXi iXli iXmi x iXlr1i x iXlr2i iXmi x iXlr1i iXmi x iXlr2i iXlr1i x iXlr2iiToi iXmi iXlr1i iomegaiisub0subi x iRr1iiToi iXmi x iXlr1i iXmi x iXlr2i iXlr1i x iXlr2i iomegaiisub0subi x iRr2i x iXmi iXlr1iSame equations using CIM attributes from AsynchronousMachineTimeConstantReactance class on left of and AsynchronousMachineEquivalentCircuit class on right except as notedxs xm RotatingMachineDynamics.statorLeakageReactancexp RotatingMachineDynamics.statorLeakageReactance xm x xlr1 xm xlr1xpp RotatingMachineDynamics.statorLeakageReactance xm x xlr1 x xlr2 xm x xlr1 xm x xlr2 xlr1 x xlr2tpo xm xlr1 2 x pi x nominal frequency x rr1tppo xm x xlr1 xm x xlr2 xlr1 x xlr2 2 x pi x nominal frequency x rr2 x xm xlr1. AsynchronousMachineEquivalentCircuit {68994963-39CA-4837-BEE1-D4F0807E421F} Kind of Asynchronous Machine. AsynchronousMachineKind {03C06AF1-0AFA-4b28-8911-9258B630BBA4} Parameter detailsolliIf iX ii Xi a single cage one equivalent rotor winding per axis is modelled.liliThe ipi in the attribute names is a substitution for a prime in the usual parameter notation e.g. itpoi refers to iToi.liolThe parameters used for models expressed in time constant reactance form include RotatingMachine.ratedS iMVAbasei RotatingMachineDynamics.damping iDi RotatingMachineDynamics.inertia iHi RotatingMachineDynamics.saturationFactor iS1i RotatingMachineDynamics.saturationFactor120 iS12i RotatingMachineDynamics.statorLeakageReactance iXli RotatingMachineDynamics.statorResistance iRsi .xs iXsi .xp iXi .xpp iXi .tpo iToi .tppo iToi. AsynchronousMachineTimeConstantReactance {20220E3A-DD4F-41fc-B00D-188C7FDCE8D9} Asynchronous machine whose dynamic behaviour is described by a userdefined model. AsynchronousMachineUserDefined {7E2DDBDE-CC15-456c-94A0-B2201C7F2DA5} Analog float measuring an atmospheric condition. AtmosphericAnalog {0EE3CCDF-F8A8-42d5-9B94-142D58F87739} Kinds of analogs floats measuring an atmospheric condition. AtmosphericAnalogKind {12972324-2F51-42eb-8281-28F68495D162} An atmospheric phenomenon with a base and altitude providing the vertical coverage combined with the Location to provide three dimensional space. AtmosphericPhenomenon {F1AD8D7C-AA6E-4851-A962-BA2C2AD117E8} A class used to provide information about an attribute. AttributeInstanceComponent {908E7712-A11D-4b97-B631-3E0749BFF95D} Property for a particular attribute that contains name and value. AttributeProperty {6DE808FB-62C0-428a-BBF9-A6FCC534EA34} A class providing the identification and type of an auction. Auction {0BEEB3F1-7308-4074-9B32-36BAB2F54807} Person who created document or activity record. Author {ECE4B2D2-00C0-4f64-A658-76BD9A6E2773} Commitment instruction types. AutomaticDispInstTypeCommitment {46164A1F-AEF5-4d65-B589-49A23E056325} Automatic Dispatch mode. AutomaticDispatchMode {C910FC36-D192-46e2-8291-BB9D98E27DF0} Variable and dynamic part of auxiliary agreement generally representing the current state of the account related to the outstanding balance defined in auxiliary agreement. AuxiliaryAccount {F1D6FA24-D6CF-42de-A657-421C3EA19A6F} An adhoc auxiliary account agreement associated with a customer agreement not part of the customers account but typically subject to formal agreement between customer and supplier utility. Typically this is used to collect revenue owed by the customer for other services or arrears accrued with the utility for other services. It is typically linked to a prepaid token purchase transaction thus forcing the customer to make a payment towards settlement of the auxiliary account balance whenever the customer needs to purchase a prepaid token for electricity.The present status of the auxiliary agreement can be defined in the context of the utilitys business rules for example enabled disabled pending over recovered under recovered written off etc. AuxiliaryAgreement {6ED1E240-5AEA-4247-955F-B05AC035D644} Models Market clearing results for Auxiliary costs. AuxiliaryCost {B672FFF0-809C-4141-9128-CFBB46BB9E9E} AuxiliaryEquipment describe equipment that is not performing any primary functions but support for the equipment performing the primary function.AuxiliaryEquipment is attached to primary equipment via an association with Terminal. AuxiliaryEquipment {CB6ECCEF-5854-40ec-A5DD-6A4E884E859C} Models Auxiliary Values. AuxiliaryObject {F12818E1-7F34-4989-95D1-919A475D2FA8} Models Auxiliary Values. AuxiliaryValues {73B1200C-1488-4b81-8B29-743FC0FD6A59} The collection of all the availability schedules for a given time range. Only one availability plan shall be valid for the same period. AvailablityPlan {00A82713-6144-4fa4-AB22-ABA57C04F3E6} Boiling water reactor used as a steam supply to a steam turbine. BWRSteamSupply {0AF61476-B124-42e0-8DB8-09FDC27BA8EF} Organisation that is a commercial bank agency or other institution that offers a similar service. Bank {AA268BA3-B7CC-4f9b-9DFF-D1213564F804} Bank account. BankAccount {AF7F22F5-7DB8-42b2-8676-0F9B9F9E9C05} Details of a bank account. BankAccountDetail {1945A7C3-F822-45c2-B83E-EA1C5A11F43C} Possibly timevarying max MW or MVA and optionally Min MW limit or MVA limit Y1 and Y2 respectively assigned to a contingency analysis base case. Use CurveSchedule XAxisUnits to specify MW or MVA. To be used only if the BaseCaseConstraintLimit differs from the DefaultConstraintLimit. BaseCaseConstraintLimit {D8ED524F-AA1B-4ea0-986F-3D30F1C3D125} The BaseFrequency class describes a base frequency for a power system network. In case of multiple power networks with different frequencies e.g. 50 Hz or 60 Hz each network will have its own base frequency class. Hence it is assumed that power system objects having different base frequencies appear in separate documents where each document has a single base frequency instance. BaseFrequency {2FA6A39A-A920-4ab7-92DC-D005DDDBB348} The BasePower class defines the base power used in the per unit calculations. BasePower {A10836E5-09FC-4862-B3C3-96D52298E21B} Common representation for reading values. Note that a reading value may have multiple qualities as produced by various systems ReadingQuality.source. BaseReading {65C0D3F7-9A2B-47ed-8E6B-6F552338C7FA} Defines a system base voltage which is referenced. BaseVoltage {2E70DC9D-AEAE-46cc-B20A-C20A636AE9B0} Common representation for work and work tasks. BaseWork {1E095EF2-6606-4ede-A9E1-40D0E9881415} Schedule of values at points in time. BasicIntervalSchedule {848DEDB2-99A8-44ec-8319-F7629519D147} The state of the battery unit. BatteryStateKind {A7535AFF-0EA1-4791-B2C9-D5D366BB427A} An electrochemical energy storage device. BatteryUnit {8DEBA1CF-D08F-4587-8EC0-237B5DDBBD5C} A collection of power system resources within a given substation including conducting equipment protection relays measurements and telemetry. A bay typically represents a physical grouping related to modularization of equipment. Bay {45910062-D4E8-40ee-99EB-FEC14DD9FAB0} The bearing in degrees with 360 degrees being True North. Measured in degrees clockwise from True North. 0 degrees indicates no direction being given. Bearing {FAB258CB-D0F4-49eb-82B5-1E3FE343A1EE} Represents both bids to purchase and offers to sell energy or ancillary services in an RTOsponsored market. Bid {E904C7AF-F98A-4448-AC67-C1DD40DD70D4} The basis used to calculate the bid price curve for an energy default bid. BidCalculationBasis {1F88ACBA-D9D3-4060-8FE6-69ED252CE0EF} This class allows SC to input different time intervals for distribution factors. BidDistributionFactor {36444558-B7DA-402b-AF2C-2D4E99F67AE3} This class represent the error information for a bid that is detected during bid validation. BidError {AA5D4965-B660-42ad-BB28-BA85D33E6BC7} Containment for bid parameters that are dependent on a market product type. BidHourlyProductSchedule {49D7B906-B374-4e4c-A49F-18D8E096F5EC} Containment for bid hourly parameters that are not product dependent. BidHourlySchedule {42A3622D-147E-432e-A47E-EDD16C015035} For exampleS Mitigated by SMPM because of misconductL Mitigated by LMPM because of misconductR Modified by LMPM because of RMR rulesM Mitigated because of misconduct both by SMPM and LMPMB Mitigated because of misconduct both by SMPM and modified by LMLM because of RMR rulesO original BidMitigationStatus {4FDAC396-55D9-4e8d-9A3C-795331B27DD0} For exampleInitialFinal BidMitigationType {D6924D44-26E3-4a20-938D-DFEF4D64E6C4} This class represent the bid price cap. BidPriceCap {C9E06915-50FD-41b5-B96F-0BA132B19F8A} BidPriceCapType {C9A65772-C08E-42ec-93A1-86FDBA50AD29} Relationship between unit operating price in hour Yaxis and unit output in MW Xaxis. BidPriceCurve {D5563BE9-55F0-4d7f-B59C-90077147E532} Defines bid schedules to allow a product bid to use specified bid price curves for different time intervals. BidPriceSchedule {8CAB15B6-4EE6-4027-8418-4703559C1BA8} Defines self schedule values to be used for specified time intervals. BidSelfSched {2D9F58A7-8C03-43fa-95EB-C1B928777C1F} As set of mutually exclusive bids for which a maximum of one may be scheduled.Of these generating bids only one generating bid can be scheduled at a time. BidSet {4A2C7058-24F5-4782-9CFC-2CC12357DAD3} Status indication for bidsCV Conditionally Valid BidCM Conditionally Modified BidV Valid BidM Modified BidRJ Rejected BidI Invalid BidCX Cancelled BidO Obsolete BidCL Clean BidRP Replicated Bid BidStatusType {899191A0-41EC-4106-9EDF-0A97D7509159} The formal specification of specific characteristics related to a bid. BidTimeSeries {39712DC0-6B13-4680-AF0F-66E08AC6DE63} For exampleDEFAULTENERGYBIDDEFAULTSTARTUPBIDDEFAULTMINIMUMLOADBID BidType {75B5BC02-B0BB-4fc3-8502-EAC3A27977C7} Bid self schedule type has two types as the required output of requirements and qualified predispatch. BidTypeRMR {E57AD2E0-4F36-4c55-ADCD-FEB338707237} BilateralExchangeActor describes an actor that provides ICCP data consumes ICCP data or both. The ICCP data provider lists the data it makes available to an ICCP data consumer. This data is described by ProvidedBilateralPoints. The relation between an ICCP data provider and a consumer is established by a BilateralExchangeAgreement. It is up to the ICCP data consumer to select what ProvidedBilateralPoints to use. The selection made is not described in this information model. BilateralExchangeActor {C4C36CA2-2418-4e2f-A0FD-F819DCBC8DE6} This is the representation of the information exchange agreement between peers. BilateralExchangeAgreement {CF6011D0-FCF1-4f5b-8F98-B14770BEFE86} Bilateral transaction BilateralTransaction {28E537B0-A5D2-4482-86F7-AF980E2C1A1C} Models various charges to support billing and settlement. BillDeterminant {A99EBB39-5FB7-40c7-B742-26AC3A6B11F3} Kind of bill media. BillMediaKind {F3D3FF79-2E14-4bc1-989F-2F0471139227} BlockDispatchComponent {0F1D4F85-15C3-4a05-A1B2-674CCE3BBBF0} BlockDispatchInstruction {A6360DD7-6199-496b-8468-7B7AEB2AC68F} BlockDispatchOrder {47F3F95D-63E2-4377-B322-31F18349B271} BlockingFunction {92F1E635-AE65-44d5-99E4-903102F30657} Boiler control mode. BoilerControlMode {08E2F3C4-C40B-44d5-8D63-CF26F9E72DB8} A type with the value space true and false. Boolean {9F8964F1-6C32-465b-A83D-F5A201A291C3} Dynamic flows and ratings associated with a branch end. BranchEndFlow {34C5B4C6-E2B6-4dc5-AA4F-B1B1AAD61447} A group of branch terminals whose directed flow summation is to be monitored. A branch group need not form a cutset of the network. BranchGroup {A795B546-34EE-419f-B392-039926A2C6E3} A specific directed terminal flow for a branch group. BranchGroupTerminal {B0C18CF1-75AE-44f3-9466-ABD95FE287EC} A mechanical switching device capable of making carrying and breaking currents under normal circuit conditions and also making carrying for a specified time and breaking currents under specified abnormal circuit conditions e.g. those of short circuit. Breaker {380D92AA-1D80-4e84-A8EE-843DACEB59DD} Classifications of network roles in which breakers can be deployed. The classifications are intended to reflect both criticality of breaker in network operations and typical usage experienced by breaker.Note This enumeration provides essential information to asset health analytics. The existing list is a starting point and is anticipated to be fleshed out further as requirements are better understood PAB 20160109. BreakerApplicationKind {7FAB5599-1820-47d6-93FA-D35DB54D1DAA} Switching arrangement for bay. BreakerConfiguration {39D7FD4A-0CE4-41e0-B792-B4F546674C1C} Reason for breaker failure.Note This enumeration provides essential information to asset health analytics. The existing list is a starting point and is anticipated to be fleshed out further as requirements are better understood PAB 20160109. BreakerFailureReasonKind {CA4E2E0F-70B3-477e-B506-0B2333FCA021} Properties of breaker assets. BreakerInfo {5C4FDE4B-F495-43fa-A2C1-9E015D4E32CF} Possible types of breaker maintenance work. BreakerMaintenanceKind {0CFB19E4-A310-4416-A6E2-F8E722D12350} Breaker components and problem areas which can be the focus of a repair work task. BreakerRepairItemKind {4B0CA5ED-A380-4094-BBEE-6BE0EF12EDBE} Used to apply user standard names to TopologicalNodes. Associated with one or more terminals that are normally connected with the bus name. The associated terminals are normally connected by nonretained switches. For a ring bus station configuration all BusbarSection terminals in the ring are typically associated. For a breaker and a half scheme both BusbarSections would normally be associated. For a ring bus all BusbarSections would normally be associated. For a straight busbar configuration normally only the main terminal at the BusbarSection would be associated. BusNameMarker {CC2E7414-F646-406e-BFE1-86C1E97305FA} Busbar layout for bay. BusbarConfiguration {E0C6B20A-0FEB-4e84-81EE-B34E49A1371F} A conductor or group of conductors with negligible impedance that serve to connect other conducting equipment within a single substation. Voltage measurements are typically obtained from voltage transformers that are connected to busbar sections. A bus bar section may have many physical terminals but for analysis is modelled with exactly one logical terminal. BusbarSection {0A63A81D-5142-4736-BD22-8C28BA32F233} Busbar section data. BusbarSectionInfo {95039B97-087A-444e-9A08-E301D7CE84C7} Bushing asset. Bushing {A29CB50C-9E82-485c-B7B5-78159D2E2C05} Bushing datasheet information. BushingInfo {4DC01EF0-CC32-4ffd-AB7B-3FA7B8ADAFD9} Insulation kind for bushings. BushingInsulationKind {486A794A-2B6E-4226-A5CE-60F8BAE9F395} Bushing insulation power factor condition as a result of a test.Typical status values are Acceptable Minor Deterioration or Moisture Absorption Major Deterioration or Moisture Absorption Failed. BushingInsulationPF {86C23E36-C99E-40d6-867B-C28F0EEEA996} Kind of PF test for bushing insulation. BushingInsulationPfTestKind {F97CAA3B-0ADC-48a7-8683-B16A6F49F13C} Business justification for capital expenditures usually addressing operations and maintenance costs as well. BusinessCase {7D1894DE-529E-4574-80FA-AA8B38E9B88D} A BusinessPlan is an organized sequence of predetermined actions required to complete a future organizational objective. It is a type of document that typically references a schedule physical andor logical resources assets andor PowerSystemResources locations etc. BusinessPlan {03997F7F-AD67-447b-ACE7-F6201AB45D10} A business role that this organisation plays. A single organisation typically performs many functions each one described as a role. BusinessRole {CC1A0C97-3407-4923-8E44-A38D972175F4} Compressed air energy storage plant. CAESPlant {9B56B51B-E15A-4439-8F43-CBA3D7D29587} CCAinverter {099FB680-0560-4201-A6A6-39B3500DAC97} CCArectifierControl {90A5831E-597B-44bf-8364-261D3C6C6B20} Standard published by CIGRE Council on Large Electric Systems. CIGREStandard {10424179-9770-4002-9BBB-439A8D33EAF6} List of editions for CIGRE standards. CIGREStandardEditionKind {FED3D9B8-BD73-4dea-85A4-1556F72C59B7} List of CIGRE standards. CIGREStandardKind {C95BEFED-E3E1-4068-A095-DC5A87035AD7} Congestion Revenue Rights category types. CRRCategoryType {0890C55A-143E-48c3-BAEB-854733B12466} Congestion Revenue Right hedge type. CRRHedgeType {5E61277D-3A24-45dd-BD94-A44A0AE79CCC} Model that describes the Congestion Revenue Rights Auction Market. CRRMarket {C1414DA4-19B7-40a3-82D2-07730A10ED6F} Identifies a way in which an organisation may participate with a defined Congestion Revenue Right CRR. CRROrgRole {3806A99D-27A4-4019-B55D-288CA9D01F63} Role types an organisation can play with respect to a congestion revenue right. CRRRoleType {AFECA684-2442-4d80-B528-D26ABA629D5D} CRRSegment represents a segment of a CRR in a particular time frame. The segment class contains amount clearing price start date and time end date and time. CRRSegment {69DF78D3-49D3-476f-9D61-3F42EDB836BA} Type of the CRR from the possible type definitions in the CRR System e.g. LSE ETC. CRRSegmentType {B5915675-DD90-4e4c-BEF1-5C121B762665} CSC function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font CSCDynamics {A2A5768C-1A20-4d59-8531-83E3741AE6FD} Current source converter CSC function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font CSCUserDefined {D02997A4-6F37-4b54-A2E6-D77C20731D2C} CSCtype1 {C3AAA040-6C8A-4023-91B9-2A17211AC45F} Relationship between the combustion turbines power output rating in gross active power Xaxis and the ambient air temperature Yaxis. CTTempActivePowerCurve {69CCCEA0-DD09-4921-ABE4-D02ABF02888D} Allowed actions Install Remove Transfer Abandon etc. CUAllowableAction {E4E9DA68-B1C9-4003-AB25-8F49404DCBD0} Compatible unit contractor item. CUContractorItem {1154E13A-BB99-4075-AF1F-D572FE30B18F} A Compatible Unit Group identifies a set of compatible units which may be jointly utilized for estimating and designating jobs. CUGroup {E982DB17-483A-4dcc-B45E-2765C09C6E46} Labor code associated with various compatible unit labor items. CULaborCode {24A4AC0F-0478-4eea-AF98-F304F6802DC2} Compatible unit labor item. CULaborItem {5E6C18AB-5DAC-46d3-B5E3-9786534DBBAA} Compatible unit of a consumable supply item. For example nuts bolts brackets glue etc. CUMaterialItem {8775417D-D473-4904-9042-5E7AFC57FE87} Compatible unit for various types of WorkEquipmentAssets including vehicles. CUWorkEquipmentItem {5A25E9C1-6C9B-453f-890A-CA0A42110858} Enclosure that offers protection to the equipment it contains andor safety to peopleanimals outside it. Cabinet {D894078C-7AE7-41f6-A83A-797220A437B6} Kind of cable construction. CableConstructionKind {13DF7BB8-6268-45bb-9169-8F1A08072878} Cable data. CableInfo {5AF01DB8-B1BF-4c26-8CA4-8030D36E725A} Kind of cable outer jacket. CableOuterJacketKind {BAC4240E-5616-4e2c-8A6F-9F8689390E2E} Kind of cable shield material. CableShieldMaterialKind {5C33DFE0-CE5B-43ce-933A-8579E23D8006} Units in which calculation interval period is defined. CalculationIntervalUnitKind {363640F5-D9CD-4faf-8391-6EC9DD3B2E17} Categorisation of calculation operation that can be done to Measurement. CalculationKind {722FB9D1-7114-4a3c-87A0-2E26AEFC1A5B} The hierarchy of calculation methods used to derive this measurement. CalculationMethodHierarchy {714364FE-E1F5-4ccd-85DC-31D2161624AB} The order of this calculation method in a hierarchy of calculation methods. CalculationMethodOrder {7B6358E2-AA72-4ceb-AF3A-F6D39E42FEA6} The mode of the calculation total periodic sliding. CalculationModeKind {91395ECA-E9D9-4a79-8F11-4F9720C59655} Possible calculation techniques. CalculationTechniqueKind {D257257C-1B4A-4a04-8BB4-5A24948089DF} Capabilities of a crew. Capability {7620D5D2-6E91-4d2e-A316-706E8B4EA0C3} Capacitive part of reactance imaginary part of impedance at rated frequency. Capacitance {B2C696FA-9529-4b58-9D82-4062406AEACF} Capacitance per unit of length. CapacitancePerLength {7436C3C1-BA51-447f-B351-1C9FAA335847} Documentation of the tender when it is a type of card credit debit etc. Card {1AD7DFBB-5985-4510-9DDA-B0F019A8C24F} The operator of the point of sale for the duration of CashierShift. Cashier is under the exclusive management control of Vendor. Cashier {A27103EB-96BA-4f2e-9CE3-3B9FE8EE9776} The operating shift for a cashier during which the cashier may transact against the cashier shift subject to vendor shift being open. CashierShift {ED290EE7-433C-4457-977B-DF074546CBD3} a Assets that may be used for planning work or design purposes. CatalogAssetType {67717FD4-C9CF-40b6-B178-138A244718EA} Describes a set of changes that can be applied in different situations. A given registered target object MRID may only be referenced once by the contained change set members. ChangeSet {EDB0ACC9-0CE3-439f-ADC6-2D753A220486} A CRUDstyle data object. ChangeSetMember {B579C575-1165-4e6c-AFEF-991BBA193E2B} A single path for the collection or reporting of register values over a period of time. For example a register which measures forward energy can have two channels one providing bulk quantity readings and the other providing interval readings of a fixed interval size. Channel {EACF932A-D491-416b-9507-B0D9ED77CC37} A charge element associated with other entities such as tariff structures auxiliary agreements or other charge elements. The total charge amount applicable to this instance of charge is the sum of fixed and variable portion. Charge {036046C7-95D4-403e-9997-B628005B934B} A Charge Component is a list of configurable charge quality items to feed into settlement calculation andor bill determinants. ChargeComponent {4A37C8E3-7E6A-4893-A1DC-9D2427D16EDF} Charge Group is the grouping of Charge Types for settlement invoicing purpose. Examples such as Ancillary Services Interests etc. ChargeGroup {E649DF9F-A47D-4f5a-8BAD-6DBD3D2397F1} Kind of charge. ChargeKind {C71AE130-154B-47e8-8E5E-AB72E94007FD} A type of profile for financial charges. ChargeProfile {FE65A9AC-50B4-4e6e-A021-A8F3EE1A7109} Model of various charges associated with an energy profile to support billing and settlement. ChargeProfileData {51D83713-9EB5-4dba-A5EF-C2307F99096A} Charge Type is the basic level configuration for settlement to process specific charges for invoicing purpose. Examples such as Day Ahead Spinning Reserve Default Invoice Interest Charge etc. ChargeType {F63E4B25-4A11-4ee0-9B6B-D95CE0EA7304} To indicate a check out type such as adjusted capacity or dispatch capacity. CheckOutType {22857E68-E659-4640-99B1-9776F7607D96} The actual tender when it is a type of cheque. Cheque {DA6DAAA3-BB3B-40e1-B6B2-9FF3523D01A5} Kind of cheque. ChequeKind {7EA8BC38-802A-4015-AB68-17869B5D1ACB} Circuit {E27D9368-509B-4ea8-9C6C-99D10F5B57E1} A Clamp is a galvanic connection at a line segment where other equipment is connected. A Clamp does not cut the line segment. A Clamp is ConductingEquipment and has one Terminal with an associated ConnectivityNode. Any other ConductingEquipment can be connected to the Clamp ConnectivityNode. Clamp {7B0758AF-6E8E-438e-BD69-A838A56F256D} Action on Clamp as a switching step ClampAction {1A877B96-636E-4f6d-9F3D-CB43E3082464} Classification of level. Specify as 1..n with 1 being the most detailed highest priority etc as described on the attribute using this data type. Classification {567D00ED-9FD9-4cd1-9B12-70AEA6F11BFC} A classification condition used to define preconditions that must be met by a phenomena classification. ClassificationCondition {47D315F4-9E04-40f6-B847-BAD432CD200C} CleanTradeProductType {948F8057-E20F-4cfb-A1B4-BA9212DCD1A7} Action on clearance document as a switching step. ClearanceAction {9CBAB5BD-4103-4aad-A7C8-225F07CBB230} Type of clearance action. ClearanceActionKind {45A80A5F-B5F8-4b80-9B6A-A17BB65ED1AD} Safety document used to authorise work on conducting equipment in the field. Tagged equipment is not allowed to be operated. ClearanceDocument {99D01537-9D57-421f-B795-AD2E5C40B628} A classified cloud phenomenon with a type. CloudCondition {55D2D9CB-2F09-49c1-8D86-6D6E64F16913} Kind of cloud. CloudKind {DC50D0DC-713E-4bb2-9917-0BE1A4014100} Participation factors per Cnode. Used to calculate participation of Cnode in an AggregateNode. Each Cnode associated to an AggregateNode would be assigned a participation factor for its participation within the AggregateNode. CnodeDistributionFactor {75C2DA55-16A0-4a0f-877B-84D86388AE49} A set of thermal generating units for the production of electrical energy and process steam usually from the output of the steam turbines. The steam sendout is typically used for industrial purposes or for municipal heating and cooling. CogenerationPlant {E9D71516-7D2D-44d5-944E-C1E43E8D365E} Kind of communication direction. ComDirectionKind {93720672-7143-45d5-8911-0228006C90DB} Communication function of communication equipment or a device such as a meter. ComFunction {356285E8-FCBD-4668-B5C4-834A6952A941} Communication media such as fibre optic cable powerline telephone etc. ComMedia {EA0A4FD5-6DEF-4f94-8F9A-036844ECFCCF} An asset having communications capabilities that can be paired with a meter or other end device to provide the device with communication ability through associated communication function. An end device that has communications capabilities through embedded hardware can use that function directly without the communication module or combine embedded communication function with additional communication functions provided through an external communication module e.g. zigbee. ComModule {EF20287A-38B8-441c-B30F-FD1A333DC294} Kind of communication technology. ComTechnologyKind {3A4B0E91-7AA6-42cc-BC26-416A68711ED9} Configuration options for combined cycle units.For example a Combined Cycle with CT1 CT2 ST1 will have CT1 ST1 and CT2 ST1 configurations as part of1CT 1STlogicalconfiguration. CombinedCycleConfiguration {7F2322C7-014A-4fc7-9F69-3474C0B89F7B} Configuration Member of CCP Configuration. CombinedCycleConfigurationMember {36551068-B3D4-4e8a-81C1-9ABBE0558648} Logical Configuration of a Combined Cycle plant.Operating Combined Cycle Plant CCP configurations are represented as Logical CCP Resources. Logical representation shall be used for Market applications to optimize and control Market Operations. Logical representation is also necessary for controlling the number of CCP configurations and to temper performance issues that may otherwise occur. For example2CT configuration1CT 1ST configuration are examples of logical configuration without specifying the specific CT and ST participating in the configuration. CombinedCycleLogicalConfiguration {C0FA5D45-3A6A-4642-B2F1-6DFC1FC762E7} A set of combustion turbines and steam turbines where the exhaust heat from the combustion turbines is recovered to make steam for the steam turbines resulting in greater overall plant efficiency. CombinedCyclePlant {C2AD1355-F8F9-4a21-9EF9-E276C34F277C} Defines the available from and to Transition States for the Combine Cycle Configurations. CombinedCycleTransitionState {82FAAEFD-CC36-4327-95CD-730766F8E669} A prime mover that is typically fuelled by gas or light oil. CombustionTurbine {9BCFB807-2761-4db7-A0E1-66D834951CB1} A Command is a discrete control used for supervisory control. Command {9CE025EC-A020-4c5c-B91F-F8D64E61693F} Models results of market clearing which call for commitment of units. CommitmentClearing {05332947-266B-420b-ADCC-A18F03233938} For exampleSELF Self commitmentISO New commitment for this market periodUC Existing commitment that was a hold over from a previous market CommitmentType {27ACD4AD-8EB7-4ce3-9632-9659A310A907} Provides the necessary information on a resource basis to capture the StartupShutdown commitment results. This information is relevant to all markets. Commitments {9132926E-7D92-4cf3-AE39-062BF7ECA914} Commodities in the context of IEC 62325 are MarketProducts energy regulation reserve etc traded at a specific location which in this case is a Pnode either a specific pricing node or a pricing area or zone defined as a collection of pricing nodes. The CommodityDefinition is a container for these two parameters plus the unit of measure and the currency in which the Commodity is traded. Each CommodityDefinition should be relatively static defined once and rarely changed. CommodityDefinition {686D0DA4-E33A-423d-A375-8D61508FDA8C} Kind of commodity being measured. CommodityKind {A2E31B03-2F48-48e5-A761-4C372BE29E12} The CommodityPrice class is used to define the price of a commodity during a given time interval. The interval may be long e.g. a year or very short e.g. 5 minutes. There will be many instances of the CommodityPrice class for each instance of the CommodityDefinition to which it is associated. Note that there may be more than once price associated with a given interval and these variances are described by the association or associations with the PriceDescriptor class. CommodityPrice {968B606D-5FCF-4d80-86A4-66E5C19020BE} The connection to remote units is through one or more communication links. Reduntant links may exist. The CommunicationLink class inherits PowerSystemResource. The intention is to allow CommunicationLinks to have Measurements. These Measurements can be used to model link status as operational out of service unit failure etc. CommunicationLink {7F2B8FC0-FCB8-4dfb-9C1C-AF982DA0ABCC} A preplanned job model containing labor material and accounting requirements for standardized job planning. CompatibleUnit {0BA3A428-B0EC-43cd-8B48-D299F19C52C0} A complete model can be used in applications to perform meaningful calculations e.g. a study case in offline tools or a real time model in a SCADAEMS. CompleteModelToBeDeleted {FE21071F-E121-4ec9-9733-6214F296C60E} Compliance events are used for reporting regulatory or contract compliance issues andor variances. These might be created as a consequence of local business processes and associated rules. It is anticipated that this class will be customised extensively to meet local implementation needs.Use inherited type to indicate that for example expected performance will not be met or reported as mandated. ComplianceEvent {A10D9E17-4A19-40d7-A558-0C11D35E0CC8} A model of a set of individual Switches normally enclosed within the same cabinet and possibly with interlocks that restrict the combination of switch positions. These are typically found in medium voltage distribution networks. A CompositeSwitch could represent a RingMainUnit RMU or padmounted switchgear with primitive internal devices such as an internal busbar plus 3 or 4 internal switches each of which may individually be open or closed. A CompositeSwitch and a set of contained Switches can also be used to represent a multiposition switch e.g. a switch that can connect a circuit to Ground Open or Busbar. CompositeSwitch {6A5875D8-2294-45a2-BEE1-C33F5FEDF914} Properties of a composite switch. CompositeSwitchInfo {BCF8B2B0-005C-4b1d-9A98-EC3C473AFD22} Kind of composite switch. CompositeSwitchKind {718854EE-F86E-4308-A11D-8D179DA07DED} Concentric neutral cable data. ConcentricNeutralCableInfo {8941D960-35C7-43ed-967C-6A75F2F2C02A} This is to specify the various condition factors for a design that may alter the cost estimate or the allocation. ConditionFactor {0AD42B70-60D4-4b5a-85BF-A4647C70D45A} Kind of condition factor. ConditionFactorKind {89182E41-81F8-4c11-A5D4-6B68220A8B7E} Factor by which voltage must be multiplied to give corresponding power lost from a circuit. Real part of admittance. Conductance {CCE4615A-C403-4c96-8122-26904C128276} Real part of admittance per unit of length. ConductancePerLength {0C25DC23-EAD4-4ea0-B0C3-D7C46488E3F8} The parts of the AC power system that are designed to carry current or that are conductively connected through terminals. ConductingEquipment {7C5F19FB-5253-430c-8E53-BDCF7EBCE4C1} Combination of conducting material with consistent electrical characteristics building a single electrical system used to carry current between points in the power system. Conductor {C435D1A4-31AE-46ef-BCF8-7932F0785DA9} Used to report details on creation change or deletion of an entity or its configuration. ConfigurationEvent {6CAAAEB2-8624-419d-A80B-3E553C3CE444} ConformLoad represent loads that follow a daily load change pattern where the pattern can be used to scale the load with a system load. ConformLoad {B47EB000-9FCB-4543-B706-90486C3CBDD9} A group of loads conforming to an allocation pattern. ConformLoadGroup {AA76C755-C3AC-494a-A8C9-5D006148E811} A curve of load versus time Xaxis showing the active power values Y1axis and reactive power Y2axis for each unit of the period covered. This curve represents a typical pattern of load over the time period for a given day type and season. ConformLoadSchedule {36B21936-3BDC-4e05-BD1E-6938243903AA} Designated Congestion Area Definition DCA. CongestionArea {CBD147E6-2BFE-451e-A558-27BD22B7CDE1} Congestion Revenue Rights CRR class that is inherited from a Document class.A CRR is a financial concept that is used to hedge congestion charges.The CRR is usually settled based on the Locational Marginal Prices LMPs that are calculated in the dayahead market. These LMPs are determined by the Dayahead resource schedulesbids. CRRs will not hedge against marginal losses. If the congestion component of LMP at the sink is greater than at the source then the CRR owner is entitled to receive a portion of congestion revenues. If the congestion component at the sink is less than at the source then an obligationtype CRR owner will be charged but an optiontype CRR owner will not. CongestionRevenueRight {4F6C4284-2F00-40f9-82EB-B6723F0438FD} A function that will disconnect and reconnect the customers load under defined conditions. ConnectDisconnectFunction {8CFA1D56-DA8D-460e-B04A-8E95D3042C26} Connectivity nodes are points where terminals of AC conducting equipment are connected together with zero impedance. ConnectivityNode {8BCACC36-B2DD-4c2a-A2AE-CFDF43731FC2} A base class for all objects that may contain connectivity nodes or topological nodes. ConnectivityNodeContainer {B985C03E-46A3-4aec-B5B6-FDD983EBE621} A conductor or group of conductors with negligible impedance that serve to connect other conducting equipment within a single substation and are modelled with a single logical terminal. Connector {E33769DD-F111-4793-AF11-B4AFE5FDE50F} Groups all items associated with Binding Constraints and Constraint Violations per interval and market. ConstraintClearing {BE695822-33D6-4b39-A212-B6C5B4EF7459} Duration constraint to activate to put in operation to deactivate ... a given event. ConstraintDuration {4CD39F85-BB1B-4b04-BB68-CF9478CADBDF} Binding constraint results limit type For exampleMAXIMUMMINIMUM ConstraintLimitType {0ACB76B5-D584-430c-A28B-6DF5FDC471A6} Constraint Ramp type. ConstraintRampType {99FB8664-490F-451b-8347-F5B6E29E5553} Provides the Market results for the constraint processing for either the DAM or RTM. The data includes the constraint type binding or violated the solved value for the constraint and the associated shadow price. ConstraintResults {0B55B70E-F2A8-44b3-B9AE-18BCCB922A17} A constraint term is one element of a linear constraint. ConstraintTerm {0888D675-B5E4-464e-A422-E1FC0197BB36} One of a sequence of intervals defined in terms of consumption quantity of a service such as electricity water gas etc. It is typically used in association with TariffProfile to define the steps or blocks in a step tariff structure where startValue simultaneously defines the entry value of this step and the closing value of the previous step. Where consumption is startValue it falls within this interval and where consumption is startValue it falls within the previous interval. ConsumptionTariffInterval {DA1CBBFF-7002-47af-B95A-1EAAA72A6DFD} An event threatening system reliability consisting of one or more contingency elements. Contingency {59E66284-A133-41d8-908F-DC6F74DF6426} Possibly timevarying max MW or MVA and optionally Min MW limit or MVA limit Y1 and Y2 respectively assigned to a constraint for a specific contingency. Use CurveSchedule XAxisUnits to specify MW or MVA. ContingencyConstraintLimit {E1D7E102-8A3F-45de-A1C8-E6971CA32DD9} An element of a system event to be studied by contingency analysis representing a change in status of a single piece of equipment. ContingencyElement {53A27FB9-542A-4e43-B614-65F89F3AAD6A} Equipment whose in service status is to change such as a power transformer or AC line segment. ContingencyEquipment {1ED472A0-8419-4547-A0B3-86DBCB9831B4} Indicates the state which the contingency equipment is to be in when the contingency is applied. ContingencyEquipmentStatusKind {CFCD4106-3B7F-4dac-8553-B06D8CB19117} Distribution among resources at the sink point or source point. ContractDistributionFactor {55172C10-DFAF-4d6b-9240-8C107107B9C0} Provides definition of Transmission Ownership Right and Existing Transmission Contract identifiers for use by SCUC. RMR contract hosting Startup lead time Contract Service Limits Max Service Hours Max MWhs Max Startups Ramp Rate Max Net Dependable Capacity Min Capacity and Unit Substitution for DAMRTM to retrieve. ContractRight {FD1F57F3-DF0A-4e41-89FB-568A0D56E562} Transmission Contract Type For exampleO Other TE Transmission Export TI Transmission Import ETC Existing Transmission Contract RMT RMT Contract TOR Transmission Ownership Right RMR Reliability Must Run Contract CVR Converted contract ContractType {A3F13F7E-E69B-4442-963A-B84BF28E8677} Contractor information for work task. ContractorItem {5B20C21D-1D33-446d-B8E8-8F3096006156} Control is used for supervisorydevice control. It represents control outputs that are used to change the state in a process e.g. close or open breaker a set point value or a raise lower command. Control {4EEEE27D-42CD-4efc-8F74-3655BF703F4E} Control executed as a switching step. ControlAction {F90EA179-BE05-4f82-9287-CCF839EF5869} A control area is a grouping of generating units andor loads and a cutset of tie lines as terminals which may be used for a variety of purposes including automatic generation control power flow solution area interchange control specification and input to load forecasting. All generation and load within the area defined by the terminals on the border are considered in the area interchange control. Note that any number of overlapping control area specifications can be superimposed on the physical model. The following general principles apply to ControlArea1. The control area orientation for net interchange is positive for an import negative for an export.2. The control area net interchange is determined by summing flows in Terminals. The Terminals are identified by creating a set of TieFlow objects associated with a ControlArea object. Each TieFlow object identifies one Terminal.3. In a single network model a tie between two control areas must be modelled in both control area specifications such that the two representations of the tie flow sum to zero.4. The normal orientation of Terminal flow is positive for flow into the conducting equipment that owns the Terminal. i.e. flow from a bus into a device is positive. However the orientation of each flow in the control area specification must align with the control area convention i.e. import is positive. If the orientation of the Terminal flow referenced by a TieFlow is positive into the control area then this is confirmed by setting TieFlow.positiveFlowIn flag TRUE. If not the orientation must be reversed by setting the TieFlow.positiveFlowIn flag FALSE. ControlArea {EB35F9FE-F63C-47f6-B2E8-774B9B2735C8} Indicates Control Area associated with selfschedule. ControlAreaDesignation {9F672624-43B0-4b32-8BBE-9D9AE4479C53} A control area generating unit. This class is needed so that alternate control area definitions may include the same generating unit. It should be noted that only one instance within a control area should reference a specific generating unit. ControlAreaGeneratingUnit {F60BBA5C-76E4-4429-8437-2846CBBD9480} Operates the Control Area. Approves and implements energy transactions. Verifies both InterControl Area and IntraControl Area transactions for the power system before granting approval and implementing the transactions. ControlAreaOperator {448C950F-042A-485b-B70B-EE8A08FA381B} State Estimator Solution Pool Interchange and Losses. ControlAreaSolutionData {04E44222-CA1D-420b-8D13-09E39F714382} The type of control area. ControlAreaTypeKind {43F2CD5E-92F8-4668-968F-1250CA99B754} Appliance controlled with a PAN device control. ControlledAppliance {1336F01E-072B-44fd-9D24-EBC9EC60B281} Method of cooling a machine. CoolantType {B998EE6D-BC68-49d3-813C-F5AB11CF6CFD} Kind of cooling. CoolingKind {5F87FD5F-12DA-4fc9-B29C-5D3C5E0874FC} There are often stages of power which are associated with stages of cooling. For instance a transformer may be rated 121kV on the primary 15kV on the secondary and 4kV on the tertiary winding. These are voltage ratings and the power ratings are generally the same for all three windings and independent of the voltage ratings there are instances where the tertiary may have a lower power rating.For example for three stages the power rating may be 152025 MVA and the cooling is OAFAFOA. The 15 MVA rating goes with the OA cooling Oil and Air cooling. This is called the self cooled rating as there are no external cooling enhancements. The 20 MVA rating goes with the FA cooling Forced Air cooling this means that when the fans are running and thus enhancing the cooling characteristics the transformer can operate at a power level of 20 MVA. The 25 MVA rating goes with the FOA cooling Forced Oil and Air cooling this means that when the fans and pumps are running and thus enhancing the cooling characteristics even more than before the transformer can operate at a power level of 25 MVA. This 152025 MVA does not state how the power is split between the various windings. It may be 25 MVA input on the primary 25 MVA output on the secondary and 0 MVA output on the tertiary. It may also operate at 25 MVA input on the primary 17 MVA output on the secondary and 8 MVA output on the tertiary. CoolingPowerRating {2CAE8CD4-F78A-402e-9CF9-45A50E9A7D30} Coordinate reference system. CoordinateSystem {D7A22063-DBE9-467d-9E72-C32640FABCA0} Kind of corporate standard. CorporateStandardKind {A378DE43-41AA-4680-B481-A7C325C36EF4} For exampleBid CostProxy CostRegistered Cost CostBasis {43DD0511-E369-4fb5-A330-FCB1FA53C08F} Cost in units of currency per quantity of electrical energy generated. CostPerEnergyUnit {781B4357-DF24-4f4f-BBE3-8C8CE1C0F2E5} Cost in units of currency per quantity of heat generated. CostPerHeatUnit {E1913AA6-E24F-4b45-BB9B-946567FC7AF6} Cost per unit volume. CostPerVolume {56D3E01F-B21E-4f00-A8F1-CBC80D384B3B} Cost in units of currency per elapsed time. CostRate {A8B9F2B7-69E6-4698-8492-D6A8E70D8755} A categorization for resources often costs in accounting transactions. Examples include material components building in service coal sales overhead etc. CostType {53228BC5-8B43-4db9-BADE-6C63046E1D52} Kinds of weather condition coverage. CoverageCodeKind {20BCE8A9-2982-4817-B8C5-01F2991E1617} Craft of a person or a crew. Examples include overhead electric underground electric high pressure gas etc. This ensures necessary knowledge and skills before being allowed to perform certain types of work. Craft {8C0BFCC8-2AFC-46d1-A9AB-7922B3447265} Group of people with specific skills tools and vehicles. Crew {C9FE3505-80D0-4126-85C4-1218FCC4A61D} Member of a crew. CrewMember {4A7EA6E5-C75B-4670-B62D-3011D27EC685} Defines the current status of the Crew assigned arrived etc. CrewStatusKind {0256250A-25A5-444f-A3E8-EF37291A12FB} Custom description of the type of crew. This may be used to determine the type of work the crew can be assigned to. Examples include repair tree trimming switching etc. CrewType {5D649DCB-6D06-49f7-A675-23C3E5B180DC} Turbinegovernor crosscompound function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font CrossCompoundTurbineGovernorDynamics {9C543894-7669-4bd9-B389-C68E4C167F6E} DC side of the current source converter CSC.The firing angle controls the dc voltage at the converter both for rectifier and inverter. The difference between the dc voltages of the rectifier and inverter determines the dc current. The extinction angle is used to limit the dc voltage at the inverter if needed and is not used in active power control. The firing angle transformer tap position and number of connected filters are the primary means to control a current source dc line. Higher level controls are built on top e.g. dc voltage dc current and active power. From a steady state perspective it is sufficient to specify the wanted active power transfer ACDCConverter.targetPpcc and the control functions will set the dc voltage dc current firing angle transformer tap position and number of connected filters to meet this. Therefore attributes targetAlpha and targetGamma are not applicable in this case.The reactive power consumed by the converter is a function of the firing angle transformer tap position and number of connected filter which can be approximated with half of the active power. The losses is a function of the dc voltage and dc current.The attributes minAlpha and maxAlpha define the range of firing angles for rectifier operation between which no discrete tap changer action takes place. The range is typically 1018 degrees.The attributes minGamma and maxGamma define the range of extinction angles for inverter operation between which no discrete tap changer action takes place. The range is typically 1720 degrees. CsConverter {A4B7CE00-5051-45cf-B107-CD62C2FF3B81} Operating mode for HVDC line operating as Current Source Converter. CsOperatingModeKind {2B29A5B8-7C9E-458b-A8D7-897FE0BF52C8} Active power control modes for HVDC line operating as Current Source Converter. CsPpccControlKind {C5B4CF4C-2315-467f-9238-26B1ED7BAEBB} Monetary currencies. ISO 4217 standard including 3character currency code. Currency {157FF307-0C5D-4c09-A480-5EBB085B0E02} Control area emergency schedules CurrentEmergencyScheduledInterchange {224611F1-DC22-4b81-933D-EC3B674B1FB8} Electrical current with sign convention positive flow is out of the conducting equipment into the connectivity node. Can be both AC and DC. CurrentFlow {DC3FD69C-E9B2-440d-A113-BE84B71BA691} Operational limit on current. CurrentLimit {608E420F-FE83-4965-9ED8-F12FF4BCF787} A device that checks current flow values in any direction or designated direction. CurrentRelay {247B2098-278F-499e-ABC4-69CDCCCC7DAF} Control area current net tie scheduled interchange sent to real time dispatch. CurrentScheduledInterchange {AAA6979C-B99A-4b9c-9C68-79BCB4C539AF} CurrentState {68BF5F3C-57C0-4961-B749-E4706391D883} ACTIVEINACTIVE CurrentStatusSC {C4ED7836-B4AF-45a0-B462-99137A351CA9} Instrument transformer used to measure electrical qualities of the circuit that is being protected andor monitored. Typically used as current transducer for the purpose of metering or protection. A typical secondary current rating would be 5A. CurrentTransformer {24CFE1CD-BFCC-4212-A1F0-CB492DAA61EC} Properties of current transformer asset. CurrentTransformerInfo {33A8D4FA-A8E0-4882-B023-3EE729876FC1} Curtailing entity must be providing at least one service to the EnergyTransaction. The CurtailmentProfile must be completely contained within the EnergyProfile timeframe for this EnergyTransaction. CurtailmentProfile {C11A5B85-693D-412c-8B62-3A1008D90158} A multipurpose curve or functional relationship between an independent variable Xaxis and dependent Yaxis variables. Curve {73A500A6-E7FF-4abe-8FDA-E68B4E60FF9F} Multipurpose data points for defining a curve. The use of this generic class is discouraged if a more specific class can be used to specify the X and Y axis values along with their specific data types. CurveData {49452B3C-BB66-4c7a-A86B-6BE155BB7193} Style or shape of curve. CurveStyle {36FD838A-90B0-4634-A4F2-B6E431D246D7} Organisation receiving services from service supplier. Customer {80011596-1798-4c9c-94A2-182EE31D017B} Assignment of a group of products and services purchased by the customer through a customer agreement used as a mechanism for customer billing and payment. It contains common information from the various types of customer agreements to create billings invoices for a customer and receive payment. CustomerAccount {FCC72824-DB71-49ff-A5B7-BF1675CDA0A5} Agreement between the customer and the service supplier to pay for service at a specific service location. It records certain billing information about the type of service provided at the service location and is used during charge creation to determine the type of service. CustomerAgreement {5245DDE2-E142-46d1-B59C-512F29575A88} The creation of the monthly customer billing statements is the method employed to notify Customers of charges adjustments and credits applied to their account for Services and Products. The actuall billing occurs through an ErpInvoice. The CustomerBillingInfo includes information from the payment collection meter reading installed meter service site customer customer account customer agreement services and pricing subject areas. Each component price shows up as a separate line item on the ErpInvoice.The Customer Billing Statement may include collection and account messages marketingcivic event messages and bill inserts.One Customer Billing Statement is produced for all Agreements under a CustomerAccount per billing cycle date defined in CustomerAccount.billingCycle.The history of CustomerBillingInfo Invoices and Payments is to be maintained in associated ActivityRecords. CustomerBillingInfo {555E5812-1CAB-4db1-91AC-2A265CF3C3C5} Kind of customer billing. CustomerBillingKind {65173887-4B95-4890-A0B9-32C0303EEB2C} The energy buyer in the energy marketplace. CustomerConsumer {EED6DB7B-9331-4741-8911-8EE740B767AA} Kind of customer. CustomerKind {9BCC64AE-9D73-46d4-BFFF-FDBEF38B891A} Conditions for notifying the customer about the changes in the status of their service e.g. outage restore estimated restoration time tariff or service level change etc. CustomerNotification {DD7A6789-1AF7-48d8-BEA1-E65E8AFCA371} A cut separates a line segment into two parts. The cut appears as a switch inserted between these two parts and connects them together. As the cut is normally open there is no galvanic connection between the two line segment parts. But it is possible to close the cut to get galvanic connection.The cut terminals are oriented towards the line segment terminals with the same sequence number. Hence the cut terminal with sequence number equal to 1 is oriented to the line segments terminal with sequence number equal to 1.The cut terminals also act as connection points for jumpers and other equipment e.g. a mobile generator. To enable this connectivity nodes are placed at the cut terminals. Once the connectivity nodes are in place any conducting equipment can be connected at them. Cut {A7BE7DB8-C02A-427a-95EE-F342693F1590} Action on cut as a switching step. CutAction {40FB11D9-C203-4534-89FA-28F98BB3DC72} A cyclone or tropical cyclone a rapidlyrotating storm system characterized by a lowpressure center strong winds and a spiral arrangement of thunderstorms that produce heavy rain. Cyclone {F10D06E9-4C74-4c6d-8FAD-8099ECC3F04C} DAMMarketType {6C25932E-59FB-4c48-88A5-021742E5127D} An electrical connection point at a piece of DC conducting equipment. DC terminals are connected at one physical DC node that may have multiple DC terminals connected. A DC node is similar to an AC connectivity node. The model requires that DC connections are distinct from AC connections. DCBaseTerminal {F76397E4-74A4-4178-9434-E33C9EBC5E7C} A breaker within a DC system. DCBreaker {CB3F5326-2F99-442b-A0EC-ED9CDC93E629} A busbar within a DC system. DCBusbar {8D60113B-4F9F-4e1c-BF63-399A475D1276} Low resistance equipment used in the internal DC circuit to balance voltages. It has typically positive and negative pole terminals and a ground. DCChopper {D96FC474-26B0-4d61-893F-89BA88CB8B1A} The parts of the DC power system that are designed to carry current or that are conductively connected through DC terminals. DCConductingEquipment {2D8739A1-0186-49f3-8C35-04EDE046E614} The operating mode of an HVDC bipole. DCConverterOperatingModeKind {C8B0DDAD-5080-46ea-85B9-C23A0FA34DE8} Indivisible operative unit comprising all equipment between the point of common coupling on the AC side and the point of common coupling DC side essentially one or more converters together with one or more converter transformers converter control equipment essential protective and switching devices and auxiliaries if any used for conversion. DCConverterUnit {C9C13B9F-32C9-48cc-B9A5-1019739572D7} A disconnector within a DC system. DCDisconnector {A2D994B3-6F23-4d32-8C72-3DC4F3940BD2} A modelling construct to provide a root class for containment of DC as well as AC equipment. The class differ from the EquipmentContaner for AC in that it may also contain DCNodes. Hence it can contain both AC and DC equipment. DCEquipmentContainer {B7EB57A9-3AD6-40e2-9D5D-F391283E63B3} A ground within a DC system. DCGround {9C3BBD85-5358-4fb4-A4B5-9A1BB7278445} Overhead lines andor cables connecting two or more HVDC substations. DCLine {4C5447F8-6789-47ec-9729-6B7DB3330C1D} A wire or combination of wires not insulated from one another with consistent electrical characteristics used to carry direct current between points in the DC region of the power system. DCLineSegment {6AD33D6A-FCE0-48ab-99A6-522868A70AD2} DC nodes are points where terminals of DC conducting equipment are connected together with zero impedance. DCNode {203CCDC9-3887-4e57-8C59-B429AADB60F6} Polarity for DC circuits. DCPolarityKind {54D992DD-DA54-4e0b-81B3-263AF2896C50} A series device within the DC system typically a reactor used for filtering or smoothing. Needed for transient and short circuit studies. DCSeriesDevice {9E35D55D-1A94-4f1e-9313-1A6D03CB91B1} A shunt device within the DC system typically used for filtering. Needed for transient and short circuit studies. DCShunt {FF3349AD-8A10-4581-83AC-8906B6F29408} A switch within the DC system. DCSwitch {70FF7870-9AC4-453d-BF3E-7FD0F9E7193E} An electrical connection point to generic DC conducting equipment. DCTerminal {6D3668E7-3378-46de-B0B6-9EB6724C8326} An electrically connected subset of the network. DC topological islands can change as the current network state changes e.g. due to disconnect switches or breakers changing state in a SCADAEMS. manual creation change or deletion of topological nodes in a planning tool.Only energised TopologicalNodes shall be part of the topological island. DCTopologicalIsland {85B3B225-BD9B-4689-8878-0CEE3E06231B} DC bus. DCTopologicalNode {36E96930-3FAF-4844-91D4-7103E3D68EAA} DC voltage control used for voltage regulation. DCvoltageControl {8A8DDDF8-77D5-4212-9C16-9F19603AC192} DERCurveData {D94B7227-9399-4e16-BF77-4AA5007B7EEC} DERFunction {247CC932-35C1-4d1d-8085-29AE0CEBD920} DERGroupDispatch {83D2BB12-0256-4239-8034-FDF696C945EB} DERGroupForecast {F9CB8CC5-A128-4b25-8EF9-8C0280844DD2} DERMonitorableParameter {369FEE00-ABA6-424d-B6F7-7C1D777F5D8E} DERParameterKind {1D5BD9FF-A03A-4271-A8E4-73BF5431FF8C} The units defined for usage in the CIM. DERUnitSymbol {7102E1CC-0B48-42aa-B738-5DDC382A17FD} Standard published by DIN German Institute of Standards. DINStandard {A4B8945D-7CB4-4afe-85F8-9CFC03E01F75} List of editions for DIN standards. DINStandardEditionKind {D918E627-FC16-4619-BCA9-7D247824D070} List of DIN standards. DINStandardKind {7C5EF823-ACF1-4862-991D-497D65FA2C45} Perunit active power variation with frequency referenced on the system apparent power base. Typical values are in the range 10 20. Damping {9CD49278-B929-4acf-A09E-43660FD1F7F7} A generic container of a version of instance data. The MRID can be used in an audit trail not in reusable script intended to work with new versions of data.A dataset could be serialized multiple times and in multiple technologies yet retain the same identity. DataSet {28D05F59-6B53-4c1f-A18D-EE6B9CC533F9} A model operation argument referencing a dataset instance. DatasetArg {30320F4F-DE3F-4314-A4D8-B59B81D75099} DatasetArgDescription {01211A0F-1460-4fb8-97C0-2610DCF987AE} Date as yyyymmdd which conforms with ISO 8601. UTC time zone is specified as yyyymmddZ. A local timezone relative UTC is specified as yyyymmddhhmm. Date {C724EF94-9D38-4673-A889-46E7C5C6321C} The date andor the time. DateAndOrTime {209EDF47-74BC-4a80-BCF8-42F3960FFE71} Interval between two dates. DateInterval {28B6A229-F6A8-4d93-BD50-F337824B5C8F} Date and time as yyyymmddThhmmss.sss which conforms with ISO 8601. UTC time zone is specified as yyyymmddThhmmss.sssZ. A local timezone relative UTC is specified as yyyymmddThhmmss.ssshhmm. The second component shown here as ss.sss could have any number of digits in its fractional part to allow any kind of precision beyond seconds. DateTime {EEAE6E83-944C-489c-8E25-CFB85F80C3EB} Interval between two date and time points where the interval includes the start time but excludes end time. DateTimeInterval {DDF0ECB1-36BC-4660-912F-9B7EF4A672D2} Group of similar days. For example it could be used to represent weekdays weekend or holidays. DayType {FC479F3A-125F-4b0c-835F-6BE1361D1378} Decimal is the base10 notational system for representing real numbers. Decimal {9CD33DFD-D5FD-46a0-A320-11DFA5341F73} Quantity with decimal value and associated unit or currency information. DecimalQuantity {B344AA52-5E10-485f-A78F-8A7F0C5543C8} DefaultBid is a generic class to hold Default Energy Bid Default Startup Bid and Default Minimum Load BidDefault Energy BidA Default Energy Bid is a monotonically increasing staircase function consisting at maximum 10 economic bid segments or 10 MW MW pairs. There are three methods for determining the Default Energy BidulliCost Based derived from the Heat Rate or Average Cost multiplied by the Gas Price Index plus 10.liliLMP Based a weighted average of LMPs in the preceding 90 days.liliNegotiated an amount negotiated with the designated Independent Entity.liulDefault Startup BidA Default Startup Bid DSUB shall be calculated for each RMR unit based on the Startup Cost stored in the Master File and the applicable GPI and EPI.Default Minimum Load BidA Default Minimum Load Bid DMLB shall be calculated for each RMR unit based on the Minimum Load Cost stored in the Master File and the applicable GPI. DefaultBid {F22AD717-92CC-402d-B153-F7611EBA24A1} Default bid curve for default energy bid curve and default startup curves cost and time. DefaultBidCurve {4F72FADE-DFE4-40d9-8F6D-CA4B8F3AB58B} Curve data for default bid curve and startup cost curve. DefaultBidCurveData {138A7702-A943-43ce-BBBF-BC7A43E4CECE} Possibly timevarying max MW or MVA and optionally Min MW limit or MVA limit Y1 and Y2 respectively applied as a default value if no specific constraint limits are specified for a contingency analysis. Use CurveSchedule XAxisUnits to specify MW or MVA. DefaultConstraintLimit {40FB4806-7F6D-470d-9F6E-92F7A857A11B} All the measurements are filtered by a first lag element with a time constant TM. Delay {3A73496A-9549-4898-A98E-E7A51B9B8A6B} Demand response program. DemandResponseProgram {3AF161FE-E37F-43f2-9C8F-DB2CA19498A9} Demographic kind of a land property. DemographicKind {5728CCB3-280B-44d7-BCCB-906AA5369F62} DependencyKind {52E660F3-5A5F-4947-8252-DF6466A00B0B} Dates for deployment events of an asset. May have multiple deployment type dates for this device and a compound type allows a query to return multiple dates. DeploymentDate {FEF8B54C-8942-42b9-897B-C5B2D481E997} Possible states of asset deployment. DeploymentStateKind {5503A06C-B46F-43f9-9BC7-A9B9D4C113EC} A design for consideration by customers potential customers or internal work.Note that the Version of design is the revision attribute that is inherited from Document. Design {1D7DF3D9-EF02-4551-8494-AE5B859270CE} Kind of design. DesignKind {90CA1FD5-6E7B-4e77-AD7C-F20383CA6CED} A logical part of the design e.g. pole and all equipment on a pole. This includes points and spans. DesignLocation {19C5D8E2-644A-4ab7-9057-3D46A6538905} Compatible unit at a given design location. DesignLocationCU {F7726C92-5D4D-4254-B628-8E3DE89B0D83} The result of a problem typically an asset failure diagnosis. Contains complete information like what might be received from a lab doing forensic analysis of a failed asset. DiagnosisDataSet {F2EE22E4-D486-420a-9E8C-86C8CDFBFB08} The diagram being exchanged. The coordinate system is a standard Cartesian coordinate system and the orientation attribute defines the orientation. The initial view related attributes can be used to specify an initial view with the xy coordinates of the diagonal points. Diagram {E982A207-6642-4fb9-A092-40DFA2B37027} An object that defines one or more points in a given space. This object can be associated with anything that specializes IdentifiedObject. For single line diagrams such objects typically include such items as analog values breakers disconnectors power transformers and transmission lines. DiagramObject {E5A0EE1A-EA81-4542-8974-B5D3C2F3F465} This is used for grouping diagram object points from different diagram objects that are considered to be glued together in a diagram even if they are not at the exact same coordinates. DiagramObjectGluePoint {9C1F1E7A-8711-422b-9415-9BCC8A04C0CD} A point in a given space defined by 3 coordinates and associated to a diagram object. The coordinates may be positive or negative as the origin does not have to be in the corner of a diagram. DiagramObjectPoint {4E77FE4E-1547-4538-A26A-26B06F42FA7C} A reference to a style used by the originating system for a diagram object. A diagram object style describes information such as line thickness shape such as circle or rectangle etc and colour. DiagramObjectStyle {2145CBC1-D95B-40b2-BCF9-A9ED41CE9941} The diagram style refers to a style used by the originating system for a diagram. A diagram style describes information such as schematic geographic etc. DiagramStyle {30A35FB7-F62D-46cf-BB1E-B6F33BD62651} A set of statements describing the changes in the network model. The statement is defined in the incremental model. DifferentialModel {E63CEC57-1DFA-4871-A262-F97DA6B8FE1C} As applicable the basic linear area or volume dimensions of an asset asset type AssetModel or other type of object such as land area. Units and multipliers are specified per dimension. DimensionsInfo {7E0E8F43-9DFD-4c50-9367-E7C7F65E648D} IEEE type DEC1A discontinuous excitation control model that boosts generator excitation to a level higher than that demanded by the voltage regulator and stabilizer immediately following a system fault.Reference IEEE 421.52005 12.2. DiscExcContIEEEDEC1A {A1EB988B-922A-43f8-A266-0B77B8F608A1} IEEE type DEC2A model for discontinuous excitation control. This system provides transient excitation boosting via an openloop control as initiated by a trigger signal generated remotely.Reference IEEE 421.52005 12.3. DiscExcContIEEEDEC2A {15DE3E2D-E9AD-4074-B6F7-4EA21A53D37C} IEEE type DEC3A model. In some systems the stabilizer output is disconnected from the regulator immediately following a severe fault to prevent the stabilizer from competing with action of voltage regulator during the first swing.Reference IEEE 421.52005 12.4. DiscExcContIEEEDEC3A {7D872155-7DE6-4dab-93A2-294AEC702FEB} A circuit breaking device including disconnecting function eliminating the need for separate disconnectors. DisconnectingCircuitBreaker {E15222BE-C02A-4417-AED7-A395E55A943A} A manually operated or motor operated mechanical switching device used for changing the connections in a circuit or for isolating a circuit or equipment from a source of power. It is required to open or close circuits when negligible current is broken or made. Disconnector {1B506DF7-CBD6-492a-8C9E-F6752F0F0185} Discontinuous excitation control function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined modelfont. DiscontinuousExcitationControlDynamics {B202808C-F4AE-457c-AFE0-B83E8F033A18} Discontinuous excitation control function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font DiscontinuousExcitationControlUserDefined {6BE446BD-B68F-471c-A74B-12660BFD8B59} Discrete represents a discrete Measurement i.e. a Measurement representing discrete values e.g. a Breaker position. Discrete {57AFC760-6CA7-42c5-B988-36221A805D38} Measurement quality flags for Discrete Values. DiscreteMeasurementValueQuality {735537BE-F1C8-49da-8742-CD2F148BA9D4} DiscreteValue represents a discrete MeasurementValue. DiscreteValue {11E52FB7-7CC9-486d-BDA1-A069F388E930} DispatchAcceptStatus {C7810608-5927-439f-822F-A028FC453FB5} Response from registered resource acknowledging receipt of dispatch instructions. DispatchInstReply {7A517BE6-6CC4-4c3a-B95D-700524D10493} For exampleNONRESPONSEACCEPTDECLINEPARTIAL DispatchResponseType {CD7CD960-8FA3-4c76-88A9-2C51DC013799} DispatchSchedule {AE7805A5-0914-464e-A1BD-C30BB36F0360} DispatchTransactionType {91B09035-05A0-4374-AD01-9B8DE8B5B204} DispatchablePowerCapability {4CD4BCA8-8938-4d8f-92F6-FFB715636B67} Unit of displacement relative to a reference position hence can be negative. Displacement {9B356995-DED3-46c2-8DB7-AE244D4D3644} A demand response event is created when there is a need to call upon resources to respond to demand adjustment requests. These events are created by ISORTO system operations and managed by a demand response management system DRMS. These events may or may not be coordinated with the Market Events and a defined Energy Market. The event will call for the deployment of a number of registered resources or for deployment of resources within a zone an organizational area within the power system that contains a number of resources. DistributedResourceActualEvent {846E5539-74A2-4faa-BCD9-B72523D08DFD} A containing class that groups all the distribution factors within a market. This is calculated daily for DA factors and hourly for RT factors. DistributionFactorSet {1E74415F-603A-40d9-BBCC-5C768430FD5E} Standard published by Doble. DobleStandard {4D299512-B9E0-4eda-A22D-8DC696AE063A} List of editions for Doble standards. DobleStandardEditionKind {2021EF35-E613-44a8-9609-BE05BB5A5AF8} List of Doble standards. DobleStandardKind {D7C30DA4-EDAE-4ded-8069-C316A8818A6A} Parent class for different groupings of information collected and managed as a part of a business process. It will frequently contain references to other objects such as assets people and power system resources. Document {EF39687B-42C9-4204-972C-0F1A9520DC31} Role an organisation plays with respect to documents. DocumentOrganisationRole {21F86ABB-5B2E-4011-98BB-34DA11EDA879} Person role with respect to documents. DocumentPersonRole {077D806F-81FF-46c2-841F-C322B4B3AFE8} An area of activity defined within the energy market. Domain {38DEC768-A35A-4213-BC91-5BA8187A564D} Provides the necessary information on a resource basis to capture the Dispatch Operating Point DOP results on a Dispatch interval. This information is only relevant to the RT interval market. DopInstruction {B6174126-E8E3-48d8-9573-FE95E1ABCED1} Provides the necessary information on a resource basis to capture the Dispatch Operating Target DOT results on a Dispatch interval. This information is only relevant to the RT interval market. DotInstruction {09D2117F-38CF-4cb5-BCFC-82787ED71AAA} Governor droop signal feedback source. DroopSignalFeedbackKind {1E70C8DC-5E3B-4808-80FE-4D191596ABE9} Drum boiler. DrumBoiler {3B3A9E99-55A6-49c1-A8E8-3D7881624BCE} A duct contains individual wires in the layout as specified with associated wire spacing instances number of them gives the number of conductors in this duct. DuctBank {55A6E582-CD40-43be-BFC1-6ED585946784} Details on amounts due for an account. Due {33ADB344-ACC2-443a-AE02-258AD2AA6C72} Duration as PnYnMnDTnHnMnS which conforms to ISO 8601 where nY expresses a number of years nM a number of months nD a number of days. The letter T separates the date expression from the time expression and after it nH identifies a number of hours nM a number of minutes and nS a number of seconds. The number of seconds could be expressed as a decimal number but all other numbers are integers. Duration {D19C4E05-3FD5-484f-A4D2-CBD48E5A34D0} A continuously variable component of a control areas MW net interchange schedule. Dynamic schedules are sent and received by control areas. DynamicSchedule {C2098222-C39F-4bf7-BCB9-71A9CCD96D0B} Abstract parent class for all Dynamics function blocks. DynamicsFunctionBlock {1CD8BBD4-A285-4466-A0D2-C02CB645EFBB} Standard published by EPA United States Environmental Protection Agency. EPAStandard {45B27DCE-A4DC-430b-9501-4A23D7993BEE} List of editions for EPA standards. EPAStandardEditionKind {5930F0B9-A581-4897-B001-D8552902E2AE} List of EPA standards. EPAStandardKind {6E4D6FF6-FFD8-4982-85D8-51BA27F3245F} The estimated time of restoration can have a confidence factor applied such as high or low confidence that the ERT will be accomplished. This confidence factor may be updated as needed during the outage period just as the actual ERT can be updated. ERTConfidenceKind {F71CD8B5-221E-4900-B9AF-51866AC236F1} A conducting equipment used to represent a connection to ground which is typically used to compensate earth faults. An earth fault compensator device modelled with a single terminal implies a second terminal solidly connected to ground. If two terminals are modelled the ground is not assumed and normal connection rules apply. EarthFaultCompensator {99B51F43-C935-4382-AB8A-6352DAB082D4} An earthquake. Earthquake {373062A9-7596-4730-8087-BC3A476D7017} Person who modified the document. Editor {8D12ED95-AB71-4d76-BA0D-2C318F5CD164} Electronic address information. ElectronicAddress {77039F8D-76F9-4d56-8B1B-23F26D4CF355} Quantity of emission per fuel heat content. Emission {E1046D37-77EE-42b0-832A-8AF115835122} Accounts for tracking emissions usage and credits for thermal generating units. A unit may have zero or more emission accounts and will typically have one for tracking usage and one for tracking credits. EmissionAccount {86DC2BBA-08D4-4334-99C1-D40983F7F1AF} Relationship between the units emission rate in units of mass per hour Yaxis and output active power Xaxis for a given type of emission. This curve applies when only one type of fuel is being burned. EmissionCurve {A694A74C-046A-40e2-8A0F-EB8CC8F81BCD} The type of emission. EmissionType {6BD2D9BD-8C9F-421c-8E0B-2B6B81ECC31F} The source of the emission value. EmissionValueSource {CEFBC9A4-53DF-487d-B557-DA0A61E2D090} Asset container that performs one or more end device functions. One type of end device is a meter which can perform metering load management connectdisconnect accounting functions etc. Some end devices such as ones monitoring and controlling air conditioners refrigerators pool pumps may be connected to a meter. All end devices may have communication capability defined by the associated communication functions. An end device may be owned by a consumer a service provider utility or otherwise.There may be a related end device function that identifies a sensor or control point within a metering application or communications systems e.g. water gas electricity.Some devices may use an optical port that conforms to the ANSI C12.18 standard for communications. EndDevice {E17004EF-EA47-4c62-9520-DA35E34F44D8} Actioncommand performed by an end device on a device other than the end device. EndDeviceAction {B4547927-0523-404d-85BF-4BA4176B2AD4} Inherent capabilities of an end device i.e. the functions it supports. EndDeviceCapability {27FAE402-A373-4580-83D4-4EF96A4F374D} Instructs an end device or an end device group to perform a specified action. EndDeviceControl {8EBA0240-AFA2-4247-BD90-5F01BF12B58B} Detailed description for a control produced by an end device. Values in attributes allow for creation of recommended codes to be used for identifying end device controls as follows type.domain.subDomain.eventOrAction. EndDeviceControlType {89967067-2948-49a7-80D8-5CAEE2182D20} Event detected by a device function associated with the end device. EndDeviceEvent {8788133B-E8AC-4df3-B820-7941507682EA} Namevalue pair specific to end device events. EndDeviceEventDetail {912FE8C4-6F96-4b12-A966-1CD1F895FFD3} Detailed description for an event produced by an end device. Values in attributes allow for creation of recommended codes to be used for identifying end device events as follows type.domain.subDomain.eventOrAction. EndDeviceEventType {EFC40D9F-D56D-4433-B46E-2FE1A129CF89} Function performed by an end device such as a meter communication equipment controllers etc. EndDeviceFunction {2D3B1D7A-126C-4978-AD23-878983457DA8} Kind of end device function. EndDeviceFunctionKind {642E41B6-A2B7-4b81-BDC9-40F67AF173D5} Abstraction for management of group communications within a twoway AMR system or the data for a group of related end devices. Commands can be issued to all of the end devices that belong to the group using a defined group address and the underlying AMR communication infrastructure. A DERGroup and a PANDeviceGroup is an EndDeviceGroup. EndDeviceGroup {C8623B62-CFD3-4cf7-BFBD-65A72EA7A61E} End device data. EndDeviceInfo {99DD997C-F77C-4153-BD29-301334A613CA} Timing for the control actions of end devices. EndDeviceTiming {BD68DA41-C97B-4bf3-B2E3-614107744D35} Describes an area having energy production or consumption. Specializations are intended to support the load allocation function as typically required in energy management systems or planning studies to allocate hypothesized load levels to individual load points for power flow analysis. Often the energy area can be linked to both measured and forecast load levels. EnergyArea {EBAF7081-971E-4960-A0AB-B38C20682FE7} EnergyComponent {31D86E1E-863D-4d07-BBD5-5D1373BBEBC0} A connection of energy generation or consumption on the power system model. EnergyConnection {13966DE6-BE71-4f50-8051-2A082891138D} Generic user of energy a point of consumption on the power system model.EnergyConsumer.pfixed .qfixed .pfixedPct and .qfixedPct have meaning only if there is no LoadResponseCharacteristic associated with EnergyConsumer or if LoadResponseCharacteristic.exponentModel is set to False. EnergyConsumer {BCEC7EE8-7294-4b50-8216-0286C31A035C} Action to connect or disconnect the Energy Consumer from its Terminal EnergyConsumerAction {1FCCA0EA-FB27-4e4e-9016-17E451BAAD4B} A single phase of an energy consumer. EnergyConsumerPhase {2933FF4A-CF68-4099-B3FE-DBE8919C85AE} EnergyGroup {13F95157-0F4C-4040-B1E9-C83D5F382D52} Energy and Ancillary Market e.g. Energy Spinning Reserve NonSpinning Reserve with a description of the Market operation control parameters. EnergyMarket {F337A947-95CB-4554-BC83-05EEA592CB8E} Relationship between a price in or other monetary unit hour Yaxis and a MW value Xaxis. EnergyPriceCurve {4DE57A72-7481-4ba0-AFEE-5B5A86F4F166} An Energy Price Index for each Resource is valid for a period e.g. daily that is identified by a Valid Period Start Time and a Valid Period End Time. An Energy Price Index is in MWh. EnergyPriceIndex {63BC381D-F1F5-4881-9543-DFE3E000878E} For exampleWHOLESALERETAILBOTH EnergyPriceIndexType {BC4A9076-4E86-4c95-A64D-D2981C6E1DED} An EnergyProduct is offered commercially as a ContractOrTariff. EnergyProduct {19926DEE-044E-4b26-84C3-E43379FDDD84} Energy product type. EnergyProductType {B4EB7F1F-E534-4ed9-B1B2-5474E9B13D45} Specifies the start time stop time level for an EnergyTransaction. EnergyProfile {46A60F35-459E-4dec-BD8D-FE46FB498CD6} Used to define the type of generation for scheduling purposes. EnergySchedulingType {8FD4114B-3942-4e7c-8E33-9600BA19CF38} A generic equivalent for an energy supplier on a transmission or distribution voltage level. EnergySource {7174F78A-A2B7-457a-8EBC-4E9CBA6DA738} Action on energy source as a switching step. EnergySourceAction {6E3EDC0D-EE7D-4e40-89BC-859964F2834C} Represents the single phase information of an unbalanced energy source. EnergySourcePhase {1EABE5E1-F61A-4758-ADFC-E9C816E97063} Specifies the schedule for energy transfers between interchange areas that are necessary to satisfy the associated interchange transaction. EnergyTransaction {3AA037B3-088F-48cd-A4D1-F72BE3E8BE83} Defines the state of a transaction. EnergyTransactionType {3C2349F8-E1BD-4fe3-943C-28C8A18116D1} Valid Enumerations1 DASE Day Ahead Scheduled Energy 2 DSSE Day Ahead Incremental Self Schedule Energy 3 DABE Day Ahead Incremental Energy Bid Awarded Energy 4 OE Optimal Energy 5 HASE Hour ahead predispatched schedule energy 6 SRE Standard Ramping Energy 7 RED Ramping Energy Deviation 8 EDE Exceptional Dispatch energy 9 RMRE RMR Energy 10 MSSLFE MSSLF Energy 11 RE Residual Energy 12 MLE Minimum Load Energy 13 SE SLIC Energy 14 RTSSE Real time self scheduled energy 15 DMLE Day ahead minimum load energy 16 PE Pumping Energy 17 TEE Total Expected Energy 18 DAPE DayAhead Pumping Energy EnergyTypeCode {98177A18-B8A3-4699-81EE-65B36F1E4F97} EnergyTypeKind {1D7EE73C-8476-40c6-B2B9-10BA57199D7A} EnergyTypeReference {235A7C92-A579-44fb-BDF1-7741E42009B3} An environmental alert issued by a provider or system. EnvironmentalAlert {0602A6D7-03E3-4067-94A9-A79A9EA3CAB3} Analog float measurement of relevance in the environmental domain. EnvironmentalAnalog {3FE893D1-3F9A-4b25-ADDB-5CF6191F2331} An environmental value described using a coded value. A triplicate of enumerated values representing intensity coverage type of weather is used. These may be concatenated into the string value. EnvironmentalCodedValue {8FF33878-EEAD-4243-86A6-7FB65DB71D18} An entity defining classifications or categories of environmental information like phenomena or alerts. EnvironmentalDataAuthority {4CAE75CE-D7C1-4346-9DC7-DBDCE2A5B59F} Entity providing environmental data. Could be an observed weather data provider an entity providing forecasts an authority providing alerts etc. EnvironmentalDataProvider {5C4D4CE8-7157-4493-91A6-EB085F29B2A9} This is a environmental based limit dependency model for calculating operational limits. EnvironmentalDependentLimit {E2741DD1-E9F5-4abd-B45E-8EA808647E09} Discrete integer measurement of relevance in the environmental domain. EnvironmentalDiscrete {B5D41EB6-5CB8-4f32-81DE-854FC340F244} Discrete integer measuring an environmental condition. EnvironmentalDiscreteKind {6C16F9CE-689B-420d-91CE-DB256FBACF80} An environmental event to which one or more forecasts or observations may be tied and which may relate to or affect one or more assets.This class is intended to be used as a means of grouping forecasts andor observations and could be used for a variety of purposes includingullito define a named event like Hurricane Katrina and allow the historic or forecast values for phenomena and measurements precipitation temperature across time to be associated with itlilito identify assets that were or are forecast to be affected by a phenomenon or set of measurementsliul EnvironmentalEvent {FFCF28A6-7F47-4970-A6D0-E39F622CC21A} Abstract class with concrete child classes of Observation and Forecast that groups phenomenon andor environmental value sets. EnvironmentalInformation {E0E65339-6D6D-49ff-846C-6A2A175C0504} Type of environmental location. Used when an environmental alert or phenomenon has multiple locations associated with it. EnvironmentalLocationType {4F05C799-C6C3-46da-8408-7B9C074FC888} An environmental monitoring station examples of which could be a weather station or a seismic monitoring station. EnvironmentalMonitoringStation {C0EF36F4-1BF0-4f20-A428-819900BFFACA} The actual or forecast characteristics of an environmental phenomenon at a specific point in time or during a specific time interval that may have both a center and arealine location. EnvironmentalPhenomenon {E5CAB7F1-22D3-4dd1-AAE4-FD2DA5C91BF2} String measurement of relevance in the environmental domain. EnvironmentalStringMeasurement {45D363CC-9B36-4fc4-9E55-C5550D9BAF23} The parts of a power system that are physical devices electronic or mechanical. Equipment {F8DD8DAC-3545-4660-9CA5-794881CC6591} A modelling construct to provide a root class for containing equipment. EquipmentContainer {F465B7B4-B488-46c5-8D05-8036F09A03A0} A fault applied at the terminal external to the equipment. This class is not used to specify faults internal to the equipment. EquipmentFault {565ED47F-1E02-464b-8D9C-517ED5726DF3} This represents one instance of an equipment that contributes to the calculation of an operational limit. EquipmentLimitSeriesComponent {56EBD7E2-15BD-4733-8247-B0D65C6C7F9C} Status of equipment. EquipmentStatusType {B731F8DA-5DDA-4018-9BA8-7DA634AB5125} EquipmentUnavailabilitySchedule {B7828F5D-2ACC-425f-8E67-D4C050E46EEE} The class represents equivalent branches. In cases where a transformer phase shift is modelled and the EquivalentBranch is spanning the same nodes the impedance quantities for the EquivalentBranch shall consider the needed phase shift. EquivalentBranch {FC8BE368-2F3E-4ff8-BDC1-4229823DC5AE} The class represents equivalent objects that are the result of a network reduction. The class is the base for equivalent objects of different types. EquivalentEquipment {966D682F-CD37-4038-9739-3EEC0E6CB044} This class represents equivalent injections generation or load. Voltage regulation is allowed only at the point of connection. EquivalentInjection {9749AD93-8F33-48c8-9291-02B9D671C172} A class that groups electrical equivalents including internal nodes of a network that has been reduced. The ConnectivityNodes contained in the equivalent are intended to reflect internal nodes of the equivalent. The boundary Connectivity nodes where the equivalent connects outside itself are not contained by the equivalent. EquivalentNetwork {1FCEE6DF-2D36-4ee8-8CB9-0EFC3F000799} The class represents equivalent shunts. EquivalentShunt {78A11A2E-59D2-4823-9137-ACBA6B6BC4FC} Kind of ERP account. ErpAccountKind {AE794AC8-10DB-40b8-BDBF-F5B708D9AD33} Information that generally describes the Bill of Material Structure and its contents for a utility.This is used by ERP systems to transfer Bill of Material information between two business applications. ErpBOM {338BF3FA-0E69-4e0a-9CE2-A99A98ADA226} Relationship under a particular name usually evidenced by a deposit against which withdrawals can be made. Types of bank accounts include demand time custodial joint trustee corporate special and regular accounts.A statement of transactions during a fiscal period and the resulting balance is maintained on each account.For Payment metering the account is associated with Bank and Supplier reflecting details of the bank account used for depositing revenue collected by TokenVendor. The name of the account holder should be specified in name attribute. ErpBankAccount {EFB4BC24-92B4-4912-B051-F7727578FA81} An individual item on a bill of materials. ErpBomItemData {198400B5-F041-4acd-B0AB-7C06E1EAE80F} Accounting structure of a business. Each account represents a financial aspect of a business such as its Accounts Payable or the value of its inventory or its office supply expenses. ErpChartOfAccounts {0A12D145-2CE5-48dd-A067-F52E6F11113B} Information that describes aptitudes of a utility employee. Unlike Skills that an ErpPerson must be certified to perform before undertaking certain type of assignments to be able to perfrom a Craft ErpCompetency has more to do with typical Human Resource HR matters such as schooling training etc. ErpCompetency {EC751E99-286F-44d5-9C43-E7EA516D766C} Shadow class for Document to isolate subclassing from this package. If any subclass gets normative and needs inheritance it will inherit directly from Document. ErpDocument {59753D30-B0C3-4126-9B64-86EE92C42B1A} General Utility Engineering Change Order information. ErpEngChangeOrder {07185DA8-4276-4c53-887C-196E31EED445} Shadow class for IdentifiedObject to isolate subclassing from this package. If any subclass gets normative and needs inheritance it will inherit directly from IdentifiedObject. ErpIdentifiedObject {06062F97-F1AD-48b6-B838-21513A6460B6} Utility inventoryrelated information about an item or part and not for description of the item and its attributes. It is used by ERP applications to enable the synchronization of Inventory data that exists on separate Item Master databases. This data is not the master data that describes the attributes of the item such as dimensions weight or unit of measure it describes the item as it exists at a specific location. ErpInventory {CAE157A1-AB4E-4403-8A06-5386CA3118F0} This is related to Inventory physical counts organized by AssetModel. Note that a count of a type of asset can be accomplished by the association inherited by AssetModel from Document to Asset.It enables ERP applications to transfer an inventory count between ERP and the actual physical inventory location. This count may be a cycle count or a physical count. ErpInventoryCount {FED13292-1658-4732-82E1-6DD3D974F8EB} A roll up of invoice line items. The whole invoice has a due date and amount to be paid with information such as customer banks etc. being obtained through associations. The invoice roll up is based on individual line items that each contain amounts and descriptions for specific services or products. ErpInvoice {2A25121F-D3C9-413e-9DE0-67BD3846DD54} Kind of ERP invoice. ErpInvoiceKind {613C1258-4E8D-4c2c-A23A-AC9C0D812876} An individual line item on an invoice. ErpInvoiceLineItem {53C3B43C-F9BD-45a5-98A8-C8820D20F3FF} Kind of invoice line item. ErpInvoiceLineItemKind {F22B0623-851B-43f7-A35C-F4771F4813F9} Can be used to request an application to process an issue or request information about an issue. ErpIssueInventory {D127CF41-0C3B-439f-A453-5071ED143BD2} Any unique purchased part for manufactured product tracked by ERP systems for a utility.Item as used by the OAG refers to the basic information about an item including its attributes cost and locations. It does not include item quantities. Compare to the Inventory which includes all quantities and other locationspecific information. ErpItemMaster {26D010CF-1FA8-43da-9EC5-A05965183BD0} Book for recording accounting transactions as they occur. Transactions and adjustments are first recorded in a journal which is like a diary of instructions advising which account to be charged and by how much.A journal represents a change in the balances of a businesss financial accounts. Many tasks or transactions throughout an enterprise will result in the creation of a journal. Some examples are creating a customer invoice paying a vendor transferring inventory or paying employees. ErpJournal {89974BFB-E268-45d8-A05F-020CAA9C3781} Details of an individual entry in a journal which is to be posted to a ledger on the posting date. ErpJournalEntry {92318DC0-968A-40de-B828-7C3C5B67BCEC} Individual entry of a given Ledger Budget typically containing information such as amount accounting date accounting period and is associated with the applicable general ledger account. ErpLedBudLineItem {497D8708-FB86-4141-8C80-548011F5C0C3} In accounting transactions a ledger is a book containing accounts to which debits and credits are posted from journals where transactions are initially recorded. Journal entries are periodically posted to the ledger. Ledger Actual represents actual amounts by account within ledger within company or business area. Actual amounts may be generated in a source application and then loaded to a specific ledger within the enterprise general ledger or budget application. ErpLedger {E9DF60B7-4E1B-4d37-A980-EFBB2FBEFDA8} Information for utility Ledger Budgets. They support the transfer budget amounts between all possible source applications throughout an enterprise and a general ledger or budget application. ErpLedgerBudget {648B9268-D9CD-468c-9BFE-B2329ED60032} Details of an individual entry in a ledger which was posted from a journal on the posted date. ErpLedgerEntry {8CFB51A0-6C9E-48a0-A8CC-AA2E97B62DAE} Of an ErpPurchaseOrder this is an individually ordered item or product along with the quantity price and other descriptive information. ErpPOLineItem {5F91E07F-F701-4b38-8CB8-1CA87251C0D5} A transaction that represents an invoice from a supplier. A payable or voucher is an open item approved and ready for payment in the Accounts Payable ledger. ErpPayable {7E9CB1F8-B68D-4dec-B5AA-50E8C891FA04} Of an ErpPayable a line item references an ErpInvoiceLineitem or other source such as credit memos. ErpPayableLineItem {0BCC0D0E-6785-4bcc-A35C-D4820897FF73} Payment infromation and status for any individual line item of an ErpInvoice e.g. when payment is from a customer. ErpPayable is also updated when payment is to a supplier and ErpReceivable is updated when payment is from a customer. Multiple payments can be made against a single line item and an individual payment can apply to more that one line item. ErpPayment {2A7E7F00-35B2-44ba-ABFA-659EF1E521DE} Information that applies to the basic data about a utility person used by ERP applications to transfer Personnel data for a worker. ErpPersonnel {40C9A7CC-0257-4961-8051-2EF29DABECD9} Utility Project Accounting information used by ERP applications to enable all relevant subsystems that submit single sided transactions to transfer information with a Project Accounting Application. This would include but not necessarily be limited to Accounts Payable Accounts Receivable Budget Order Management Purchasing Time and Labor Travel and Expense. ErpProjectAccounting {93D527C0-CE28-4069-A6FB-D862754B4420} A document that communicates an order to purchase goods from a buyer to a supplier. The PurchaseOrder carries information to and from the buyer and supplier. It is a legally binding document once both Parties agree to the contents and the specified terms and conditions of the order. ErpPurchaseOrder {B59BE666-E41E-4f68-A564-2A6E32C8DA78} Document describing the prices of goods or services provided by a supplier. It includes the terms of the purchase delivery proposals identification of goods or services ordered as well as their quantities. ErpQuote {0908A794-42AB-4d96-915B-CD52EA913AFD} Of an ErpQuote the item or product quoted along with quantity price and other descriptive information. ErpQuoteLineItem {41C0DEAC-191E-4b9c-85DA-917554C0FDF7} Of an ErpReceiveDelivery this is an individually received good or service by the Organisation receiving goods or services. It may be used to indicate receipt of goods in conjunction with a purchase order line item. ErpRecDelvLineItem {B4E2F4F0-78A8-4dd7-BC64-7A5E37411161} Individual entry of an ErpReceivable it is a particular transaction representing an invoice credit memo or debit memo to a customer. ErpRecLineItem {A74D2B06-6DE3-419b-AE17-0B7F3E3F1340} Transaction representing an invoice credit memo or debit memo to a customer. It is an open unpaid item in the Accounts Receivable ledger. ErpReceivable {8F2ED892-4481-40a4-9E78-9090AE9E10D0} Transaction for an Organisation receiving goods or services that may be used to indicate receipt of goods in conjunction with a purchase order. A receivable is an open unpaid item in the Accounts Receivable ledger. ErpReceiveDelivery {9A73381D-9D2E-45ba-9D63-6B31C8EE2F68} Information that describes a requested item and its attributes. ErpReqLineItem {704B113A-CD61-4877-97DA-A23E4F7F77C8} General information that applies to a utility requisition that is a request for the purchase of goods or services. Typically a requisition leads to the creation of a purchase order to a specific supplier. ErpRequisition {1D8F6379-AE58-4c91-B287-CA3BEF7851BD} General purpose Sales Order is used for utility service orders etc.As used by the OAG the SalesOrder is a step beyond a PurchaseOrder in that the receiving entity of the order also communicates SalesInformoration about the Order along with the Order itself. ErpSalesOrder {B4F609BD-F167-4d16-A382-99CEB1054332} For a utility general information that describes physical locations of organizations or the location codes and their meanings. This enables ERP applications to ensure that the physical location identifiers are synchronized between the business applications. ErpSiteLevelData {4625CE64-B06A-49a8-A819-9CF8A454876B} An individual entry on an ErpTimeSheet. ErpTimeEntry {FC84C591-8D30-4217-BA53-DB078BB684AA} Time sheet for employees and contractors. Note that ErpTimeSheet inherits the relationship to ErpPerson from Document. ErpTimeSheet {9725D15F-064E-4660-B4C1-359903B2B1C9} The Estimated Restoration Time for a single outage EstimatedRestorationTime {FC049904-001D-4ca5-B4B0-1082AA699C7B} Model of expost calcultion of MW losses. ExPostLoss {DD74E80C-6CA3-40a5-A955-6DF08D937754} Model results of expost calculation of MW losses. Summarizes loss in two categories losses on the the extra high voltage transmission and total losses. Calculated for each subcontrol area. ExPostLossResults {03B84153-3A47-4202-8538-6852B96D57E8} Model of expost calculation of cleared MW on a regional basis. ExPostMarketRegion {7BE3E59F-BA80-4c3e-83B5-B52985D66244} Model of expost calculation of cleared MW on a region basis. Includes cleared price. ExPostMarketRegionResults {BF56AD5D-4BC9-41fc-9BB3-98A5E21A2ABE} Model of expost pricing of nodes. ExPostPricing {7126046F-1F0B-4a9e-8640-86396331A06C} Model of expost pricing of nodes. Includes LMP information pnode based. ExPostPricingResults {A0C86A9F-25C5-4904-AF0B-4F9312CAD08E} Model of expost pricing of resources. ExPostResource {F7E72241-5CBB-4cb7-B29B-FC4EC51F8F83} Model of expost pricing of resources contains components of LMPs energy congestion loss. Resource based. ExPostResourceResults {5784BC07-3A3E-40e0-AD6E-595897F8857D} Modified IEEE AC1A alternatorsupplied rectifier excitation system with different rate feedback source. ExcAC1A {7C5087C8-2137-40b6-89FE-5426A5A880A7} Modified IEEE AC2A alternatorsupplied rectifier excitation system with different field current limit. ExcAC2A {427E622F-63B0-453f-B645-111E8D44788E} Modified IEEE AC3A alternatorsupplied rectifier excitation system with different field current limit. ExcAC3A {442B06CD-43E7-4cc5-9E46-87B65F5E90A8} Modified IEEE AC4A alternatorsupplied rectifier excitation system with different minimum controller output. ExcAC4A {39A6B24D-CA7E-4ea8-9562-D82AAD8DC08C} Modified IEEE AC5A alternatorsupplied rectifier excitation system with different minimum controller output. ExcAC5A {A407821B-2FF5-4e1f-992E-BCDDC0EEB4F7} Modified IEEE AC6A alternatorsupplied rectifier excitation system with speed input. ExcAC6A {DA1114C6-79E5-4a44-AC23-B4D5417C71EF} Modified IEEE AC8B alternatorsupplied rectifier excitation system with speed input and input limiter. ExcAC8B {F71F0FCB-91F7-4d93-9B69-B7BCE2B9B605} Italian excitation system. It represents static field voltage or excitation current feedback excitation system. ExcANS {D95B626D-AAD0-4551-B642-BD8E8040992C} Italian excitation system corresponding to IEEE 1968 type 1 model. It represents an exciter dynamo and electromechanical regulator. ExcAVR1 {D52F6976-E896-4a1d-97FE-B20145E07A4A} Italian excitation system corresponding to IEEE 1968 type 2 model. It represents an alternator and rotating diodes and electromechanic voltage regulators. ExcAVR2 {4ED12E66-DA7D-4bd3-B85E-88F5A10E9DC2} Italian excitation system. It represents an exciter dynamo and electric regulator. ExcAVR3 {D364518B-D877-42ff-8227-1625F54175F8} Italian excitation system. It represents a static exciter and electric voltage regulator. ExcAVR4 {3A5F8C1A-125E-4a31-A9C0-E47A651225AE} Manual excitation control with field circuit resistance. This model can be used as a very simple representation of manual voltage control. ExcAVR5 {6E6ABF9C-E5AE-4ae0-A338-2F4EA53270E8} IVO excitation system. ExcAVR7 {73844DAB-C2BA-416d-A10A-1BAC8B6E73EA} Transformer fed static excitation system static with ABB regulator. This model represents a static excitation system in which a gated thyristor bridge fed by a transformer at the main generator terminals feeds the main generator directly. ExcBBC {A44053E0-AE0F-4cf5-A19C-801DB19B2563} Czech proportionintegral exciter. ExcCZ {EA437F0B-982E-4c6e-A9CF-C619F70D7E11} Modified IEEE DC1A direct current commutator exciter with speed input and without underexcitation limiters UEL inputs. ExcDC1A {E53F809E-6680-46a1-AD94-9ADC8506CC61} Modified IEEE DC2A direct current commutator exciter with speed input one more leg block in feedback loop and without underexcitation limiters UEL inputs. DC type 2 excitation system model with added speed multiplier added leadlag and voltagedependent limits. ExcDC2A {41511A09-BAC8-4894-BAB4-8AF49C918BF7} Modified IEEE DC3A direct current commutator exciter with speed input and deadband. DC old type 4. ExcDC3A {D4FAEA40-9F0D-4494-A94F-C976B7B21BB8} Modified old IEEE type 3 excitation system. ExcDC3A1 {61150142-5A5C-4950-8737-CCCA34D9C146} Static PI transformer fed excitation system ELIN VATECH simplified model. This model represents an allstatic excitation system. A PI voltage controller establishes a desired field current set point for a proportional current controller. The integrator of the PI controller has a followup input to match its signal to the present field current. A power system stabilizer with power input is included in the model. ExcELIN1 {61B64CDD-C0DC-4805-9FAE-F5CE6F84BE93} Detailed excitation system ELIN VATECH. This model represents an allstatic excitation system. A PI voltage controller establishes a desired field current set point for a proportional current controller. The integrator of the PI controller has a followup input to match its signal to the present field current. Power system stabilizer models used in conjunction with this excitation system model PssELIN2 PssIEEE2B Pss2B. ExcELIN2 {A70C011D-657F-48d6-9773-355DE124B959} Hungarian excitation system with builtin voltage transducer. ExcHU {CA42FF68-2CA7-467e-AF70-883F91E7B54F} IEEE 421.52005 type AC1A model. The model represents the fieldcontrolled alternatorrectifier excitation systems designated type AC1A. These excitation systems consist of an alternator main exciter with noncontrolled rectifiers.Reference IEEE 421.52005 6.1. ExcIEEEAC1A {ACDB84C3-576D-4700-8C29-C7C1762CCCC9} IEEE 421.52005 type AC2A model. The model represents a high initial response fieldcontrolled alternatorrectifier excitation system. The alternator main exciter is used with noncontrolled rectifiers. The type AC2A model is similar to that of type AC1A except for the inclusion of exciter time constant compensation and exciter field current limiting elements.Reference IEEE 421.52005 6.2. ExcIEEEAC2A {872A1C8E-D47A-438c-9AE6-CC6471983F4A} IEEE 421.52005 type AC3A model. The model represents the fieldcontrolled alternatorrectifier excitation systems designated type AC3A. These excitation systems include an alternator main exciter with noncontrolled rectifiers. The exciter employs selfexcitation and the voltage regulator power is derived from the exciter output voltage. Therefore this system has an additional nonlinearity simulated by the use of a multiplier whose inputs are the voltage regulator command signal iVai and the exciter output voltage iEfdi times iKiisubRsubi. This model is applicable to excitation systems employing static voltage regulators.Reference IEEE 421.52005 6.3. ExcIEEEAC3A {F4168622-5B5F-4acf-A248-E670C038660A} IEEE 421.52005 type AC4A model. The model represents type AC4A alternatorsupplied controlledrectifier excitation system which is quite different from the other types of AC systems. This high initial response excitation system utilizes a full thyristor bridge in the exciter output circuit. The voltage regulator controls the firing of the thyristor bridges. The exciter alternator uses an independent voltage regulator to control its output voltage to a constant value. These effects are not modelled however transient loading effects on the exciter alternator are included.Reference IEEE 421.52005 6.4. ExcIEEEAC4A {A19ECF3E-99EC-46c1-A2E0-892E351F1F79} IEEE 421.52005 type AC5A model. The model represents a simplified model for brushless excitation systems. The regulator is supplied from a source such as a permanent magnet generator which is not affected by system disturbances. Unlike other AC models this model uses loaded rather than open circuit exciter saturation data in the same way as it is used for the DC models. Because the model has been widely implemented by the industry it is sometimes used to represent other types of systems when either detailed data for them are not available or simplified models are required.Reference IEEE 421.52005 6.5. ExcIEEEAC5A {B8C00890-B9AB-4687-8B3C-B194D0BBD8B7} IEEE 421.52005 type AC6A model. The model represents fieldcontrolled alternatorrectifier excitation systems with systemsupplied electronic voltage regulators. The maximum output of the regulator iViisubRsubi is a function of terminal voltage iViisubTsubi. The field current limiter included in the original model AC6A remains in the 2005 update.Reference IEEE 421.52005 6.6. ExcIEEEAC6A {52AB8022-3DF9-4f56-8342-FBBD1650B319} IEEE 421.52005 type AC7B model. The model represents excitation systems which consist of an AC alternator with either stationary or rotating rectifiers to produce the DC field requirements. It is an upgrade to earlier AC excitation systems which replace only the controls but retain the AC alternator and diode rectifier bridge.Reference IEEE 421.52005 6.7. Note however that in IEEE 421.52005 the 1 isTiisubEsubi block is shown as 1 1 isTiisubEsubi which is incorrect. ExcIEEEAC7B {7FA5C845-958C-4fde-823A-F43B7912A2C0} IEEE 421.52005 type AC8B model. This model represents a PID voltage regulator with either a brushless exciter or DC exciter. The AVR in this model consists of PID control with separate constants for the proportional iKiisubPRsubi integral iKiisubIRsubi and derivative iKiisubDRsubi gains. The representation of the brushless exciter iTiisubEsubi iKiisubEsubi iSiisubEsubi iKiisubCsubi iKiisubDsubi is similar to the model type AC2A. The type AC8B model can be used to represent static voltage regulators applied to brushless excitation systems. Digitally based voltage regulators feeding DC rotating main exciters can be represented with the AC type AC8B model with the parameters iKiisubCsubi and iKiisubDsubi set to 0. For thyristor power stages fed from the generator terminals the limits iViisubRMAXsubi and iViisubRMINsubii ishould be a function of terminal voltage VisubTsubi x iViisubRMAXsubisub suband iViisubTsubi x iViisubRMINsubi.Reference IEEE 421.52005 6.8. ExcIEEEAC8B {5A5BF11A-2D01-4ab7-9F3E-6F9D0EBA1054} IEEE 421.52005 type DC1A model. This model represents fieldcontrolled DC commutator exciters with continuously acting voltage regulators especially the directacting rheostatic rotating amplifier and magnetic amplifier types. Because this model has been widely implemented by the industry it is sometimes used to represent other types of systems when detailed data for them are not available or when a simplified model is required.Reference IEEE 421.52005 5.1. ExcIEEEDC1A {8045C2BD-5BDB-401f-BB79-0FA9E8E30E27} IEEE 421.52005 type DC2A model. This model represents fieldcontrolled DC commutator exciters with continuously acting voltage regulators having supplies obtained from the generator or auxiliary bus. It differs from the type DC1A model only in the voltage regulator output limits which are now proportional to terminal voltage iViisubTsubi.It is representative of solidstate replacements for various forms of older mechanical and rotating amplifier regulating equipment connected to DC commutator exciters.Reference IEEE 421.52005 5.2. ExcIEEEDC2A {3D715368-2991-450d-B9BB-F687CD39CD43} IEEE 421.52005 type DC3A model. This model represents older systems in particular those DC commutator exciters with noncontinuously acting regulators that were commonly used before the development of the continuously acting varieties. These systems respond at basically two different rates depending upon the magnitude of voltage error. For small errors adjustment is made periodically with a signal to a motoroperated rheostat. Larger errors cause resistors to be quickly shorted or inserted and a strong forcing signal applied to the exciter. Continuous motion of the motoroperated rheostat occurs for these larger error signals even though it is bypassed by contactor action.Reference IEEE 421.52005 5.3. ExcIEEEDC3A {BD327C73-BB24-4204-81F0-1D7C0CBE4B73} IEEE 421.52005 type DC4B model. These excitation systems utilize a fieldcontrolled DC commutator exciter with a continuously acting voltage regulator having supplies obtained from the generator or auxiliary bus.Reference IEEE 421.52005 5.4. ExcIEEEDC4B {7E27C1F0-2917-4f37-8B8F-629F0F437CBF} IEEE 421.52005 type ST1A model. This model represents systems in which excitation power is supplied through a transformer from the generator terminals or the units auxiliary bus and is regulated by a controlled rectifier. The maximum exciter voltage available from such systems is directly related to the generator terminal voltage.Reference IEEE 421.52005 7.1. ExcIEEEST1A {538E9666-4A7D-4819-9C99-E8601AFE86B3} Types of connections for the UEL input used in ExcIEEEST1A. ExcIEEEST1AUELselectorKind {1A5A9C7E-881D-4271-A694-3409A68164BC} IEEE 421.52005 type ST2A model. Some static systems use both current and voltage sources generator terminal quantities to comprise the power source. The regulator controls the exciter output through controlled saturation of the power transformer components. These compoundsource rectifier excitation systems are designated type ST2A and are represented by ExcIEEEST2A.Reference IEEE 421.52005 7.2. ExcIEEEST2A {56B255D8-1684-4542-B654-D5357CAB39A0} IEEE 421.52005 type ST3A model. Some static systems utilize a field voltage control loop to linearize the exciter control characteristic. This also makes the output independent of supply source variations until supply limitations are reached. These systems utilize a variety of controlledrectifier designs full thyristor complements or hybrid bridges in either series or shunt configurations. The power source can consist of only a potential source either fed from the machine terminals or from internal windings. Some designs can have compound power sources utilizing both machine potential and current. These power sources are represented as phasor combinations of machine terminal current and voltage and are accommodated by suitable parameters in model type ST3A which is represented by ExcIEEEST3A.Reference IEEE 421.52005 7.3. ExcIEEEST3A {BE50DBC0-E168-4afe-A988-66841022814A} IEEE 421.52005 type ST4B model. This model is a variation of the type ST3A model with a proportional plus integral PI regulator block replacing the laglead regulator characteristic that is in the ST3A model. Both potential and compound source rectifier excitation systems are modelled. The PI regulator blocks have nonwindup limits that are represented. The voltage regulator of this model is typically implemented digitally.Reference IEEE 421.52005 7.4. ExcIEEEST4B {9245EED1-30E1-4f2f-9988-4F1BB548767B} IEEE 421.52005 type ST5B model. The type ST5B excitation system is a variation of the type ST1A model with alternative overexcitation and underexcitation inputs and additional limits.The block diagram in the IEEE 421.5 standard has input signal iVc iand does not indicate the summation point with iVrefi. The implementation of the ExcIEEEST5B shall consider summation point with iVrefi.Reference IEEE 421.52005 7.5. ExcIEEEST5B {A3248F33-3B25-4879-9B29-C0E09FAF8695} IEEE 421.52005 type ST6B model. This model consists of a PI voltage regulator with an inner loop field voltage regulator and precontrol. The field voltage regulator implements a proportional control. The precontrol and the delay in the feedback circuit increase the dynamic response.Reference IEEE 421.52005 7.6. ExcIEEEST6B {7A625070-2B4A-48c0-BB20-C7C7DD709BC5} IEEE 421.52005 type ST7B model. This model is representative of static potentialsource excitation systems. In this system the AVR consists of a PI voltage regulator. A phase leadlag filter in series allows the introduction of a derivative function typically used with brushless excitation systems. In that case the regulator is of the PID type. In addition the terminal voltage channel includes a phase leadlag filter. The AVR includes the appropriate inputs on its reference for overexcitation limiter OEL1 underexcitation limiter UEL stator current limiter SCL and current compensator DROOP. All these limitations when they work at voltage reference level keep the PSS VS signal from PSS in operation. However the UEL limitation can also be transferred to the high value HV gate acting on the output signal. In addition the output signal passes through a low value LV gate for a ceiling overexcitation limiter OEL2.Reference IEEE 421.52005 7.7. ExcIEEEST7B {2855D47A-633A-4fdb-8372-F91955B62741} Bus or solid fed SCR siliconcontrolled rectifier bridge excitation system model type NI NVE. ExcNI {0CD180C8-EE66-4407-B672-6462C586CCC5} Modified IEEE type ST1 excitation system with semicontinuous and acting terminal voltage limiter. ExcOEX3T {886558CE-899B-4d55-BB83-B7F73C5F663F} Proportionalintegral regulator excitation system. This model can be used to represent excitation systems with a proportionalintegral PI voltage regulator controller. ExcPIC {059AD67D-F00F-4fff-A769-4267112802A1} General purpose rotating excitation system. This model can be used to represent a wide range of excitation systems whose DC power source is an AC or DC generator. It encompasses IEEE type AC1 AC2 DC1 and DC2 excitation system models. ExcREXS {F3E4EB5B-1DEA-418b-945D-2F82E47C8600} Types of rate feedback signals. ExcREXSFeedbackSignalKind {D5C43B1C-5D32-4906-9916-02A0E8D90985} Excitation system type RQB fourloop regulator r?gulateur quatre boucles developed in France primarily used in nuclear or thermal generating units. This excitation system shall be always used together with power system stabilizer type PssRQB. ExcRQB {1EF393B6-BC78-42f1-B8C7-30791D76FC50} Simple excitation system with generic characteristics typical of many excitation systems intended for use where negative field current could be a problem. ExcSCRX {A153B28E-4577-4ff7-9EFA-EF47377694D7} Simplified excitation system. ExcSEXS {58E2432F-4610-47c7-A972-A243939E860B} Slovakian excitation system. UEL and secondary voltage control are included in this model. When this model is used there cannot be a separate underexcitation limiter or VAr controller model. ExcSK {1EE78E1C-0446-48dd-87E8-AA4990E99CB7} Modification of an old IEEE ST1A static excitation system without overexcitation limiter OEL and underexcitation limiter UEL. ExcST1A {704F07B6-4C3F-40eb-8C13-F964EDFE8BE9} Modified IEEE ST2A static excitation system with another leadlag block added to match the model defined by WECC. ExcST2A {5F48CA29-4D28-45f2-A46C-A49FA24CCB5F} Modified IEEE ST3A static excitation system with added speed multiplier. ExcST3A {9FA72263-AE74-4911-969F-64971BC90618} Modified IEEE ST4B static excitation system with maximum inner loop feedback gain iVgmaxi. ExcST4B {85D10103-7F88-4241-8E66-58D467B5AAB4} Modified IEEE ST6B static excitation system with PID controller and optional inner feedback loop. ExcST6B {BDCDDFDC-9773-41d0-A4FA-5A2004FAD693} Types of connections for the OEL input used for static excitation systems type 6B. ExcST6BOELselectorKind {C53689DF-C5DD-496d-8153-DFC748199B83} Modified IEEE ST7B static excitation system without stator current limiter SCL and current compensator DROOP inputs. ExcST7B {57B557A4-6D9F-4ce9-975F-88A6D06C98A9} Types of connections for the OEL input used for static excitation systems type 7B. ExcST7BOELselectorKind {195B8230-9DE1-41fb-871D-72529EE326A1} Types of connections for the UEL input used for static excitation systems type 7B. ExcST7BUELselectorKind {3777F9AB-A057-48e3-B662-216096146DB0} Excitation system function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font ExcitationSystemDynamics {F119E4EC-2DC8-4801-B68B-A282AF621324} Excitation system function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font ExcitationSystemUserDefined {1C977604-2D1C-4296-98E1-648696434BFD} Execution types of Market Runs. ExecutionType {B5E8F179-7284-425b-B1EA-41102D76AD66} Model Expected Energy from Market Clearing interval based. ExpectedEnergy {7B23FCCD-6749-4a1a-BC0C-0876AA127229} Model Expected Energy from Market Clearing. ExpectedEnergyValues {A07D68F4-9F27-40b6-9738-BDDEC26020F7} ExtensionItem {6A0ED3D3-488C-46b0-ADF5-BA4FECD1C76C} ExtensionsList {B7ADD1FE-36AB-4d66-B1F4-CFE0938D6E23} A type of customer agreement involving an external agency. For example a customer may form a contracts with an Energy Service Supplier if Direct Access is permitted. ExternalCustomerAgreement {1575CDC5-2EC2-4697-8D9F-E2AE90C2C282} This class represents the external network and it is used for IEC 60909 calculations. ExternalNetworkInjection {B7E110A4-CE7A-4414-9477-4310D44B43D0} FACTS device asset. FACTSDevice {72F6944F-86AC-4777-B060-132006C88993} Kind of FACTS device. FACTSDeviceKind {DF08C5B7-466B-42d9-950D-59B1EBE5305B} Fujita scale referred to as EFscale starting in 2007 for tornado damage. A set of wind estimates not measurements based on damage. It uses threesecond gusts estimated at the point of damage based on a judgment of 8 levels of damage to 28 indicators. These estimates vary with height and exposure. The 3 second gust is not the same wind as in standard surface observations.Enumerations based on NOAA conventions. FScale {399B2769-2649-4d03-81E7-9AB64348C110} Financial Transmission Rights FTR regarding transmission capacity at a flowgate. FTR {6240D9E7-B494-4a46-926F-3F840BA65ACB} A facility may contain buildings storage facilities switching facilities power generation manufacturing facilities maintenance facilities etc. Facility {ABD0F5AB-6E76-47cc-AB57-87BF50E45DDF} Types of facilities at which an asset can be deployed. FacilityKind {70D16D41-D031-4542-ABBE-A477D1CB0872} An event where an asset has failed to perform its functions within specified parameters. This class is intended to reflect the failure itself. Additional information resulting from forensic analysis could be captured by a diagnosis data set. FailureEvent {25FAD1AB-8885-4a72-9AD2-EFD361F4FFB2} How the failure has been isolated. FailureIsolationMethodKind {02D24517-FD1D-4225-AE36-A1FF7BCE5E08} Abnormal condition causing current flow through conducting equipment such as caused by equipment failure or short circuits from objects not typically modelled for example a tree falling on a line. Fault {73ABECF2-4B28-4c55-8665-0882A2C8BCA4} Type of cause of the fault. FaultCauseType {FA0CB393-8E7C-411c-B4F1-14073D940EED} Impedance description for the fault. FaultImpedance {1BEA10DB-2F71-467b-82A6-6C453C5657A5} A FaultIndicator is typically only an indicator which may or may not be remotely monitored and not a piece of equipment that actually initiates a protection event. It is used for FLISR Fault Location Isolation and Restoration purposes assisting with the dispatch of crews to most likely part of the network i.e. assists with determining circuit section where the fault most likely happened. FaultIndicator {E0096FB8-0394-4d99-9726-5FBD336FD801} Parameters of fault indicator asset. FaultIndicatorInfo {04AAC775-8766-4880-B02A-117B106F26A9} Kind of resetting the fault indicators. FaultIndicatorResetKind {7BB32092-FB77-4ead-B49C-569B73F25CA0} A collection of equipment for organizational purposes used for grouping distribution resources.The organization a feeder does not necessarily reflect connectivity or current operation state. Feeder {FE6F802E-8B23-470b-B678-A29A27235CA8} The history of field dispatch statuses for this work. FieldDispatchHistory {6781E967-A300-4e16-825B-50CE206FDC8A} Details of the step in the field dispatch history. FieldDispatchStep {FD9DBBC8-AE78-4ca9-8E16-2B6906E69D6C} Crew member on work site responsible for all local safety measures for the work crew doing maintenance construction and repair in a substation or on a power linecable. FieldSafetySupervisor {A4E26C63-7079-4b95-9862-97326FEA4EFA} Various current financial properties associated with a particular asset. Historical properties may be determined by ActivityRecords associated with the asset. FinancialInfo {2286987A-2E81-4f68-A13E-86A855D3441C} A fire often uncontrolled covering an area of land which typically contains combustible vegetation. Associated location information is assumed to describe the total area burned as of a specified time. Fire {5D83ADBF-889F-472b-AD60-D126B2168DC5} Models 5Minutes Auxiliary Data. FiveMinAuxiliaryData {394D0052-710F-40b4-88D5-2CAAB902C5E6} Indicates whether the unit is RMR and its condition type for exampleN not an RMR unit1 RMR Condition 1 unit2 RMR Condition 2 unit FlagTypeRMR {CF74BB1B-3F7F-43ac-B99E-4C1132A094AC} A floating point number. The range is unspecified and not limited. Float {921A00A7-D33C-43ea-9DE4-70A026CBA70F} Quantity with float value and associated unit information. FloatQuantity {6E887B5A-F340-462c-9186-8556588ACE6C} A flood an overflowing of a large amount of water beyond its normal confines esp. over what is normally dry land. Flood {34D34F4D-3397-4ab8-98D9-1C39CDCBC1D5} The coded identification of the direction of energy flow. FlowDirection {C724715B-5A1F-4393-859C-459860DB9419} Kind of flow direction for readingmeasured values proper to some commodities such as for example energy power demand. FlowDirectionKind {CBEAA8A6-BD51-4960-B930-6A371FCDFA91} Specifies the direction of energy flow in the flowgate. FlowDirectionType {19F19F68-B788-471e-8349-A3EDF95BEE79} A flowgate is single or group of transmission elements intended to model MW flow impact relating to transmission limitations and transmission service usage. Flowgate {A0EA95BA-8681-46f8-A5DB-DF7003A7734A} Flowgate defined partner. FlowgatePartner {54949507-20B9-4135-B5B6-7D373BE45C8B} IDC Interchange Distribution Calulator sends data for a TLR Transmission Loading Relief. FlowgateRelief {B419B7DC-C747-4501-95FF-E94F159157D8} Day Ahead Network Native Load Economic Dispatch values used for calculation of Network Native Load NNL Determinator process. FlowgateValue {16B3D002-934F-4986-B30C-96188561F813} Forbbiden region is operating ranges where the units are unable to maintain steady operation without causing equipment damage. The four attributes that define a forbidden region are the low MW the High MW the crossing time and the crossing cost. ForbiddenRegion {EA690114-4848-42f6-ACE5-C639BB0C8BC5} A forecast group of value sets andor phenomena characteristics. Forecast {4D1FE60B-DA7E-465f-B2D5-CD008A89A5E8} Used to indicate former references to the same piece of equipment. The ID name and effectivity dates are utilized. FormerReference {22991F8A-9D03-4aa7-B881-782BE244E6A6} The fossil fuel consumed by the nonnuclear thermal generating unit. For example coal oil gas etc. These are the specific fuels that the generating unit can consume. FossilFuel {CEB38297-AEE1-4b55-8ECC-272DE5EDA874} Fossil fuelled boiler e.g. coal oil gas. FossilSteamSupply {47678786-032B-421a-A56B-CC5EFE4A269D} The type of alternate model frame. For example it could be generator group used to represent generators in state estimator planning planning dynamics short circuit or realtime dynamics etc. but does not specifically represent any one alternative model. This need to know what objects to be removed in the realization of any one alternate model. FrameworkPart {78B6C3E3-1981-4953-8F7D-E5D66F6495A7} Governor control flag for Francis hydro model. FrancisGovernorControlKind {AD4A17B1-6646-47dc-84A9-14243D94BDAF} Cycles per second. Frequency {DD71FE93-4683-440c-8622-A8AA2EB44F6F} A device to convert from one frequency to another e.g. frequency F1 to F2 comprises a pair of FrequencyConverter instances. One converts from F1 to DC the other converts the DC to F2. FrequencyConverter {CE012E43-26BF-4af0-ABD2-68CA9BB35D60} The amount of fuel of a given type which is allocated for consumption over a specified period of time. FuelAllocationSchedule {B21C6F0E-95AD-4069-A317-588C262B1EF0} Relationship between unit fuel cost in kWhYaxis and unit output in MW Xaxis. FuelCostCurve {A3F92FD6-486F-41c0-A635-0DA1F0B58D9C} Indication of region for fuel inventory purposes. FuelRegion {E8B08844-9549-4af2-BBD2-59B663583982} For exampleBio Gas Landfill Sewage Digester etc.BiomassCoalDISTNatural GasGeothermalHRCVNoneNuclearOilOtherSolarWaste to EnergyWaterWind FuelSource {E635DEB6-EC30-43bf-A794-170EDB83721B} Type of fuel. FuelType {AE75B683-1EF9-4536-B566-3EED1DAA67D6} An overcurrent protective device with a circuit opening fusible part that is heated and severed by the passage of overcurrent through it. A fuse is considered a switching device because it breaks current. Fuse {48B8830C-2798-4c86-8B89-01449EA9D4F6} Price of gas in monetary units. GasPrice {EDD07EC7-2D92-44a4-B07F-EDF75A6C744E} Logical gate than support logical operation based on the input. Gate {EE0C575D-1F3F-4034-96EB-EB4B493B9788} Input pin for a logical gate. The condition described in the input pin will give a logical true or false. Result from measurement and calculation are converted to a true or false. GateInputPin {34FB8459-3EC3-424d-8903-D1B106DD0E74} Define the different logical operations. GateLogicKind {512FB5B2-9206-4fc1-B233-F8EF2A054F44} This class models the generation distribution factors. This class needs to be used along with the AggregatedPnode and the IndividualPnode to show the distribution of each individual party. GenDistributionFactor {8BFC9A50-2A30-454c-9906-8F95A9A88057} Resistive and reactive components of compensation for generator associated with IEEE type 2 voltage compensator for current flow out of another generator in the interconnection. GenICompensationForGenJ {FEED90B2-2208-4aca-AFD0-1ABDF5B94DE8} Relationship between unit operating cost Yaxis and unit output active power Xaxis. The operating cost curve for thermal units is derived from heat input and fuel costs. The operating cost curve for hydro units is derived from water flow rates and equivalent water costs. GenUnitOpCostCurve {62F9E804-3243-40f6-8C02-F860EAF75514} The generating units Operatorapproved current operating schedule or plan typically produced with the aid of unit commitment type analyses. The Xaxis represents absolute time. The Y1axis represents the status 0offline and unavailable 1available 2must run 3must run at fixed power value etc.. The Y2axis represents the must run fixed power value where required. GenUnitOpSchedule {FF8AAD42-67F3-4310-A1D0-9E3500E69261} Model of clearing result of the market run at the market level. Identifies interval. GeneralClearing {7A9E03C5-840B-40fa-9E7E-61FDC21CB655} Provides the adjusted load forecast value on a load forecast zone basis. GeneralClearingResults {221DD6A3-C3E6-4218-BBD9-4F0A30A232FF} Offer to supply energyancillary services from a generating unit or resource. GeneratingBid {EE38CBD0-D27E-4b93-9ECC-C43233E58F2B} A single or set of synchronous machines for converting mechanical power into alternatingcurrent power. For example individual machines within a set may be defined for scheduling purposes while a single control signal is derived for the set. In this case there would be a GeneratingUnit for each member of the set and an additional GeneratingUnit corresponding to the set. GeneratingUnit {A4C4D1F8-0359-44b1-8F2A-521D3F9F3C28} Optimal Power Flow or State Estimator Unit Data for Operator Training Simulator. This is used for RealTime Study and Maintenance Users. GeneratingUnitDynamicValues {ED80EA56-BB67-4e02-A964-B4E6AE879FE4} The energy seller in the energy marketplace. GenerationProvider {62C1A922-74F9-4148-A30A-E65774AE8B84} Unit control modes. GeneratorControlMode {F30D1912-7652-4857-9FA5-2EADBFF160E6} The source of controls for a generating unit. GeneratorControlSource {3C0C9F3D-956D-4459-A81A-40D922761537} Generic generation equipment that may be used for various purposes such as work planning. It defines both the Real and Reactive power properties modelled at the PSR level as a GeneratingUnit SynchronousMachine. GeneratorTypeAsset {2DCA6CE9-F4BC-443c-A5F7-4140642C4A92} An arbitrary switching step. GenericAction {7B245759-F49C-4c34-AEF1-F93D37992CD7} Generic constraints can represent secure areas voltage profile transient stability and voltage collapse limits.The generic constraints can be one of the following formsaThermal MW limit constraints typebGroup line flow constraint type GenericConstraints {DEE63525-3D7B-41c3-98F6-EFA5FAE3DEF1} GenericDataSetVersion {87547DA2-F02C-4ffa-9CD3-F2A19B225127} Type of generic nonlinear load model. GenericNonLinearLoadModelKind {2634FBEB-5D94-469a-B61C-F35CB8FB2012} A geographical region of a power system network model. GeographicalRegion {F935232D-65FF-4720-BAFB-50639B7CA0AB} Analog float measuring a geospheric condition. GeosphericAnalog {5617575E-DF8A-4109-AD72-E263516214C8} Kinds of analogs floats measuring a geospheric condition. GeosphericAnalogKind {A5FECA26-89F5-4c54-8C7E-70AB5982880D} A geospheric phenomenon. GeosphericPhenomenon {9CD3B4E3-7164-434c-82C2-F922CBACEAA9} General model for any prime mover with a PID governor used primarily for combustion turbine and combined cycle units.This model can be used to represent a variety of prime movers controlled by PID governors. It is suitable for example for the representation of ulligas turbine and single shaft combined cycle turbinesliulullidiesel engines with modern electronic or digital governors liulullisteam turbines where steam is supplied from a large boiler drum or a large header whose pressure is substantially constant over the period under studylilisimple hydro turbines in dam configurations where the water column length is short and water inertia effects are minimal.liulAdditional information on this model is available in the 2012 IEEE report iuDynamic Models for TurbineGovernors in Power System Studiesui 3.1.2.3 pages 34 GGOV1. GovCT1 {EC304C29-08AD-426b-BEBF-8167E8655879} General governor with frequencydependent fuel flow limit. This model is a modification of the GovCT1b bmodel in order to represent the frequencydependent fuel flow limit of a specific gas turbine manufacturer. GovCT2 {0A73B225-89A2-4f10-A1F2-E0FEB59F2980} Single shaft gas turbine. GovGAST {07B79378-ECC2-4394-8357-92C171D89683} Modified single shaft gas turbine. GovGAST1 {B63B3483-F3C3-4acb-B076-AE361754C3C1} Gas turbine. GovGAST2 {C2365E2F-CF56-49c5-A63D-1736696A686A} Generic turbogas with acceleration and temperature controller. GovGAST3 {153BECCA-9710-4d48-8BEC-30215D859B61} Generic turbogas. GovGAST4 {77197C40-C093-43f7-B2FA-434AC89EE019} Woodward gas turbine governor. Footnote Woodward gas turbines are an example of suitable products available commercially. This information is given for the convenience of users of this document and does not constitute an endorsement by IEC of these products. GovGASTWD {659A678F-7407-4f04-82AE-D55250A64A93} Basic hydro turbine governor. GovHydro1 {43B50912-F9F9-458f-AFDF-36ADB06FB9A6} IEEE hydro turbine governor with straightforward penstock configuration and hydraulicdashpot governor. GovHydro2 {A9B869A0-0669-477d-BA5B-55EE790D8878} Modified IEEE hydro governorturbine. This model differs from that defined in the IEEE modelling guideline paper in that the limits on gate position and velocity do not permit wind up of the upstream signals. GovHydro3 {EB80B6E9-4479-49dd-AFA2-66D75F934300} Hydro turbine and governor. Represents plants with straightforward penstock configurations and hydraulic governors of the traditional dashpot type. This model can be used to represent simple FrancisPelton or Kaplan turbines. GovHydro4 {4E8A3071-7AC6-490c-A12C-5BD140E8D992} Possible types of GovHydro4 models. GovHydro4ModelKind {DC8738E4-F4A7-44cc-A3C2-A247C6EC76A7} Double derivative hydro governor and turbine. GovHydroDD {0767E4BD-4883-4280-85D8-D84895677D6E} Detailed hydro unit Francis model. This model can be used to represent three types of governors.A schematic of the hydraulic system of detailed hydro unit models such as Francis and Pelton is provided in the DetailedHydroModelHydraulicSystem diagram. GovHydroFrancis {340132B0-5FB9-4bc4-B48C-ED58E4386135} IEEE simplified hydro governorturbine model. Used for mechanicalhydraulic and electrohydraulic turbine governors with or without steam feedback. Typical values given are for mechanicalhydraulic turbinegovernor.Reffont color0f0f0ference IEEE Transactions on Power Apparatus and Systems NovemberDecember 1973 Volume PAS92 Number 6 iuDynamic Models for Steam and Hydro Turbines in Power System Studiesui page 1904.font GovHydroIEEE0 {A314A5D0-7848-447d-9CF5-9A96F323C788} IEEE hydro turbine governor model represents plants with straightforward penstock configurations and hydraulicdashpot governors.Reffont color0f0f0ference IEEE Transactions on Power Apparatus and Systems NovemberDecember 1973 Volume PAS92 Number 6 iuDynamic Models for Steam and Hydro Turbines in Power System Studiesui page 1904.font GovHydroIEEE2 {74B49329-9624-4a07-9C68-40235213A0E0} PID governor and turbine. GovHydroPID {FEAAA52E-0434-4656-B9A3-2A08B0768840} Hydro turbine and governor. Represents plants with straightforward penstock configurations and three term electrohydraulic governors i.e. WoodwardsupTMsup electronic.Footnote Woodward electronic governors are an example of suitable products available commercially. This information is given for the convenience of users of this document and does not constitute an endorsement by IEC of these products. GovHydroPID2 {7BD580D8-6A60-452c-A8B8-3D5C4376B87A} Detailed hydro unit Pelton model. This model can be used to represent the dynamic related to water tunnel and surge chamber.The DetailedHydroModelHydraulicSystem diagram located under the GovHydroFrancis class provides a schematic of the hydraulic system of detailed hydro unit models such as Francis and Pelton. GovHydroPelton {93F7CE4F-A7AD-4c0a-A714-1F6BB59E4CF2} Fourth order leadlag governor and hydro turbine. GovHydroR {38EF4670-8EAE-4d49-8476-65B3666140D4} WoodwardsupTM supelectric hydro governor. Footnote Woodward electric hydro governors are an example of suitable products available commercially. This information is given for the convenience of users of this document and does not constitute an endorsement by IEC of these products. GovHydroWEH {44F7E8EE-7150-4a8b-B451-EB756B45B2C3} WoodwardsupTMsup PID hydro governor.Footnote Woodward PID hydro governors are an example of suitable products available commercially. This information is given for the convenience of users of this document and does not constitute an endorsement by IEC of these products. GovHydroWPID {61178980-5C8E-4adf-925A-DF8A56CCE23B} A simplified steam turbine governor. GovSteam0 {498AA55A-0254-4b68-921D-AD322CD62C4E} Steam turbine governor based on the GovSteamIEEE1 with optional deadband and nonlinear valve gain added. GovSteam1 {05E9615F-2E7C-44a0-BB2E-93B6EB601232} Simplified governor. GovSteam2 {21648324-C0D1-4125-855B-CCCA46600E7B} European governor model. GovSteamBB {BAF42F15-B5DF-4b1f-B240-5A70C71826A4} Cross compound turbine governor. Unlike tandem compound units cross compound units are not on the same shaft. GovSteamCC {710F836E-E997-4363-8621-0F02146A82A9} Simplified boiler and steam turbine with PID governor. GovSteamEU {7046E843-1875-488a-B066-069ADD277955} Steam turbine governor with reheat time constants and modelling of the effects of fast valve closing to reduce mechanical power. GovSteamFV2 {E9DCB0A5-5693-431c-837A-C46A62C00661} Simplified GovSteamIEEE1 steam turbine governor with Prmax limit and fast valving. GovSteamFV3 {885FC264-5D92-465a-881C-12B87113ABA7} Detailed electrohydraulic governor for steam unit. GovSteamFV4 {5ACC759A-302F-4057-9506-893267597F7F} IEEE steam turbine governor model.Reffont color0f0f0ference IEEE Transactions on Power Apparatus and Systems NovemberDecember 1973 Volume PAS92 Number 6 iuDynamic Models for Steam and Hydro Turbines in Power System Studiesui page 1904.font GovSteamIEEE1 {0C56115D-6698-4d80-ACEC-59C9609E8EB6} Simplified steam turbine governor. GovSteamSGO {EEEBBC29-3B6E-49a6-A1C1-354A867CE94F} Relationship between the generating units gross active power output on the Xaxis measured at the terminals of the machines and the generating units net active power output on the Yaxis based on utilitydefined measurements at the power station. Station service loads when modelled should be treated as nonconforming bus loads. There may be more than one curve depending on the auxiliary equipment that is in service. GrossToNetActivePowerCurve {830A0115-F812-4eb9-8973-ACC87D49F8CB} A point where the system is grounded used for connecting conducting equipment to ground. The power system model can have any number of grounds. Ground {437ABFFA-B6B0-47fd-BFE2-76ACD0B7FFDC} Action on ground as a switching step. GroundAction {2EC03659-4055-4b75-AD25-BA805A479D1D} A manually operated or motor operated mechanical switching device used for isolating a circuit or equipment from ground. GroundDisconnector {39802A96-B06F-4dc2-B805-8DF16C5B398D} A fixed impedance device used for grounding. GroundingImpedance {5E278FF4-B19F-4c63-8AA5-5DE09E2586DA} HVDC whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font HVDCDynamics {45E165D9-4A7C-4c6f-8256-550E4E86DF94} HVDCLookUpTable {9B759B51-5C5D-4f1f-9015-DA8CA821B75F} An object or a condition that is a danger for causing loss or perils to an asset andor people. Hazard {387A5492-C5F8-4537-9F38-36348F45D3F9} Score that is indicative of the health of one or more assets. HealthScore {E0135417-A3CC-4e66-AE7D-C1643FCC1E8C} Relationship between unit heat input in energy per time for main fuel Y1axis and supplemental fuel Y2axis versus unit output in active power Xaxis. The quantity of main fuel used to sustain generation at this output level is prorated for throttling between definition points. The quantity of supplemental fuel used at this output level is fixed and not prorated. HeatInputCurve {5FC9AE23-A924-4e2e-81AB-F793F5712C34} Heat generated in energy per time unit of elapsed time. HeatRate {8E0A1478-92E7-445a-9F23-9BCEB17FD303} Relationship between unit heat rate per active power Yaxis and unit output Xaxis. The heat input is from all fuels. HeatRateCurve {8C0D7783-0EF9-4d60-B329-C9E7ED71AECA} The heat recovery system associated with combustion turbines in order to produce steam for combined cycle plants. HeatRecoveryBoiler {CC23120F-6FA7-48b4-8366-F5C6A57FF2FF} A HostControlArea has a set of tie points and a set of generator controls i.e. AGC. It also has a total load including transmission and distribution losses. HostControlArea {B16A7A82-06A9-49e2-A693-D9853F1DFCFE} An indicator specifying that a resource shall have an Hourly PreDispatch. The resource could be a RegisteredGenerator or a RegisteredInterTie.This schedule is assocated with the hourly parameters in a resource bid. HourlyPreDispatchSchedule {43F206DA-24E9-4900-A416-2CD5AA7B5571} Time specified in hours. Hours {C8C67111-A8BF-46d8-B8DB-F0336CD201D1} A hurricane a subtype of cyclone occurring in the North Atlantic Ocean or Northeastern Pacific Ocean whose intensity is measured using the SaffirSimpson Hurricane Scale. Hurricane {078BAC7C-F2F4-4b92-9819-A4B0A9B51AFA} Specifies the capability of the hydro generating unit to convert energy as a generator or pump. HydroEnergyConversionKind {4CBE71BD-F7EC-4313-B5DF-F828931C7234} Relationship between unit efficiency as percentage and unit output active power for a given net head in meters. The relationship between efficiency discharge head and power output is expressed as follows E KPHQwhere E is the efficiency as a percentage P is the active power H is the height Q is the discharge volumetime unit K is a constant.For example a curve instance for a given net head could show efficiency Yaxis versus active power output Xaxis or versus discharge on the Xaxis. HydroGeneratingEfficiencyCurve {DDE543F6-E0E1-4d0d-B58D-E725A4736E7D} A generating unit whose prime mover is a hydraulic turbine e.g. Francis Pelton Kaplan. HydroGeneratingUnit {2B8CC296-5CEF-4662-9FB2-48F968B7C3D9} The type of hydro power plant. HydroPlantStorageKind {9CBFF0AA-F3E6-4c65-A545-71017DDFC252} A hydro power station which can generate or pump. When generating the generator turbines receive water from an upper reservoir. When pumping the pumps receive their water from a lower reservoir. HydroPowerPlant {363A5090-1D0E-40fc-91F1-7540EE479345} A synchronous motordriven pump typically associated with a pumped storage plant. HydroPump {4C4342EA-F3E1-469a-ACB4-CA80A2524FFE} The hydro pumps Operatorapproved current operating schedule or plan typically produced with the aid of unit commitment type analyses. The units operating schedule status is typically given as 0unavailable 1available to startup or shutdown 2must pump. HydroPumpOpSchedule {DC4836E6-546A-4cb7-86AA-82CC7690803D} A water driven prime mover. Typical turbine types are Francis Kaplan and Pelton. HydroTurbine {F8920620-0A8D-4878-818B-67AB6813D9AC} Type of turbine. HydroTurbineKind {099C5D06-8AE4-4e91-85DF-6142C7DABBE2} Analog float measuring a hydrospheric condition. HydrosphericAnalog {0E591614-B81B-4ea6-B1CD-FC9F1637E35C} Kinds of analogs floats measuring a hydrospheric condition. HydrosphericAnalogKind {6D4D68B2-CD2F-4660-A5F2-EDA22D2F057E} A hydrospheric phenomenon. HydrosphericPhenomenon {5C42D377-F15F-4ed7-8CE6-5A3B882FAD2E} Provides access privilege information regarding an ICCP point. ICCPAccessPrivilegeKind {D336341F-ED1A-4fcb-9152-78BC95E89F18} This class represents the TASE.2 Information Message Object. The IdentifiedObject.name attribute must be nonnull. The value of the attribute shall be used as the TASE.2 Information Reference as specified by 608706503. ICCPInformationMessage {91E03624-A558-4c3f-84CA-1EB2E25826F7} The kind of ICCP point that is to be conveyed. ICCPPointKind {00C531A3-C3C1-4c30-97C3-1419D06F0B15} The IdentifiedObject.name attribute must have a value. The name attribute shall be used as the DataValue name used for the exchange. ICCPProvidedPoint {33160A9A-23C7-4086-A723-E674D19B3892} Indicates the type of quality information that is to be exchanged. For protection events the value shall be none. ICCPQualityKind {3151BAD5-095A-49e4-ABBC-CF40C5B0182E} Specifies the control centre scope. ICCPScopeKind {222D3D35-C731-46a4-9157-4AB6623E7F29} Indicates that the ICCP information is global in nature and normally is available to all authorized peers. ICCPVCC {2688C5F0-9A0D-4275-8AB5-9BF09B233FDD} This contains the information that a particular actor exposes for a particular agreed upon ICCP Bilateral Table. ICCPVirtualControlCentre {290E9B5B-AAC5-4e36-A858-BE5AC797E8E0} IEC 61968 version number assigned to this UML model. IEC61968CIMVersion {E7F88519-1D37-4cd2-86C2-3C0CE06246CE} This is the IEC 61970 CIM version number assigned to this UML model. IEC61970CIMVersion {990AB50C-5CF8-46d2-B5FF-887BBBD3346F} IEC 62325 version number assigned to this UML model. IEC62325CIMVersion {6240F09E-51C4-49b5-8222-A4C4FB63CE67} Standard published by IEC International Electrotechnical Commission. IECStandard {0EED159E-2522-453c-AEE2-CC950BB56A9F} List of editions for IEC standards. IECStandardEditionKind {0F8569A9-9436-45bf-9138-CEEA87517630} List of IEC standards. IECStandardKind {E7174CDB-9EB8-4d98-B283-7C2F17073996} Standard published by IEEE Institute of Electrical and Electronics Engineers. IEEEStandard {8E61E9C2-2E60-4a07-82F2-05DE8B659579} List of editions for IEEE standards. IEEEStandardEditionKind {B4926170-C2FB-4da5-AA7B-7BFDE19A469A} List of IEEE standards. IEEEStandardKind {9365A9A1-C15E-45df-8D39-BDF4BC894A20} The class describe a measurement or control value. The purpose is to enable having attributes and associations common for measurement and control. IOPoint {538879CD-D8B6-4eff-B980-FE6510E2699A} Indicates the point source for an IO Point. IOPointSource {E7EF5D7B-47F2-4830-82A4-B867566CBF7E} Internet Protocol Access Point used to represent an addressing structure is based upon an Internet Protocol IP address. IPAccessPoint {11EB184F-AA94-4954-9B70-2F3D5F358790} Indicates if the addressing of the IPAccessPoint gateway and subnet are per IPv4 or IPv6. IPAddressKind {63D432DD-2F98-4142-8CA2-8490F343B490} Standard published by ISO International Organization for Standardization. ISOStandard {0C619E7D-CF4D-4436-9E26-745DDB0C67BB} List of editions for ISO standards. ISOStandardEditionKind {C1E47926-3880-4b91-83B6-3E6027D88AC2} List of ISO standards. ISOStandardKind {1EF67A3A-FC5E-4e52-A356-8D98C8C10EFB} Is a set of configure addressing information that is required since ICCP utilizes addressing other than a TCP port. ISOUpperLayer {E56AA980-565B-4931-AB9E-DA88591B48E8} IdcInverterControl {6A534873-94AB-429f-B19A-50F1C3309772} This is a root class to provide common identification for all classes needing identification and naming attributes. IdentifiedObject {055C5806-E9D8-4a7a-9307-DAF7C31763C7} Excitation base system mode. IfdBaseKind {2EB6DACC-559E-46ac-A5B8-6BF0C250A461} IgnAngleContInverter {AD744D8D-7206-4601-B9D5-C353A05517CB} Ratio of voltage to current. Impedance {3E46E0C6-230A-475b-B15C-B5B4754CDD65} Dates associated with asset in use status. May have multiple in use dates for this device and a compound type allows a query to return multiple dates. InUseDate {48B1F3CD-2256-40e3-BC42-EB2331E89D28} Possible in use states that an asset can be in. InUseStateKind {2DACF751-AA54-4347-ABD3-A1F43DC35D98} An account for tracking inadvertent interchange versus time for each control area. A control area may have more than one inadvertent account in order to track inadvertent over one or more specific tie points in addition to the usual overall net inadvertent. Separate accounts would also be used to track designated time periods such as onpeak and offpeak. InadvertentAccount {377EDC82-091E-4abf-8A72-D78C0D98C4D0} Description of a problem in the field that may be reported in a trouble ticket or come from another source. It may have to do with an outage. Incident {0ED91420-F3BF-47ae-B626-192C9A40CC1A} Hazardous situation associated with an incident. Examples are line down gas leak fire etc. IncidentHazard {298E6C6D-2A99-4a63-A5D7-64FE018C3EB9} A generic model operation argument referencing an incremental change description. IncrementalDatasetArg {4AC6A487-907B-4a92-AF68-AB20542CD308} IncrementalDatasetArgDescription {850587EF-67CD-46a0-8449-9BDC215E8648} Relationship between unit incremental heat rate in delta energytime per delta active power and unit output in active power. The IHR curve represents the slope of the HeatInputCurve. Note that the incremental heat rate and the heat rate have the same engineering units. IncrementalHeatRateCurve {C785D117-CA7F-43b9-9781-A2C4F23C539C} Individual pricing node based on Pnode. IndividualPnode {E6B3566B-661A-4e6f-819E-67B18C815E70} Inductive part of reactance imaginary part of impedance at rated frequency. Inductance {A5C20135-6480-450b-812C-23263BCC8553} Inductance per unit of length. InductancePerLength {256B27BD-003D-4cf9-9BAE-D9AD4CF6D948} Natural water inflow to a reservoir usually forecasted from predicted rain and snowmelt. Typically in one hour increments for up to 10 days. The forecast is given in average cubic meters per second over the time increment. InflowForecast {41CA4275-BBFB-431b-912C-599AC5B2642C} Questions and answers associated with a type of document for purposes of clarification. Questions may be predefined or ad hoc. InfoQuestion {A02C4C78-68EE-49cb-848C-C7E34BD60B45} Types of input signals. In dynamics modelling commonly represented by the iji parameter. InputSignalKind {FF87046C-0F52-4924-8269-7F7E9E719673} Asset inspection type of analog. InspectionAnalog {A9A741B5-E772-424b-A705-77F294FAC685} Analogs typically recorded during a field inspection. InspectionAnalogKind {838A2C66-9B01-4e76-9527-6981B5BE49FB} Documents the result of one inspection for a given attribute of an asset. InspectionDataSet {3E6EAF5A-9EEE-4ef1-B083-0A204C6A67B7} Asset inspection type of discrete. InspectionDiscrete {3B2DAA43-17A3-4b9a-A295-55F2F49B5E7D} Discretes representing breaker inspection result. InspectionDiscreteKind {0D9D4668-4B3A-494d-A220-8AAB270616D2} Instance of a version of a model part. This corresponds to a payload of instance data. InstanceSet {FEDB9C0B-593C-4a43-BB13-710F6141C1E3} Model of market clearing relating to commitment instructions. Identifies interval. InstructionClearing {EC8FBDD8-880A-49cb-9E58-39774488E1B5} Model of market clearing related to Dispatch Operating Point. Identifies interval. InstructionClearingDOP {64C614BD-1170-49a3-93A0-464AA289153B} Model of market clearing related to Dispatch Operating Target model of anticipatory dispatch. Identifies interval. InstructionClearingDOT {6C295531-7D62-45ee-AB5F-46533D1F413B} Provides the necessary information on a resource basis to capture the StartupShutdown instruction results. This information is relevant to the DA Market RUC only as well as the RT Market HASP Predispatch and Interval. Instructions {78311B60-9E5A-4ea1-8ED7-B9A5A192FBCD} A type of agreement that provides the default method by which interchange schedules are to be integrated to obtain hourly MWh schedules for accounting. IntSchedAgreement {9B01D3C0-7F3E-44b5-A45E-B6585D9B253B} An integer number. The range is unspecified and not limited. Integer {5F6B613B-C31A-4476-8050-E600FBD5F789} Quantity with integer value and associated unit information. IntegerQuantity {932A8711-818C-4821-877F-4EF3AA27D4AD} Kinds of weather condition intensity. IntensityCodeKind {F6A7E1AE-2170-4169-8D09-2417631E55D2} This class represents the inter tie bid. InterTieBid {334A7315-32D5-4ec6-9948-7617450C554E} Model of market clearing related to results at the interties. Identifies interval InterTieClearing {E25E8CDB-A8BF-4552-B0F3-0D52DBBB017A} Direction of an intertie. InterTieDirection {B0936608-F625-4f4d-962D-43AE70AA685C} Response from an intertie resource acknowledging receipt of dispatch instructions. InterTieDispatchResponse {6EAF0507-95E7-4903-B956-357BB5D0B2F2} Provides the tie point specific output from the market applications. Currently this is defined as the loop flow compensation MW value. InterTieResults {B7E8BAE0-6817-4352-BFBA-A533508B7DDE} Existing Transmission Contract data for an interchange schedule. InterchangeETCData {AA37D26B-B897-43ce-B8F6-FC8C02AB6BA7} Interchange schedule class to hold information for interchange schedules such as import export type energy type and etc. InterchangeSchedule {83700D33-E476-4f73-B53C-141249827158} Indicates whether unit is eligible for treatment as a intermittent variable renewable resource. IntermittentResourceEligibility {F58AC39F-91BD-4366-88BD-EB2967288474} There is one internal control area in the system which is the single control area in the primary network company. Real time generation control affects only the internal control area. InternalControlArea {6C4C9F2E-840A-4d68-8F9B-BE9B806AB713} Description of location internal to a building. InternalLocation {BDBC338B-362B-44d7-B28A-8EA84B84D512} Breaker interrupter.Some interrupters have one fixed and one moving contact some have 2 fixed contacts some 2 moving contacts. An interrupter will have relationships with 2 bushings and those relationships may be any combination of the FixedContact and MovingContact associations. InterrupterUnit {18E3DB60-03B9-47df-8914-232FFE326ED5} Interrupter datasheet information. InterrupterUnitInfo {77A86BCD-E347-4ce5-94F0-155D2B9E579B} Kinds of interrupting mediums. InterruptingMediumKind {42A70513-C116-4708-B2D1-300745E7E624} Time sequence of readings of the same reading type. Contained interval readings may need conversion through the application of an offset and a scalar defined in associated pending.Table 548 shows all association ends of IntervalBlock with other classes.Table 548 Association ends of MeteringIntervalBlock with other classesAssociationsnamemult totypedescription0..PendingCalculation0..1PendingCalculationPending calculation to apply to interval reading values contained by this block after which the resulting reading type is different than the original because it reflects the conversion result.0..IntervalReadings0..IntervalReadingInterval reading contained in this block.0..ReadingType0..1ReadingTypeType information for interval reading values contained in this block.0..MeterReading0..1MeterReadingMeter reading containing this interval block.IntervalReadingData captured at regular intervals of time. Interval data could be captured as incremental data absolute data or relative data. The source for the data is usually a tariff quantity or an engineering quantity. Data is typically captured in timetagged uniform fixedlength intervals of 5 min 10 min 15 min 30 min or 60 min.Note Interval Data is sometimes also called Interval Data Readings IDR. IntervalBlock {7E23ABA5-5850-49e6-A741-F54C32CA3E2A} Data captured at regular intervals of time. Interval data could be captured as incremental data absolute data or relative data. The source for the data is usually a tariff quantity or an engineering quantity. Data is typically captured in timetagged uniform fixedlength intervals of 5 min 10 min 15 min 30 min or 60 min.Note Interval Data is sometimes also called Interval Data Readings IDR. IntervalReading {779A4909-8E4E-4587-B2DB-C60366EAE9F4} The schedule has time points where the time between them varies. IrregularIntervalSchedule {3CCC0D33-A9DC-49c4-9A3A-7DCF4CF792DE} TimePoints for a schedule where the time between the points varies. IrregularTimePoint {F3BCC51E-D829-45c1-BC79-9A6E463EFB0F} Person who issued the document and is responsible for its content. Issuer {FBB1E735-6650-42d8-8B2F-9180C073C7AF} JobFlagType {DD9F3A69-9DA0-4b75-BF91-FE984AB783F3} JobScheduleType {5C60DBB1-BEB2-4888-AD07-F511DA77253F} JobStartEndType {CBBA25CF-115A-485f-A32F-09D8073180A0} Joint connects two or more cables. It includes the portion of cable under wipes welds or other seals. Joint {CAE9DEC7-39E9-4f9e-80FC-6AA9FF086528} Kind of configuration for joints. JointConfigurationKind {4025A5DE-B03E-4d90-87F7-1BD696834393} Kind of fill for Joint. JointFillKind {21B4CEF2-88B8-4558-9AA0-70669BF06D4D} A short section of conductor with negligible impedance which can be manually removed and replaced if the circuit is deenergized. Note that zeroimpedance branches can potentially be modelled by other equipment types. Jumper {1D1D3E1A-76FB-4219-90DD-F6AE687989FC} Action on jumper as a switching step. JumperAction {2A90B861-B4FF-4aa8-9A3E-67859AB1303D} A point where one or more conducting equipments are connected with zero resistance. Junction {BE90EE60-8212-44ec-9F4D-775719E80216} Active power in kilowatts. KiloActivePower {BE17081C-6888-4153-B4AB-A672392B7467} LFCResourceType {9C05F8D9-4C2F-409f-908A-BC1DBFA90996} Results of testing done by a lab. LabTestDataSet {E43E62E6-3131-40cd-AFB4-E98F6F6DA528} Labor used for work order. LaborItem {87B7FAF3-F823-4d17-8C7E-B3C24A3C9829} Standard published by Laborelec. LaborelecStandard {893CFA2A-D17F-40ec-9E4B-0859DCF3A569} List of editions for Laborelec standards. LaborelecStandardEditionKind {CBA804C3-86D7-4ac0-9F4B-6E5D60458089} List of Laborelec standards. LaborelecStandardKind {1122E9CD-8BF5-48b0-9A0D-C7D0C87ABC69} Information about a particular piece of land property such as its use. Ownership of the property may be determined through associations to Organisations andor ErpPersons. LandProperty {B793B5F9-0EB8-4854-92EC-0D26B22AFAF1} Kind of land property. LandPropertyKind {85409433-8660-4b97-8E0D-CCA8BDE45DEC} A landslide a large mass of rocks and earth that suddenly and quickly moves down the side of a mountain or hill. Landslide {1588E45D-CCE6-44e2-89B6-BD8C4D859472} Unit of length. It shall be a positive value or zero. Length {06F9A3F0-3AE3-4ad1-88F8-06C207238C3B} Relationship between reservoir volume and reservoir level. The volume is at the Yaxis and the reservoir level at the Xaxis. LevelVsVolumeCurve {F9F1E0C3-9A25-4e46-8E17-91ED55579473} Dates for asset lifecycle state changes. May have multiple lifecycle dates for this device and a compound type allows a query to return multiple dates. LifecycleDate {67AECABD-F376-4a6e-B6E0-F84A33F324EC} A cloudtoground lightning strike at a particular location. LightningStrike {A68FB6F4-6463-4937-A1E8-B22BB98F453C} Specifies one limit value for a Measurement. A Measurement typically has several limits that are kept together by the LimitSet class. The actual meaning and use of a Limit instance i.e. if it is an alarm or warning limit or if it is a high or low limit is not captured in the Limit class. However the name of a Limit instance may indicate both meaning and use. Limit {ED3F9694-F2AC-43af-B3CA-57395E31AD94} A limit calculation model used to compute an operational limit based on external input such as temperature. These are intended to be shared among operational limits with the same calculation form that apply to a piece of equipment.. LimitDependency {B2593470-2C8B-4b8e-B88E-5C9B177172DB} Specifies an operational limit is calculated by scaling another operational limit. LimitScalingLimit {8E9F6A36-A81C-4cc7-BD92-738BE123B1F5} Specifies a set of Limits that are associated with a Measurement. A Measurement may have several LimitSets corresponding to seasonal or other changing conditions. The condition is captured in the name and description attributes. The same LimitSet may be used for several Measurements. In particular percentage limits are used this way. LimitSet {D0F989DA-F598-4d05-98C6-4148DE43F7AB} Contains equipment beyond a substation belonging to a power transmission line. Line {43D9D2B8-DA1E-45c4-B99D-EC28FCAB742B} Details on an amount line with rounding date and note. LineDetail {5BE14CC8-F5D1-4677-8239-955933CCC630} A fault that occurs on an AC line segment at some point along the length. LineFault {784DAFDE-99A3-4b69-A759-169FFD08E627} A linear shunt compensator has banks or sections with equal admittance values. LinearShuntCompensator {94E82A47-069F-4e2b-A4FA-8CFD5E140FD7} A per phase linear shunt compensator has banks or sections with equal admittance values. LinearShuntCompensatorPhase {15B42F89-92AF-4830-BC3C-4CD7FB779043} Aggregate loads are used to represent all or part of the real and reactive load from one or more loads in the static power flow data. This load is usually the aggregation of many individual load devices and the load model is an approximate representation of the aggregate response of the load devices to system disturbances.Standard aggregate load model comprised of static andor dynamic components. A static load model represents the sensitivity of the real and reactive power consumed by the load to the amplitude and frequency of the bus voltage. A dynamic load model can be used to represent the aggregate response of the motor components of the load. LoadAggregate {EE06C0E9-A1EE-4b3f-AD4D-D225DFE10EEF} A specialized class of type AggregatedNode type. Defines Load Aggregation Points. LoadAggregationPoint {023C46A0-57C3-4ebe-97D0-FFFD80D7B619} The class is the root or first level in a hierarchical structure for grouping of loads for the purpose of load flow load scaling. LoadArea {88627287-3FFF-4f0b-954D-3CDA82016DEB} Offer to supply energyancillary services from a load resource participating load reduces consumption. LoadBid {EDE7D5E6-419B-4e2b-9E96-D9FCD6797B89} A mechanical switching device capable of making carrying and breaking currents under normal operating conditions. LoadBreakSwitch {D64FF392-C9F8-4220-8861-1944D504F342} Combined static load and induction motor load effects.The dynamics of the motor are simplified by linearizing the induction machine equations. LoadComposite {BDFAC440-3B77-47a6-B8DB-C480D393299F} This class models the load distribution factors. This class should be used in one of two waysUse it along with the AggregatedPnode and the IndividualPnode to show the distriubtion of each individual partyORUse it with MktEnergyConsumer to represent the current MWMvar distribution within its parnet load group. LoadDistributionFactor {5F30ADF0-511F-460c-BA44-39A90062F536} Load whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.fontA standard feature of dynamic load behaviour modelling is the ability to associate the same behaviour to multiple energy consumers by means of a single load definition. The load model is always applied to individual bus loads energy consumers. LoadDynamics {0589465F-40A5-4de5-B0FE-A21D8275117B} LoadFollowingCapacityType {ABC959DC-721F-4bc9-94BE-940B0844075A} Metered SubSystem Load Following Instruction. LoadFollowingInst {A366CFF5-28B3-4052-9EA2-A228FA053F62} Model of load following capabilities that are entered by operators on a temporary basis. Related to Registered Resources in Metered Subsystems. LoadFollowingOperatorInput {61CFAA82-4719-4897-8251-439FE7ADED7C} Load forecast zone types. LoadForecastType {5FC3A4F6-B913-4e9d-BA33-E253363199A6} Generic nonlinear dynamic GNLD load. This model can be used in midterm and longterm voltage stability simulations i.e. to study voltage collapse as it can replace a more detailed representation of aggregate load including induction motors thermostatically controlled and static loads. LoadGenericNonLinear {66917254-AB0B-4699-936A-BDFABC710CD5} The class is the third level in a hierarchical structure for grouping of loads for the purpose of load flow load scaling. LoadGroup {BC60B72D-57A5-4705-96C2-21180B040E5B} Load a model part version. LoadModelPartVersion {5F6F7368-7DAE-4e57-8CF3-372C07FCC64A} Aggregate induction motor load. This model is used to represent a fraction of an ordinary load as induction motor load. It allows a load that is treated as an ordinary constant power in power flow analysis to be represented by an induction motor in dynamic simulation. This model is intended for representation of aggregations of many motors dispersed through a load represented at a high voltage bus but where there is no information on the characteristics of individual motors.Either a onecage or twocage model of the induction machine can be modelled. Magnetic saturation is not modelled.This model treats a fraction of the constant power part of a load as a motor. During initialisation the initial power drawn by the motor is set equal to iPfraci times the constant iPi part of the static load. The remainder of the load is left as a static load.The reactive power demand of the motor is calculated during initialisation as a function of voltage at the load bus. This reactive power demand can be less than or greater than the constant iQi component of the load. If the motors reactive demand is greater than the constant iQi component of the load the model inserts a shunt capacitor at the terminal of the motor to bring its reactive demand down to equal the constant iQi reactive load. If an induction motor load model and a static load model are both present for a load the motor iPfraci is assumed to be subtracted from the power flow constant iPi load before the static load model is applied. The remainder of the load if any is then represented by the static load model. LoadMotor {26A10608-6EE9-42d6-8969-6212CD99C9E0} Representing the ratio of the load share for the associated SC. LoadRatio {1D3E872B-9078-493e-B9BF-A61556AEA453} This is the price sensitivity that bidder expresses for allowing market load interruption. Relationship between price Y1axis vs. MW Xaxis. LoadReductionPriceCurve {753672A1-11E1-4850-8525-DCD1CD02FB80} This is the cureve that describes the load reduction time. Relationship between time Y1axis vs. MW Xaxis. LoadReductionTimeCurve {47191455-BCF8-45a0-B1FA-5E205AC82308} Models the characteristic response of the load demand due to changes in system conditions such as voltage and frequency. It is not related to demand response.If LoadResponseCharacteristic.exponentModel is True the exponential voltage or frequency dependent models are specified and used as to calculate active and reactive power components of the load model.The equations to calculate active and reactive power components of the load model are internal to the power flow calculation hence they use different quantities depending on the use case of the data exchange. The equations for exponential voltage dependent load model injected power are pInjection Pnominal VoltagecimBaseVoltage.nominalVoltage cimLoadResponseCharacteristic.pVoltageExponentqInjection Qnominal VoltagecimBaseVoltage.nominalVoltage cimLoadResponseCharacteristic.qVoltageExponentWhere 1 means multiply and is raised to power of2 Pnominal and Qnominal represent the active power and reactive power at nominal voltage as any load described by the voltage exponential model shall be given at nominal voltage. This means that EnergyConsumer.p and EnergyConsumer.q are at nominal voltage.3 After power flow is solved pInjection and qInjection correspond to SvPowerflow.p and SvPowerflow.q respectively. Voltage corresponds to SvVoltage.v at the TopologicalNode where the load is connected. LoadResponseCharacteristic {F80EE4DD-B985-47e3-9832-B5005C24C87E} General static load. This model represents the sensitivity of the real and reactive power consumed by the load to the amplitude and frequency of the bus voltage. LoadStatic {2205909C-5373-450d-AE71-9D3F01B279FE} Load whose dynamic behaviour is described by a userdefined model. LoadUserDefined {1D45E2C9-CDEE-47b0-98FA-D79DC698CED5} Allows definition of reliability areas e.g.. load pockets within the ISORTO. LocalReliabilityArea {2577783B-B2ED-4938-B2BB-071686AA5A25} The place scene or point of something where someone or something has been is andor will be at a given moment in time. It can be defined with one or more position points coordinates in a given coordinate system. Location {671B9EF5-A0CB-467e-ADAC-FBEA4156EEBB} A grant provides a right as defined by type for a parcel of land. Note that the association to Location Asset Organisation etc. for the Grant is inherited from Agreement a type of Document. LocationGrant {BC7CB30C-AD3F-4ca4-B3E1-0790F9AFF07B} The nature of the location being defined for an environmental entity. Possible values are center perimeter primary secondary. LocationKind {D661E2A1-1ABC-4c6c-9422-08455FFE3715} LookUpTableFunctionKind {3BEBAC1D-EFF7-4733-A4EE-E92CD6AA7910} RT only and is published on 5 minute intervals for the previous RT time interval results. LossClearing {A675112F-3536-4224-8DAA-0DEDEE9C8055} Provides the MW loss for RUC Zones subcontrol areas and the total loss. LossClearingResults {13E4D24D-E662-436f-98DA-EB56DD64E571} LossProfile is associated with an EnerrgyTransaction and must be completely contained within the time frame of the EnergyProfile associated with this EnergyTransaction. LossProfile {54BFFACA-ABB8-4351-AEF1-5377172641D9} Loss sensitivity applied to a ConnectivityNode for a given time interval. LossSensitivity {E66C89D9-F387-4ef0-BF87-81874BCEB6CD} Model of results of Market Power tests and possible mitigation. Interval based. MPMClearing {D3251165-323E-4741-8CDB-9D20FB10A74F} Model of results of Market Power tests gives status of resource for the associated interval. MPMResourceStatus {7B63A03C-B965-4f27-B50E-CE3E077C0774} Provides a reference to the Market Power Mitigation test identifiers and methods for the results of the DA or RT markets. Specific data is the test identifier Price Conduct or Impact and the test method System MPM Local MPM Alternate System MPM or Alternate Local MPM. MPMTestCategory {1C74B6FD-241F-4d4f-9281-DD92367C23D9} Market power mitigation test identifier type for example1 Global Price Test2 Global Conduct Test3 Global Impact Test4 Local Price Test5 Local Conduct Test6 Local Impact Test MPMTestIdentifierType {B4D946D6-6691-43e0-AEEB-7CEFBA38B30E} Market power mitigation test method type.Tests with the normal default thresholds or tests with the alternate thresholds. MPMTestMethodType {E789C4C4-C240-4a01-88F8-DDE49392EE31} For examplePassedFailedDisabledSkipped MPMTestOutcome {39FD64E4-1D0A-4656-9F31-CEFA9E3D343E} Provides the outcome and margin percent as appropriate result data for the MPM tests. There are relationships to Zone for Designated Congestion Area Tests CurveSchedData for bid segment tests to the SubControlArea for the system wide level tests and Pnodes for the LMPM impact tests. MPMTestResults {CF50DDD1-6FF8-4e5f-8C6E-0990AFCE6C9B} Market Power Mitigation MPM test thresholds for resource as well as designated congestion areas DCAs. MPMTestThreshold {B33BA46E-DC3B-4b67-BE55-EEDDE0B2DFAC} For exampleADD addCHG change MQSCHGType {DBF7DFA5-206A-4db1-AE0C-5EC07F52D6F9} ADD addDEL deleteCHG change MQSDELType {9E965561-6FC8-47d0-882E-F353338B2405} Valid values for example INS Instruction from RTMACT Actual instruction after the fact MQSInstructionSource {4E798929-48FC-4231-8A87-E70ABF184684} Metered SubSystem aggregation of MSS Zones. MSSAggregation {48D5BEFC-9AF1-46b6-8288-509365AD7053} Model to define a zone within a Metered Sub System. MSSZone {E27C18F9-46D2-495f-B67A-8548DBCA38F9} Maximum MW and optionally Minimum MW Y1 and Y2 respectively. MWLimitSchedule {40FDD18B-50C8-4ddc-A1C4-DFC133B178E3} Kind of macro period for calculations on read measured values. MacroPeriodKind {244D847D-1CAB-4bbe-9F4A-A63C52FE273D} Magnetic field in nanotesla. MagneticField {2C3CA1D1-1DBB-4f95-9BC9-60B0DD26DA65} A magnetic storm a temporary disturbance of the earths magnetic field induced by radiation and streams of charged particles from the sun. MagneticStorm {58047739-8B91-44ea-8807-EEDFC6F44AF5} Organisation that maintains assets. Maintainer {FEF8A51A-0C79-429e-ACF4-79F03231A77A} The result of a maintenance activity a type of Procedure for a given attribute of an asset. MaintenanceDataSet {D7D486F8-5BBE-4985-B51A-6E86727929C3} Location where to perform maintenance work. MaintenanceLocation {71079308-2B69-4067-8A52-46B62BBD1F48} Maintenance work task. Costs associated with this are considered preventive maintenance PM costs. MaintenanceWorkTask {F2865AF9-CDD2-4194-A533-260CA1AEED79} A Major Charge Group is the same as Invoice Type which provides the highest level of grouping for charge types configuration. Examples Market FERC RMR. MajorChargeGroup {C6DA5003-F272-4d50-8183-33E7FA08E3B9} Organisation that manufactures asset products. Manufacturer {7A73B277-AD64-4e35-BCB0-C6495F8E63CA} Market e.g. Day Ahead Market Real Time Market with a description of the Market operation control parameters. Market {0E7800EF-F016-473c-A6CA-15C11994D3B1} This class represents the actual instance of an event. MarketActualEvent {4A7047CA-692A-4f28-B52C-2F3FFF88BBDA} An identification or eventually the contents of an agreement between two or more parties. MarketAgreement {D4F3E628-DD4C-4d56-B25B-7683B1B75611} Market case clearing results are posted for a given settlement period. MarketCaseClearing {310853AB-4168-40e4-ABE4-7631C0024991} Electronic document containing the information necessary to satisfy a given business process set of requirements. MarketDocument {C3394CCE-C232-4c44-AEFE-C7449974B30B} The identification of an entity where energy products are measured or computed. MarketEvaluationPoint {5C7856BA-008C-4e93-B0B0-80E339AB6A08} Market event status types. MarketEventStatusKind {C140C991-419D-4093-9496-7C884CD999DA} Aggregation of market information relative for a specific time interval. MarketFactors {DC324B9D-14ED-47f5-8F9C-6779797D04F7} A roll up of invoice line items. The whole invoice has a due date and amount to be paid with information such as customer banks etc. being obtained through associations. The invoice roll up is based on individual line items that each contain amounts and descriptions for specific services or products. MarketInvoice {C70AF7F3-A8E2-4c10-A262-E5EC8388A555} An individual line item on an invoice. MarketInvoiceLineItem {E89C82DB-FA7B-4c33-88A7-065081AC01DF} In accounting transactions a ledger is a book containing accounts to which debits and credits are posted from journals where transactions are initially recorded. Journal entries are periodically posted to the ledger. Ledger actual represents actual amounts by account within ledger within company or within business area. Actual amounts may be generated in a source application and then loaded to a specific ledger within the enterprise general ledger or budget application. MarketLedger {A6A29DB1-79CF-43de-8520-8874A84D0551} Details of an individual entry in a ledger which was posted from a journal on the posted date. MarketLedgerEntry {6820DAEE-AAED-43ee-9364-DA01ED2BCB7D} The condition or position of an object with regard to its standing. MarketObjectStatus {DB7CC22D-A5B9-4978-9B03-155D3F3D7610} An identification of a party acting in a electricity market business process. This class is used to identify organizations that can participate in market management andor market operations. MarketParticipant {75B473D1-2626-4e11-BB45-1B2434163D6D} General purpose information for name and other information to contact people. MarketPerson {920B428C-558A-4196-AC2B-DFD8CB2F83C1} This class identifies a set of planned markets. MarketPlan {78D79406-CCAC-4e37-82FE-BBB5FDB0771B} A product traded by an RTO e.g. energy 10 minute spinning reserve. Ancillary service product examples include Regulation Regulation Up Regulation Down Spinning Reserve NonSpinning Reserve etc. MarketProduct {181E8299-A6B5-4e02-AFC0-D1890C50FC39} Market product self schedule bid types. MarketProductSelfSchedType {502B95E5-B0D2-4eb0-B86F-9E1C5166CE2E} For exampleEnergy Reg Up Reg Down Spin Reserve Nonspin Reserve RUC Load Folloing Up and Load Following Down. MarketProductType {1920E8CD-6BD4-4056-B957-9776FC340CA1} RU Regulation UpRD Regulation DownSR Spin ReserveNR Nonspin ReserveAS Upward Ancillary Service MarketProductTypeAsReq {EB7283D5-CE00-42e9-83EC-8DE0B089271F} Certain skills are required and shall be certified in order for a person typically a member of a crew to be qualified to work on types of equipment. MarketQualificationRequirement {F30DEF68-DD5F-40e5-8646-0997994399AE} A specialized class of AggregatedNode type. Defines the MarketRegions. Regions could be system Market Regions Energy Regions or Ancillary Service Regions. MarketRegion {2E8AF05C-A65B-4002-9AB4-40F7E351CF05} Provides all Region Ancillary Service results for the DA and RT markets. The specific data is commodity type Regulation Up Regulation Down Spinning Reserve Nonspinning Reserve or Total Up reserves based for the cleared MW cleared price and total capacity required for the region. MarketRegionResults {1F94ED51-CDDB-48f7-85CB-407110E194EB} This class holds elements that are single values for the entire market time horizon. That is for the Day Ahead market there is 1 value for each element not hourly based. Is a summary of the market run. MarketResults {DBD013BA-5C9D-4450-8A6F-1551BE77FC75} The external intended behavior played by a party within the electricity market. MarketRole {67F6267D-A999-4c0d-8D42-18D30418307C} Kind of market role an organisation can have. This list is not exhausted as other roles may exist. MarketRoleKind {86C84FDF-C303-49c7-827F-3EB7E7541C86} This class represents an actual instance of a planned market. For example a Day Ahead market opens with the Bid Submission ends with the closing of the Bid Submission. The market run represent the whole process. MarketRuns can be defined for markets such as Day Ahead Market Real Time Market Hour Ahead Market Week Ahead Market etc. MarketRun {E99740BA-F157-4353-95B5-F466E80BB1BC} MarketScheduleServices {7BFB094E-5E4C-4b25-ADBE-94BF15F4A323} Signifies an event to trigger one or more activities such as reading a meter recalculating a bill requesting work when generating units shall be scheduled for maintenance when a transformer is scheduled to be refurbished etc. MarketScheduledEvent {62C99EEC-52F8-41aa-9D1D-0F6DA2351A74} Proficiency level of a craft which is required to operate or maintain a particular type of asset andor perform certain types of work. MarketSkill {4EACB8B2-0E30-4b17-9A2D-844B414A1B6B} A statement is a roll up of statement line items. Each statement along with its line items provide the details of specific charges at any given time. Used by Billing and Settlement. MarketStatement {6EF21B53-20A7-4174-BC67-2E175BCEEDDB} Description of market statement MarketStatementDescription {3F2FEF60-EB83-434c-87B5-39B726201FEE} market statement document status MarketStatementDocStatus {4480C85A-D453-4552-8264-6FC758A87B1B} market statement document type MarketStatementDocType {FA72604B-B44B-4c63-9BD7-6525568312C5} An individual line item on an ISO settlement statement. MarketStatementLineItem {8EEFD522-B659-4b02-AA47-9D57996FACCF} market statement line item alias name MarketStatementLineItemAliasName {2F07BFB9-CA35-4767-9306-2C9756789465} Market type. MarketType {9974A28A-9581-48c6-B7F9-B019B1E1DC80} Matches buyers and sellers and secures transmission and other ancillary services needed to complete the energy transaction. Marketer {037CF759-5512-4012-8753-3922B3D2B8C4} Mass. Mass {3090EC66-8B19-4224-A206-00BFE70ECED0} The physical consumable supply used for work and other purposes. It includes items such as nuts bolts brackets glue etc. MaterialItem {71A96EF3-A030-44b2-9B34-92A72564646C} The maximum Startup costs and time as a function of down time. Relationship between unit startup cost Y1axis vs. unit elapsed down time Xaxis. This is used to validate the information provided in the Bid. MaxStartUpCostCurve {ECBD3F6B-2F34-4850-9BD0-146A8827E42F} A Measurement represents any measured calculated or nonmeasured noncalculated quantity. Any piece of equipment may contain Measurements e.g. a substation may have temperature measurements and door open indications a transformer may have oil temperature and tank pressure measurements a bay may contain a number of power flow measurements and a Breaker may contain a switch status measurement. The PSR Measurement association is intended to capture this use of Measurement and is included in the naming hierarchy based on EquipmentContainer. The naming hierarchy typically has Measurements as leaves e.g. SubstationVoltageLevelBaySwitchMeasurement.Some Measurements represent quantities related to a particular sensor location in the network e.g. a voltage transformer VT or potential transformer PT at a busbar or a current transformer CT at the bar between a breaker and an isolator. The sensing position is not captured in the PSR Measurement association. Instead it is captured by the Measurement Terminal association that is used to define the sensing location in the network topology. The location is defined by the connection of the Terminal to ConductingEquipment. If both a Terminal and PSR are associated and the PSR is of type ConductingEquipment the associated Terminal should belong to that ConductingEquipment instance.When the sensor location is needed both MeasurementPSR and MeasurementTerminal are used. The MeasurementTerminal association is never used alone. Measurement {AB1758FA-3A4D-478f-BE4F-ADC8E2F886CC} Measurement taken as a switching step. MeasurementAction {D2A8F7F3-5902-40b2-9A33-6873CB46EAAD} Result of a calculation of one or more measurement. MeasurementCalculator {87497F71-8E8B-4b4f-ADA0-35E128E5812C} Input to measurement calculation. Support Analog Discrete and Accumulator. MeasurementCalculatorInput {74EA1CCE-5F3A-437b-B90E-3C4E02DE69A3} Kind of read measured value. MeasurementKind {54D3D7E0-8107-4130-8AED-E0E1D5E20F3A} Path Flow PFPath Inflow Limit PILPath Inflow Available Limit PIAL Path Inflow Armed Limit PIMLPath Outflow Limit POLPath Outflow Available Limit POAL Path Outflow Armed Limit OARLGeneration Output GO Generation Max Operating Limit GMOL Generation Min Operating Limit GNOL Generation Regulation GR Generation Status GS Pump Production PP System Load SL System ACE ACESystem INADV INADV MeasurementTypeEMS {CDBBE8AA-2696-4cfa-9520-FB470C37ECCA} The current state for a measurement. A state value is an instance of a measurement from a specific source. Measurements can be associated with many state values each representing a different source for the measurement. MeasurementValue {E6D7B57A-456A-43b5-838B-3CFB466EE4C4} Measurement quality flags. Bits 010 are defined for substation automation in IEC 6185073. Bits 1115 are reserved for future expansion by that document. Bits 1631 are reserved for EMS applications. MeasurementValueQuality {D45A5712-F5C6-410e-8799-A6EEBD3DAEA2} MeasurementValueSource describes the alternative sources updating a MeasurementValue. User conventions for how to use the MeasurementValueSource attributes are defined in IEC 61970301. MeasurementValueSource {9A0BEA87-6F15-4c48-A102-9DA595DD7B0A} Kind of period for reading measuring values. MeasuringPeriodKind {0DC2C07F-966E-43ab-8DA0-B65F51CB6E2E} Mechanical load model type 1. MechLoad1 {114B65DF-8F90-46c6-952D-2FC3E46F9169} Mechanical load function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font MechanicalLoadDynamics {3C5B6644-5E53-4330-8E77-595A2B1335DD} Mechanical load function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font MechanicalLoadUserDefined {B88FDC2F-09B6-4967-8C87-9896D3EEBF26} A substance that either 1 provides the means of transmission of a force or effect such as hydraulic fluid or 2 is used for a surrounding or enveloping substance such as oil in a transformer or circuit breaker. Medium {EE7BBAF4-7FC2-4777-BCB7-2C0CC47C4899} Kind of medium. MediumKind {F7D95C04-FBC0-490a-8587-6B50CE99B307} The operating account controlled by merchant agreement against which the vendor may vend tokens or receipt payments. Transactions via vendor shift debit the account and bank deposits via bank statement credit the account. MerchantAccount {9872E766-CD0F-47dc-A36A-0BA0E1A3DBBE} A formal controlling contractual agreement between supplier and merchant in terms of which the merchant is authorised to vend tokens and receipt payments on behalf of the supplier. The merchant is accountable to the supplier for revenue collected at point of sale. MerchantAgreement {264A71E5-64A3-4977-BEE2-F571D4576C97} Physical asset that performs the metering role of the usage point. Used for measuring consumption and detection of events. Meter {205B6F34-8938-4372-BC87-FB51486FE4A6} Multiplier applied at the meter. MeterMultiplier {8A9D442B-3BA0-4165-8ABA-EF2D8A351B51} Kind of meter multiplier. MeterMultiplierKind {DE169701-1595-4706-BE8D-544BCD71F7C8} Set of values obtained from the meter. MeterReading {115DC4EA-8B92-4bfa-B8BE-4AC3A83934CD} Work task involving meters. MeterWorkTask {9770E496-51C1-4d53-A219-8138C2701943} A metered subsystem. MeteredSubSystem {72CD6CEF-766E-4cab-A58D-5E6020F0E358} A specification of the metering requirements for a particular point within a network. MetrologyRequirement {E81DF00E-E1C5-414a-852C-D627D2A1A51E} Time in minutes. Minutes {68F89418-6302-42a8-8177-5637B46ED1DB} Various cost items that are not associated with compatible units. Examples include rental equipment labor materials contractor costs permits anything not covered in a CU. MiscCostItem {4026BBE0-4EDE-4a88-9540-4BEE474CA739} Mitigated bid results posted for a given settlement period. MitigatedBid {BB03E840-974D-42d2-889C-538806C4467D} Model of market power mitigation through reference or mitigated bids. Interval based. MitigatedBidClearing {70FE2C69-FAF0-43fa-8233-648A2E7ECC60} Model of mitigated bid. Indicates segment of piecewise linear bid that has been mitigated. MitigatedBidSegment {8283C8BB-51F6-4b6e-9165-F0720FBAEA71} Subclass of IEC 61970WiresACLineSegment. MktACLineSegment {5D97034C-EE14-4ec9-B92A-E90EE3C3AC9F} Kind of Market account. MktAccountKind {3C1B1532-00FF-4d12-99CA-7A793AFCEE15} Subclass of IEC61968 CommonActivityRecord. MktActivityRecord {F3BA1ABB-530F-4267-843F-D65CBB609987} Subclass of IEC 61970MeasAnalogLimit. MktAnalogLimit {3CCBFC52-897B-40b2-99CD-016915C75A3D} Subclass of IEC 61970MeasAnalogLimitSet. MktAnalogLimitSet {A1AC7965-7C94-45e1-B94C-207E6AA9A604} Kind of bill media. MktBillMediaKind {A247AC71-10FA-4d51-80E3-83B671EAD70C} Subclass of Production CombinedCyclePlant from IEC 61970 package.A set of combustion turbines and steam turbines where the exhaust heat from the combustion turbines is recovered to make steam for the steam turbines resulting in greater overall plant efficiency. MktCombinedCyclePlant {B0A0BCA1-2D6C-445f-9024-174B473927B8} Subclass of IEC 61970CoreConductingEquipment. MktConductingEquipment {7F788297-F026-4e8b-A1D7-1BC2001050F2} Subclass of IEC61970TopologyConnectivityNode. MktConnectivityNode {C1B50235-BB57-46b1-8156-D728B377DB02} Subclass of IEC 61970Contingency. MktContingency {836AD0B6-1B52-46ea-8BF0-C210A74EDB3D} Market subclass of IEC 61970ControlArea. MktControlArea {247F6C1A-E9AF-49c0-B00D-05FB8D49CF78} Subclass of IEC61970ProductionGeneratingUnit. MktGeneratingUnit {C783CC9F-4FDF-4911-BA30-0FBA52A031D2} Subclass of IEC 61970 Generation ProductionHeatRateCurve. MktHeatRateCurve {142CE3B4-C829-4f94-8571-7009E5FEB0C7} Kind of invoice line item. MktInvoiceLineItemKind {30CBD890-6578-48b4-BA4E-4C563A77103A} Subclass for IEC61970WiresLine. MktLine {AC98E4CC-3B82-4c05-BBAE-13FAFC8CEFFD} Subclass of IEC61970MeasMeasurement. MktMeasurement {F792A9D7-1097-4bf1-8B00-E894C6CD2AFA} The type of a power system resource. MktPSRType {A544B969-57EA-4bd1-9E5F-6127F5C9AB8F} Subclass of IEC61970WiresPowerTransformer. MktPowerTransformer {234E9796-CB64-4bae-A3EC-C33F3B4F7275} Subclass of IEC 61970WiresSeriesCompensator. MktSeriesCompensator {21DEC6A0-ADFE-48bf-A560-DCDEFE9C0958} Subclass of IEC 61970WiresShuntCompensator. MktShuntCompensator {63B45A42-9F8C-4462-9CF9-194D2CA60E17} MktSubClassType {DFD03D77-33FE-41d0-A327-0EECD0FEC905} Subclass of IEC 61970WiresSwitch. MktSwitch {34A1D3B5-55F1-44f8-906D-73EB04C34B87} Subclass of IEC 61970WiresTapChanger. MktTapChanger {BCEAC343-15E5-4871-B74F-1FE4593A6128} Subclass of IEC61970CoreTerminal. MktTerminal {CB4EA124-E91C-4e18-97EC-1AFD85646AFE} Subclass of ThermalGeneratingUnit from Production Package in IEC 61970. MktThermalGeneratingUnit {FDE35007-FB33-4d14-B0B4-96A9AA230BD3} Subclass of IEC61968Domain2UserAttribute. MktUserAttribute {480FBBF0-926A-4125-ADAA-6CA279DCEF6E} A Modeling Authority is an entity responsible for supplying and maintaining the data defining a specific set of objects in a network model. ModelAuthority {C2D644C3-20C1-408d-86F0-738AD512C121} A Modeling Authority Set is a group of objects in a network model where the data is supplied and maintained by the same Modeling Authority.This class is typically not included in instance data exchange as this information is tracked by other mechanisms in the exchange. ModelAuthoritySet {6D6E62ED-DCB6-4e54-9159-8469729C9828} Examples would be Boundary or Region type of frame. ModelFrameType {441F5D00-3017-42ce-8499-698FD8022177} An operation performed on models. ModelOperation {DD8B0627-7F67-4d51-9ABC-03D0BF4BA7CD} Describes the role a dataset plays in a model operation. The role is applicable only in the context of a single operation. ModelOperationArg {B29AFAE4-9F24-4482-85E2-C1C8CB65F146} The type of custom operation dataset role for an operation description. ModelOperationArgDescription {E557275F-6438-417b-9835-80AA612233C9} The type of model operation. This class is referenced by model operations and defines the kind of operation. ModelOperationDescription {E7A4D5EF-6269-4060-9926-32B91503ED92} A concrete sequence of operations. For example this may be used to describe a specific audit trail a script or other specific set of actions on specific datasets. ModelOperationSequence {9656D19D-8924-42b5-8754-3DCECBCC6B9C} The type of model. For example state estimator planning planning dynamics short circuit or realtime dynamics etc. The model must conform to a profile. ModelPartSpecification {763139C3-DC02-4af5-9CFC-AB46D2F47180} This is a version of a part of a model. New instances of this class with new identity are instantiated upon changes to the content of this class or changes to the associated data set. Instances of this class are considered immutable. The case audit trail can reference this immutable data to exactly reproduce a case. ModelPartVersion {7B26D541-A396-4882-8F03-75BE30976A2F} A Model is a collection of Datasets. ModelToBeDeleted {9F3ABE94-E4F2-49ee-ABCC-F804CCCF0004} Amount of money. Money {5E4B6DE1-9115-4fce-9859-6714580E5C66} MonthDay format as mmdd which conforms with XSD data type gMonthDay. MonthDay {06EEB33A-0F70-4c8c-A932-3836A0BF6872} Interval between two times specified as month and day. MonthDayInterval {4EA61E08-03B6-4eec-9C3B-0978F4898AB3} This class represents the zero sequence line mutual coupling. MutualCoupling {A46F0441-DB66-4ff2-A892-7C5F9F54FA38} The Name class provides the means to define any number of human readable names for an object. A name is bnotb to be used for defining interobject relationships. For interobject relationships instead use the object identification mRID. Name {D6F3DF4E-3363-48d2-AB61-7872E337C422} Type of name. Possible values for attribute name are implementation dependent but standard profiles may specify types. An enterprise may have multiple IT systems each having its own local name for the same object e.g. a planning system may have different names from an EMS. An object may also have different names within the same IT system e.g. localName as defined in CIM version 14. The definition from CIM14 isThe localName is a human readable name of the object. It is a free text name local to a node in a naming hierarchy similar to a file directory structure. A power system related naming hierarchy may be Substation VoltageLevel Equipment etc. Children of the same parent in such a hierarchy have names that typically are unique among them. NameType {666F94BF-13E3-4947-830F-3A2D4E7CC9FC} Authority responsible for creation and management of names of a given type typically an organization or an enterprise system. NameTypeAuthority {F4E2C3FE-B480-46c9-8840-DF8D3F3BD6CC} A framework part that is a boundary between 2 frames. NetworkBoundary {4803F850-0F9E-4f4b-9928-60C03BEA2BF7} A region isolated by boundaries. NetworkFrame {98774A6E-0A19-461c-BD45-3B81201BF60C} Instructions to build a network model case including when appropriate the results. NetworkModelCaseDefinition {42B17612-9428-4011-901E-A0360E01C5C1} A grouping of network model change descriptions. Primarily used to organize the phases of an overall project. NetworkModelProject {39DCFCF6-80FC-4183-820D-4390F0E260FC} NetworkModelProject2 {122073A1-D327-4ccf-BAEF-8092D3C71117} Network model project change described by versions of an associated change set. Has persistent identity over multiple versions of the associated change set. NetworkModelProjectChange {3BE1FB32-2A3E-4d65-8D09-B4F513D28FC6} Describes the status and the planned implementation of the associated change set into the asbuilt model. New instances of this class with new identity are instantiated upon changes to the content of this class or changes to the associated change set. Instances of this class are considered immutable. The case audit trail can reference this immutable data to exactly reproduce a case. NetworkModelProjectChangeVersion {DC8F905B-85AF-46f5-9233-C494C3942C12} NetworkModelProjectCollection {DC429367-A8F5-442e-A5AF-C5A33EA166D4} Abstract class for both a network model project and network model change. NetworkModelProjectComponent {B2433B1C-C4C4-4f2d-B57E-ECB3BB008AAD} NetworkModelProjectComponent2 {B71281F5-4070-444e-9D7A-42C7D9DE600A} NetworkModelProjectDocument {DCA0BAED-45FE-45d1-BBF3-32B22F2798A7} A relationship that assists humans and software building cases by assembling project changes in the correct sequence. This class may be specialized to create specific types of relationships. NetworkModelProjectRelationship {6437D5D0-8803-45ba-8075-BE458D7F09E0} NetworkModelProjectStage {43AABFB5-F2C5-475d-9648-EC752AF6C0BB} A network model project version state. States are agreed upon by the exchange community. Examples are approved proposed withdrawn committed etc. NetworkModelProjectState {26500825-18B8-4dc5-99AC-56AFF0A87378} Noload test results determine core admittance parameters. They include exciting current and core loss measurements from applying voltage to one winding. The excitation may be positive sequence or zero sequence. The test may be repeated at different voltages to measure saturation. NoLoadTest {ED8C37BD-DF33-447e-8A17-96B22ECA0228} To be used only to constrain a quantity that cannot be associated with a terminal. For example a registered generating unit that is not electrically connected to the network. NodeConstraintTerm {76D61CB8-3AC6-4380-912C-3A7D776DC872} NonConformLoad represents loads that do not follow a daily load change pattern and whose changes are not correlated with the daily load change pattern. NonConformLoad {E1506289-85CA-4e5b-BD89-6E483BCE1C0F} Loads that do not follow a daily and seasonal load variation pattern. NonConformLoadGroup {BE40965D-042B-4901-9F5D-DED85218AF51} An active power Y1axis and reactive power Y2axis schedule curves versus time Xaxis for nonconforming loads e.g. large industrial load or power station service where modelled. NonConformLoadSchedule {41B7642C-D924-4ebf-9AE9-4BD3706390FD} This document provides information for nonstandard items like customer contributions e.g. customer digs trench vouchers e.g. credit and contractor bids. NonStandardItem {2D51D3F2-0C51-48c2-B14F-277761C9644A} A non linear shunt compensator has bank or section admittance values that differ. The attributes g b g0 and b0 of the associated NonlinearShuntCompensatorPoint describe the total conductance and admittance of a NonlinearShuntCompensatorPoint at a section number specified by NonlinearShuntCompensatorPoint.sectionNumber. NonlinearShuntCompensator {111DB4FF-7967-4eb5-AABE-CDA0EA065CF8} A per phase non linear shunt compensator has bank or section admittance values that differ. The attributes g and b of the associated NonlinearShuntCompensatorPhasePoint describe the total conductance and admittance of a NonlinearShuntCompensatorPhasePoint at a section number specified by NonlinearShuntCompensatorPhasePoint.sectionNumber. NonlinearShuntCompensatorPhase {178D630D-8883-41d1-BFE0-81BFD2B70087} A per phase non linear shunt compensator bank or section admittance value. The number of NonlinearShuntCompenstorPhasePoint instances associated with a NonlinearShuntCompensatorPhase shall be equal to ShuntCompensatorPhase.maximumSections. ShuntCompensator.sections shall only be set to one of the NonlinearShuntCompenstorPhasePoint.sectionNumber. There is no interpolation between NonlinearShuntCompenstorPhasePoints. NonlinearShuntCompensatorPhasePoint {44BDEBB6-4580-4df6-9245-179240EB5058} A non linear shunt compensator bank or section admittance value. The number of NonlinearShuntCompenstorPoint instances associated with a NonlinearShuntCompensator shall be equal to ShuntCompensator.maximumSections. ShuntCompensator.sections shall only be set to one of the NonlinearShuntCompenstorPoint.sectionNumber. There is no interpolation between NonlinearShuntCompenstorPoints. NonlinearShuntCompensatorPoint {96F8BB1B-2776-413c-A4AF-63924395C921} Notification time curve as a function of down time. Relationship between crew notification time Y1axis and unit startup time Y2axis vs. unit elapsed down time Xaxis. NotificationTimeCurve {985F418D-3104-422d-A6F4-39C1CBEEFF69} Kind of trigger to notify customer. NotificationTriggerKind {A52701A8-85CB-4fe2-9DC7-F5EDCF562D95} A nuclear generating unit. NuclearGeneratingUnit {76B2A63F-FF2A-44e9-8B22-4F676433E485} OASISBidReportType {F6B92D4C-F3CF-48d0-BD68-0898E6EAD432} OASISDataItems {0EF82D29-24C5-42ee-A931-8FD83DC2B4D5} OASISErrCode {4C17B308-BFDF-4c44-B1C9-E5EA5E73905D} OASISErrDescription {A72CFA46-17ED-4e68-B3E5-C932438487D5} OASISIntervalType {7AF449CC-A336-4e0c-B910-4B4736786526} OASISMarketType {0C172CD1-7F9C-4623-940D-A382E4A7ADAF} OASISMasterType {6FF8B250-E97A-4948-878F-9BAE9ADF2F0E} OASISMeasType {12DE137A-06F7-41af-8572-A2F8DFFA65B7} OASISReportType {4454664E-4E23-4773-B5CB-216BDB61BD47} OASISStatusType {3F8A7A13-1C10-4e7c-8363-4893A8779A7E} An object is to be created in the context. ObjectCreation {591F1533-DB67-457b-9DCE-AA6CB4C0C37C} An object is to be deleted in the context. ObjectDeletion {D10B2E11-D903-4381-AD98-89D7435CA678} The object already exists and is to be modified. ObjectModification {CBEFB19D-8A18-4e4e-8E97-E8A6669744B9} Used to specify precondition properties for a preconditioned update. ObjectReverseModification {1EB8623A-48DC-441d-A6CB-BFDEE6F305FA} Observed actual nonforecast values sets andor phenomena characteristics. Observation {78A1E5B0-C614-47f1-A3DD-DF1AFD5A39B3} Asset oil analysis fluid test type of analog. OilAnalysisFluidAnalog {54A4C289-DCC4-4b33-92D8-5D30BF2336D8} Analogs representing oil fluid test analysis result. OilAnalysisFluidAnalogKind {DD11BE9A-3F55-4866-A1B7-5C835F6B2DD9} Asset oil analysis fluid type of discrete. OilAnalysisFluidDiscrete {2B492897-7038-4a4f-85D2-9FA689A45A21} Discretes representing oil fluid test analysis result. OilAnalysisFluidDiscreteKind {696E81B8-3FE5-4b76-A9F4-4AECE5D7031D} Asset oil analysis gas type of analog. OilAnalysisGasAnalog {5C08DE43-EAD9-479f-A078-ED491F372F54} Analogs representing oil dissolved gas analysis result. OilAnalysisGasAnalogKind {FB38FFF8-8B26-4438-A8B9-DDB8EA475FEB} Asset oil analysis metals type of analog. OilAnalysisMetalsAnalog {8721552D-692E-43a1-A287-EDEE8383AED7} Analogs representing oil metals and elements analysis result. OilAnalysisMetalsAnalogKind {6A648944-7C96-4758-9F5F-8FB935CB2505} Asset oil analysis moisture type of analog. OilAnalysisMoistureAnalog {6B74F4C9-042F-4a13-9428-8AB9CEFAC414} Analogs representing oil moisture analysis result. OilAnalysisMoistureAnalogKind {FC1F4947-3F1A-49e4-8572-8FB4B7B1136C} Asset oil analysis PCB type of analog. OilAnalysisPCBAnalog {B4DC7BB6-D455-49e2-87AE-30375070DBDC} Analogs representing oil PCB analysis result. OilAnalysisPCBAnalogKind {241D48C5-4BAC-4fd9-85CC-EB7A3B227F36} Asset oil analysis PCB type of discrete. OilAnalysisPCBDiscrete {3F028E3C-2BD8-43ad-A73F-F26F4C1C30AF} Discretes representing oil PCB test analysis result. OilAnalysisPCBDiscreteKind {EA96531E-665F-4237-822A-1488CF0C1410} Asset oil inspection paper type of analog. OilAnalysisPaperAnalog {F1469DB0-F04E-4a16-B7A0-BC5659E2BFF0} Analogs representing oil paper degradation analysis result. OilAnalysisPaperAnalogKind {C1AB95B9-A09A-466c-BEE0-CDF175C30E70} Asset oil analysis particle type of analog. OilAnalysisParticleAnalog {D22A10AB-551E-47be-9E54-5F3D1857B7BB} Analogs representing oil particulate analysis result. OilAnalysisParticleAnalogKind {A13775D6-E276-411b-A46F-EDA3477B6EB6} Asset oil analysis particle type of discrete. OilAnalysisParticleDiscrete {8495F790-20B3-4a9a-8B8A-9C452C9B3EDA} Discretes representing oil particulate analysis result. OilAnalysisParticleDiscreteKind {4C443F53-AB38-4774-922D-140EFB8852F6} Kind of oil preservation. OilPreservationKind {DDAC92E2-14E4-4e0c-A384-BC5596BC9520} Price of oil in monetary units. OilPrice {5BA9F9A4-622A-41b1-8951-811C4BC9E8DC} Locations where oil can be sampled. OilSampleLocation {A0B10F74-025D-4966-8127-FA1FF8E5BD2C} OilSpecimen {53695A93-8369-4d59-9903-81B3867E7688} Sources for oil temperature. OilTemperatureSource {EBCB5BFC-C0B7-4c82-83BE-26B0AAD47DCF} A crew is a group of people with specific skills tools and vehicles. OldCrew {DDDFE85B-09C2-4ae1-85F8-E85572AB27F8} General purpose information for name and other information to contact people. OldPerson {C5A7D63A-BE27-4f6b-BC2F-A070401B38DA} Properties of switch assets. OldSwitchInfo {DFEA6966-9F30-4ec7-81DF-D0A1F33EC95A} OldTransformerEndInfo {81DF1954-79FE-4b6f-BFB6-E760D899C702} OldTransformerTankInfo {27D05BB6-D441-4925-8E5D-8BE2039DF3E5} A set of tasks is required to implement a design. OldWorkTask {1C3C4B03-3764-42d0-8B12-D4E3EA08748D} ONOFF OnOff {78428A4F-29E8-4d9c-BB8C-E92CB3114B93} A request for other utilities to mark their underground facilities prior to commencement of construction andor maintenance. OneCallRequest {8C193B90-CD98-4398-919A-155CDCEEC197} Contracts for services offered commercially. OpenAccessProduct {A1B2DFAA-6B83-4b0e-9B2E-42B95D63917F} Opencircuit test results verify winding turn ratios and phase shifts. They include induced voltage and phase shift measurements on opencircuit windings with voltage applied to the energised end. For threephase windings the excitation can be a positive sequence the default or a zero sequence. OpenCircuitTest {9D68E211-F604-4c71-BC1C-0F6D43E2F882} Result of bid validation against conditions that may exist on an interchange that becomes disconnected or is heavily discounted with respect the MW flow.This schedule is assocated with the hourly parameters in a resource bid. OpenTieSchedule {89F66067-6AA6-4ac5-9527-A02455F3698D} Breaker mechanism. OperatingMechanism {7467E313-35CE-4845-9B1E-F4D19D77CE46} Breaker operating mechanism datasheet information. OperatingMechanismInfo {2FC3E8DD-4A6F-4752-9081-0FAED4693C42} Kinds of operating mechanisms. OperatingMechanismKind {2D0C0B24-30F4-4484-8774-E91D00289E08} An operator of multiple power system resource objects. Note multple operating participants may operate the same power system resource object. This can be used for modeling jointly owned units where each owner operates as a contractual share. OperatingParticipant {04AAF1AE-4A67-4130-8259-DEA85BBCD65F} Specifies the operations contract relationship between a power system resource and a contract participant. OperatingShare {D615EDD6-6E2D-40b3-8190-3555A34BF9FF} Operation {CCD5ED72-C1C1-4cd3-86DD-3BE1FE65BC5F} Person role in the context of utility operations. OperationPersonRole {BB2C9585-FF19-4a70-A56F-45517ED541C3} A value and normal value associated with a specific kind of limit. The sub class value and normalValue attributes vary inversely to the associated OperationalLimitType.acceptableDuration acceptableDuration for short. If a particular piece of equipment has multiple operational limits of the same kind apparent power current etc. the limit with the greatest acceptableDuration shall have the smallest limit value and the limit with the smallest acceptableDuration shall have the largest limit value. Note A large current can only be allowed to flow through a piece of equipment for a short duration without causing damage but a lesser current can be allowed to flow for a longer duration. OperationalLimit {2E614D04-0107-4d78-B959-28ECD475219C} The direction attribute describes the side of a limit that is a violation. OperationalLimitDirectionKind {2C9E3AFE-268D-41c7-9BC9-29548EF57F5E} A set of limits associated with equipment. Sets of limits might apply to a specific temperature or season for example. A set of limits may contain different severities of limit levels that would apply to the same equipment. The set may contain limits of different types such as apparent power and current limits or high and low voltage limits that are logically applied together as a set. OperationalLimitSet {B0D1133E-CFA4-467d-81D1-75719BF02976} The operational meaning of a category of limits. OperationalLimitType {B5E14C75-6C8D-4e7e-9FAF-D49F3BE177B9} A document that can be associated with equipment to describe any sort of restrictions compared with the original manufacturers specification or with the usual operational practice e.g. temporary maximum loadings maximum switching current do not operate if bus couplers are open etc.In the UK for example if a breaker or switch ever maloperates this is reported centrally and utilities use their asset systems to identify all the installed devices of the same manufacturers type. They then apply operational restrictions in the operational systems to warn operators of potential problems. After appropriate inspection and maintenance the operational restrictions may be removed. OperationalRestriction {0093960F-86E8-4b3c-AD90-C7777658369A} Operational tag placed on a power system resource or asset in the context of switching plan execution or other work in the field. OperationalTag {2F8EE3CF-2319-4078-A5C2-CA89E6C8B884} Lowered capability because of deterioration or inadequacy sometimes referred to as derating or partial outage or other kind of operational rating change. OperationalUpdatedRating {5C9A09CF-769C-44fe-99C6-461466362FF0} Operator with responsibility that the work in high voltage installation is executed in a safe manner and according to safety regulation. OperationsSafetySupervisor {15BBC9FA-EEB7-4283-8B46-0438BEA468AC} One operational limit type scales values of another operational limit type when under the same operational limit set. This applies to any operational limit assigned to the target operational limit type and without other limit dependency models. OperatonalLimitTypeScaling {E75CE86C-80F7-43b3-A52B-45D4D28093FC} Control room operator. Operator {1D6E83CC-11B8-4c82-B832-D1B0BC8A2E04} Roles played between Organisations and other Organisations. This includes role ups for ogranisations cost centers profit centers regulatory reporting etc.Note that the parent and child relationship is indicated by the name on each end of the association. OrgOrgRole {BC155F06-3541-48cf-A84A-B1E6A3BFFF0A} This class models the allocation between asset owners and pricing nodes. OrgPnodeAllocation {AE1F59C4-5574-486b-A3B6-51C18D0FBDA1} This class model the ownership percent and type of ownership between resource and organisation. OrgResOwnership {146E3842-CF1A-43dd-A1CB-8512CB1101A5} Organisation that might have roles as utility contractor supplier manufacturer customer etc. Organisation {F8CDB36C-C67A-437e-B836-79674718904E} organization code OrganisationCode {56C04FBA-90C5-4e50-9897-DFB5473A7EFC} Identifies a way in which an organisation may participate in the utility enterprise e.g. customer manufacturer etc. OrganisationRole {01405DC2-1603-450e-BE69-A6C7E7629423} organization type OrganisationType {1CB85EEA-8552-4683-96A2-CE5D796C6ECE} The orientation of the coordinate system with respect to top left and the coordinate number system. OrientationKind {A91C1953-7D39-41d4-B0E8-C88B80E11D26} Document describing details of an active or planned outage in a part of the electrical network.A nonplanned outage may be created upon a breaker trip a fault indicator status change a meter event indicating customer outage a reception of one or more customer trouble calls or an operator command reflecting information obtained from the field crew.Outage restoration may be performed using a switching plan which complements the outage information with detailed switching activities including the relationship to the crew and work.A planned outage may be created upon a request for service maintenance or construction work in the field or an operatordefined outage for whatifcontingency network analysis. Outage {F40E2EAD-3BCA-4a17-A41E-A74212822DAA} This defines the area covered by the Outage. OutageArea {4CCB893D-9C2D-4985-AAA1-756A8708B31D} This enumeration describes the primary cause of the outage planned unplanned etc. OutageCauseKind {288135CD-0CCB-48d9-906B-2E3998575562} Transmits an outage plan to a crew in order for the planned outage to be executed. OutageOrder {E92F410F-17D3-497b-B612-3B1693031AA4} Document containing the definition of planned outages of equipment andor usage points. It will reference switching plans that are used to execute the planned outage. OutagePlan {ACA48F97-FA05-4c4d-94AA-226E14FA7E5C} This defines if the outage have been predicted or confirmed OutageStatusKind {EEA30D3B-F1FD-4289-BD60-81C91AEB7886} Different from LimIEEEOEL LimOEL2 has a fixed pickup threshold and reduces the excitation setpoint by means of a nonwindup integral regulator.iIratedi is the rated machine excitation current calculated from nameplate conditions iViisubnomsubi iPiisubnomsubi iCosPhiiisubnomsubi. OverexcLim2 {C6018567-991D-4489-8F77-66EB34417ABD} The over excitation limiter model is intended to represent the significant features of OELs necessary for some largescale system studies. It is the result of a pragmatic approach to obtain a model that can be widely applied with attainable data from generator owners. An attempt to include all variations in the functionality of OELs and duplicate how they interact with the rest of the excitation systems would likely result in a level of application insufficient for the studies for which they are intended.Reference IEEE OEL 421.52005 9. OverexcLimIEEE {123E0D03-692E-4567-A697-C64C50ABA7C7} Field voltage over excitation limiter. OverexcLimX1 {04722CC0-52FA-45c2-BA1A-A4AF3A44EB2B} Field voltage or current overexcitation limiter designed to protect the generator field of an AC machine with automatic excitation control from overheating due to prolonged overexcitation. OverexcLimX2 {50B12A55-58EB-4286-9D29-934B2E7E9539} Overexcitation limiter function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font OverexcitationLimiterDynamics {9ADB0414-A6FA-47ab-A3B2-EA95E9551500} Overexcitation limiter system function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font OverexcitationLimiterUserDefined {DDDC31A9-D00B-490c-9FE8-5F00AFF65085} Overhead cost applied to work order. OverheadCost {3A2959A1-9448-41e5-AAA9-E762F32458BA} Overhead wire data. OverheadWireInfo {4DD1FC69-2D71-4337-A697-B952F97733EC} Ownership of e.g. asset. Ownership {28F059EF-408D-4bde-93EE-0173ABC67D39} Power factor or VAr controller type 1 function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font PFVArControllerType1Dynamics {1880F77A-765D-4759-AE22-1E43ED912C81} Power factor or VAr controller type 1 function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font PFVArControllerType1UserDefined {D2E1BBFA-6A00-4cc2-8E2D-1295E13392AD} Power factor or VAr controller type 2 function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font PFVArControllerType2Dynamics {D476F3FB-EC19-45d0-99B2-3B218BC1481B} Power factor or VAr controller type 2 function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font PFVArControllerType2UserDefined {B6706B2D-7D88-4378-AA62-CB2E3A61F31F} IEEE PF controller type 1 which operates by moving the voltage reference directly.Reference IEEE 421.52005 11.2. PFVArType1IEEEPFController {536A2525-1C48-4d52-A97C-4234E27B5BD9} IEEE VAR controller type 1 which operates by moving the voltage reference directly.Reference IEEE 421.52005 11.3. PFVArType1IEEEVArController {052E3899-735D-414d-B54E-56CB584B0BEA} Power factor reactive power regulator. This model represents the power factor or reactive power controller such as the Basler SCP250. The controller measures power factor or reactive power PU on generator rated power and compares it with the operators set point.Footnote Basler SCP250 is an example of a suitable product available commercially. This information is given for the convenience of users of this document and does not constitute an endorsement by IEC of this product. PFVArType2Common1 {8914671E-3A96-45b6-8FA3-77317BAA7893} IEEE PF controller type 2 which is a summing point type controller making up the outside loop of a twoloop system. This controller is implemented as a slow PI type controller. The voltage regulator forms the inner loop and is implemented as a fast controller.Reference IEEE 421.52005 11.4. PFVArType2IEEEPFController {5211ED6D-3BA7-4b1f-8E0B-C32886FB1B11} IEEE VAR controller type 2 which is a summing point type controller. It makes up the outside loop of a twoloop system. This controller is implemented as a slow PI type controller and the voltage regulator forms the inner loop and is implemented as a fast controller.Reference IEEE 421.52005 11.5. PFVArType2IEEEVArController {CA6F2633-0D2C-4de9-80BF-83690546DFE1} PFmode {8EBE7C53-0C0F-48e0-B638-C4D33AA22148} Event recording the change in operational status of a power system resource may be for an event that has already occurred or for a planned activity. PSREvent {F9B560A6-357D-47b6-8F38-4BD42BE286C4} Kind of power system resource event. PSREventKind {ACC00459-6F3B-4c7a-8BCA-3A885E34C9AB} Classifying instances of the same class e.g. overhead and underground ACLineSegments. This classification mechanism is intended to provide flexibility outside the scope of this document i.e. provide customisation that is non standard. PSRType {CF59539F-A910-4af6-A84D-A52BBA7300CB} Per Unit a positive or negative value referred to a defined base. Values typically range from 10 to 10. PU {B47F1EC8-BE4F-47df-9ACA-3F12A128BF85} Pressurized water reactor used as a steam supply to a steam turbine. PWRSteamSupply {06990F92-71F6-4b0d-9CAA-2DE6B199C317} The version of dependencies description among top level subpackages of the combined CIM model. This is not the same as the combined packages version. PackageDependenciesCIMVersion {EEB4990E-A0CF-4f4b-981C-2A2C774153BC} PAN control used to issue actioncommand to PAN devices during a demand responseload control event. PanDemandResponse {6203B004-2A00-4ce1-A8ED-546B60C392C6} PAN actioncommand used to issue the displaying of text messages on PAN devices. PanDisplay {C12437E2-EA2C-4827-8251-42CF56B2C7A3} PAN actioncommand used to issue pricing information to a PAN device. PanPricing {2A41821C-8F9D-44f9-9FDF-AB4D0F06D327} Detail for a single price commandaction. PanPricingDetail {FF9F96DE-88E6-4ca2-AD7C-DFE7D8DA5681} ParentOrganization {F30F7262-89B5-4112-8867-770A060AAD09} Participation level of a given Pnode in a given AggregatePnode. Participation {029E0A30-B136-4cf2-91E5-8DE0DD57F07C} For exampleY Participates in both LMPM and SMPMN Not included in LMP price measuresS Participates in SMPM price measuresL Participates in LMPM price measures ParticipationCategoryMPM {6AC4A6FC-64C2-4776-AB71-537ADF0EF100} Particulate density as kgmsup3sup. ParticulateDensity {47AA7054-AC2F-4daf-B509-136A5802F368} Defines the individual passes that produce results per execution typemarket type. PassIndicatorType {48EA8E65-07ED-4bb2-BD0F-5A8B9AADD331} Pass Through Bill is used for1Two sided charge transactions with or without ISO involvement2 Specific direct charges or payments that are calculated outside or provided directly to settlements3 Specific charge bill determinants that are externally supplied and used in charge calculations PassThroughBill {06D05CC2-7BD1-4561-8C77-80ED631F22EC} Pcontrol {0525C521-5221-4bce-B41D-1DB2EFD896CA} When present a scalar conversion that needs to be applied to every IntervalReading.value contained in IntervalBlock. This conversion results in a new associated ReadingType reflecting the true dimensions of IntervalReading values after the conversion. PendingCalculation {AEB2AE35-E037-462d-ACFE-BDEBC3AD5285} Relationship between penstock head loss in meters and total discharge through the penstock in cubic meters per second. One or more turbines may be connected to the same penstock. PenstockLossCurve {1B61FB4A-C9C4-4bfb-9240-5D174664320A} Percentage on a defined base. For example specify as 100 to indicate at the defined base. PerCent {8345A4E0-E4BB-45d6-894B-983BB43C4B4F} Common type for perlength electrical catalogues describing DC line parameters. PerLengthDCLineParameter {5D15EC24-6829-4038-80A3-6C8F1C58EE75} Common type for perlength impedance electrical catalogues. PerLengthImpedance {C4C200C6-DFC4-4bec-AE5E-84B332E79E0C} Common type for perlength electrical catalogues describing line parameters. PerLengthLineParameter {5E96862B-1FFF-4fbf-B5D5-919E4DE8A1A9} Impedance and admittance parameters per unit length for nwire unbalanced lines in matrix form. PerLengthPhaseImpedance {048ADD31-9C78-4fb8-93AD-0F89496AC846} Sequence impedance and admittance parameters per unit length for transposed lines of 1 2 or 3 phases. For 1phase lines define xx0xself. For 2phase lines define xxsxm and x0xsxm. PerLengthSequenceImpedance {03E92000-9F13-4deb-B5E1-B3262BEBDE92} An identification of a time interval that may have a given resolution. Period {CF8ACB5F-11D6-4e05-9699-7D122B1DA29C} Description of period for which calculation is performed.ConditionsFNot sure where these came from delete from UML? PeriodicStatisticalCalculation {9265203F-579B-440d-B1AA-75F8EB309D82} General purpose information for name and other information to contact people. Person {29202C3E-E050-443e-A5FA-F139D34A26F6} Role an organisation plays with respect to persons. PersonOrganisationRole {0E229F32-EC45-4bf8-BEAA-344389063127} The role of a person relative to a given piece of property. Examples of roles include owner renter contractor etc. PersonPropertyRole {0D27C992-8058-48c7-BFD1-494CC3F24130} PersonRole {E24A8569-EF9C-450b-8B2D-2AB8A6CFAD85} A variable impedance device normally used to offset line charging during single line faults in an ungrounded section of network. PetersenCoil {5538A367-14D4-4160-836F-2D049DB218B6} The mode of operation for a Petersen coil. PetersenCoilModeKind {D7A85068-34C3-4fcd-ABCF-8D0867FEC0FF} An unordered enumeration of phase identifiers. Allows designation of phases for both transmission and distribution equipment circuits and loads. The enumeration by itself does not describe how the phases are connected together or connected to ground. Ground is not explicitly denoted as a phase.Residential and small commercial loads are often served from singlephase or splitphase secondary circuits. For the example of s12N phases 1 and 2 refer to hot wires that are 180 degrees out of phase while N refers to the neutral wire. Through singlephase transformer connections these secondary circuits may be served from one or two of the primary phases A B and C. For threephase loads use the A B C phase codes instead of s12N.The integer values are from IEC 619689 to support revenue metering applications. PhaseCode {3687AEED-A1B1-4557-899E-5985D184FCE9} The type of fault connection among phases. PhaseConnectedFaultKind {B8167562-D487-4e40-82F9-26C9E487E1F1} Impedance and conductance matrix element values. The diagonal elements are described by the elements having the same toPhase and fromPhase value and the off diagonal elements have different toPhase and fromPhase values. The matrix can also be stored in symmetric lower triangular format using the row and column attributes which map to ACLineSegmentPhase.sequenceNumber. PhaseImpedanceData {8D8D03C8-6278-4397-9EFA-EDC98D359BBC} The configuration of phase connections for a single terminal device such as a load or capacitor. PhaseShuntConnectionKind {5DE5A24B-B6E5-4f26-890B-6906EB2213C8} A transformer phase shifting tap model that controls the phase angle difference across the power transformer and potentially the active power flow through the power transformer. This phase tap model may also impact the voltage magnitude. PhaseTapChanger {7CEA69EF-C8A8-4f3d-99B2-9F934CC95BF4} Describes the tap model for an asymmetrical phase shifting transformer in which the difference voltage vector adds to the inphase winding. The outofphase winding is the transformer end where the tap changer is located. The angle between the inphase and outofphase windings is named the winding connection angle. The phase shift depends on both the difference voltage magnitude and the winding connection angle. PhaseTapChangerAsymmetrical {4161A809-7542-4c92-A7D0-99AE5682E89C} Describes a tap changer with a linear relation between the tap step and the phase angle difference across the transformer. This is a mathematical model that is an approximation of a real phase tap changer.The phase angle is computed as stepPhaseShiftIncrement times the tap position.The voltage magnitude of both sides is the same. PhaseTapChangerLinear {BFC68185-DEEC-4665-B2E9-64EC73F18241} The nonlinear phase tap changer describes the nonlinear behaviour of a phase tap changer. This is a base class for the symmetrical and asymmetrical phase tap changer models. The details of these models can be found in IEC 61970301. PhaseTapChangerNonLinear {5B26C38F-A09B-439c-B5E2-A9F4ED801883} Describes a symmetrical phase shifting transformer tap model in which the voltage magnitude of both sides is the same. The difference voltage magnitude is the base in an equalsided triangle where the sides corresponds to the primary and secondary voltages. The phase angle difference corresponds to the top angle and can be expressed as twice the arctangent of half the total difference voltage. PhaseTapChangerSymmetrical {4841E53F-1B5B-487b-8F43-2ABA7B1FC93D} Describes a tabular curve for how the phase angle difference and impedance varies with the tap step. PhaseTapChangerTable {350A69CE-A6C9-4967-9BB9-7BF7A361B5C8} Describes each tap step in the phase tap changer tabular curve. PhaseTapChangerTablePoint {D2A2282D-3EBD-47ea-8339-B78FEC97977F} Describes a tap changer with a table defining the relation between the tap step and the phase angle difference across the transformer. PhaseTapChangerTabular {27778291-3EC1-429b-AD1C-2E9841406540} A predefined phenomenon classification as defined by a particular authority. PhenomenonClassification {02B4C2EF-115A-4282-9AEE-51545B483B7A} A photovoltaic device or an aggregation of such devices. PhotoVoltaicUnit {4C57184E-FF79-4e7b-97FC-E2252FCA82A7} Value associated with branch group is used as compare. PinBranchGroup {8070DE9F-BCD5-4e30-AFEF-091F13415996} Categorisation of type of compare done on a branch group. PinBranchGroupKind {EB08D837-948F-439c-A26F-97F411BB2EE4} Value associated with Equipment is used as compare. PinEquipment {0F70682A-0B2E-4542-ACC3-46F2CEBCDE73} Categorisation of type of compare done on Equipment. PinEquipmentKind {3AA04BCC-27D2-4ff4-BFF6-1A811B466A22} An output from one gate represent an input to another gate. PinGate {DB3E650E-6D8F-45ac-96E2-DD5F199DB803} Gate input pin that is associated with a Measurement or a calculation of Measurement. PinMeasurement {8E12F655-DF68-4199-9B4F-59E5BF7467FF} Value associated with Terminal is used as compare. PinTerminal {66F63EBF-9677-468b-B919-D7477FE9FBE3} Categorisation of type of compare done on Terminal. PinTerminalKind {2BB5947C-26F1-4258-9FEA-805D176CA90E} Represent a planned market. For example a planned DAHART market. PlannedMarket {A865CCF4-5C55-4f2a-8404-AE694B815016} This class represents planned events. Used to model the various planned events in a market closing time clearing time etc. PlannedMarketEvent {F5455A24-65BB-48af-ADBB-F31BB885FD75} PlannedOutage {0BCDD7D7-E6DF-41ea-BE54-19C927ADCFF9} This class will be used to generate call ahead lists for customers who will be affected by a planned outage. PlannedOutageNotification {0F285974-FB1F-4b4b-A71D-C8DB1B4F9389} A Plant is a collection of equipment for purposes of generation. Plant {D10F6D5A-6E2C-4d81-BFE5-9DF925119193} A pricing node is directly associated with a connectivity node. It is a pricing location for which market participants submit their bids offers buysell CRRs and settle. Pnode {C8A89D1C-E63F-429c-B543-92BEB004BADD} Pricing node clearing results posted for a given settlement period. PnodeClearing {7D3FCF72-E47C-4d53-A9D9-AB7E6204C810} This class allows SC to input different distribution factors for pricing node. PnodeDistributionFactor {116353F7-F4CD-4f9d-8B45-BEE771C51F06} Provides the total price the cost component the loss component and the congestion component for Pnodes for the forward and real time markets. There are several prices produced based on the run type MPM RUC Pricing or SchedulingDispatch. PnodeResults {73FB5C97-DB9B-4153-89F4-4C602A079906} An identification of a set of values beeing adressed within a specific interval of time. Point {82841BAA-3085-432f-AD5E-3F87056F550F} Logical point where transactions take place with operational interaction between cashier and the payment system in certain cases the point of sale interacts directly with the end customer in which case the cashier might not be a real person for example a selfservice kiosk or over the internet. PointOfSale {5F4F45D1-B356-4efb-8D4C-C2C2F635D65A} Pole asset. Pole {6005F1EA-E3BB-4318-A931-D7584D2B4EFC} Kind of base for poles. PoleBaseKind {34B79F57-EA29-4a4e-A3E4-A13C1383B3E7} Preservative kind for poles. PolePreservativeKind {AB3FD322-F29E-4933-827B-EEE6C6AD3BF7} Kind of treatment for poles. PoleTreatmentKind {FE3FF735-23CD-42ac-888E-B379DC6C585D} Set of spatial coordinates that determine a point defined in the coordinate system specified in Location.CoordinateSystem. Use a single position point instance to describe a pointoriented location. Use a sequence of position points to describe a lineoriented object physical location of nonpoint oriented objects like cables or lines or area of an object like a substation or a geographical zone in this case have first and last position point with the same values. PositionPoint {17847D7C-A86C-43c9-B8AA-522B70002D29} A sensor used mainly in overhead distribution networks as the source of both current and voltage measurements. PostLineSensor {7B763652-C385-4903-9FB1-E780E0C52E57} Instrument transformer also known as Voltage Transformer used to measure electrical qualities of the circuit that is being protected andor monitored. Typically used as voltage transducer for the purpose of metering protection or sometimes auxiliary substation supply. A typical secondary voltage rating would be 120V. PotentialTransformer {C23E2611-BCD6-4bba-8700-0FE573038340} Properties of potential transformer asset. PotentialTransformerInfo {3C463B88-5774-44cb-8C78-4EBD99CD3691} The construction kind of the potential transformer. PotentialTransformerKind {0EC6DEF8-4139-47b7-82C7-7E8E18A3D4A1} An area or zone of the power system which is used for load shedding purposes. PowerCutZone {8B5E449E-F8E0-4b7a-93B4-2A0D37E5677C} A connection to the AC network for energy production or consumption that uses power electronics rather than rotating machines. PowerElectronicsConnection {AEF4A2AB-D126-4311-B299-CAB7D826A16E} A single phase of a power electronics connection. PowerElectronicsConnectionPhase {E1CB8A17-1A54-4eff-B918-817872DEA162} A generating unit or battery or aggregation that connects to the AC network using power electronics rather than rotating machines. PowerElectronicsUnit {EC401F21-E818-46dc-88CE-2CFD1E60B76C} A wind generating unit that connects to the AC network with power electronics rather than rotating machines or an aggregation of such units. PowerElectronicsWindUnit {9052BC05-5069-456d-9608-332CB9272664} Pricing can be based on power quality. PowerQualityPricing {90C89F99-E6E7-4b81-8D3C-3070C9E7853D} Represent the base lifecycle of a functional model change that could be a construction of new elements. PowerSystemProjectLifecycleToBeDeleted {AB23472D-DDD3-443d-9A82-4256A71DA7A5} A power system resource PSR can be an item of equipment such as a switch an equipment container containing many individual items of equipment such as a substation or an organisational entity such as subcontrol area. Power system resources can have measurements associated. PowerSystemResource {0340C084-3759-40cc-AAF2-386101DE842F} Power system stabilizer function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font PowerSystemStabilizerDynamics {3F0A3D95-88A1-428a-8F47-7B6F73E52AB6} font color0f0f0fPower system stabilizerfont function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font PowerSystemStabilizerUserDefined {65A4611C-F5C6-4f93-80E8-5FC8D45C5BCC} An electrical device consisting of two or more coupled windings with or without a magnetic core for introducing mutual coupling between electric circuits. Transformers can be used to control voltage and phase shift active power flow.A power transformer may be composed of separate transformer tanks that need not be identical.A power transformer can be modelled with or without tanks and is intended for use in both balanced and unbalanced representations. A power transformer typically has two terminals but may have one grounding three or more terminals.The inherited association ConductingEquipment.BaseVoltage should not be used. The association from TransformerEnd to BaseVoltage should be used instead. PowerTransformer {3D50627C-324C-4e9d-AB5C-592E0A1E0AFE} A PowerTransformerEnd is associated with each Terminal of a PowerTransformer.The impedance values r r0 x and x0 of a PowerTransformerEnd represents a star equivalent as follows.1 for a two Terminal PowerTransformer the high voltage TransformerEnd.endNumber1 PowerTransformerEnd has non zero values on r r0 x and x0 while the low voltage TransformerEnd.endNumber2 PowerTransformerEnd has zero values for r r0 x and x0. Parameters are always provided even if the PowerTransformerEnds have the same rated voltage. In this case the parameters are provided at the PowerTransformerEnd which has TransformerEnd.endNumber equal to 1.2 for a three Terminal PowerTransformer the three PowerTransformerEnds represent a star equivalent with each leg in the star represented by r r0 x and x0 values.3 For a three Terminal transformer each PowerTransformerEnd shall have g g0 b and b0 values corresponding to the no load losses distributed on the three PowerTransformerEnds. The total no load loss shunt impedances may also be placed at one of the PowerTransformerEnds preferably the end numbered 1 having the shunt values on end 1. This is the preferred way.4 for a PowerTransformer with more than three Terminals the PowerTransformerEnd impedance values cannot be used. Instead use the TransformerMeshImpedance or split the transformer into multiple PowerTransformers.Each PowerTransformerEnd must be contained by a PowerTransformer. Because a PowerTransformerEnd or any other object can not be contained by more than one parent a PowerTransformerEnd can not have an association to an EquipmentContainer Substation VoltageLevel etc. PowerTransformerEnd {51A671B1-C546-4106-92F9-ED7C0305A2DB} Set of power transformer data from an equipment library. PowerTransformerInfo {46FF16E8-5771-4f84-BFAF-AE487FF9ED06} Pressure in pascals. Pressure {BBEF7CB4-FBE0-4bc5-9EB4-A3E586C7F34C} The cost corresponding to a specific measure and expressed in a currency. Price {BA13415E-3C31-4522-8171-7B6F728A03D8} The price of a Commodity during a given time interval may change over time. For example a price may be forecasted a year ahead a month ahead a day ahead an hour ahead and in real time this is defined using the MarketType. Additionally a price may have one or more components. For example a locational marginal energy price may be the arithmetic sum of the system price the congestion price and the loss price. The priceType enumeration is used determine if the price is the complete price priceTypetotal or one of potentially many constituent components. PriceDescriptor {2C266D06-8B90-4844-96BD-02735ACDC715} Y indicates a resource is capable of setting the Markte Clearing Price S indicates the resource must submit bids for energy at 0N indicates the resource does not have to submit bids for energy at 0 PriceSetFlag {526D0731-D2A7-4851-AA3D-9665E1987A8F} Value of this enumeration for different prices include total for the completefullallin price congestion for the congestion cost associated with the total price the loss for the loss price associated with the total price capacity for prices related to installed or reserved capacity mileage for usebased accounting system for systemwidecopperplate prices and delivery for distributionbased prices. PriceTypeKind {013C960C-3541-445f-A0D0-3081FA4BBE6D} Grouping of pricing components and prices used in the creation of customer charges and the eligibility criteria under which these terms may be offered to a customer. The reasons for grouping include state customer classification site characteristics classification i.e. fee price structure deposit price structure electric service price structure etc. and accounting requirements. PricingStructure {696BAC8C-6DA3-4fe3-BB2F-4D4572463FC2} The machine used to develop mechanical energy used to drive a generator. PrimeMover {D20ACBF5-8A0B-472e-8155-B4B70315ADA3} Priority definition. Priority {3E61C9C1-97C4-413e-B585-28CF83B90EC7} Documented procedure for various types of work or work tasks on assets. Procedure {AFA1E7DF-53AE-4831-A007-89E83E579270} A data set recorded each time a procedure is executed. Observed results are captured in associated measurement values andor values for properties relevant to the type of procedure performed. ProcedureDataSet {2B18C173-DC33-4a5b-9808-CB6A18321039} Kind of procedure. ProcedureKind {1516C9A8-910D-4b98-AAED-035828BF3B59} The formal specification of a set of business transactions having the same business goal. Process {2324D336-1F92-46ac-9F20-F4F58E8FFDF1} Asset model by a specific manufacturer. ProductAssetModel {3355C111-67F6-40b0-97D2-660FF76A1F1E} Component of a bid that pertains to one market product. ProductBid {417C5B05-3165-4405-8422-9275E3C59AC4} A profile is a simpler curve type. Describes the existence of a profile. The MRID is usually defined as a static value by the document or artifact that defines the contents of the profile and the rules for using the profile. Profile {BC499E60-2398-46aa-A340-8421A864B0C1} {DA460209-200E-46b5-A5FB-3C600B650ED2} Data for profile. ProfileData {75BA1129-9F82-4511-B04F-E21D80832053} A collection of related work. For construction projects and maintenance projects multiple phases may be performed. Project {A2FA7B7B-8141-4486-AE1E-5CDE98AFCB36} Project B is an alternative to project A. Project A is the primary alternative.Multiple project alternatives should not be selected into a single network study case. ProjectAlternative {CAC3DF1E-520C-4d51-AFBC-7B5D3751B91D} Project A change sets should be applied before Project B during case creation. ProjectDependency {6233873A-EEF6-4d78-8033-AFD194028490} ProjectStatusKind {1EAAE124-6945-4d0e-977D-1D4C5A1A3E6B} Role an organisation plays with respect to property for example the organisation may be the owner renter occupier taxiing authority etc.. PropertyOrganisationRole {932B12D0-870B-4599-A9F1-735101651947} Unit of property for reporting purposes. PropertyUnit {4364909D-8DDE-40db-B0C8-E3CF7EC2EABC} ProportionalDistributionComponent {29EE59D5-E1CE-4420-9A89-7C93996DBBA2} Supports definition of one or more parameters of several different datatypes for use by proprietary userdefined models. This class does not inherit from IdentifiedObject since it is not intended that a single instance of it be referenced by more than one proprietary userdefined model instance. ProprietaryParameterDynamics {511A476A-15FF-4c1e-A02D-348B2843D4D5} A ProtectedSwitch is a switching device that can be operated by ProtectionEquipment. ProtectedSwitch {BADE2A18-37F4-49bf-87BC-A087E4D2E4F7} An electrical device designed to respond to input conditions in a prescribed manner and after specified conditions are met to cause contact operation or similar abrupt change in associated electric control circuits or simply to display the detected condition. Protection equipment is associated with conducting equipment and usually operate circuit breakers. ProtectionEquipment {9EAE8A03-D411-432a-AC39-38ACEC6B1FAD} Properties of protection equipment asset. ProtectionEquipmentInfo {8996F48A-CD6B-4c7a-A7B4-AA9C5F8E51BA} A protective action for supporting the integrity of the power system. ProtectiveAction {2786E00A-6880-4d25-8D67-475403893A82} Protective actions on nonswitching equipment. The operating condition is adjusted. ProtectiveActionAdjustment {8C1CFD32-6C07-45fa-A0CF-E91B76443855} Categorisation of different protective action adjustments that can be performed on equipment. ProtectiveActionAdjustmentKind {D8125BC3-EC60-4d67-B5C3-5A579997BDC4} A collection of protective actions to protect the integrity of the power system. ProtectiveActionCollection {122E89AF-E8F4-4003-8375-EC133E9069AA} Protective action to put an Equipment inserviceoutofservice. ProtectiveActionEquipment {FC41A9D7-3388-4465-847F-47FA8090CE1F} Protective action to change regulation to Equipment. ProtectiveActionRegulation {B30177E0-4A8A-4ab2-AA46-7101297B969D} Allows declaration of ICCP points to be provided through a Bilateral Table agreement. ProvidedBilateralPoint {1D2F8BB4-43BC-4f56-A274-90C964668491} Italian PSS with three inputs speed frequency power. Pss1 {61359006-B6EA-4d44-88D5-037172A02902} Single input power system stabilizer. It is a modified version in order to allow representation of various vendors implementations on PSS type 1A. Pss1A {90B120AE-6659-477b-821A-516EE39E9EDD} Modified IEEE PSS2B. Extra leadlag or rate block added at end up to 4 leadlags total. Pss2B {A95B2DA4-2E19-4831-82FF-AB7074ACAEC4} PTI microprocessorbased stabilizer type 1. Pss2ST {499441DD-F189-4833-9878-B0179B101011} Detailed Italian PSS. Pss5 {63072F6E-933B-4719-923E-7FADA9019D79} Power system stabilizer typically associated with ExcELIN2 though PssIEEE2B or Pss2B can also be used. PssELIN2 {00471B64-A672-4065-A78A-36E806FFC2FB} IEEE 421.52005 type PSS1A power system stabilizer model. PSS1A is the generalized form of a PSS with a single input signal. Reference IEEE 1A 421.52005 8.1. PssIEEE1A {E62CBD96-8B26-4707-8646-1587F7C2476E} IEEE 421.52005 type PSS2B power system stabilizer model. This stabilizer model is designed to represent a variety of dualinput stabilizers which normally use combinations of power and speed or frequency to derive the stabilizing signal.Reference IEEE 2B 421.52005 8.2. PssIEEE2B {30BA081A-9688-4734-AC81-859B3851B720} IEEE 421.52005 type PSS3B power system stabilizer model. The PSS model PSS3B has dual inputs of electrical power and rotor angular frequency deviation. The signals are used to derive an equivalent mechanical power signal.This model has 2 input signals. They have the following fixed types expressed in terms of InputSignalKind values the first one is of rotorAngleFrequencyDeviation type and the second one is of generatorElectricalPower type.Reference IEEE 3B 421.52005 8.3. PssIEEE3B {F7C38135-ADBE-4f67-A7B3-2A7BF378835A} IEEE 421.52005 type PSS4B power system stabilizer. The PSS4B model represents a structure based on multiple working frequency bands. Three separate bands respectively dedicated to the low intermediate and highfrequency modes of oscillations are used in this delta omega speed input PSS.There is an error in the in IEEE 421.52005 PSS4B model the iPei input should read iPei. This implies that the input iPei needs to be multiplied by 1.Reference IEEE 4B 421.52005 8.4. Parameter detailsThis model has 2 input signals. They have the following fixed types expressed in terms of InputSignalKind values the first one is of rotorAngleFrequencyDeviation type and the second one is of generatorElectricalPower type. PssIEEE4B {C6556415-B3C7-4b4c-B73C-A37F295680DA} PTI microprocessorbased stabilizer type 1. PssPTIST1 {229FA810-11BB-4ba2-A87E-BF24CB715940} PTI microprocessorbased stabilizer type 3. PssPTIST3 {D0383527-C7C2-43b3-BDA2-2185C523E0C2} Power system stabilizer type RQB. This power system stabilizer is intended to be used together with excitation system type ExcRQB which is primarily used in nuclear or thermal generating units. PssRQB {4B9A2B52-0378-49b2-AB8D-8979ECA37D09} Power sensitive stabilizer model. PssSB4 {3E2172A5-0DE1-40e7-9ACC-314FCF16B78E} SiemenssupTMsup H infinity power system stabilizer with generator electrical power input.Footnote Siemens H infinity power system stabilizers are an example of suitable products available commercially. This information is given for the convenience of users of this document and does not constitute an endorsement by IEC of these products. PssSH {462F11AB-EED2-487a-9FB4-9224CB7FCC4A} Slovakian PSS with three inputs. PssSK {93E7D9BA-C95F-4303-8490-5F00FA1C4983} Power system stabilizer part of an ABB excitation system.Footnote ABB excitation systems are an example of suitable products available commercially. This information is given for the convenience of users of this document and does not constitute an endorsement by IEC of these products. PssSTAB2A {8BDE4EF4-4308-4c14-AB44-89290DDC8FE0} Dual input power system stabilizer based on IEEE type 2 with modified output limiter defined by WECC Western Electricity Coordinating Council USA. PssWECC {C5F30981-FF77-471c-83F4-F3D2BF2D29DB} Used to convey information that will allow matching in order to determine which certificate to use. Actual certificates are exchanged externally to the CIM exchange. PublicX509Certificate {277F7762-AB0C-4ed7-B2FB-E3B9917CD28B} The operating cost of a Pump Storage Hydro Unit operating as a hydro pump.This schedule is assocated with the hourly parameters in a resource bid associated with a specific product within the bid. PumpingCostSchedule {744A31CD-0CC4-4a29-807F-629CEA19B426} The fixed operating level of a Pump Storage Hydro Unit operating as a hydro pump. Associated with the energy market product type.This schedule is assocated with the hourly parameters in a resource bid associated with a specific product within the bid. PumpingLevelSchedule {29E98791-D733-4f25-8000-8F388D1AD00B} The cost to shutdown a Pump Storage Hydro Unit in pump mode or a pump.This schedule is assocated with the hourly parameters in a resource bid associated with a specific product within the bid. PumpingShutDownCostSchedule {00872D59-BC24-49e8-B3B9-3C56933137A7} MPM Purpose Flag for exampleNature of threshold dataM Mitigation thresholdR Reporting threshold PurposeFlagType {46820D5A-7D62-4874-9C53-818A6A3AC0D0} Qlimiter {94F16A89-EA3F-454b-9361-D4F78908B8AF} Qmode {CB7EDD05-5E7E-4eff-BB9B-A4F71412B6B4} Qregulator {3D1F7383-2254-4da0-BB6E-38FFA6A5ABCF} Certain skills are required and must be certified in order for a person typically a member of a crew to be qualified to work on types of equipment. QualificationRequirement {540D4F43-4F53-4ea4-8DEB-07918430C8AE} Quality flags in this class are as defined in IEC 61850 except for estimatorReplaced which has been included in this class for convenience. Quality61850 {3561961B-F3BD-41f7-B693-9D9F77C613A0} Description of quantities needed in the data exchange. The type of the quantity is described either by the role of the association or the type attribute.The quality attribute provides the information about the quality of the quantity measured estimated etc.. Quantity {2FE8FA95-2C67-4b07-B3F9-86385F4D6CB3} Indicates whether unit is a reliablity must run unit required to be on to satisfy Grid Code Reliablitiy criteria load demand or voltage support. RMRDetermination {D0252DAE-607C-4ebe-85A7-D3D4D37C65A0} Model to support processing of reliability must run units. RMRHeatRateCurve {C95EDDA2-4B22-4442-80F7-31668981CA43} RMR Operators entry of the RMR requirement per market interval. RMROperatorInput {FB23ACBA-4D15-4196-9926-30AFFE7D6701} Model to support processing of reliability must run units. RMRStartUpCostCurve {B0C00BC7-E976-48c1-9C53-934002E8183D} Model to support processing of reliability must run units. RMRStartUpEnergyCurve {8B6D418C-1030-45e5-97B7-804358642B52} Model to support processing of reliability must run units. RMRStartUpFuelCurve {BBF0FCA0-4E32-4456-906A-AADBB77DD257} Model to support processing of reliability must run units. RMRStartUpTimeCurve {54677F28-5BBD-4329-9240-5A3DEFD9BA74} Regional transmission operator. RTO {1E0CABAF-4ABF-4934-9F92-F65A765A8A0A} This class models the information about the RUC awards. RUCAwardInstruction {FF4C9484-9951-43e7-9216-7585CD85AFFC} A specialized class of type AggregatedNode type. Defines RUC Zones. A forecast region represents a collection of Nodes for which the Market operator has developed sufficient historical demand and relevant weather data to perform a demand forecast for such area. The Market Operator may further adjust this forecast to ensure that the Reliability Unit Commitment produces adequate local capacity procurement. RUCZone {CEF61B01-E182-415c-836A-9423A9A98BAD} An analog control that increases or decreases a set point value with pulses. Unless otherwise specified one pulse moves the set point by one. RaiseLowerCommand {E19BB2D1-4556-4afd-994D-3244337C8F3E} For example0 Fixed ramp rate independent of rate function unit MW output1 Static ramp rates as a function of unit MW output only 2 Dynamic ramp rates as a function of unit MW output and ramping time RampCurveType {53370A5E-4445-4ab9-BB26-5FAF551BA6E6} Ramp rate condition. RampRateCondition {FF13A48D-7F4C-4c39-BE56-FAB8AFE530A3} Ramp rate as a function of resource MW output. RampRateCurve {24CCE498-D38B-4e4b-94FF-E84EFBA6E05D} Ramp rate curve type. RampRateType {45A50DBB-81E1-4287-B563-BD58851D11BB} Kind of randomisation to be applied to control the timing of end device control commands andor the definition of demand response and load control events. Value other than none is typically used to mitigate potential deleterious effects of simultaneous operation of multiple devices. RandomisationKind {3A872CA2-ED74-4716-B472-08117E428527} Fraction specified explicitly with a numerator and denominator which can be used to calculate the quotient. Ratio {F5D18BFC-D800-46b9-9A8B-CFCA6387C4C8} A tap changer that changes the voltage ratio impacting the voltage magnitude but not the phase angle across the transformer.Angle sign convention general Positive value indicates a positive phase shift from the winding where the tap is located to the other winding for a twowinding transformer. RatioTapChanger {09909286-00A6-451c-B420-2E52ABEB2667} Describes a curve for how the voltage magnitude and impedance varies with the tap step. RatioTapChangerTable {8A7FA923-A193-4c6f-B315-1DF1A13C9AA1} Describes each tap step in the ratio tap changer tabular curve. RatioTapChangerTablePoint {607E97C8-E4A3-4721-8592-1AE1B256EB77} Rational number numerator denominator. RationalNumber {55480F31-7DA3-4c2d-A240-0A31C3271DE6} Reactance imaginary part of impedance at rated frequency. Reactance {F1C90FB4-B7BE-4528-A974-E36BBEAB8616} Reactance imaginary part of impedance per unit of length at rated frequency. ReactancePerLength {ECCBABE8-F29C-4878-9504-35D08A1E9CA1} Reactive power rating envelope versus the synchronous machines active power in both the generating and motoring modes. For each active power value there is a corresponding high and low reactive power limit value. Typically there will be a separate curve for each coolant condition such as hydrogen pressure. The Y1 axis values represent reactive minimum and the Y2 axis values represent reactive maximum. ReactiveCapabilityCurve {AB5F986C-93A1-4f1f-A62B-CFB733BEF874} Product of RMS value of the voltage and the RMS value of the quadrature component of the current. ReactivePower {C15CB4E4-4430-43ea-AF69-BC3250B1F4A3} Specific value measured by a meter or other asset or calculated by a system. Each Reading is associated with a specific ReadingType. Reading {7E8C3166-9471-4e2c-8BC5-082F9D4B2F53} Interharmonics are represented as a rational number numerator denominator and harmonics are represented using the same mechanism and identified by denominator1. ReadingInterharmonic {80DBF0DD-0EBD-4e62-89E1-BF2CEF3B59BA} Quality of a specific reading value or interval reading value. Note that more than one quality may be applicable to a given reading. Typically not used unless problems or unusual conditions occur i.e. quality for each reading is assumed to be good unless stated otherwise in associated reading quality type. It can also be used with the corresponding reading quality type to indicate that the validation has been performed and succeeded. ReadingQuality {4AB2B23E-75A5-41d5-A46F-B9D414AFBD38} Detailed description for a quality of a reading value produced by an end device or a system. Values in attributes allow for creation of the recommended codes to be used for identifying reading value quality codes as follows systemId.category.subCategory. ReadingQualityType {20EE2D53-52C6-4a74-8009-F135C62FE4F8} Reason for the reading being taken. ReadingReasonKind {7EE63604-51AF-4e8b-AFD4-6117CB2C7D8A} Detailed description for a type of a reading value. Values in attributes allow for the creation of recommended codes to be used for identifying reading value types as follows macroPeriod.aggregate.measuringPeriod.accumulation.flowDirection.commodity.measurementKind.interharmonic.numerator.interharmonic.denominator.argument.numerator.argument.denominator.tou.cpp.consumptionTier.phases.multiplier.unit.currency. ReadingType {256DE8A2-72B1-4be6-A8D1-1C3D16886B83} Real electrical energy. RealEnergy {FD0D7251-962F-4c57-ACFB-C1F578AB6361} The motivation of an act. Reason {D85ACC55-1B5A-4f2a-8083-9F533EC1B60A} Record of total receipted payment from customer. Receipt {8C5F5500-4850-4997-A7C7-5C3B363E7049} A reclose sequence open and close is defined for each possible reclosure of a breaker. RecloseSequence {2BB9ABD3-5CB7-43ba-88A8-04D971642DA2} Polemounted fault interrupter with builtin phase and ground relays current transformer CT and supplemental controls. Recloser {6408BE78-ED1B-4fcc-9463-EBC827CDFEBB} Properties of recloser assets. RecloserInfo {DC3A327E-9773-42d8-B464-66CCD91FFBFF} Reconditioning information for an asset. Reconditioning {23446D7A-AE7B-42a2-A40F-37999AF3A101} This class is used for handling the accompanying annotations time stamp author etc. of designs drawings and maps. A red line can be associated with any Location object. RedLine {504F964D-F017-4062-B152-1B845265C22D} A device that indicates or records units of the commodity or other quantity measured. Register {66D18B62-79CA-4cdd-A36D-CE77E47EE545} Temporary holding for load reduction attributes removed from RegisteredLoad. Use for future use case when developing the RegisteredDistributedResource specialized classes. RegisteredControllableLoad {7455916E-A376-4f1e-B9CC-E5FD90AB37CB} A registered resource that represents a distributed energy resource such as a microgenerator fuel cell photovoltaic energy source etc. RegisteredDistributedResource {797D2ABC-99D4-4f9a-92A7-E3816F614B08} Model of a generator that is registered to participate in the market. RegisteredGenerator {BB898438-F72C-40a5-9D06-3E70DAE96144} This class represents the inter tie resource. RegisteredInterTie {3A575D6B-3C0D-46ab-92F5-A7FEB25D9633} Model of a load that is registered to participate in the market.RegisteredLoad is used to model any load that is served by the wholesale market directly. RegisteredLoads may be dispatchable or nondispatchable and may or may not have bid curves. Examples of RegisteredLoads would include distribution company load energy retailer load large bulk power system connected facility load.Loads that are served indirectly for example through an energy retailer or a vertical utility should be modeled as RegisteredDistributedResources. Examples of RegisteredDistributedResources would include distribution level storage distribution level generation and distribution level demand response. RegisteredLoad {02F67FF4-9BCC-401f-ADDC-C56F8D9A19B6} A resource that is registered through the market participant registration system. Examples include generating unit load and nonphysical generator or load. RegisteredResource {920A6CB8-97C1-4c0a-8A7C-C20B85B04F7E} The schedule has time points where the time between them is constant. RegularIntervalSchedule {A2B1A5C3-6129-4e3b-A1B5-1AC417DEF3AA} Time point for a schedule where the time between the consecutive points is constant. RegularTimePoint {8E858A31-A91C-4e9f-BEFA-6604EE4A4E30} A type of conducting equipment that can regulate a quantity i.e. voltage or flow at a specific point in the network. RegulatingCondEq {598D5E45-FF89-4074-B3C1-3F40425EE8D6} Specifies a set of equipment that works together to control a power system quantity such as voltage or flow. Remote bus voltage control is possible by specifying the controlled terminal located at some place remote from the controlling equipment.The specified terminal shall be associated with the connectivity node of the controlled point. The most specific subtype of RegulatingControl shall be used in case such equipment participate in the control e.g. TapChangerControl for tap changers.For flow control load sign convention is used i.e. positive sign means flow out from a TopologicalNode bus into the conducting equipment.The attribute minAllowedTargetValue and maxAllowedTargetValue are required in the following cases For a power generating module operated in power factor control mode to specify maximum and minimum power factor values Whenever it is necessary to have an off center target voltage for the tap changer regulator. For instance due to long cables to off shore wind farms and the need to have a simpler setup at the off shore transformer platform the voltage is controlled from the land at the connection point for the off shore wind farm. Since there usually is a voltage rise along the cable there is typical and overvoltage of up 34 kV compared to the on shore station. Thus in normal operation the tap changer on the on shore station is operated with a target set point which is in the lower parts of the dead band.The attributes minAllowedTargetValue and maxAllowedTargetValue are not related to the attribute targetDeadband and thus they are not treated as an alternative of the targetDeadband. They are needed due to limitations in the local substation controller. The attribute targetDeadband is used to prevent the power flow from move the tap position in circles hunting that is to be used regardless of the attributes minAllowedTargetValue and maxAllowedTargetValue. RegulatingControl {8C28B28D-4735-4033-9F33-7D86F6819922} The kind of regulation model. For example regulating voltage reactive power active power etc. RegulatingControlModeKind {7AA04AD0-E999-4595-877D-33844C01F860} This class represents the physical characteristic of a generator regarding the regulating limit. RegulatingLimit {B9C0775A-9238-4f30-8872-3BC702394185} Special requirements andor regulations may pertain to certain types of assets or work. For example fire protection and scaffolding. Regulation {74C4BFF0-26BA-4841-8B3C-3AB942F7B5C4} Kind of regulation branch for shunt impedance. RegulationBranchKind {0765D2AB-8A32-4676-9233-5C0D221A9CF4} A preestablished pattern over time for a controlled variable e.g. busbar voltage. RegulationSchedule {48632975-29AC-44f1-AC6C-1C7E7CEDBB0B} Vertical displacement relative to either sealevel ground or the center of the earth. RelativeDisplacement {3F066029-C493-49ce-A282-54B245B31FD6} The types of relative displacement RelativeDisplacementKind {D4F6C390-4C62-4e58-8230-E830916A4AE2} Information regarding the experienced and expected reliability of a specific asset type of asset or asset model. ReliabilityInfo {A482ED74-2DA2-44d4-B516-615598573052} Remedial Action Scheme RAS Special Protection Schemes SPS System Protection Schemes SPS or System Integrity Protection Schemes SIPS. RemedialActionScheme {DA505846-8BFC-4185-8F6E-20C3A5761B0C} Classification of Remedial Action Scheme. RemedialActionSchemeKind {A024B5FF-8AE9-4f91-A91B-806CA4FF2B6C} Details of remote connect and disconnect function. RemoteConnectDisconnectInfo {83F01164-7557-4707-A39A-7A840EC61796} Remote controls are outputs that are sent by the remote unit to actuators in the process. RemoteControl {5B096850-E749-4b88-AC9B-AB0EFD66A72F} Supports connection to a terminal associated with a remote bus from which an input signal of a specific type is coming. RemoteInputSignal {4343E844-5BAF-4175-9144-8319CA06EF02} For an RTU remote points correspond to telemetered values or control outputs. Other units e.g. control centres usually also contain calculated values. RemotePoint {4628091D-2315-459f-9E5F-2CFECA557F1C} Type of input signal coming from remote bus. RemoteSignalKind {8A481858-022C-4903-B46C-7440303AB35A} Remote sources are state variables that are telemetered or calculated within the remote unit. RemoteSource {CC135E99-5C6E-41ad-8FE4-E7EBEC8E0D8C} A remote unit can be an RTU IED substation control system control centre etc. The communication with the remote unit can be through various standard protocols e.g. IEC 61870 IEC 61850 or non standard protocols e.g. DNP RP570 etc.. A remote unit contains remote data points that might be telemetered collected or calculated. The RemoteUnit class inherits PowerSystemResource. The intention is to allow RemoteUnits to have Measurements. These Measurements can be used to model unit status as operational out of service unit failure etc. RemoteUnit {93AA36A5-8421-432f-89ED-64774D6A10A3} Type of remote unit. RemoteUnitType {C956444A-A2E6-4f96-B6F0-DCCF81B934BF} Asset component to be repaired or problem area to be corrected. RepairItem {6A3C3555-E931-4806-8142-46836248309A} Work task for asset repair. Costs associated with this are considered corrective maintenance CM costs. RepairWorkTask {827FA145-0271-4e69-A97A-ABC22B89391F} font color0f0f0fDefinition of one set of reporting capabilities for this monitoring station. The associated EnvironmentalValueSets describe the maximum range of possible environmental values the station is capable of returning. This attribute is intended primarily to assist a utility in managing its stations. font ReportingCapability {32F281EE-89A4-4602-BB63-310AD3626494} A reporting group is used for various adhoc groupings used for reporting. ReportingGroup {EB1C81AA-89E4-44f4-8BA2-45FF36E88015} Method by which information is gathered from station. ReportingMethodKind {4CF94AE5-3B0A-4089-99C5-5AAB31F71603} A reporting super group groups reporting groups for a higher level report. ReportingSuperGroup {68A3A6AE-719A-4172-9EE1-5858D6327ED4} MPISO RequestorRmrTest {5529927B-0386-4b8b-98FE-BE33F91D4853} Reserve demand curve. Models maximum quantities of reserve required per Market Region and models a reserve demand curve for the minimum quantities of reserve. The ReserveDemandCurve is a relationship between unit operating reserve price in MWhr Yaxis and unit reserves in MW Xaxis. ReserveDemandCurve {E883299B-F114-4f66-A3F5-71A6BEAE650E} Requirements for minimum amount of reserve andor regulation to be supplied by a set of qualified resources. ReserveReq {8E435FB0-35C8-4ece-AEEA-1A9F5C65798D} A curve relating reserve requirement versus time showing the values of a specific reserve requirement for each unit of the period covered. The curve can be based on absolute time or on normalized time. X is time typically expressed in absolute timeY1 is reserve requirement typically expressed in MW ReserveReqCurve {71B015A0-EACE-438f-8303-7BCD769465A6} For exampleOperating Reserve Regulation Contingency ReserveRequirementType {649D7C9C-6861-4f39-B603-6CD796C5FCB2} A water storage facility within a hydro system including ponds lakes lagoons and rivers. The storage is usually behind some type of dam. Reservoir {7702412B-7FEB-4af0-9785-C4FDBEB525F0} Resistance real part of impedance. Resistance {EDB281E6-BBB4-438d-953B-7D746CAF55B5} Resistance real part of impedance per unit of length. ResistancePerLength {A4EFE5A9-F88A-4d8a-A35F-26D017259C43} For exampleAsset Owner Sink designator for use by CRRAsset Owner Source designator for use by CRRReliability Must Run Scheduling Coordinator Load Serving Entity ResourceAssnType {0A9B91BC-AD35-4990-A8BA-CC4401EA8032} Models details of bid and offer market clearing. Class indicates whether a contingency is active and whether the automatic dispatching system is active for this interval of the market solution. ResourceAwardClearing {F58861DA-5DAC-4572-9D47-348DEC93315D} Model of market results instruction for resource. Contains details of award as attributes. ResourceAwardInstruction {A4F2E108-DA91-4903-8D23-6C657C7E014E} Energy bid for generation load or virtual type for the whole of the markettrading period i.e. one day in day ahead market or one hour in the real time market. ResourceBid {C30DB807-0AE3-4e0c-AAE1-4E9433E532BA} This class model the various capacities of a resource. A resource may have numbers of capacities related to operating ancillary services energy trade and so forth. Capacities may be defined for active power or reactive power. ResourceCapacity {3E84F6F8-797E-4e4c-8901-DA7E5B1DFB67} Resource capacity type. ResourceCapacityType {B1F01A3B-E3FC-4f5f-B836-1AF45A135A8B} Specifies certification for a resource to participate in a specific markets. This class represent the resource certification for a specific product type. For example a resource is certified for NonSpinning reserve for RTM. ResourceCertification {82B48F0E-EC60-4e73-AC59-4A134991765F} {C27E4ACF-F11A-4912-9628-29357405DB51} ResourceCertificationCategory {08242269-903E-4785-A027-5FB69930C2D8} Types used for resource certification. ResourceCertificationKind {1A8E9455-69B0-4569-AB6A-139B5AF62D66} ResourceCertificationType {BB1C814A-CBFB-4aa8-BF54-BBDFA7EB1C18} Model of market results including cleaing result of resources. Associated with ResourceDispatchResults. ResourceClearing {AE7158B0-FBBB-42d1-8B34-0B98A9E2F777} ResourceDeploymentStatus {3C11781A-95A7-4d39-9DF2-77AE0C86FFD0} The ResourceDispatchResults class provides market results that can be provided to a SC. The specific data provided consists of several indicators such as contingency flags blocked start up and RMR dispatch. It also provides the projected overall and the regulating status of the resource. ResourceDispatchResults {376A011D-B48B-4989-BAC1-510269091E2B} A logical grouping of resources that are used to model location of types of requirements for ancillary services such as spinning reserve zones regulation zones etc. ResourceGroup {91E0A619-9EE5-4067-842E-1D325BBDF7ED} Ancillary service requirements for a market. ResourceGroupReq {0E838216-C7A6-456b-B0CA-4132390C7B42} Locational AS Flags indicating whether the Upper or Lower Bound limit of the AS regional procurement is binding. ResourceLimitIndicator {DA416C3B-7202-4b9c-BFF9-3DDA372D5A73} Model of market clearing results for resources that bid to follow load. ResourceLoadFollowingInst {1874CDEF-F92E-449f-A0B1-0FF929793AAB} To model the Operation and Maintenance O and M costs of a generation resource. ResourceOperationMaintenanceCost {80204EE8-3326-45cd-A41B-385DFC54F5D3} Represents an the performance evaluation of a resource deployment. Every resource deployment may have many performance evaluations using different evaluation metrics or algorithms or produced by different evaluation authorities. ResourcePerformanceEvaluation {96F08A4F-48D6-4060-A348-291FA2C39A9D} Global factors are propertyvalue pairs that are used to adjust resource performance values. Example include scale factors e.g. scale a baseline up or down adders positive or negative etc. ResourcePerformanceGlobalFactor {DCBD23CE-0574-4fa9-ABB2-7BA5C3E7BE63} Rating of a resource for its demand response performance. e.g. given a set on monthly resource demand response performance evaluations the resource may be rated with excellent average or poor performance for the sample set. ResourcePerformanceRating {A0F02391-DA9F-41dd-8539-9D4A34696690} Represents the performance of a resource as time series data for a specified time period time interval and evaluation criteria. ResourcePerformanceTimeSeriesFactor {BC04C5C3-2138-4b6f-B7B2-98C3905EB788} Types of resource registration status for exampleActiveMothballedPlannedDecommissioned ResourceRegistrationStatus {C19F80AC-7457-4a2e-8AFE-481193821C55} To model the startup costs of a generation resource. ResourceStartupCost {1969CDE2-401C-4490-88C2-5E16365B5B54} This class is defined to describe the verifiable costs associated with a generation resource. ResourceVerifiableCosts {9B7A2594-4808-491e-8A57-C917B16AE913} Specifies a category of energy usage that the demand response applies for e.g. energy from lighting HVAC other. ResponseMethod {9878550E-874A-44d5-8003-59ED85F2A8CE} Market results binding constraint types. ResultsConstraintType {3A3A99EF-3315-42ac-80E3-0E64307353EA} Reason asset retired. RetiredReasonKind {2D035DD5-C66F-421d-9339-31C7D7205A44} Accounting classification of the type of revenue collected for the customer agreement typically used to break down accounts for revenue accounting. RevenueKind {FE40851C-B2FA-41ae-AE39-30A6E441A293} A rightofway ROW is for land where it is lawful to use for a public road an electric power line etc. Note that the association to Location Asset Organisation etc. for the Grant is inherited from Agreement a type of Document. RightOfWay {44FBA225-6F53-4b26-BF4C-7792D077AFF2} Score that is indicative of the risk associated with one or more assets. RiskScore {72633FD4-C345-4b4b-B26D-88085BCB1973} Types of risk scores. RiskScoreKind {0A7A6DC8-E106-4f1f-B10C-106ADDA343FF} Enumeration of potential roles that might be played by one object relative to another. Role {9A4F58D3-9532-4488-AC87-867473F3EC06} A rotating machine which may be used as a generator or motor. RotatingMachine {8ADF23B6-43B5-436b-91CE-E22D54B323B8} Abstract parent class for all synchronous and asynchronous machine standard models. RotatingMachineDynamics {AE986CE7-783B-4310-8D50-95FEB16A0A76} Number of revolutions per second. RotationSpeed {D9556FC3-5453-44d9-94C5-07D51D3BAD82} Type of rotor on physical machine. RotorKind {B784D340-A930-49c4-AF7C-23CB2D9C8E4D} Route that is followed for example by service crews. Route {97D5A1C9-7293-4f53-9E36-6436203F3080} Contains information about the update from SCADA. SCADAInformation {6AF470D5-833C-4f98-A478-B123D22758FB} SVC asset allows the capacitive and inductive ratings for each phase to be specified individually if required. SVC {F35F78AD-2E5A-4b02-8563-66478EC5EE09} Static VAr Compensator control mode. SVCControlMode {269933B9-3FD0-433d-B360-86FF6CDCDDC8} Static var compensator SVC function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font SVCUserDefined {6661826C-0F88-4064-A3B0-418E922F2BFE} Document restricting or authorising works on electrical equipment for example a permit to work sanction for test limitation of access or certificate of isolation defined based upon organisational practices. SafetyDocument {AC73635B-66D4-4451-B175-9206C19BA6A9} Types of sample containers. SampleContainerType {73A622F5-63A5-4c8d-BD09-F0A3997811EA} Kinds of scaling. ScaleKind {DA55F75E-AED7-4b4a-9B0C-2ED718D620D7} SchedClassType {83A7FC09-5452-49bb-91E2-91B193DFFE96} ScheduledActivePowerLimitValue {D03914BB-F02B-4722-BF53-1C09B5A994D0} A time scheduled value for apparent power limit. ScheduledApparentPowerLimitValue {530D3590-84C8-40bf-A6DF-F36A61F164D2} A current limit that is scheduled. ScheduledCurrentLimitValue {1DF02F1D-5B29-4ab9-B925-A921AD897A93} An event to trigger one or more activities such as reading a meter recalculating a bill requesting work when generating units must be scheduled for maintenance when a transformer is scheduled to be refurbished etc. ScheduledEvent {5320DB66-1FF5-4e87-8029-8D8E938E9D72} Schedule parameters for an activity that is to occur is occurring or has completed. ScheduledEventData {49C8A8CF-3B31-49e1-AF68-279D11721DE2} ScheduledLimitDependency {75574C0E-2A86-47a4-8D58-14D494EA033F} A limit that is applicable during a scheduled time period. ScheduledLimitValue {93BE7FA6-D43E-4844-8A9A-A9F7F84B37E5} A voltage limit value for a scheduled time. ScheduledVoltageLimitValue {9D007556-3FFA-4632-B9FF-719141F5D595} Market participants could be represented by Scheduling Coordinators SCs that are registered with the RTOISO. One participant could register multiple SCs with the RTOISO. Many market participants can do business with the RTOISO using a single SC. One SC could schedule multiple generators. A load scheduling point could be used by multiple SCs. Each SC could schedule load at multiple scheduling points. An intertie scheduling point can be used by multiple SCs. Each SC can schedule interchange at multiple intertie scheduling points. SchedulingCoordinator {29DD7B48-807D-4f7a-8570-3C7EFF51D865} Describing users of a Scheduling Coordinator. SchedulingCoordinatorUser {FE8B191F-0122-4f90-968A-81D44B223005} Connection to other organizations at the boundary of the ISORTO. SchedulingPoint {D577CAB9-7258-4a51-8AFD-60D5FB2EE2FD} Physically controls access to AssetContainers. Seal {5CF7300B-8B0C-4c1e-AC84-6CD0EB5F8B4B} Kind of seal condition. SealConditionKind {44679AEE-F169-4f0a-B42B-4306FC058FB2} Kind of seal. SealKind {16AB0BBD-B6D6-4206-A8FB-1840132542A9} A specified time period of the year. Season {34DC6AAA-A359-4408-9348-0305AB9E9E9A} A time schedule covering a 24 hour period with curve data for a specific type of season and day. SeasonDayTypeSchedule {56D10F07-3518-4dec-BAD8-82B5ED26C817} Time in seconds. Seconds {A2008978-193D-4955-8102-599E43C7CFE4} Automatic switch that will lock open to isolate a faulted section. It may or may not have load breaking capability. Its primary purpose is to provide fault sectionalising at locations where the fault current is either too high or too low for proper coordination of fuses. Sectionaliser {6F75B963-A39E-4dc7-B75B-E205EE11AE4F} Typically provided by RTO systems constraints identified in both base case and critical contingency cases have to be transferred.A constraint has N gt1 constraint terms. A term is represented by an instance of TerminalConstraintTerm. The constraint expression isminValue lt c1x1 c2x2 .... cnxn k lt maxValuewhere cn is ConstraintTerm.factor xn is the flow at the terminalFlow into the associated equipment is positive for the purpose of ConnectivityNode NodeConstraintTerm.k is SecurityConstraintsLinear.resourceMW.The units of k are assumed to be same as the units of the flows xn. The constants cn are dimensionless.With these conventions cn and k are all positive for a typical constraint such as weighted sum of generation shall be less than limit. Furthermore cn are all 1.0 for a case such as interface flow shall be less than limit assuming the terminals are chosen on the importing side of the interface. SecurityConstraintSum {2D47275A-FA55-47a4-BC5E-7A04E8519117} Typical for regional transmission operators RTOs these constraints include transmission as well as generation group constraints identified in both base case and critical contingency cases. SecurityConstraints {873BBE76-79B7-4f36-AEB3-B8B95953B700} Binding security constrained clearing results posted for a given settlement period. SecurityConstraintsClearing {3B989922-47C7-4a9e-A793-83B152C727B3} SegmentCurveType {1833DF1C-00AA-4bde-9F9E-85E31CE07503} Indication of which type of self schedule is being referenced. SelfSchedReferenceType {CE41E713-4E36-4980-A41D-DB7426A83045} SelfSchedTypeCleanBid {F93913DC-9FD9-4954-85C4-2BCA478D06F7} SelfSchedTypeRawBid {77EE204F-678E-418c-8983-7CED48150194} Model of Self Schedules Results. Includes self schedule MWand type of self schedule for each self schedule type included in total self schedule MW value found in ResourceAwardInstruction. SelfScheduleBreakdown {9134E482-78E1-4d37-9F1D-545330C38BDB} Self schedule breakdown type. SelfScheduleBreakdownType {1F46DF6C-CAA9-41cb-92BA-F92C1FF8F771} self schedule typesPTETCTORRMRRMTRGMRORFCSP SelfScheduleType {AD3CD604-1975-4c32-9EB7-FACDD1E9CA6A} Self Schedule Types applicable to Mitigated Bid SelfScheduleTypeMB {2E1723E0-276C-46a9-8910-823B9FDE6B9C} Optionally this curve expresses elasticity of the associated requirement. For example used to reduce requirements when clearing price exceeds reasonable values when the supply quantity becomes scarce. For example a single point value of 1000MW for a spinning reserve will cause a reduction in the required spinning reserve. X axis is constrained quantity e.g. MWY1 axis is money per constrained quantity SensitivityPriceCurve {236E1822-6F83-4df3-9F29-8796386E876B} This class describe devices that transform a measured quantity into signals that can be presented at displays used in control or be recorded. Sensor {0697374C-946D-4033-A892-BA0929F3D30A} A set of similar physical or conceptual objects defined for the same period or point of time. Series {CA5E8158-5348-4165-920A-1E02D29E4C7C} A Series Compensator is a series capacitor or reactor or an AC transmission line without charging susceptance. It is a two terminal device. SeriesCompensator {5B656059-8C65-455e-9E02-5A14C2631D6A} Limit based on most restrictive series equipment limit.A specification of of equipment that determines the calculated operational limit values based upon other equipment and their ratings. The most restrictive limit connected in series within the group is used. The physical connection based on switch status for example may also impact which elements in the group are considered. Any equipment in the group that are presently connected in series with the equipment of the directly associated operational limit are used. This provides a means to indicate which potentially series equipment limits are considered for a computed operational limit. The operational limit of the same operational limit type is assumed to be used from the grouped equipment. It is also possible to make assumptions or calculations regarding how flow might split if the equipment is not simply in series. SeriesEquipmentDependentLimit {5F8AFC2E-E319-4c12-B886-CBFDB4CFC78B} Category of service provided to the customer. ServiceCategory {3B841B0B-C66B-47e6-86F3-2AD7396BFDC0} A service guarantee often imposed by a regulator defines conditions that if not satisfied will result in the utility making a monetary payment to the customer. Note that guarantees identifier is in the name attribute and the status of the guarantee is in the Status.status attribute.Example service requirements include1 If power is not restored within 24 hours customers can claim 50 for residential customers or 100 for commercial and industrial customers. In addition for each extra period of 12 hours the customers supply has not been activated the customer can claim 25.2 If a customer has a question about their electricity bill the utility will investigate and respond to the inquiry within 15 working days. If utility fails to meet its guarantee utility will automatically pay the customer 50. ServiceGuarantee {21F81CF0-10CF-4a60-94FC-CEB045927D7E} Kind of service. ServiceKind {1E950BD8-0A33-40a4-924B-F1A272126E3C} A real estate location commonly referred to as premises. ServiceLocation {90D00036-1728-473a-9966-26BADB297110} Multiplier applied at the usage point. ServiceMultiplier {64F18056-C8A2-4d2c-9A6B-ABA98536ED37} Kind of service multiplier. ServiceMultiplierKind {621E7C20-0F73-4bf2-A294-9FCD3F4C6B93} The defined termination points of a transmission path. Service points are defined from the viewpoint of the transmission service. Each service point is contained within or on the boundary of an interchange area. A service point is source or destination of a transaction. ServicePoint {E0569B00-C504-4bd4-BC15-97A64DA26866} Summary counts of service points affected by an outage. These counts are sometimes referred to as total and critical customer count. ServicePointOutageSummary {AE9E2743-9D59-4dd9-BFA9-8798985B6200} Organisation that provides services to customers. ServiceSupplier {D521178C-D4CD-4701-9633-E658D9D812EC} An analog control that issues a set point value. SetPoint {34230D45-F881-4938-9104-22653DEFE6A2} Specifies a settlement run. Settlement {C50E18F4-0D25-4f2c-AF5A-70E1851041B2} Generally referring to a period of operation or work performed. Whether the shift is openclosed can be derived from attributes activityInterval.start and activityInterval.end.The grand total for receipts i.e. cumulative total of all actual receipted amounts during this shift bankable nonbankable excludes rounding error totals can be derived from receiptsumReceipt.receiptAmount includes bankable and nonbankable receipts.It also has to be reconciled againstsumreceiptsGrandTotalBankable receiptsGrandTotalNonBankableand against receipt summarysumReceiptSummary.receiptsTotal.The attributes with GrandTotal defined in this class may need to be used when the source data is periodically flushed from the system and then these cannot be derived. Shift {12465F6E-EA5E-4a9e-AEA0-FDD1E2F30E49} The patterns of shifts worked by people or crews. ShiftPattern {5D821447-C660-4d55-8241-966E9C8F0359} Type of rotor used by short circuit applications. ShortCircuitRotorKind {FD4BEA47-D945-4bc1-A574-5C0618B5C429} Shortcircuit test results determine mesh impedance parameters. They include load losses and leakage impedances. For threephase windings the excitation can be a positive sequence the default or a zero sequence. There shall be at least one grounded winding. ShortCircuitTest {B753F4F1-9D09-406e-990B-790FC16EFA5A} A shunt capacitor or reactor or switchable bank of shunt capacitors or reactors. A section of a shunt compensator is an individual capacitor or reactor. A negative value for reactivePerSection indicates that the compensator is a reactor. ShuntCompensator is a single terminal device. Ground is implied. ShuntCompensator {92B30569-5ED0-4fc0-B796-984D9BF75453} ShuntCompensatorAction {428D6B1A-AE90-437e-8E09-3318CF951328} Distribution capacitor bank control settings. ShuntCompensatorControl {5FFFB760-AFCE-495a-8F94-95B84D23690E} Optimal Power Flow or State Estimator Filter Bank Data for OTS. This is used for RealTime Study and Maintenance Users. ShuntCompensatorDynamicData {0D14F688-E1B1-414a-8268-543060FFAE9A} Properties of shunt capacitor shunt reactor or switchable bank of shunt capacitor or reactor assets. ShuntCompensatorInfo {3E9CFB82-B958-4601-9FE4-F334F40FA838} Single phase of a multiphase shunt compensator when its attributes might be different per phase. ShuntCompensatorPhase {081B186A-D45B-44d1-81DF-94EE3918A4D5} Kind of control for shunt impedance. ShuntImpedanceControlKind {6F86F7A1-3B9B-4675-BFE8-7B47013B60A1} Kind of local control for shunt impedance. ShuntImpedanceLocalControlKind {1DF1339E-9D7C-4d81-A2FE-6E08BC99C021} Relationship between the rate in gross active powerminute Yaxis at which a unit should be shutdown and its present gross MW output Xaxis. ShutdownCurve {AAF85FC5-3F25-44db-BDDF-E595F3D1442A} Simple end device function distinguished by kind. Use this class for instances that cannot be represented by another end device function specialisations. SimpleEndDeviceFunction {A31060F5-6C63-4ddd-8F07-A06D752DA79A} Enumeration of single phase identifiers. Allows designation of single phases for both transmission and distribution equipment circuits and loads. SinglePhaseKind {0AD52D65-4270-45c1-9AF4-29C53A398AE3} Proficiency level of a craft which is required to operate or maintain a particular type of asset andor perform certain types of work. Skill {13EF0D6F-830A-4054-B0A2-D02F94EF4C74} Kind of skill level. SkillLevelKind {159907A1-CFDD-4260-91BB-B8F48D276230} A solar thermal generating unit connected to the grid by means of a rotating machine. This class does not represent photovoltaic PV generation. SolarGeneratingUnit {C5A085AB-DDD3-41b0-91DE-9071B466AE9A} Source gives information related to the origin of a value. Source {2DDE9E7D-6C38-4e8d-83FD-E0CE637A0E37} SourceSinkFlag {8884AFCA-B94E-41ea-86E9-0DE651DB6C87} SourceSinkType {9026EE61-8E4B-4e3d-AFF8-92D284407A05} Analog float measuring a space extraterrestrial condition. SpaceAnalog {218C406A-9E85-4756-BE01-2A5058AE5403} Kinds of analogs floats measuring a space condition. SpaceAnalogKind {B54762BE-B4CE-4841-A0E6-C2ED3C921661} An extraterrestrial phenomenon. SpacePhenomenon {968F42AA-AC91-42fd-AF85-A3EA53AA7EB6} Specification can be used for various purposes relative to an asset a logical device PowerSystemResource location etc. Examples include documents supplied by manufacturers such as asset installation instructions asset maintenance instructions etc. Specification {E2672086-449E-4a8a-ADBD-82485754DF76} Sample or specimen of a material fluid or solid. Specimen {DCE4CB8A-10F1-401d-AD1A-60AF570E5D09} Distance per unit of time. Speed {B2B55BF9-D1CD-4a20-8B96-E9509B356C6D} SpinningEventNameType {676FDD34-A716-4bff-BB1D-A7FC37736ED5} SpinningEventType {7FC49840-94E6-4808-841E-B8CCE110F3A9} Stage of a remedial action scheme. Stage {F18F00A6-9C7B-483b-A568-BFD9B14DCB0E} Condition that is triggered either by TriggerCondition of by gate condition within a stage and has remedial actions. StageTrigger {88383979-C8C0-46c1-9E3B-2E720872694F} The Standard Industrial Classification SIC are the codes that identify the type of productsservice an industry is involved in and used for statutory reporting purposes. For example in the USA these codes are located by the federal government and then published in a book entitled The Standard Industrial Classification Manual. The codes are arranged in a hierarchical structure.Note that Residential Service Agreements are not classified according to the SIC codes. StandardIndustryCode {4BD9C91C-E2EF-48fa-A6C2-A7E03669C29B} The quantity of ignition fuel Yaxis used to restart and repay the auxiliary power consumed versus the number of hours Xaxis the unit was off line. StartIgnFuelCurve {D6091F0C-3817-4ed9-83F2-42DFCAA3BDBD} The quantity of main fuel Yaxis used to restart and repay the auxiliary power consumed versus the number of hours Xaxis the unit was off line. StartMainFuelCurve {7E3057A5-5274-4743-BE6B-832426F6EC3F} Rate in gross active power per minute Yaxis at which a unit can be loaded versus the number of hours Xaxis the unit was off line. StartRampCurve {EA64A047-C475-45e4-A0AA-A2D208152FA8} Startup costs and time as a function of down time. Relationship between unit startup cost Y1axis vs. unit elapsed down time Xaxis. StartUpCostCurve {99245E92-6D85-42ac-91F7-7B044006140A} The energy consumption of a generating resource to complete a startup from the StartUpEnergyCurve. Definition of the StartUpEnergyCurve includes xvalue as the cooling time and y1value as the MW value. StartUpEnergyCurve {22697274-C38F-4f5b-ADD7-F5345FA159E2} The fuel consumption of a Generating Resource to complete a StartUp.xcooling time Form Startup Fuel Curve. xAxisData gt cooling time y1AxisData gt MBtu. StartUpFuelCurve {233FA2CB-2BCB-4d3c-9042-3319DB5916C1} Startup time curve as a function of down time where time is specified in minutes. Relationship between unit startup time Y1axis vs. unit elapsed down time Xaxis. StartUpTimeCurve {016B40BA-1E07-4f91-9113-EA0006C71B19} Unit start up characteristics depending on how long the unit has been off line. StartupModel {FBC83D02-01EA-487c-8FAD-3BE0BA87C6ED} An abstract class for state variables. StateVariable {76444E94-D4BE-4cbf-9146-CD50D2F87A93} Type of static load model. StaticLoadModelKind {9D882F45-ACA2-4c41-B820-A8C4BED1126B} A facility for providing variable and controllable shunt reactive power. The SVC typically consists of a stepdown transformer filter thyristorcontrolled reactor and thyristorswitched capacitor arms.The SVC may operate in fixed MVar output mode or in voltage control mode. When in voltage control mode the output of the SVC will be proportional to the deviation of voltage at the controlled bus from the voltage setpoint. The SVC characteristic slope defines the proportion. If the voltage at the controlled bus is equal to the voltage setpoint the SVC MVar output is zero. StaticVarCompensator {B540EF99-8CE4-4da6-9E4D-D22E867F8BAE} Static var compensator whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font StaticVarCompensatorDynamics {B979A376-AE67-4798-8E61-A1745649B242} Station supply with load derived from the station output. StationSupply {67147C58-10F8-4463-93B7-7905358489FD} Description of statistical calculation performed. StatisticalCalculation {1FDD4916-3696-4ea3-9481-85106E3296DE} Current status information relevant to an entity. Status {9EF7B157-4B24-45ee-A340-2CFB8F049D68} The cogeneration plants steam sendout schedule in volume per time unit. SteamSendoutSchedule {4C02B840-80C5-4d55-AB0D-3006749FD6A5} Steam supply for steam turbine. SteamSupply {EFFC79C3-293D-4a14-ADCA-E5F18F29951B} Steam turbine. SteamTurbine {6195DBA1-8A7F-491e-BD36-AFF11AD6D563} General purpose street and postal address information. StreetAddress {90007399-BB87-4f28-9898-853DAB696115} Street details in the context of address. StreetDetail {A4198329-7F25-4e72-8E8D-C4B4D37288F8} Streetlight asset. Streetlight {265BB5FA-D760-4500-BDD8-734847324F48} Kind of lamp for the streetlight. StreetlightLampKind {F0B6B07C-FC15-4ec6-92E8-96EA94AC530F} A string consisting of a sequence of characters. The character encoding is UTF8. The string length is unspecified and unlimited. String {E50DF78B-84CE-42e9-A275-A956DEF45490} StringMeasurement represents a measurement with values of type string. StringMeasurement {3EC705BA-D494-4102-AD0B-8CD7A9EECE3B} StringMeasurementValue represents a measurement value of type string. StringMeasurementValue {76C03FC7-3DB4-46ec-977E-7C00BF90B881} Quantity with string value when it is not important whether it is an integral or a floating point number and associated unit information. StringQuantity {C2DA5F9A-96E4-4c11-8EC6-B29AE5783A1A} Construction holding assets such as conductors transformers switchgear etc. Where applicable number of conductors can be derived from the number of associated wire spacing instances. Structure {C67E3DDB-366A-4d7f-B83B-8B85A957FF72} Kind of material used for structures. StructureMaterialKind {F4916917-6D37-4b5b-A967-F4D9B2644D92} Support for structure assets. StructureSupport {04CA8222-E0A1-4a67-A5AD-9CE3AFE3D439} Kind of structure support. StructureSupportKind {5BD2EFA5-CD28-4785-B9A7-10EF38FD47C9} An area defined for the purpose of tracking interchange with surrounding areas via tie points may or may not serve as a control area. SubControlArea {1A77F399-87B3-4dce-A329-739AEAB09175} A subset of a geographical region of a power system network model. SubGeographicalRegion {D3CE44CA-5AED-484b-92A3-89F156425204} The class is the second level in a hierarchical structure for grouping of loads for the purpose of load flow load scaling. SubLoadArea {A9E17C64-1729-4286-B30E-A26DED501DAC} Oncethrough subcritical boiler. Subcritical {2367E56D-3725-431a-BBB2-878D191F2B1B} Price curve for specifying the cost of energy X at points in time y1 according to a prcing structure which is based on a tariff. SubscribePowerCurve {52014668-2514-4a2f-9238-F992C8BDF1EC} A collection of equipment for purposes other than generation or utilization through which electric energy in bulk is passed for the purposes of switching or modifying its characteristics. Substation {D8A14AC5-D17B-4d42-8F12-1B674E5D12D7} List of resources that can be substituted for within the bounds of a Contract definition. This class has a precedence and a resource. SubstitutionResourceList {CF27F874-FDF5-429e-8D90-5A174497999A} Oncethrough supercritical boiler. Supercritical {7D4EE8CF-059A-45bd-962B-341C75D876F6} Kind of supplier. SupplierKind {03BF74FB-B448-4112-8394-9E1EC7D2BAA7} Shunt device installed on the network usually in the proximity of electrical equipment in order to protect the said equipment against transient voltage transients caused by lightning or switching activity. SurgeArrester {5B376A76-B1BA-48a1-B0BF-A0EAE8B4C61B} Properties of surge arrester. SurgeArresterInfo {370B4FF9-5E0B-471b-84E3-8CA9185651CD} Imaginary part of admittance. Susceptance {F246F97E-529D-4ec3-9F06-BAF4AFD0829B} Imaginary part of admittance per unit of length. SusceptancePerLength {59A364BC-34EB-41b6-810C-88484A2D929C} The SvInjection reports the calculated bus injection minus the sum of the terminal flows. The terminal flow is positive out from the bus load sign convention and bus injection has positive flow into the bus. SvInjection may have the remainder after state estimation or slack after power flow calculation. SvInjection {067C680D-D749-4c6a-891E-0DE4CAAD8451} State variable for power flow. Load convention is used for flow direction. This means flow out from the TopologicalNode into the equipment is positive. SvPowerFlow {0289223C-1161-4047-84EC-201D00A0CD92} State variable for the number of sections in service for a shunt compensator. SvShuntCompensatorSections {BC85044F-2D85-462a-AE9A-CC3E1D541D44} State variable for status. SvStatus {5DB950E7-EA86-4bc2-B627-D05EDF9131A2} State variable for switch. SvSwitch {039A6EAC-2BB9-4f9a-A578-F925C2AD8468} State variable for transformer tap step. SvTapStep {EDA41BC3-4A8F-46d0-851F-EFCAB8942211} State variable for voltage. SvVoltage {22A26B24-0A8E-402a-895E-AFAE18292542} A generic device designed to close or open or both one or more electric circuits. All switches are two terminal devices including grounding switches. The ACDCTerminal.connected at the two sides of the switch shall not be considered for assessing switch connectivity i.e. only Switch.open .normalOpen and .locked are relevant. Switch {ACE2DDBB-536E-489a-A3A8-22589256302D} Action on switch as a switching step. SwitchAction {4B8F56B0-FE35-4aa4-BB8B-DD756F9898AA} Kind of action on switch. SwitchActionKind {4B2B08CF-4F3C-4dba-871B-CC48F7241111} was Switch data.Switch datasheet information. SwitchInfo {1F119DDF-DDDB-463e-8712-CA1343550B9A} Uptodate ofrecord summary of switch operation information distilled from a variety of sources realtime data or realtime data historian field inspections etc. of use to asset health analytics. SwitchOperationSummary {FA56C86D-F988-404a-AE34-CDAEAC52A3E7} Single phase of a multiphase switch when its attributes might be different per phase. SwitchPhase {4BAF4C19-5181-41b2-B690-9758DB9D4F8B} A schedule of switch positions. If RegularTimePoint.value1 is 0 the switch is open. If 1 the switch is closed. SwitchSchedule {3C7AD112-5779-4f2a-8A87-ABB7FBA99EBF} Optimal Power Flow or State Estimator Circuit Breaker Status. SwitchStatus {9694A566-8C17-475e-9EB1-0F10E084A6A6} Circuit Breaker Status closed or open of the circuit breaker. SwitchStatusType {7D3C1DA0-2B00-486c-A8BC-6A284EF41DAC} Atomic switching action. SwitchingAction {71CB75D5-6E45-4438-90A2-B15C918B1BB3} Event indicating the completion success or fail of any switching action jumper action cut action tag action etc. The switching action may or may not be a consequential event in response to a request to complete the action. SwitchingEvent {12009FF8-FCCD-459b-8D67-9366AF32DD46} Transmits a switching plan to a crew in order for the plan to be executed. SwitchingOrder {C75D1EAD-CEA6-450d-9C1A-A5C3AE78911D} A sequence of grouped or atomic steps intended to deenergise equipment or part of the network for safe work andor bring back in service previously deenergised equipment or part of the network. SwitchingPlan {94D8F29A-7F14-475a-A47C-4A7A44FDC831} A document used to request that a switching plan be created for a particular purpose. SwitchingPlanRequest {2B4E7A26-DE70-4df2-BDD1-7C36E013BFAF} Atomic switching step can be part of a switching step group or part of a switching plan. SwitchingStep {EE8680C2-ED07-4a60-9EF9-7A23C54F7FD0} A logical step grouping atomic switching steps that are important to distinguish when they may change topology e.g. placing a jumper between two cuts. SwitchingStepGroup {A45191CC-01B4-4f9d-BD30-806616AC04C8} A device that operates when two AC circuits are within the desired limits of frequency phase angle and voltage to permit or to cause the paralleling of these two circuits. Used to prevent the paralleling of nonsynchronous topological islands. SynchrocheckRelay {B00D97A5-F7E7-44ad-A2C8-EEE11DCF1F42} An electromechanical device that operates with shaft rotating synchronously with the network. It is a single machine operating either as a generator or synchronous condenser or pump. SynchronousMachine {7862E21E-F054-4a33-949F-04B8B4690D49} All synchronous machine detailed types use a subset of the same data parameters and inputoutput variables. The several variations differ in the following ways the number of equivalent windings that are included the way in which saturation is incorporated into the model whether or not subtransient saliency iXqi not iXdi is represented.It is not necessary for each simulation tool to have separate models for each of the model types. The same model can often be used for several types by alternative logic within the model. Also differences in saturation representation might not result in significant model performance differences so model substitutions are often acceptable. SynchronousMachineDetailed {B272216C-A098-436d-80C8-02AD11F5B97F} Synchronous machine whose behaviour is described by reference to a standard model expressed in one of the following forms simplified or classical where a group of generators or motors is not modelled in detail detailed in equivalent circuit form detailed in time constant reactance form orfont color0f0f0f by definition of a userdefined model.fontfont color0f0f0fIt is a common practice to represent small generators by a negative load rather than by a dynamic generator model when performing dynamics simulations. In this case a SynchronousMachine in the static model is not represented by anything in the dynamics model instead it is treated as an ordinary load.fontfont color0f0f0fParameter detailsfontollifont color0f0f0fSynchronous machine parameters such as iXl Xd Xpi etc. are actually used as inductances in the modelsfont but are commonly referred to as reactances since at nominal frequency the PU values are the same. However some references use the symbol iLi instead of iXi.liol SynchronousMachineDynamics {575BECE2-4C08-40c3-9B81-1C8E6F4FCF8C} The electrical equations for all variations of the synchronous models are based on the SynchronousEquivalentCircuit diagram for the direct and quadrature axes.Equations for conversion between equivalent circuit and time constant reactance formsiXdi iXad ii XliiXdi iXli iXadi x iXfdi iXadi iXfdiiXdi iXli iXadi x iXfdi x iX1di iXadi x iXfdi iXadi x iX1di iXfdi x iX1diiXqi iXaqi iXliiXqi iXli iXaqi x iX1qi iXaqi iX1qiiXqi iXli iXaqi x iX1qi x iX2qi iXaqi x iX1qi iXaqi x iX2qi iX1qi x iX2qiiTdoi iXadi iXfdi iomegaiisub0subi x iRfdiiTdoi iXadi x iXfdi iXadi x iX1di iXfdi x iX1di iomegaiisub0subi x iR1di x iXadi iXfdiiTqoi iXaqi iX1qi iomegaiisub0subi x iR1qiiTqoi iXaqi x iX1qi iXaqi x iX2qi iX1qi x iX2qi iomegaiisub0subi x iR2qi x iXaqi iX1qiSame equations using CIM attributes from SynchronousMachineTimeConstantReactance class on left of and SynchronousMachineEquivalentCircuit class on right except as notedxDirectSync xad RotatingMachineDynamics.statorLeakageReactancexDirectTrans RotatingMachineDynamics.statorLeakageReactance xad x xfd xad xfdxDirectSubtrans RotatingMachineDynamics.statorLeakageReactance xad x xfd x x1d xad x xfd xad x x1d xfd x x1dxQuadSync xaq RotatingMachineDynamics.statorLeakageReactancexQuadTrans RotatingMachineDynamics.statorLeakageReactance xaq x x1q xaq x1qxQuadSubtrans RotatingMachineDynamics.statorLeakageReactance xaq x x1q x x2q xaq x x1q xaq x x2q x1q x x2q tpdo xad xfd 2 x pi x nominal frequency x rfdtppdo xad x xfd xad x x1d xfd x x1d 2 x pi x nominal frequency x r1d x xad xfdtpqo xaq x1q 2 x pi x nominal frequency x r1qtppqo xaq x x1q xaq x x2q x1q x x2q 2 x pi x nominal frequency x r2q x xaq x1qThese are only valid for a simplified model where Canay reactance is zero. SynchronousMachineEquivalentCircuit {A0EB0748-18CF-4602-AD73-7FB0E75DC126} Synchronous machine type. SynchronousMachineKind {DC90E008-CE3C-4415-960F-D7BFC4EB4693} Type of synchronous machine model used in dynamic simulation applications. SynchronousMachineModelKind {EE3419FE-0A7A-4b84-9D7B-AB4A48EE501D} Synchronous machine operating mode. SynchronousMachineOperatingMode {2A28E29E-8761-4008-AAD2-FDA8D5889F29} The simplified model represents a synchronous generator as a constant internal voltage behind an impedancei iiRs jXpi as shown in the Simplified diagram.Since internal voltage is held constant there is no iEfdi input and any excitation system model will be ignored. There is also no iIfdi output.This model should not be used for representing a real generator except perhaps small generators whose response is insignificant. The parameters used for the simplified model include RotatingMachineDynamics.damping iDi RotatingMachineDynamics.inertia iHi RotatingMachineDynamics.statorLeakageReactance used to exchange ijXp ifor SynchronousMachineSimplified RotatingMachineDynamics.statorResistance iRsi. SynchronousMachineSimplified {2D12C865-F0DB-43fa-9172-C08BDBE68790} Synchronous machine detailed modelling types are defined by the combination of the attributes SynchronousMachineTimeConstantReactance.modelType and SynchronousMachineTimeConstantReactance.rotorType. Parameter detailsolliThe p in the timerelated attribute names is a substitution for a prime in the usual parameter notation e.g. tpdo refers to iTdoi.liliThe parameters used for models expressed in time constant reactance form includeliol RotatingMachine.ratedS iMVAbasei RotatingMachineDynamics.damping iDi RotatingMachineDynamics.inertia iHi RotatingMachineDynamics.saturationFactor iS1i RotatingMachineDynamics.saturationFactor120 iS12i RotatingMachineDynamics.statorLeakageReactance iXli RotatingMachineDynamics.statorResistance iRsi SynchronousMachineTimeConstantReactance.ks iKsi SynchronousMachineDetailed.saturationFactorQAxis iS1qi SynchronousMachineDetailed.saturationFactor120QAxis iS12qi SynchronousMachineDetailed.efdBaseRatio SynchronousMachineDetailed.ifdBaseType .xDirectSync iXdi .xDirectTrans iXdi .xDirectSubtrans iXdi .xQuadSync iXqi .xQuadTrans iXqi .xQuadSubtrans iXqi .tpdo iTdoi .tppdo iTdoi .tpqo iTqoi .tppqo iTqoi .tc. SynchronousMachineTimeConstantReactance {C6F04365-226C-4457-AE52-86A30D76F764} Synchronous machine whose dynamic behaviour is described by a userdefined model. SynchronousMachineUserDefined {37B233FC-B7CB-49cd-8AB3-4618A5FA3250} This class models the system distribution factors. This class needs to be used along with the HostControlArea and the ConnectivityNode to show the distribution of each individual party. SysLoadDistributionFactor {1F407B8B-0DCD-4440-A23A-2571F2009882} SystemType {DF554719-7CB9-459c-97CB-BF50631359CC} Transmission Access Charge Area. Charges assessed on behalf of the Participating Transmission Owner to parties who require access to the controlled grid. TACArea {6DE57238-5C2B-49f5-96B5-4FB480581646} Standard published by TAPPI. TAPPIStandard {537D52C0-0FD0-45aa-BBCE-D4A34B5F845E} List of editions for TAPPI standards. TAPPIStandardEditionKind {E1D1B979-F3C4-4daa-96A3-346147E991AC} List of TAPPI standards. TAPPIStandardKind {3BD16AC8-BA39-4c56-92FB-2BABA898E792} This class describe the sending providing side in a bilateral ICCP data exchange. Hence the ICCP bilateral table descriptions are created by exchanging ICCP Provider data between the parties. TASE2BilateralTable {EECBB158-724F-411e-ABE9-FF28E5DCE4B3} Allows addressing and behavioural information regarding the use of TCP by ICCP links. TCPAccessPoint {9A1BFBDE-2EDA-4512-9BA4-0281C6966DA9} A Transmission RightTR can be a chain of TRs or on individual. When a transmission right is not a chain this is formally the ETCTOR Entitlement for each ETCTOR contract with the inclusion of CVRConverted Rights as an ETC. This is the sum of all entitlements on all related transmission interfaces for the same TR.When TR is a chain its entitlement is the minimum of all entitlements for the individual TRs in the chain. TREntitlement {B1B279F7-7A35-4cca-BCD5-612C161CAD68} Transmission Contract Right type for exampleindividual or chain of contract rights TRType {F787B721-AD7D-49a0-8C10-2A3720CC437A} Action on operation tag as a switching step. TagAction {E2B02A1D-2648-4060-90ED-13641B1782DF} Kind of action on tag. TagActionKind {6BC03167-2A28-4eab-8411-8FDAE36C1B3F} Relationship between tailbay head loss height Yaxis and the total discharge into the power stations tailbay volume per time unit Xaxis . There could be more than one curve depending on the level of the tailbay reservoir or river level. TailbayLossCurve {C4341551-417C-46df-AD8D-4AAB455DF8CB} Mechanism for changing transformer winding tap positions. TapChanger {F43099C0-90EA-47f1-B038-EDE831744C07} Describes behaviour specific to tap changers e.g. how the voltage at the end of a line varies with the load level and compensation of the voltage drop by tap adjustment. TapChangerControl {32D5C39A-ABB5-4ac8-8B3F-FBDC00DB19BB} Optimal Power Flow or State Estimator Phase Shifter Data. This is used for RealTime Study and Maintenance Users. SE Solution Phase Shifter Measurements from the last run of SE. TapChangerDynamicData {7E8D865C-55AD-4ebb-9380-2A1271288F7B} Tap changer data. TapChangerInfo {72DDFFCD-3592-413c-AAFA-E3834EB67086} Describes each tap step in the tabular curve. TapChangerTablePoint {199B695F-644C-4cbf-AB67-76AB51EE5078} A preestablished pattern over time for a tap step. TapSchedule {204A4D0D-C13F-4c97-BBE8-EEE743ACDA3F} Tape shield cable data. TapeShieldCableInfo {A8752772-CFD3-4eb2-9456-73B15504040D} Reservoir water level targets from advanced studies or rule curves. Typically in one hour increments for up to 10 days. TargetLevelSchedule {0BF4BBDA-CADE-4a85-B8CB-F0C4A18075BF} Document approved by the responsible regulatory agency listing the terms and conditions including a schedule of prices under which utility services will be provided. It has a unique number within the state or province. For rate schedules it is frequently allocated by the affiliated Public utilities commission PUC. Tariff {0BE74F01-4122-4e79-A801-A70BCEAE82B2} A schedule of charges structure associated with Tariff that allows the definition of complex tarif structures such as step and time of use when used in conjunction with TimeTariffInterval and Charge. Inherited status.value is defined in the context of the utilitys business rules for example active inactive etc. TariffProfile {96DD424D-40A2-4b2b-88EA-D66EE08B1313} Telephone number. TelephoneNumber {456C7633-96C3-448b-BF2D-8D6110084CC6} Kind of action on temporary equipment such as cut jumper ground energy source. TempEquipActionKind {1049668D-02E1-4336-86E4-306D60B6CE13} Value of temperature in degrees Celsius. Temperature {2C614F42-FED1-4705-82C8-57771A0466CE} A point on a table of limit verses temperature. TemperatureDependentLimitPoint {D7663B24-BFFA-4226-82F3-FB51D0C254E1} This is a table lookup that provides limit values corresponding to a temperature input. TemperatureDependentLimitTable {E27624EE-9CAF-45bb-8E53-5FF5083B6595} This describes the coefficients of a polynomial function that has temperature as input and calculates limit values as output. TemperaturePolynomialLimit {D7320B08-B289-41d0-BC42-2F471427A93B} Models 10Minutes Auxiliary Data. TenMinAuxiliaryData {DA559358-89B5-4579-A3C6-1B01513FCC22} Tender is what is offered by the customer towards making a payment and is often more than the required payment hence the need for change. The payment is thus that part of the Tender that goes towards settlement of a particular transaction.Tender is modelled as an aggregation of Cheque and Card. Both these tender types can exist in a single tender bid thus accountHolderName has to exist separately in each of Cheque and Card as each could have a different account holder name. Tender {3937B337-1AFD-4c5b-832F-0C13C893EE41} Kind of tender. TenderKind {E0FD3999-B4C6-4dd3-AB75-9A2CD71DE95C} An AC electrical connection point to a piece of conducting equipment. Terminals are connected at physical connection points called connectivity nodes. Terminal {1A0F8321-5E77-4d68-BE29-B36FA31549DC} A constraint term associated with a specific terminal on a physical piece of equipment. TerminalConstraintTerm {4705BCBF-E616-4d1c-8CA4-3AD2BD777401} Test results usually obtained by a lab or other independent organisation. TestDataSet {22F31D68-A247-4eb9-9388-56AAE86EB740} The test applied to determine if the condition is met. TestKind {558863B0-1947-46d8-BE29-54D352B6F524} Possible test methods. TestMethod {E2503A9B-2045-45b6-9945-9F7F40349894} Reason for test. TestReason {4B7FBB8C-99D2-47c2-95A6-74079F8F9AC4} The precise standard used in executing a lab test including the standard and standard version test method and variant if needed. TestStandard {D1CACECC-8319-4326-9871-BD2DB19CA4CB} Test variants. TestVariantKind {F1139730-E3EA-41bf-B39B-8A759C840EA6} A diagram object for placing freetext or text derived from an associated domain object. TextDiagramObject {ECCF586E-4F69-4f21-B234-DDE8C6974F0F} A generating unit whose prime mover could be a steam turbine combustion turbine or diesel engine. ThermalGeneratingUnit {74F16962-C880-450f-8B4F-0CFBD6BEF79A} Defines the structure in terms of location and direction of the net interchange constraint for a control area. This constraint may be used by either AGC or power flow. TieFlow {AA47BC16-A18A-4beb-9CB3-5F942819B925} TieLine {5E38218F-5C3C-4eea-B97B-CA3E8932B344} Site of an interface between interchange areas. The tie point can be a network branch e.g. transmission line or transformer or a switching device. For transmission lines the interchange area boundary is usually at a designated point such as the middle of the line. Line end metering is then corrected for line losses. TiePoint {5646690B-90BB-4493-B579-67E48CDF0860} Time as hhmmss.sss which conforms with ISO 8601. UTC time zone is specified as hhmmss.sssZ. A local timezone relative UTC is specified as hhmmss.ssshhmm. The second component shown here as ss.sss could have any number of digits in its fractional part to allow any kind of precision beyond seconds. Time {09171B95-287D-44b3-8E93-1376FDF0E55A} Interval between two times. TimeInterval {1A62B1E2-8C2D-4459-A10B-118C16A22A03} TimeIntervalKind {BAD15303-A2BD-4e5f-86B7-30D9CD344146} Time of Use used by a CRR definition for specifying the time the CRR spans. ON CRR spans the on peak hours of the day OFF CRR spans the off peak hours of the day 24HR CRR spans the entire day. TimeOfUse {95168B2D-6BDF-4442-99C0-C7C729EA8BC0} Units in which reporting frequency is specified. TimePeriodUnit {9768A0B6-3320-438b-902F-2ADAB9B19356} A point in time within a sequence of points in time relative to a time schedule. TimePoint {336EA49A-BDDF-47d3-A9BC-B1B5BD070ED4} Description of anything that changes through time. Time schedule is used to perform a singlevalued function of time. Use inherited type attribute to give additional information on this schedule such as periodic hourly daily weekly monthly etc. day of the month by date calendar specific times and dates. TimeSchedule {49D4B4E2-FF11-4a48-8418-7E660E6B34C8} A set of regular timeordered measurements or values of quantitative nature of an individual or collective phenomenon taken at successive in most cases equidistant periods points of time. TimeSeries {4E4FCB53-20DF-4ce4-947E-E3D41406911E} One of a sequence of time intervals defined in terms of real time. It is typically used in association with TariffProfile to define the intervals in a time of use tariff structure where startDateTime simultaneously determines the starting point of this interval and the ending point of the previous interval. TimeTariffInterval {A61EEF7B-B1DE-4db9-9825-F1BA4F9C0478} TimeZoneType {C823AFC3-EADA-4bc7-B6B1-BDA5F6BB257B} Tool asset. Tool {C7051DBE-5667-4bec-A88B-ABAFF00B1A5F} An electrically connected subset of the network. Topological islands can change as the current network state changes e.g. due to disconnect switches or breakers changing state in a SCADAEMS. manual creation change or deletion of topological nodes in a planning tool.Only energised TopologicalNodes shall be part of the topological island. TopologicalIsland {7AAF072C-6B81-4f1b-95F5-0BA3A3B7BE68} For a detailed substation model a topological node is a set of connectivity nodes that in the current network state are connected together through any type of closed switches including jumpers. Topological nodes change as the current network state changes i.e. switches breakers etc. change state.For a planning model switch statuses are not used to form topological nodes. Instead they are manually created or deleted in a model builder tool. Topological nodes maintained this way are also called busses. TopologicalNode {82489582-0ECB-4066-970D-A265B1065315} A tornado a violent destructive whirling wind accompanied by a funnelshaped cloud that progresses in a narrow path over the land. Tornado {AE09C199-6AF9-4dbf-A4D7-659755174D22} Tower asset. Dimensions of the Tower are specified in associated DimensionsInfo class.When used for planning purposes a transmission tower carrying two 3phase circuits will have 2 instances of Connection each of which will have 3 MountingPoint instances one for each phase all with coordinates relative to a common origin on the tower. It may also have a 3rd Connection with a single MountingPoint for the Neutral line. Tower {B61B782C-51A5-49d4-AB6B-2971702A92D8} Kind of tower construction. TowerConstructionKind {05A4A8FC-A77F-4900-BAF4-E434DE69B080} Town details in the context of address. TownDetail {26275F22-BDC6-4a76-ABE7-AC797CFE35D9} Inter Scheduling Coordinator Trades to model financial trades which may impact settlement. Trade {BC568130-E2FD-4938-8D44-2749731BC734} Trade error and warning messages associated with the rule engine processing of the submitted trade. TradeError {D8246ADF-5D06-4955-B17A-F04446F07420} bTradeTypeb bTradeProductbIST InterSC Trade PHY Physical Energy TradeIST APN Energy Trades at Aggregated Pricing NodesIST CPT Converted Physical Energy TradeAST Ancilliary Services Trade RUT Regulation Up TradeAST RDT Regulation Down TradeAST SRT Spinning Reserve TradeAST NRT NonSpinning Reserve TradeUCT Unit Commitment Trade null TradeProduct {634B14D4-5D26-43dc-B7DC-BA7F311E04FF} TradeProductType {CDAFD9DB-9506-4d0c-A42C-4F5159E63E23} RJ Rejected TradeI Invalid TradeV Valid TradeM Modified TradeCV Conditionally Valid TradeCM Conditionally Modified TradeCI Conditionally Invalid TradeCX Cancelled TradeO Obsolete TradeMT Matched TradeU Unmatched Trade TradeStatusType {3184AF14-7AE7-44dd-A246-B1F365768661} Trade type. TradeType {FD67B160-B7BF-4b89-82C2-ACA6CCB6FE63} Models prices at Trading Hubs interval based. TradingHubPrice {6AE25FE5-559A-4df8-8DBB-CE11CA6B35CC} Models prices at Trading Hubs. TradingHubValues {1DCB9371-4DAC-4c6a-ACCF-04219ABCA46E} The record of details of payment for service or token sale. Transaction {5D8018E8-DD12-4e67-B98A-26B79A920B63} Bilateral or scheduled transactions for energy and ancillary services considered by market clearing process. TransactionBid {CCB96D43-271B-46b2-AC67-CBBBADB5904F} Contains the intervals relavent for the associated TransactionBidResults. For example Day Ahead cleared results for the transaction bids for each interval of the market day. TransactionBidClearing {A39B0D3F-B3C6-45e2-BA4F-E7C4CE37598A} Contains the cleared results for each TransactionBid submitted to and accepted by the market. TransactionBidResults {DFC58795-C87F-4cdb-AEE2-DF1BC5832E1B} Kind of transaction. TransactionKind {E6FA723B-B828-4ed5-8F99-28E3C70CAFC7} The entity that ultimately executes the transaction and which is in control of the process typically this is embodied in secure software running on a server that may employ secure hardware encryption devices for secure transaction processing. Transactor {D0927466-4532-44e7-803B-1F7FE1D7CC44} A Transfer Interface is made up of branches such as transmission lines and transformers. TransferInterface {365B4939-767B-4501-8C3C-42C0EDA20A53} TNA Interface Definitions from OPF for VSA. TransferInterfaceSolution {FCCDF1D2-4051-4397-837C-9CF9A31A13B6} Classifications of network roles in which transformers can be deployed. The classifications are intended to reflect both criticality of transformer in network operations and typical usage experienced by transformer.Note This enumeration provides essential information to asset health analytics. The existing list is a starting point and is anticipated to be fleshed out further as requirements are better understood PAB 20160109. TransformerApplicationKind {5B47EE8F-11D0-49d9-A4BF-3CBA8AFCBB5C} Kind of transformer construction. TransformerConstructionKind {5FDFF2F1-83A7-4a56-9ACA-6B15F6866D49} Control modes for a transformer. TransformerControlMode {601E1E7A-46DB-4d07-95C8-4B61EBFC65C0} The transformer core admittance. Used to specify the core admittance of a transformer in a manner that can be shared among power transformers. TransformerCoreAdmittance {25B2D790-161A-45c8-8551-E77A34DE684C} Kind of transformer construction. TransformerCoreKind {6D41676A-0497-413b-BC16-FCDBC360EFEA} A conducting connection point of a power transformer. It corresponds to a physical transformer winding terminal. In earlier CIM versions the TransformerWinding class served a similar purpose but this class is more flexible because it associates to terminal but is not a specialization of ConductingEquipment. TransformerEnd {6E6AF445-8CD5-434b-8E74-08970A4E6D95} Transformer end data. TransformerEndInfo {EE451097-1E73-4a48-98F7-5558C8D4D5AB} Reason for transformer failure.Note This enumeration provides essential information to asset health analytics. The existing list is a starting point and is anticipated to be fleshed out further as requirements are better understood. PAB 20160109. TransformerFailureReasonKind {24239988-FB55-4831-9713-30FB47C94C6C} Function of a transformer. TransformerFunctionKind {297A1B39-7634-4195-B755-AF5F6638BC15} Kinds of transformer maintenance.BreakerMaintenanceKind enumerationPossible types of breaker maintenance work. TransformerMaintenanceKind {0671A231-626D-40ac-A402-1F3A48297200} Transformer mesh impedance Deltamodel between transformer ends.The typical case is that this class describes the impedance between two transformer ends pairwise i.e. the cardinalities at both transformer end associations are 1. However in cases where two or more transformer ends are modelled the cardinalities are larger than 1. TransformerMeshImpedance {49FE2028-1AD5-4550-A55A-FA43C4D07C38} Common information captured during transformer inspections andor diagnostics. Note that some properties may be measured through other means and therefore have measurement values in addition to the observed values recorded here. TransformerObservation {19852455-FDDC-4a91-966A-A3D1676F6F93} Transformer components and problem areas which can be the focus of a repair work task.WorkTimeScheduleKind enumerationKind of work schedule. TransformerRepairItemKind {00E45113-3606-4c58-87B4-1F73B01DB811} Transformer star impedance Pimodel that accurately reflects impedance for transformers with 2 or 3 windings. For transformers with 4 or more windings TransformerMeshImpedance class shall be used.For transmission networks use PowerTransformerEnd impedances r r0 x x0 b b0 g and g0. TransformerStarImpedance {35D1EE00-F393-4e93-A01A-B4E816466033} An assembly of two or more coupled windings that transform electrical power between voltage levels. These windings are bound on a common core and placed in the same tank. Transformer tank can be used to model both singlephase and 3phase transformers. TransformerTank {0CAA4373-C2DA-47f6-A18B-9EDC59465FCE} Transformer tank end represents an individual winding for unbalanced models or for transformer tanks connected into a bank and bank is modelled with the PowerTransformer. TransformerTankEnd {7CAE4704-5B8C-4ad5-B3B1-6ECD141F8A09} Set of transformer tank data from an equipment library. TransformerTankInfo {C4D8C511-0532-4ac2-8888-61C0D77D4BE7} Test result for transformer ends such as shortcircuit opencircuit excitation or noload test. TransformerTest {6882227B-F7AD-48fd-A7C6-9C6A08A41979} This class models the transmission either a transmission interface or a PORPOD pair capacity including Total Transfer Capacity TTC Operating Transfer Capacity OTC and Capacity Benefit Margin CBM. TransmissionCapacity {2F86A45A-5879-4e81-A18E-AC2BE1406190} A corridor containing one or more rights of way TransmissionCorridor {E5523AA5-47CB-4537-ACC5-E09A4AA0B9D9} This is formally called the branch group ETCTOR entitlement with the inclusion of CVR as ETC. This could be also used to represent the TR entitlement on a PORPOD. TransmissionInterfaceRightEntitlement {7B694F5B-4F2B-483e-B5ED-D993101EEF9D} Transmission mode for end device display controls applicable to premises area network PAN devices. TransmissionModeKind {CAB1E8F9-F646-4cd8-BF07-FD26D4021CCF} An electrical connection link or line consisting of one or more parallel transmission elements between two areas of the interconnected electric systems or portions thereof. TransmissionCorridor and TransmissionRightOfWay refer to legal aspects. The TransmissionPath refers to the segments between a TransmissionProviders ServicePoints. TransmissionPath {44B2693F-73B9-4f42-B74F-067D411CDF55} TransmissionProduct {355728E0-DBFF-4ff5-A9DE-28FBAD39E465} Provider of the transmission capacity interconnecting wires between Generation and Consumption required to fulfill and Energy Transactions energy exchange. Posts information for transmission paths and AvailableTransmissionCapacities on a reservation node. Buys and sells its products and services on the same reservation node. TransmissionProvider {C8BC0391-9D15-4c2e-A491-15A73845C406} A transmission reservation is obtained from the OASIS system to reserve transmission for a specified time period transmission path and transmission product. TransmissionReservation {1E49E136-2EDC-45a3-AEB8-345AF93E5F5E} Allows chaining of TransmissionContractRights. Many individual contract rights can be included in the definition of a TransmissionRightChain. A TransmissionRightChain is also defined as a TransmissionContractRight itself. TransmissionRightChain {7211DE22-106C-4bd9-BCF2-51DB34A7FDBC} A collection of transmission lines that are close proximity to each other. TransmissionRightOfWay {3D85EC01-B65A-442a-AECE-5831D6C8BC59} A conditions that can trigger remedial actions. TriggerCondition {D3318288-1811-4c7a-98FC-DB3D4585AC89} A tropical cyclone a subtype of cyclone that forms to the east of 90E in the Southern Hemisphere whose intensity is measured by the Australian tropical cyclone intensity scale. TropicalCycloneAustralia {C5570427-A052-4f94-85C3-410D6F383BEB} Describes the type of Trouble based on customer input. TroubleCallKind {39F12B89-BCAB-47cf-BF3C-D19717A5B4DC} Trouble order sends an incident to a crew to initiate a response to an unplanned outage. TroubleOrder {7C67A635-A909-4e41-82B5-2A786790D362} Kind of trouble reporting. TroubleReportingKind {69FC5C51-2840-4e50-A456-690D9026C079} TroubleTicket {1976402F-5A73-4079-A2B1-0044903352D2} A tsunami tidal wave a long high sea wave caused by an earthquake submarine landslide or other disturbance. Tsunami {47F4C552-1F1C-4a7a-8ACB-40E292598249} Turbine load controller model developed by WECC. This model represents a supervisory turbine load controller that acts to maintain turbine power at a set value by continuous adjustment of the turbine governor speedload reference. This model is intended to represent slow reset outer loop controllers managing the action of the turbine governor. TurbLCFB1 {B04FCA7C-DB3E-4dcc-B991-F9B87BBC1330} Turbinegovernor function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font TurbineGovernorDynamics {C759C48A-48F3-4038-8572-625367012530} Turbinegovernor function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font TurbineGovernorUserDefined {BFEEC272-1EAA-42ec-A831-C332817B296B} Turbine load controller function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font TurbineLoadControllerDynamics {7BB91FE6-FE5C-4ee6-B5BD-B2D092F8AFD9} Turbine load controller function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font TurbineLoadControllerUserDefined {1D2BD586-ADCE-4b08-83FE-60629E28F59F} Catalogue of generic types of assets TypeAsset that may be used for design purposes. It is not associated with a particular manufacturer. TypeAssetCatalogue {1740D770-E84A-42e6-AD51-CA7779A78944} Documentation for a generic material item that may be used for design work and other purposes. Any number of MaterialItems manufactured by various vendors may be used to perform this TypeMaterial.Note that class analagous to AssetModel is not used for material items. This is because in some cases for example a utility sets up a Master material record for a 3 inch long half inch diameter steel bolt and they do not necessarily care what specific supplier is providing the material item. As different vendors are used to supply the part the Stock Code of the material item can stay the same. In other cases each time the vendor changes a new stock code is set up so they can track material used by vendor. Therefore a Material Item Model is not typically needed. TypeMaterial {EC640844-2A38-430d-AF20-D32909547B2A} Standard published by United Kingdom Ministry of Defence. UKMinistryOfDefenceStandard {AAE5D3FA-5C3A-4740-8495-D6E351A88263} List of editions for UK Ministry of Defence standards. UKMinistryOfDefenceStandardEditionKind {6C7BC949-58D1-43e0-9935-E3FB228569E3} List of UK Ministry of Defence standards. UKMinistryofDefenceStandardKind {535F510B-6100-4199-AFBB-7A73F47557BF} UOMType {097BE75E-CE72-4123-A21B-4E5235E281EB} Umode {890AA3BA-102B-4715-97D0-14F0B32EA8B8} UnavailabilityScheduleDependency {E80A0296-8D99-477a-B80C-843C9ACD52D8} Relevant switching action for supporting the availability or unavailability plans. This could open or close a switch that is not directly connected to the unavailable equipment . UnavailabilitySwitchAction {C46CA7EF-4F22-4fb4-B39C-F71193CAE3AE} A schedule of unavailability for one or more specified equipment that need to follow the same scheduling periods. UnavailablitySchedule {0495DBAE-5061-4469-954B-91269347261E} The type of uncertainty for a reading. UncertaintyKind {1CFCF12A-F6AE-4d4e-82F5-3B2358D2340D} Simplified type UEL2 underexcitation limiter. This model can be derived from UnderexcLimIEEE2. The limit characteristic look up table is a single straightline the same as UnderexcLimIEEE2 see Figure 10.4 p 32 IEEE 421.52005 Section 10.2. UnderexcLim2Simplified {C334B6E0-A80B-4211-BE69-4B7D894E379F} Type UEL1 model which has a circular limit boundary when plotted in terms of machine reactive power vs. real power output.Reference IEEE UEL1 421.52005 10.1. UnderexcLimIEEE1 {8B14239E-961A-4d9a-817F-2F67CE6CDBC7} Type UEL2 underexcitation limiter which has either a straightline or multisegment characteristic when plotted in terms of machine reactive power output vs. real power output.Reference IEEE UEL2 421.52005 10.2 limit characteristic lookup table shown in Figure 10.4 p 32. UnderexcLimIEEE2 {B375402B-97CA-4cb0-8481-5B4BAD2DC234} font color0f0f0fAllisChalmers minimum excitation limiter.font UnderexcLimX1 {15AF875B-D1DA-4f94-9694-AB5C0F490BB0} font color0f0f0fWestinghouse minimum excitation limiter.font UnderexcLimX2 {23F73DA8-DC29-4079-8E17-C845792E00C6} Underexcitation limiter function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font UnderexcitationLimiterDynamics {C765F8F2-EACC-46ac-8EC1-62B38E9A38FF} Underexcitation limiter function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font UnderexcitationLimiterUserDefined {C6808F8C-2144-452e-99CD-774D24191F97} Underground structure. UndergroundStructure {09077FDE-DEED-46be-AC7E-1C70E6EB9A49} Kind of underground structure. UndergroundStructureKind {328E2139-78D6-4b24-BA0D-486D58516712} The identification of the unit name for the time series quantities. Unit {B6A71106-5272-4bca-9E7D-136D2278B311} Resource status at the end of a given clearing period. UnitInitialConditions {80C061E1-02EC-485d-B2C1-D45841DB65BD} The unit multipliers defined for the CIM. When applied to unit symbols the unit symbol is treated as a derived unit. Regardless of the contents of the unit symbol text the unit symbol shall be treated as if it were a singlecharacter unit symbol. Unit symbols should not contain multipliers and it should be left to the multiplier to define the multiple for an entire data type. For example if a unit symbol is m2Pers and the multiplier is k then the value is km2s and the multiplier applies to the entire final value not to any individual part of the value. This can be conceptualized by substituting a derived unit symbol for the unit type. If one imagines that the symbol represents the derived unit m2Pers then applying the multiplier k can be conceptualized simply as k.For example the SI unit for mass is kg and not g. If the unit symbol is defined as kg then the multiplier is applied to kg as a whole and does not replace the k in front of the g. In this case the multiplier of m would be used with the unit symbol of kg to represent one gram. As a text string this violates the instructions in IEC 800001. However because the unit symbol in CIM is treated as a derived unit instead of as an SI unit it makes more sense to conceptualize the kg as if it were replaced by one of the proposed replacements for the SI mass symbol. If one imagines that the kg were replaced by a symbol then it is easier to conceptualize the multiplier m as creating the proper unit m and not the forbidden unit mkg. UnitMultiplier {DC62CC93-2E3F-4b9c-9C81-C84C30A6C67D} Unit regulation kind. UnitRegulationKind {8A931678-F5F6-4de3-BCAD-4CA1E454766B} The derived units defined for usage in the CIM. In some cases the derived unit is equal to an SI unit. Whenever possible the standard derived symbol is used instead of the formula for the derived unit. For example the unit symbol Farad is defined as F instead of CPerV. In cases where a standard symbol does not exist for a derived unit the formula for the unit is used as the unit symbol. For example density does not have a standard symbol and so it is represented as kgPerm3. With the exception of the kg which is an SI unit the unit symbols do not contain multipliers and therefore represent the base derived unit to which a multiplier can be applied as a whole. Every unit symbol is treated as an unparseable text as if it were a singleletter symbol. The meaning of each unit symbol is defined by the accompanying descriptive text and not by the text contents of the unit symbol.To allow the widest possible range of serializations without requiring special character handling several substitutions are made which deviate from the format described in IEC 800001. The division symbol is replaced by the letters Per. Exponents are written in plain text after the unit as m3 instead of being formatted as m with a superscript of 3 or introducing a symbol as in m3. The degree symbol is replaced with the letters deg. Any clarification of the meaning for a substitution is included in the description for the unit symbol.NonSI units are included in list of unit symbols to allow sources of data to be correctly labelled with their nonSI units for example a GPS sensor that is reporting numbers that represent feet instead of meters. This allows software to use the unit symbol information correctly convert and scale the raw data of those sources into SIbased units. The integer values are used for harmonization with IEC 61850. UnitSymbol {80012160-A038-43b5-BA6F-9862E525518C} Combined CycleGas TurbineHydro TurbineOtherPhotovoltaicHydro PumpTurbineReciprocating EngineSteam TurbineSynchronous CondenserWind Turbine UnitType {047F37B4-5A6D-43a9-A632-0262342CD67F} MWFLAG UnitTypeEMS {C94C3321-078D-4827-9FF7-C68971BF0294} Document describing the consequence of an unplanned outage in a part of the electrical network. For the purposes of this model an unplanned outage refers to a state where energy is not delivered such as customers out of service a street light is not served etc.A unplanned outage may be created upon impacts the SAIDI calculation a breaker trip a fault indicator status change a meter event indicating customer outage a reception of one or more customer trouble calls or an operator command reflecting information obtained from the field crew.Outage restoration may be performed using a switching plan which complements the outage information with detailed switching activities including the relationship to the crew and work. UnplannedOutage {7E6D39E3-90B7-419f-9A40-A63CEA976DE4} The way material and assets are used to perform a certain type of work task. The way is described in text in the inheritied description attribute. Usage {D7436092-8424-48ae-A4A5-CDD1D549CD31} Logical or physical point in the network to which readings or events may be attributed. Used at the place where a physical or virtual meter may be located however it is not required that a meter be present. UsagePoint {54796D9B-C2B0-4186-99CB-70E4CEF64C85} State of the usage point with respect to connection to the network. UsagePointConnectedKind {28D01EAC-4704-4a35-8584-9D85CAAB9128} Abstraction for management of group communications within a twoway AMR system or the data for a group of related usage points. Commands can be issued to all of the usage points that belong to a usage point group using a defined group address and the underlying AMR communication infrastructure. UsagePointGroup {A13F73A0-CF45-42eb-8CDD-A7D37F059989} Location of an individual usage point. UsagePointLocation {355DF23F-F5D0-43f8-A206-1831971FB617} Generic namevalue pair class with optional sequence number and units for value can be used to model parts of information exchange when concrete types are not known in advance. UserAttribute {33A9E156-1160-4c87-B9BC-EF96C09A6BFB} IEEE voltage adjuster which is used to represent the voltage adjuster in either a power factor or VAr control system.Reference IEEE 421.52005 11.1. VAdjIEEE {C517D5B9-8DE4-4809-A2CC-2FA6902EDBCD} font color0f0f0fTerminal voltage transducer and load compensator as defined in IEEE 421.52005 4. This model is common to all excitation system models described in the IEEE Standard. fontfont color0f0f0fParameter detailsfontollifont color0f0f0fIf iRci and iXci are set to zero the lfontoad compensation is not employed and the behaviour is as a simple sensing circuit.liololliIf all parameters iRci iXci and iTri are set to zero the standard model VCompIEEEType1 is bypassed.liolReference IEEE 421.52005 4. VCompIEEEType1 {58FEC809-4186-40e8-AFE8-88EE546426C2} font color0f0f0fTerminal voltage transducer and load compensator as defined in IEEE 421.52005 4. This model is designed to cover the following types of compensation fontullifont color0f0f0freactive droopfontlilifont color0f0f0ftransformerdrop or linedrop compensationfontlilifont color0f0f0freactive differential compensation known also as crosscurrent compensation.fontliulfont color0f0f0fReference IEEE 421.52005 4.font VCompIEEEType2 {4B0B8BCB-A18C-4ad3-BCA6-8669B3E51D26} VDCOL {01B1712A-A728-40b7-8289-40834537C20A} VSC function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font VSCDynamics {7A75C445-CEA2-4928-8329-51B05093D7B3} Voltage source converter VSC function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font VSCUserDefined {E02C33A5-4F8C-4113-8E95-06FF6BA82E7D} VSCtype1 {3B4C89A8-DD2D-4e68-AB68-EB6320ABD849} Validity for MeasurementValue. Validity {79E0E8FE-0F93-4fa3-B38F-9A8CA893F785} Describes the translation of a set of values into a name and is intendend to facilitate custom translations. Each ValueAliasSet has a name description etc. A specific Measurement may represent a discrete state like Open Closed Intermediate etc. This requires a translation from the MeasurementValue.value number to a string e.g. 0gtInvalid 1gtOpen 2gtClosed 3gtIntermediate. Each ValueToAlias member in ValueAliasSet.Value describe a mapping for one particular value to a name. ValueAliasSet {BBCB7356-E07A-417a-8B1B-0DF35589245D} Describes the translation of one particular value into a name e.g. 1 as Open. ValueToAlias {75778847-1FA9-4c53-9075-68C88D3D2369} Vehicle asset. Vehicle {B7371286-9313-44c8-8D81-3FAD831ACC9B} Usage of a vehicle. VehicleUsageKind {EC6DF29B-5A61-4d44-96D8-6DD0D5D4DFB8} The entity that owns the point of sale and contracts with the cashier to receipt payments and vend tokens using the payment system. The vendor has a private contract with and is managed by the merchant which is a type of organisation. The vendor is accountable to the merchant for revenue collected and the merchant is in turn accountable to the supplier. Vendor {F66E6B41-82E4-4a55-AABC-14660887E4A6} The operating shift for a vendor during which the vendor may transact against the merchants account. It aggregates transactions and receipts during the shift and periodically debits a merchant account. The totals in vendor shift should always be the sum of totals aggregated in all cashier shifts that were open under the particular vendor shift. VendorShift {7B733E0A-EB0F-4e94-B638-9B140A883587} Verification of a switch position or other condition as a switching step VerificationAction {D7D96493-B36A-45b9-9FC4-D765897756EF} This is the version for a group of devices or objects. This could be used to track the version for any group of objects or devices over time. For example for a DERGroup the requesting system may want to get the details of a specific version of a DERGroup. Version {2CE9983F-D902-48d7-859B-398F47403ACD} A type of limit that indicates if it is enforced and through association the organisation responsible for setting the limit. ViolationLimit {77CA79D6-C66C-4a28-9AC8-7779395E8416} Layers are typically used for grouping diagram objects according to themes and scales. Themes are used to display or hide certain information e.g. lakes borders while scales are used for hiding or displaying information depending on the current zoom level hide text when it is too small to be read or when it exceeds the screen size. This is also called decluttering.CIM based graphics exchange supports an mn relationship between diagram objects and layers. The importing system shall convert an mn case into an appropriate 1n representation if the importing system does not support mn. VisibilityLayer {8EE633AA-3247-439f-BD39-59D924061A0B} An ash cloud formed as a result of a volcanic eruption. VolcanicAshCloud {162DBE7F-3666-4598-AB70-05EA04A35213} Electrical voltage can be both AC and DC. Voltage {233C330A-11B8-4705-879C-5497380F1D82} Voltage adjuster function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font VoltageAdjusterDynamics {89A3B646-0C4E-4f77-8B82-4C638EE1A451} font color0f0f0fVoltage adjusterfont function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font VoltageAdjusterUserDefined {A9B4A076-6A4F-4205-B30A-7B73D241A06A} Voltage compensator function block whose behaviour is described by reference to a standard model font color0f0f0for by definition of a userdefined model.font VoltageCompensatorDynamics {E0CF51AF-D694-4e22-8FBA-9E7B9A78FA31} Voltage compensator function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font VoltageCompensatorUserDefined {683A0B24-E578-4171-A729-487C76F86BEF} An area of the power system network which is defined for secondary voltage control purposes. A voltage control zone consists of a collection of substations with a designated bus bar section whose voltage will be controlled. VoltageControlZone {709A85C2-97B8-431c-A661-FB83BDEBF933} A collection of equipment at one common system voltage forming a switchgear. The equipment typically consists of breakers busbars instrumentation control regulation and protection devices as well as assemblies of all these. VoltageLevel {B147BAEA-7339-406b-A8C3-47F85EA0E82A} Operational limit applied to voltage.The use of operational VoltageLimit is preferred instead of limits defined at VoltageLevel. The operational VoltageLimits are used if present. VoltageLimit {9D49B294-C5CA-4145-BE42-437419517604} Voltage variation with reactive power. VoltagePerReactivePower {00D99B0C-4D20-43b7-AFA4-B0F9746CFE74} Volume. Volume {20E0B5CF-6DA4-452c-A366-CBE9FC2DF962} Volume per time. VolumeFlowRate {0EFCC366-353D-41d8-983D-E16E170F716A} The PQ capability curve for a voltage source converter with P on Xaxis and Qmin and Qmax on Y1axis and Y2axis. VsCapabilityCurve {64F5C25B-18FF-4bb5-AA4C-F66F8EE815D5} DC side of the voltage source converter VSC. VsConverter {D3B18BC2-AB54-475c-A731-6EBA3D738BF7} Types applicable to the control of real power andor DC voltage by voltage source converter. VsPpccControlKind {AE461FFC-B580-42ce-8520-39C15BCA721F} Kind of reactive power control at point of common coupling for a voltage source converter. VsQpccControlKind {082505D6-AAE1-42a4-9E62-70710BAF79D6} Standard published by Westinghouse a WEP Westinghouse Engineering Procedure. WEPStandard {4271B466-ED80-4d6a-BAA8-2C21B2562651} List of editions for WEP standards. WEPStandardEditionKind {804116AA-E77C-415c-8854-717DB54778DA} List of WEP standards. WEPStandardKind {856A7623-B7CE-4d2a-8E27-9FE8E5DAF69C} Reservoir water level referred to a given datum such as mean sea level. WaterLevel {97337107-69C4-4b94-B996-1375EF171312} Line traps are devices that impede high frequency power line carrier signals yet present a negligible impedance at the main power frequency. WaveTrap {3519E53B-C18B-48f6-9E29-18D73223B91B} Kinds of weather conditions. WeatherCodeKind {3EC746A3-C1F6-4e58-9967-D7CF8177C57A} This represents a source of ambient temperature. WeatherStation {122DAA6F-E5F6-43e0-9E7D-5ECC985513B7} Counter party in a wheeling transaction. WheelingCounterParty {6901C2B7-81B7-4efd-984D-F43E4F6AB1C3} A unique identifier of a wheeling transaction. A wheeling transaction is a balanced Energy exchange among Supply and Demand Resources.This schedule is assocated with the hourly parameters in a resource bid. WheelingReferenceSchedule {310951F0-7FFD-4314-988D-795F083243A1} A whirlpool a rapidly rotating mass of water in a river or sea into which objects may be drawn typically caused by the meeting of conflicting currents. Whirlpool {1F450F50-4C54-40b3-B516-B813380A59A1} Constant aerodynamic torque model which assumes that the aerodynamic torque is constant.Reference IEC 614002712015 5.6.1.1. WindAeroConstIEC {383DDCA3-2DB5-4005-9AD9-ED86EB3FDCC5} Onedimensional aerodynamic model. Reference IEC 614002712015 5.6.1.2. WindAeroOneDimIEC {E1709164-3A33-4153-A521-C9D9096FE066} Twodimensional aerodynamic model. Reference IEC 614002712015 5.6.1.3. WindAeroTwoDimIEC {11B60FC6-8301-4c1a-90A8-2088A2DC11F0} Current limitation model. The current limitation model combines the physical limits and the control limits.Reference IEC 614002712015 5.6.5.8. WindContCurrLimIEC {F8C470F8-1D2E-480b-90C1-01A9084B5231} P control model type 3.Reference IEC 614002712015 5.6.5.4. WindContPType3IEC {8C54657E-6009-43ee-9D5B-27347C81C160} P control model type 4A.Reference IEC 614002712015 5.6.5.5. WindContPType4aIEC {517C136D-F29A-4078-A451-70A4EF1CA1B5} P control model type 4B.Reference IEC 614002712015 5.6.5.6. WindContPType4bIEC {1735A7CB-F76E-413d-97E8-6425A1C86BE5} Pitch angle control model.Reference IEC 614002712015 5.6.5.2. WindContPitchAngleIEC {371F797D-6704-46b0-88C0-ED38AE045309} Q control model.Reference IEC 614002712015 5.6.5.7. WindContQIEC {D845C466-FD3D-4777-A5D9-0A4F09CFC513} Constant Q limitation model.Reference IEC 614002712015 5.6.5.9. WindContQLimIEC {0467343B-F045-4055-BC86-B324E456F959} QP and QU limitation model.Reference IEC 614002712015 5.6.5.10. WindContQPQULimIEC {81CC172F-97DA-47a7-9FD3-05DB211DA99D} Rotor resistance control model.Reference IEC 614002712015 5.6.5.3. WindContRotorRIEC {F502B382-DD6B-4ea9-B945-E4DDB050126C} Look up table for the purpose of wind standard models. WindDynamicsLookupTable {E76DF2A3-865B-4280-9AA3-FCE228118FE8} Wind turbine IEC type 1A.Reference IEC 614002712015 5.5.2.2. WindGenTurbineType1aIEC {5FCBDDD3-F7A7-47e9-A373-FF6228EEE7B9} Wind turbine IEC type 1B.Reference IEC 614002712015 5.5.2.3. WindGenTurbineType1bIEC {22011117-A0F2-475f-80B5-9008F7AB29E6} Wind turbine IEC type 2.Reference IEC 614002712015 5.5.3. WindGenTurbineType2IEC {AB2082A1-658B-459c-86F7-E0256B0793F6} Parent class supporting relationships to IEC wind turbines type 3 generator models of IEC type 3A and 3B. WindGenType3IEC {32C4D844-4EB5-4f33-87C4-F382CD72C6E5} IEC type 3A generator set model.Reference IEC 614002712015 5.6.3.2. WindGenType3aIEC {829F160E-1632-4e20-8131-B3A150D7CEDD} IEC type 3B generator set model.Reference IEC 614002712015 5.6.3.3. WindGenType3bIEC {CF018773-CA7C-42eb-9ABB-25B08171749C} IEC type 4 generator set model.Reference IEC 614002712015 5.6.3.4. WindGenType4IEC {69688BAC-2396-4a92-B7A6-F6B224B9AD75} Kind of wind generating unit. WindGenUnitKind {F66917CD-B970-42ec-B82C-3696341AB38C} A wind driven generating unit connected to the grid by means of a rotating machine. May be used to represent a single turbine or an aggregation. WindGeneratingUnit {7B2E09D8-C9AD-4228-B014-0AA2DE3D4BDE} Function of the lookup table. WindLookupTableFunctionKind {6735A5DE-574A-4c0a-BAC1-09CE63D5BB30} Two mass model.Reference IEC 614002712015 5.6.2.1. WindMechIEC {9E677047-A1CF-4e4f-81D6-778E126A0B0C} Pitch control power model.Reference IEC 614002712015 5.6.5.1. WindPitchContPowerIEC {03564493-C833-430f-8DDE-1BC031C171D9} Parent class supporting relationships to wind turbines type 3 and type 4 and wind plant IEC and userdefined wind plants including their control models. WindPlantDynamics {B60295F4-04E6-43e9-BC0E-F91F22664A67} Frequency and active power controller model.Reference IEC 614002712015 Annex D. WindPlantFreqPcontrolIEC {A6A0C6E1-3076-4cef-B5CA-3913BC3C0440} Simplified IEC type plant level model. Reference IEC 614002712015 Annex D. WindPlantIEC {0DBB7A33-19DB-41a4-952D-ECB797036597} Reactive powervoltage controller mode. WindPlantQcontrolModeKind {599D33AA-458E-44cd-958D-CAEF63E8EAA5} Simplified plant voltage and reactive power control model for use with type 3 and type 4 wind turbine models.Reference IEC 614002712015 Annex D. WindPlantReactiveControlIEC {EC65930A-5B76-4f27-921D-4694BCAADDC1} Wind plant function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font WindPlantUserDefined {C79E857A-54BF-441e-AE09-7A1F6C0FBE66} The grid protection model includes protection against over and undervoltage and against over and underfrequency.Reference IEC 614002712015 5.6.6. WindProtectionIEC {C2A06D61-8879-4b9b-A32E-68822308A460} General wind turbine Q control modes iMiisubqGsubii.i WindQcontrolModeKind {3625636B-98D9-4a47-A2D5-04D9EF31A7EA} Reference frame rotation model.Reference IEC 614002712015 5.6.3.5. WindRefFrameRotIEC {88FA754F-33E4-439c-A372-88659F26101D} Parent class supporting relationships to wind turbines type 1 and type 2 and their control models. Generator model for wind turbine of type 1 or type 2 is a standard asynchronous generator model. WindTurbineType1or2Dynamics {EDAC9109-C756-4d3c-8664-FBA520860E3E} Parent class supporting relationships to IEC wind turbines type 1 and type 2 including their control models.Generator model for wind turbine of IEC type 1 or type 2 is a standard asynchronous generator model.Reference IEC 614002712015 5.5.2 and 5.5.3. WindTurbineType1or2IEC {44103F96-CF13-4b64-8875-501A162C4388} Parent class supporting relationships to IEC wind turbines type 3 including their control models. WindTurbineType3IEC {376190F0-3641-4391-A5C7-E7529CC5D0B4} Parent class supporting relationships to wind turbines type 3 and type 4 and wind plant including their control models. WindTurbineType3or4Dynamics {6CF8DB58-B3A5-4e36-994C-F5E48304166C} Parent class supporting relationships to IEC wind turbines type 3 and type 4 including their control models. WindTurbineType3or4IEC {BF659CC1-2596-4e28-AF74-C5177DDE557E} Parent class supporting relationships to IEC wind turbines type 4 including their control models. WindTurbineType4IEC {B2FC2B31-9A83-4262-8192-EA91A2AD1F11} Wind turbine IEC type 4A.Reference IEC 614002712015 5.5.5.2. WindTurbineType4aIEC {1E6625D5-29E9-40db-B610-03E29C878925} Wind turbine IEC type 4B.Reference IEC 614002712015 5.5.5.3. WindTurbineType4bIEC {F255323C-ABF7-4552-B1BB-7C4F99632F6B} Wind type 1 or type 2 function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font WindType1or2UserDefined {71EC7AB7-0780-4ee9-8B53-CB50B548F1B5} Wind type 3 or type 4 function block whose dynamic behaviour is described by font color0f0f0fa userdefined model.font WindType3or4UserDefined {A75BFA1D-33A6-4a88-9203-3BE683D9FD0E} UVRT Q control modes iMiisubqUVRTsubii.i WindUVRTQcontrolModeKind {74722AE7-62E4-42de-BC4A-5E39E2D3A666} Winding connection type. WindingConnection {FF3816E1-1CFE-4051-9F75-0F3E94DABAFB} Winding insulation condition as a result of a test. WindingInsulation {465EC854-7E59-4f11-99E9-A6D9FBA7522B} Insulation kind for windings. WindingInsulationKind {7EC6DA40-F14F-446d-8BFD-CCA4C712C76D} Describes the construction of a multiconductor wire.NOTE period missing. WireAssemblyInfo {7806189A-6D8F-4c2c-84A1-2C4EBF0C33A7} Wire data that can be specified per line segment phase or for the line segment as a whole in case its phases all have the same wire characteristics. WireInfo {4C4D8C3D-A5C2-4fec-B9AF-1E5CDB329B44} Kind of wire insulation. WireInsulationKind {5DEE00A8-4B14-4375-95B6-F07914121D9E} Kind of wire material. WireMaterialKind {79C6A256-4E46-4717-9E2F-BBB1984DB9D5} Information on a wire carrying a single phase. WirePhaseInfo {D8FFDAE8-943B-4f6f-B04F-07AB06B7E75E} Identification spacing and configuration of the wires of a conductor with respect to a structure. WirePosition {B62996D7-5A21-437d-9C1C-FCC061733196} A two terminal and power conducting device of negligible impedance and length represented as zero impedance device that can be used to connect auxiliary equipment to its terminals. WireSegment {56BC76FE-5834-43c3-A34B-B9749293629D} Represents a single wire of an alternating current wire segment. WireSegmentPhase {91BE148F-E7B0-4687-B275-4A9FF1797051} Wire spacing data that associates multiple wire positions with the line segment and allows to calculate line segment impedances. Number of phases can be derived from the number of associated wire positions whose phase is not neutral. WireSpacingInfo {B035BD42-43E8-49f5-9685-B4ECF92364A4} Kind of wire usage. WireUsageKind {670B1BC7-ED86-4b0a-99A9-5233357BB560} Document used to request initiate track and record work. Work {BBD91857-52A1-4304-AC16-27142B5B76FB} Kinds of activities to be performed on a Compatible Unit. WorkActionKind {20BAC52F-3C56-468a-B36F-0EBD262D55D9} Records information about the status of work or work task at a point in time. WorkActivityRecord {3EF37F50-3992-4300-A522-C3799AEA62EE} Asset used to perform work. WorkAsset {D6ADD1A2-0860-4d9d-AEDC-78818C208396} Billing information for work performed for the customer. The history of Work Billing Info Invoices and Payments is to be maintained in associated ActivityRecords. WorkBillingInfo {259E88DB-BC1E-460c-93C8-A033E1E5F1BD} A collection of all of the individual cost items collected from multiple sources. WorkCostDetail {9EC4A363-1D2C-4ecf-AD53-D7122EA5FC4F} A roll up by cost type for the entire cost of a work order. For example total labor. WorkCostSummary {4A747178-90E7-4b6a-9DCD-44FC59138A34} Shadow class for Document to isolate subclassing from this package. If any subclass gets normative and needs inheritance it will inherit directly from Document. WorkDocument {CE72B804-8E27-48ac-8A4D-F08A8BF57095} A predefined set of work steps for a given type of work. WorkFlowStep {41A4996B-E85F-48bb-9849-706FA0E7BDB7} Shadow class for IdentifiedObject to isolate subclassing from this package. If any subclass gets normative and needs inheritance it will inherit directly from IdentifiedObject. WorkIdentifiedObject {E405EB71-441E-4a19-BE96-831EA211FD6F} Kinds of work. WorkKind {51D116FE-611A-4f90-BA0B-96901E106AE3} Information about a particular location for various forms of work. WorkLocation {CFEB5DD5-B1F3-4dc1-8312-174824017CC9} Kind of status specific to work. WorkStatusKind {AA715820-3F71-45a6-9E21-B8F331C03999} A task within a set of work. WorkTask {E374758E-4AC0-4b81-9D2E-D56E1D8C5F50} Kinds of work tasks. WorkTaskKind {0485332B-3E0E-44c5-ADC6-4808216558DD} Time schedule specific to work. WorkTimeSchedule {151098F5-3E82-403f-89F2-3D53C5DF65E7} Kind of work schedule. WorkTimeScheduleKind {0265E52A-D5D6-43bf-8ABA-854FECBB9692} Used as a flag set to Yes or No. YesNo {7D3890C4-A74E-4e42-9493-07D941668D9C} Area divided off from other areas. It may be part of the electrical network a land area where special restrictions apply weather areas etc. For weather it is an area where a set of relatively homogenous weather measurements apply. Zone {23655D84-D21F-4411-9083-8AE7916DDA1F} Kind of zone. ZoneKind {58B3E8B9-CC93-4616-A231-BE1178D76314} zone type ZoneType {31C02A52-C9D6-4f4f-A0CD-DC7072BFD643} S SchedulingP Pricing runTypeCAISO {C308C5FD-C74E-449c-848B-CDF8778016B6} SHUT_DOWN {84E9D518-0EF0-4c46-860D-BAE56EBC1837} START_UP {5486F5C0-B53D-432f-8564-363A0F7FEFD4} FIXED_CONSTRAINT {E27B575E-604C-4bdc-818C-BC4B914DFFA0} MAX_CONSTRAINT {F11340C3-A991-4c3d-ACEB-467D35AB5870} MIN_CONSTRAINT {0D13000E-6938-4252-AF6F-4F41031EA7DF} 01 standard edition. 01 {B80D7E77-038B-4f86-AAC6-C26DCFCDFE63} 01e1 standard edition. 01e1 {547CACFA-AE53-445c-9706-44F26B1B69BA} 02 standard edition. 02 {CC5B70F3-1A65-496b-827B-38CD5CC54FD1} 02a standard edition. 02a {24756ABA-07F2-4b85-ABE4-B037FF6EFB73} 02b standard edition. 02b {CF915DA3-500B-49bf-8411-21ECA901E6BD} 02e1 standard edition. 02e1 {DAB74175-5F48-468e-94C7-D07EA3386A4E} 03 standard edition. 03 {1284187C-0C77-48ec-B47B-1E78F816FEE3} 03a standard edition. 03a {7D20D562-285D-4fd5-84E5-20E663410634} 04 standard edition. 04 {92CB997D-36E8-46b0-BE5E-63CD43DA85C6} 04a standard edition. 04a {4E9AF060-E2DD-4a32-8253-616C0C300719} 04ae1 standard edition. 04ae1 {60F1113C-C74C-4d74-A692-EC9884AC541C} 04e1 standard edition. 04e1 {4C1FDD18-DF21-4c2e-A4FC-8A5194F66313} 04e2 standard edition. 04e2 {0F5E2528-E2ED-47d1-9DE2-E792C46E74D3} 05 standard edition. 05 {E692974C-6BFB-432e-97E5-D4F5853FAB52} 05a standard edition. 05a {D1DCB59F-D6F7-422b-A6A7-8514A321E743} 06 standard edition. 06 {0C86EFCA-781B-4a7f-9D5F-11D70F12E1A1} 07 standard edition. 07 {BAACED6C-A32A-4850-BA14-618BA6F80790} 08 standard edition. 08 {3748265A-FDA0-40b0-91F1-7876AA50A586} 08e1 standard edition. 08e1 {0F2B9507-6F2B-482b-9537-610A11AC6082} 09 standard edition. 09 {6CA8E970-C8D5-4c4d-A0BC-491208163B8B} 10 standard edition. 10 {BE0A25DB-74EF-4357-9CE9-756D92E67A24} 10a standard edition. 10a {D054A828-886D-4166-9161-334826F2C07D} 11 standard edition. 11 {3E940072-CEB6-4912-B65E-67A30C519454} 11a standard edition. 11a {1262688E-0F9C-4a92-9E5A-0B93AC21A76B} 12 standard edition. 12 {A8FA5C2F-38F6-4142-8E72-65D41B219CD8} 12a standard edition. 12a {E84C7B7C-C2F3-4729-AD2E-420C70A2C547} 12b standard edition. 12b {221DC14C-72C4-4894-A637-5F22A24BED6D} 13 standard edition. 13 {48A4934B-9067-486b-9C5A-11E7AF36E548} 13e1 standard edition. 13e1 {3718D436-D87F-4b64-B797-7B4AFE418E60} 14 standard edition. 14 {61302FE9-D016-40f7-A310-01E61DE66AB6} 14a standard edition. 14a {A48959D9-7755-4c68-B204-BC3E38849964} 14e1 standard edition. 14e1 {D83C3960-C91F-44ef-8684-9EEEDD6FBFB7} 14e2 standard edition. 14e2 {3E597D0E-5B8D-42de-AAE2-6ECF40862610} 15 standard edition. 15 {123F42EB-5D49-4a21-9258-009A9863AD95} 15a standard edition. 15a {0D89D8ED-2C87-43d7-8880-4A8D41E730BC} 65 standard edition. 65 {54A78FE5-DAA3-4e79-B088-4414E6A754CC} 71 standard edition. 71 {69DD9820-2BFC-427a-907F-B16A2D2EC433} 74 standard edition. 74 {49917246-D240-4e11-B350-F0A991624D57} 80e1 standard edition. 80e1 {48BAA2A9-E851-4a2f-B55C-86B3AD74FD37} 82 standard edition. 82 {EBD9656E-1C69-4171-A1BD-36E8ABA8D61B} 85 standard edition. 85 {1FC6B816-D0F7-4742-A337-9D8F6B385F62} 87e1 standard edition. 87e1 {ADBB3502-F42A-4d53-B37B-C21F203ECF0F} 88 standard edition. 88 {4AA005BE-4D18-419e-BF8D-3C0A287A2C02} 90e1 standard edition. 90e1 {F7AD6EAC-78F2-447c-9DB4-8AC4D8EA40CD} 91 standard edition. 91 {499240D8-74CA-4845-B5AD-128C07E281E4} 92 standard edition. 92 {9F714487-5619-4f8a-8C9D-B341F4455EC5} 94 standard edition. 94 {F82C808B-E574-4420-B494-83BCB350297D} 94e1 standard edition. 94e1 {872D4963-D962-4d2f-B173-9540FF39ED96} 95 standard edition. 95 {F660D7A2-E8BF-42eb-97B8-2D76B859878E} 96 standard edition. 96 {60E37299-5F60-461e-90B8-FE3999BBC01B} 96a standard edition. 96a {AECE6E97-279C-48a8-A042-F8E9521FAEED} 96e1 standard edition. 96e1 {BC789993-A3AC-401d-AFD4-BE1AA7CE3531} 97 standard edition. 97 {C6236D3F-F457-44b0-81E6-726637B61A9F} 97a standard edition. 97a {E58E931A-8AA1-4973-B510-2EFC5B31B009} 98 standard edition. 98 {63471520-3CA9-490a-BF67-163FC7AF5007} 98a standard edition. 98a {D1861806-824C-4722-A5F5-4A8AFA284E05} 99 standard edition. 99 {51A57EFC-8C94-42c8-80F5-40AB95A7DBF4} 99a standard edition. 99a {BBD4B265-7825-4d9c-8063-79481D451E0F} 99e1 standard edition. 99e1 {CDEAC077-330A-4781-A86A-A3F3BC5A3CA5} 99e2 standard edition. 99e2 {7AEEED05-DE64-4663-8DFB-76B75C8916C7} No kind of standard. none {F9E578FF-3D32-465a-85F5-26AB5E3229EE} Unknown kind of standard. unknown {B8FCE4EA-71A8-4f96-A49D-EF4D348B7AD6} Standard Test Method for Specific Resistance Resistivity of Electrical Insulating Liquids. D1169 {BDA838E2-BC16-4722-9DE7-A01FD0A23565} Standard Test Method for Corrosive Sulfur in Electrical Insulating Oils. D1275 {520B1325-2E8E-46e5-BDD0-E55ED98D7E37} Standard Test Method for Density Relative Density or API Gravity of Crude Petroleum and Liquid Petroleum Products by Hydrometer Method orStandard Test Method for Density Relative Density Specific Gravity or API Gravity of Crude Petroleum and Liquid Petroleum Products by Hydrometer Method. D1298 {45EBAA7D-1281-4d37-ACB9-31D90A69ECAC} Standard Test Method for Dielectric Breakdown Voltage and Dielectric Strength of Solid Electrical Insulating Materials at Commercial Power Frequencies. D149 {4587F9EE-F3E2-4065-A4DC-608C55238E1D} Standard Test Method for ASTM Color of Petroleum Products ASTM Color Scale. D1500 {E4DED850-65F5-42ca-B163-EF6E59EEA9CB} Standard Test Method for Visual Examination of Used Electrical Insulating Oils of Petroleum Origin in the Field. D1524 {413C5720-2394-42df-9875-A50B3D7A2353} Standard Test Method for Water in Insulating Liquids by Coulometric Karl Fischer Titration. D1533 {C510C0FA-D50A-4efa-B5F0-ECF7962EC423} Standard Test Method for Dielectric Breakdown Voltage of Insulating Liquids Using VDE Electrodes. D1816 {BF78B213-9EE7-40fb-973D-8C232FE01265} Standard Test Methods for Water Vapor Content of Electrical Insulating Gases by Measurement of Dew Point. D2029 {126DBAFD-7B91-47e3-80D5-75496545A4AA} Standard Test Method for Oxidation Stability of Inhibited Mineral Insulating Oil by Pressure Vessel. D2112 {FFAF595B-6824-481f-84F9-3A951742C8A8} Standard Test Method for Color of Clear Electrical Insulating Liquids PlatinumCobalt Scale. D2129 {A3D11146-E01D-4664-904F-7C3ECED41733} Standard Practice for Calculating CarbonType Composition of Insulating Oils of Petroleum Origin orStandard Test Method for CarbonType Composition of Insulating Oils of Petroleum Origin. D2140 {D23659F8-51E1-441d-96DE-C6666094A564} Standard Practices for Examination of Electrical Insulating Oils by Infrared Absorption orStandard Test Methods for Examination of Electrical Insulating Oils by Infrared Absorption. D2144 {B6C6D2AF-6EE0-41b8-979F-10D9DD573E8F} Standard Test Method for 26ditertButyl pCresol and 26ditertButyl Phenol in Electrical Insulating Oil by Infrared Absorption orStandard Test Method for 26DitertiaryButyl Para Cresol and 26DitertiaryButyl Phenol in Electrical Insulating Oil by Infrared Absorption. D2668 {00504546-78F4-4891-BCE7-0B33305176C7} Standard Test Method for Analysis of Gases Dissolved in Electrical Insulating Oil by Gas Chromatography. D3612 {31EB35FE-B204-4b24-BE81-5D861128714B} Standard Test Method for Density Relative Density and API Gravity of Liquids by Digital Density Meter orStandard Test Method for Density and Relative Density of Liquids by Digital Density Meter. D4052 {24BDA1F0-BD2B-4b27-930C-2268930BA2DA} Standard Test Method for Analysis of Polychlorinated Biphenyls in Insulating Liquids by Gas Chromatography. D4059 {97CA1A7E-C08F-402a-A756-990C09EFABF5} Standard Test Method of Measuring Humidity with CooledSurface Condensation DewPoint Hygrometer. D4230 {2BAE4CD6-3C3C-492e-920A-815BBC11D42C} Standard Test Method for Measurement of Average Viscometric Degree of Polymerization of New and Aged Electrical Papers and Boards. D4243 {FDBA07BB-B863-48bd-9FA1-F7F4F68C4CBA} Standard Test Method for Kinematic Viscosity of Transparent and Opaque Liquids and Calculation of Dynamic Viscosity orStandard Method Of Test For Viscosity Of Transparent And Opaque Liquids Kinematic And Dynamic Viscosities. D445 {3A1116AB-EED3-41de-81F6-29A76C8B4931} Standard Test Method for Analysis of 26DitertiaryButyl ParaCresol and 26DitertiaryButyl Phenol in Insulating Liquids by Gas Chromatography. D4768 {36F35B66-AADA-4a68-A4DF-DB41B1B8411B} Standard Test Method for Furanic Compounds in Electrical Insulating Liquids by HighPerformance Liquid Chromatography HPLC. D5837 {F7E3CDF0-BD8E-4849-8BE8-8C78CE4AB544} Standard Test Method for Pour Point of Crude Oils. D5853 {75B78622-F1F8-437a-AE68-5C971E3F10D5} Standard Test Method for Pour Point of Petroleum Products Automatic Pressure Pulsing Method. D5949 {3DC6643A-5ACD-4bc8-828D-EF783AE6088E} Standard Test Method for Pour Point of Petroleum Products Automatic Tilt Method. D5950 {54DCD366-AD08-4c33-B507-29C21D51F144} Standard Test Method for Pour Point of Petroleum Products Rotational Method. D5985 {3A3380A0-A124-41f3-9464-BE45CBBDE912} Standard Test Method for Determination of Water in Petroleum Products Lubricating Oils and Additives by Coulometric Karl Fischer Titration. D6304 {B29E4892-37B8-4d51-9AE7-53FD162B16C4} Standard Test Method for Pour Point of Petroleum Products Automatic Air Pressure Method. D6749 {14D28F29-F833-4846-9732-FE5CF4A62B75} Standard Test Method for Particle Count in Mineral Insulating Oil Using Automatic Optical Particle Counters. D6786 {D36911FD-D1B2-4617-8E45-43F1589026C4} Standard Test Method for Pour Point of Petroleum Products Robotic Tilt Method. D6892 {DAB88866-B01A-4229-A61C-6887D449AC4F} Standard Test Method for Determination of Elements in Insulating Oils by Inductively Coupled Plasma Atomic Emission Spectrometry ICPAES. D7151 {C8221233-0266-4b32-B8C8-9070E62EAFC4} Standard Test Method for No Flow Point and Pour Point of Petroleum Products and Liquid Fuels orStandard Test Method for No Flow Point and Pour Point of Petroleum Products orStandard Test Method for No Flow Point of Petroleum Products. D7346 {B785E03F-52C6-49bd-ADE5-E0869421448B} Standard Test Method for Tensile Properties of Paper and Paperboard Using ConstantRateofElongation Apparatus Withdrawn 2009. D828 {F11EEB75-9C59-4085-A95E-D33523E0362D} Standard Test Method for Dielectric Breakdown Voltage of Insulating Liquids Using Disk Electrodes. D877 {D2E500C9-3440-4f47-8CFA-4EB856E4B5D6} Standard Test Method for Flash and Fire Points by Cleveland Open Cup Tester orStandard Test Method for Flash and Fire Points by Cleveland Open Cup. D92 {B1D58CA7-1194-49fd-8972-E704144B8538} Standard Test Method for Dissipation Factor or Power Factor and Relative Permittivity Dielectric Constant of Electrical Insulating Liquids. D924 {890D0E74-B788-426a-8114-DB5840502C87} Standard Test Methods for Flash Point by PenskyMartens Closed Cup Tester orStandard Test Method for Flash Point by PenskyMartens Closed Tester orStandard Method Of Test For Flash Point by PenskyMartens Closed Tester. D93 {C52F8AE8-DED9-4a99-97D0-5537857DF251} Standard Test Method for Pour Point of Petroleum Products orStandard Test Method for Pour Point of Petroleum Oils. D97 {4022FFDE-786F-411d-ABEA-82DD1E1E1947} Standard Test Method for Acid and Base Number by ColorIndicator Titration. D974 {6D0A2EE6-76A1-4fe1-BCDE-590211676CCB} A timeindependent cumulative quantity much like a bulkQuantity or a latchingQuantity except that the accumulation stops at the maximum or minimum values. When the maximum is reached any additional positive accumulation is discarded but negative accumulation may be accepted thus lowering the counter. Likewise when the negative bound is reached any additional negative accumulation is discarded but positive accumulation is accepted thus increasing the counter. boundedQuantity {32F41A88-A184-42a8-8D52-DF6F1DC51DDA} A value from a register which represents the bulk quantity of a commodity. This quantity is computed as the integral of the commodity usage rate. This value is typically used as the basis for the dial reading at the meter and as a result will roll over upon reaching a maximum dial value. Note 1 With the metering system the rollover behaviour typically implies a rollunder behavior so that the value presented is always a positive value e.g. unsigned integer or positive decimal. However when communicating data between enterprise applications a negative value might occur in a case such as net metering.Note 2 A bulkQuantity refers primarily to the dial reading and not the consumption over a specific period of time. bulkQuantity {399FA930-B42D-43c3-9D07-61AAB6753CD4} The sum of the previous billing period values and the present period value.Note continuousCumulative is commonly used in conjunction with demand and it would represent the cumulative sum of the previous billing period maximum demand values as occurring with each demand reset summed with the present period maximum demand value which has yet to be reset. continuousCumulative {C0ED909E-32CA-458b-ADDC-5C89AF7C5DA2} The sum of the previous billing period values.Note cumulative is commonly used in conjunction with demand. Each demand reset causes the maximum demand value for the present billing period since the last demand reset to accumulate as an accumulative total of all maximum demands. So instead of zeroing the demand register a demand reset has the effect of adding the present maximum demand to this accumulating total. cumulative {BABECDA5-A39C-41ef-A70E-ABAB39A760FD} The difference between the value at the end of the prescribed interval and the beginning of the interval. This is used for incremental interval data. Note One common application would be for load profile data another use might be to report the number of events within an interval such as the number of equipment energisations within the specified period of time. deltaData {DFA6FB19-2A7C-4aab-9A78-753822D67012} As if a needle is swung out on the meter face to a value to indicate the current value.Note An indicating value is typically measured over hundreds of milliseconds or greater or may imply a pusher mechanism to capture a value. Compare this to instantaneous which is measured over a shorter period of time. indicating {3C61E398-3FC4-430c-AB7B-81B42B91BC92} Typically measured over the fastest period of time allowed by the definition of the metric usually milliseconds or tens of milliseconds.Note instantaneous was moved to attribute 3 in Ed.2 of IEC 619689 from attribute 1 in Ed.1 of IEC 619689. instantaneous {238008C2-0A22-40b2-B4EB-6B65C9F67C85} When this description is applied to a metered value it implies that the value is a timeindependent cumulative quantity much like a bulkQuantity except that it latches upon the maximum value upon reaching that value. Any additional accumulation positive or negative is discarded until a reset occurs. Note A latchingQuantity may also occur in the downward direction upon reaching a minimum value. The terms maximum or minimum for aggregate will usually be included when this type of accumulation behaviour is present. When this description is applied to an encoded value UOM Code it implies that the value has one or more bits which are latching. The condition that caused the bit to be set may have long since evaporated.In either case the timestamp that accompanies the value may not coincide with the moment the value was initially set.In both cases a system will need to perform an operation to clear the latched value. latchingQuantity {63214527-EC2F-4b67-88E9-046D41E8ABBD} Not applicable or implied by the unit of measure. none {86370381-DBEA-4802-B068-AB8EEE43D45E} A form of accumulation which is selective with respect to time. Note summation could be considered a specialisation of bulkQuantity as it selectively accumulates pulses over a timing pattern while bulkQuantity accumulates pulses all of the time. summation {D58C159E-28AF-485e-843C-C13FC94067C0} A form of computation which introduces a time delay characteristic to the data value. timeDelay {BD170B22-4CB4-48a7-B7E5-DDC7F329D97B} Cancel a trade. CANCEL {E5EA090F-7915-4c33-89A3-9926F4B6D383} BASELINE {D1E66A1E-075B-4ce0-8057-DCEAA40946FC} NEGOTIATED {E879A569-DF85-4407-A3C1-A268FFD5A54B} The value represents average. average {D0D4CE63-D116-4285-9739-C0E4AA58B9EF} The value represents an amount over which a threshold was exceeded. excess {8E510F94-C290-4a12-B510-E87FA1637768} The fifth highest value observed. fifthMaximum {715C2F7B-E77B-4356-B28C-C12ABB192647} The fourth highest value observed. fourthMaximum {F912DE09-EE7D-470a-8901-9F7B7F441ECF} The value represents a programmed high threshold. highThreshold {278D72B1-F5EC-4af5-BF68-610B6FC54E0A} The value represents a programmed low threshold. lowThreshold {3BB9F9E6-E9EA-46db-B0E4-9656F9788AC1} The highest value observed. maximum {72B3FA61-59DC-4eed-9026-849B0188CEFD} The smallest value observed. minimum {9C51BF89-A4AE-41ed-BC37-0441998A6D06} The nominal value. nominal {68DE4069-31AC-41d5-B7C6-6882B74807FB} Not applicable. none {15C5DB87-83D3-48a5-B2C6-A564FF42979F} The normal value. normal {C4AABDA6-D25C-4e5f-BE44-868E9D58976A} The second highest value observed. secondMaximum {50D29B59-8085-432d-AFD3-6A337CC4DF62} The second smallest value observed. secondMinimum {0D5AC330-E006-4bab-9119-860F67A75A75} The accumulated sum. sum {377B8C36-5568-4a13-A139-2B0A6AF1D18B} The third highest value observed. thirdMaximum {9AE63C4A-2221-419e-9574-B375C7FEE6F2} Appear {4A455840-9ACF-4d86-8007-85E6425AF09D} Disappear {4E9DB412-7B94-456b-8CD7-2F4630042D12} Fleeting {ED3726A3-0E63-455d-9CA8-9571175F118B} ACNG {21F8F7EB-C281-48f7-8C41-272D616EC2F7} BS {D1D8052A-3D26-4695-9D37-420D21ADA516} DAPE {9F362C89-AB7B-46b7-AB15-317834D48406} DASE {1E702837-C1C7-408e-858F-AB916A16950C} ESRT {D4DF1E4C-C4F6-45f1-925A-1A3889268BE8} ESYS {7FA33841-3CA6-464a-8C50-FE273BEA6EE9} ETC {87F640A6-E9E6-4ff5-91BE-CBFCA4DABF9A} HASE {47236E18-B746-4201-B273-AD4E43787154} LMPM {DCB903B7-2BC6-49c3-8F62-61EBF83883FF} MINL {C4556F89-7E5E-40f7-9767-45145FA542FD} MLE {FD2F93D0-0F34-4eb8-8F32-D55E891F0736} MSSLFE {3051EC37-8AA1-4d4d-A4A9-E62A5A06F16F} OE {4E396B39-57D4-4343-8F04-B153081F3611} OTHER {9743082A-BC58-4fb5-A856-96552E49692E} OVGN {64AB4E96-C891-4579-B53F-98ABA034C44E} PE {5111E3ED-E3DC-4632-A459-85BF995A2BD6} RCNG {E69A541C-53E6-4fe9-B6A6-50262891628B} RE {3A1C7ACE-7543-4a9e-ACBB-7F5055AEC98F} RED {022F6657-72DA-4e44-AD52-9F0A7368D2D5} RMRD {04862EAF-DEEA-4237-BBD2-093D21B5F24E} RMRH {FFCCA9BD-CCBD-4675-9DBD-01810EB676B5} RMRR {EC0F9A44-3E0E-4985-9362-C250400F3F8C} RMRS {50C7D5EC-A15D-4e31-862D-31B5A2566313} RMRT {AED689C5-A2F5-4167-BFAC-91C7F07DB352} RSYS {BFE0E28F-5531-47d9-8FA9-21D0F474ECE8} RTSSE {29B92C8B-F463-48e5-955D-ED1118AFF8BD} SDWN {2B517CFB-0DCB-4e9d-865B-252B43DA9B4C} SE {21CC1ADB-3C30-48c9-9E02-6C4992DBA674} SLIC {5A3DCA63-9AA8-439f-8A9A-663CC9E70875} SRE {35F70B21-C8A2-428f-B06E-077D249E11BF} STRT {53EEC3C8-4023-4daa-A227-73ED2C27DBAB} SUMR {C6C5970F-9A9D-4b61-8D58-C44B08430FF5} TCNG {00382BFC-B925-4e25-AE53-E2E16CA8B73C} TEST {4BA981CB-EF29-4bed-A143-53CFC95B7AAF} TOR {C137DBE6-1CBA-48b0-B887-60AC2902221F} VS {EE0E6E12-F7D4-4a49-BB06-3A00B58ADCE2} Usage point is equipped with an AMI capable meter that is not yet currently equipped with a communications module. amiCapable {1A5859D6-149E-4b93-B8B4-09C7E53B57BD} Usage point is equipped with an AMI capable meter however the AMI functionality has been disabled or is not being used. amiDisabled {FD29CB68-66E0-4238-BBB9-0E73322B2292} Usage point is equipped with an operating AMI capable meter and accuracy has been certified for billing purposes. billingApproved {9ADC2417-4D85-4d78-9A54-F2D12C0C1860} Usage point is equipped with an AMI capable meter having communications capability. enabled {CF70448A-6855-42fb-B84E-174152DEA3AE} Usage point is equipped with a non AMI capable meter. nonAmi {E7C2F2B1-6F4B-40de-8199-8E2E77CFFC89} Usage point is not currently equipped with a meter. nonMetered {5B7ACD6E-011F-4530-B4AC-7501C1C94921} Usage point is equipped with an AMI capable meter that is functioning and communicating with the AMI network. operable {1E16365F-8608-4895-9DB5-8A8A60ED8813} Branch Long Term Limit BranchLongTerm {95B28857-7460-4ba8-AD65-1DBADC4E5D00} Branch Medium Term Limit BranchMediumTerm {D0A2C9E4-CDD2-4b0b-85F2-8AA027BFC710} Branch Short Term Limit BranchShortTerm {B0EDA439-C57C-4645-8EE5-3F213D1BD1C7} Voltage High Limit VoltageHigh {6276D8BF-F042-4b6c-A79A-F3FDA624386B} Voltage Low Limit VoltageLow {AE30CEBB-368D-4b60-8B27-4DA0C76CC35F} Equal like comparison operation. eq {093BD8B8-4782-43c5-80EE-CDA6DF2F5F45} Greater or equal comparison operation. ge {90E460DE-C7BB-4ea5-8398-6BB17B135F16} Greater than comparison operation. gt {9CB66A12-F8B9-4abf-B99A-F09E42A6880C} Less or equal comparison operation. le {FB63F810-2A6B-4b69-B1AD-8BE4FF62B22D} Less than comparison operation. lt {76EE8579-DD6C-42c5-A5DD-4EFBAF2BDC64} Not equal unlike comparison operation. ne {2BD79851-4D3E-4d99-81F5-9BFFAD6381EA} Analytic evaluates aging. agingAnalytic {C2C33117-B7FE-4233-A933-7C23B01E520A} Analytic evaluates fault. faultAnalytic {726154C7-E536-4968-9BC0-2C1AAE3A41C5} Analytic evaluates asset health. healthAnalytic {CF0B2DE7-D41E-4d18-97AA-445AF712C110} Analytic evaluates other factor. other {E767E08B-69C9-4d39-9A72-1FD1D6BD22E7} Analytic evaluates need for replacement. replacementAnalytic {13E1F480-805D-4484-A51A-D12C9C37016A} Analytic evaluates risk. riskAnalytic {E6D05734-6D4B-4722-8395-91B557285363} concrete {321FE6AB-4A05-4552-846A-5812C5C10E3B} helix {5BEA99D4-3A23-4d3a-9AFC-EF66531B42AF} multiHelix {F4B063EB-1573-448a-BC5F-9B1F05D0A039} other {50D42452-0CF6-4f6c-B241-B55DF6BF6682} rod {6CB14A47-7404-4c27-975E-9E76888F09ED} screw {FF4B65C4-F75F-4930-8A3F-662E8807A06E} unknown {FD124732-3587-4440-B507-CE77CD9AE702} non spinning reserve NONSPIN {1F9AF23F-8328-432e-B8E6-450957AF41DE} regulation down REGDN {07D5E031-00AC-4ac9-B60A-2290E944EB4C} regulation up REGUP {DC70C300-636C-4397-BD57-19D4B5E74436} spinning reserve SPIN {BD91A884-323A-4402-A0F7-C6D3FD1113B6} Adjacent Control Area ACA {929C183C-EFBC-450a-933E-746946DB1B1E} Aggregate Generation Resource AGR {06596BE2-95DF-41f3-9D14-4DE68BC5F41C} Aggregate Load Resource ALR {71DB6C1C-3866-4277-82F5-DB0A8ADFE06F} Aggregated System Resource ASR {61EE5B26-C05E-4e98-8993-48F336251852} Distributed Energy Resource. DER {21121CED-7CFD-4db1-B54E-D0ADC11B101E} Embedded Control Area ECA {68B130B3-3C87-4d62-B635-5F44FC577725} Load Forecast Zone LFZ {ADD85D8B-E15B-41eb-B16F-A06A870AD8C9} Load TransmissionAccessCharge TAC Group LTAC {725B6D04-0D32-4748-BD8F-BD57C4EFC826} Point of Delivery POD {6FFA71B6-8EC5-4cc5-8FBE-C957B4F17620} Market EnergyAncillary Service Region REG {2CBCD676-5533-4054-93C3-6EAD45B15B6E} RUC Zone RUC {17F6F84D-F24F-4723-A50E-C003DAEF944C} System ZoneRegion SYS {B5F1C6CF-0131-4b9c-85F9-221A7C54D78D} Aggregated Generation AG {8FFFC9D3-5E35-44b7-BBF8-0E30D46C86BF} Bus BUS {CC6C6C72-DD18-4a38-9D82-FCC89ABFCEE8} Control Area CA {191A6CAB-46CA-49bf-9400-FF12C8716B79} Custom Price Zone CPZ {4BF236DB-57B9-46d8-9401-2DD590D4E4EC} Designated Congestion Area DCA {17EBD495-E485-4601-95BD-ED81CEFADD80} Default Price Zone DPZ {5A5F528E-9CA0-4398-91E6-7963F0093285} 500 kV Extra High Voltage aggregate price nodes EHV {8B5CD47A-97D3-499d-A08B-8F8BA9AB64DB} generic aggregation GA {4F379793-6C43-40eb-A3E8-DAD964168374} generic hub GH {E025C7AB-7031-4ff6-87ED-A0355BFC4BA8} Interface INT {63601B12-6E90-4d5f-95E8-A49F9D964869} System Zone SYS {AA6A60BA-12A4-45ee-8A33-CF45DF5C6985} Trading Hub TH {4DB37CC8-C33D-4cad-8F27-1FD96B67976C} Zone ZN {4F3412AC-1108-4b49-9EC4-9A7BE287B633} Indicates that E2Esecurity shall be used in order to allow establishment of an MMS association. endToEndSecure {97B77F60-CAE5-4d9d-9C95-AB0170C985C2} Indicates that an application security shall not be used in order to allow establishment of an MSS association. nonSecure {E4A01C19-4BBC-49f7-98B3-DE9D687226F6} Indicates that the Asecurityprofile as specified in Clause 11 or IEC TS 6235142007 shall be used in order to allow establishment of an MMS association. secure {463A0794-00C8-4643-936D-0949911B70DA} CF Constant Frequency CF {529C9077-53BA-46fb-8587-CC6D29A7CDC4} Constant TieLine CTL {8CC65B96-9CC2-4bb5-9456-02D069DDE91F} Off control OFF {FAE5FD94-9BA9-43b9-A0A7-53A2D8DE4DE0} TieLine Bias TLB {FC6A16C8-19D7-4f0a-A1BE-E5ADA2C20B61} borough {3929CD68-4876-431c-820C-1B35351C339D} county {715CA34A-30C0-41d4-8EB1-2CFA88D71E16} parish {8D29E3D2-4B18-461f-9BF6-B0408BB573CA} serviceArea {DC5E0522-266A-4f4e-A719-68214501E399} state {7339F7DB-5EA8-4cde-858B-A05EF354C5A4} township {CE8703F8-3862-4d29-A177-7CE4D7ABEAD5} ward {4492488F-93F7-4cf0-B2B8-C1433A4704BC} zipcode {12E86C0E-2585-4289-9414-7EFB1E6EB1E5} Failure due to defect. defect {C59D8E34-F7EE-403c-936F-17B7185B78B1} Major failure. major {ED9CC37C-9C83-4058-988F-9980776E9879} Major failure asset needs to be replaced. majorNeedsReplacement {B5B93A54-EFDE-465a-B8D3-2A0AA8686718} Minor failure. minor {BC3805D1-FE7F-47f4-9710-18AA2BCD6381} Failure to carry load. failToCarryLoad {BC8AFBA8-1F26-49d5-BD0F-6E53E1212263} Failure to close. failToClose {6984DA56-F93C-4218-804E-6465E1744568} Failure to interrupt. failToInterrupt {49587DE4-0847-4316-BE98-37DBF87546FC} Failure to open. failToOpen {22A59BDA-8CEC-4ac6-BFC8-958E8D47EA9E} Failure to provide insulation. failToProvideInsulationLevel {4414E83D-12AD-4488-B6BE-0997E9491C13} Group is used for analysis purposes. analysisGroup {84E498AF-1A4C-4996-8640-653AB193FF35} Group is used for compliance purposes. complianceGroup {E4CB5E53-BE1E-4749-A81C-8C2F1A743F50} Group is used for functional purposes for example assets which are grouped together because they are part of a for a particular function such as a group of feeders. functionalGroup {324D043B-837F-47d9-A38C-EDBBF534E336} Group is used for inventory purposes. inventoryGroup {288A0375-4246-42d0-9CFA-ED7550BBF0AA} other {1C1B952C-CE7A-489e-BC8A-38B46AB59C56} Subject to ambient temperature above 38 C. ambientTempAbove38 {E5545CFC-3E9B-41a8-B4F4-4B05E0E28212} Subject to ambient temperature of below 12 C. ambientTempBelowMinus12 {C5731FF5-5B94-4b0e-9C87-EBF1AF2BDE22} Children play in area stray kiteball hazard. childrenAtPlay {EE74DD4C-B4FF-4bd6-8D82-2B65EC8947A7} Fishing in area fishing poleline hazard. fishingArea {923E8E6E-B00D-44fb-A376-93181CB77B65} If other look at type field for more information. other {959A89A0-EF9D-40d4-9F73-F9EF28297FBC} Vegetation growing below asset that may cause problem. vegetation {5AFC3FEF-5B20-42c7-81A5-4250D7C67CA4} Air blast circuit breaker. breakerAirBlastBreaker {64F67AC1-7464-41d9-96A9-8F68298A9CFA} Bulk oil circuit breaker. breakerBulkOilBreaker {204DFF6B-68C0-478b-A1FC-E44EF6C19885} Breaker insulating stack assembly for live tank breaker. breakerInsulatingStackAssembly {245F78CC-F5E6-4fc5-96AE-83CC504ACC89} Minimum oil circuit breaker. breakerMinimumOilBreaker {645468F0-B634-40eb-BE39-2D5B0F2003C1} SF6 dead tank breaker. breakerSF6DeadTankBreaker {FA31EDE3-9827-4133-8E05-83F189129E55} SF6 live tank breaker. breakerSF6LiveTankBreaker {E2DF121F-43C4-4f8e-8927-1521902FA1F8} Breaker tank assembly. breakerTankAssembly {07D76E72-D58C-4c94-8272-5E98825ACAEF} Other type of Asset. The type attribute may provide more details in this case. other {9AB12E93-A9B7-4fe4-9363-D4DDE5D0A3FD} Transformer. transformer {4F356D4E-EA3E-4b2b-A8A8-0E259D7AF287} Transformer tank. transformerTank {009B1A17-21FF-4e85-85BF-925B30FA7431} Asset disposed of. disposedOf {8AF24D67-5AC4-4865-8F81-359F23CE388D} Asset manufactured. manufactured {28F39F7B-52AF-4795-84B8-3330A88D6B81} Asset purchased. purchased {0109C3B7-DEE5-4643-B17F-1DFF433DDC5D} Asset received. received {28D023DE-3DEE-43db-94A5-CA054BBF71A5} Asset retired. retired {3912E1A6-E64B-46ee-881D-1B2D7215888A} Asset model is intended for use in customer substation. customerSubstation {B5F26010-FAE7-4494-8666-D017F621165D} Asset model is intended for use in distribution overhead network. distributionOverhead {6ED2A098-34B2-4370-8738-2BF77D514B48} Asset model is intended for use in underground distribution network. distributionUnderground {1AC16B3C-F46C-45b9-9FF2-BA2C4E280AC7} Other kind of asset model usage. other {CE7FC7BB-7A72-49d5-96E5-80849B98D13D} Asset model is intended for use as streetlight. streetlight {EA2B3AFA-B15E-47f4-81AA-54FA6B763D0C} Asset model is intended for use in substation. substation {F0C50BB4-5DA4-47f5-8243-A1222047C338} Asset model is intended for use in transmission network. transmission {BBDFC966-DE68-442e-B61D-71C565225F24} Usage of the asset model is unknown. unknown {74ED83A2-5135-4e9f-AB90-9C28C5B7795D} Remarks related to a visual exam.Could be used for remarks on oil appearance resulting from visual examination including sediment appearance free water. visualExamRemarks {C1EBE9EB-BFB1-4a23-A66C-8E2B6BFBDC8B} Oil pressure at valve in KPa. oilPressureAtValve {70FCFD40-A97A-4fc6-86C9-17E719AD73E4} Oil temperature at valve in C. oilTemperatureAtValve {0B9E7C36-612D-4653-A9D3-24D93321F96F} The Asynchronous Machine is a generator. generator {E653D495-7583-4d27-A25F-AADBBA7D9B8D} The Asynchronous Machine is a motor. motor {E6162696-2DA3-413f-AA16-9713D25F040B} albedo {F7C31D2F-3FC9-46cc-9287-EB11633B39B8} The temperature measured bfont color0f0f0fy a thermometer exposed to the air in a place sheltered from direct solar radiation. fontAlso known as dry bulb becausefont color0f0f0f the air temperature is indicated by a thermometer not affectefontd by the moisture of the air. ambientTemperature {4FE54B9C-C5AB-4f72-BF51-D59B94B1B910} atmosphericPressure {BC2F397D-79F9-4d3e-9874-38736385F173} ceiling {D7BD1247-0588-4fd1-AF7B-41C06773BB54} The temperature to which air must be cooled at constant pressure and constant watervapor content in order for saturation to occur. In other words it is the temperature at which water vapor starts to condense out of the air. dewPoint {9A65200F-CB0D-4e54-9FC7-60DF77641567} The temperature of how hot it feels like for a given combination of warm air temperature and relative humidity. heatIndex {E889DA88-ABFB-4c66-8396-6128878D7C0B} horizontalVisibility {15E251C6-5E47-4b94-95BA-DDB29EFD683C} humidity {961A04DA-2A6D-4bf8-98B5-7CC5627F033D} ice {14B099E9-1584-40f0-8993-BB26C648A6EE} illuminanceDiffuseHorizontal {3C1CD5F6-1832-48e4-B1F8-B0D2B98E0710} illuminanceDirectNormal {88EED2B0-387B-4cd5-BF84-BC3B6495FBC1} illuminanceGlobalHorizontal {5770A7B8-E33B-4098-A2DB-19FFDE192BB9} irradianceDiffuseHorizonal {CDE68F44-2AEF-4fb7-BAFD-A6BDDDF2CAE2} irradianceDirectNormal {620FA028-98F6-40b4-B4FA-21F0AA1417A7} irradianceExtraTerrestrialHorizontal {ADF07F5C-4E2F-4e02-A523-0E064AFE7432} irradianceExtraTerrestrialVertical {CE2CD05C-77FD-48a7-9790-E601A531EEFF} irradianceGlobalHorizontal {BB71B4FF-D561-4290-9806-C8BB579885C1} luminanceZenith {8BAD88FA-5CDE-49cc-B14E-30AEB55A2F61} precipitation {EED8F27E-A300-4ac2-A1F3-4FE31CCFAE4C} rain {F43421C9-EA43-4bc8-8DA9-C15DA0C2C0C8} skyCoverageOpaque {56E468AF-7A3C-47f6-AD89-A9A39C58B2AD} skyCoverageTotal {DA76CE2B-E30A-43b2-9DB3-40126B665E18} Snow amount over a specified period of time. snow {1765835F-C903-4b1d-B159-48E0BDCD7C35} verticalVisibility {BFE4FB1D-0F10-4e2d-AB91-CAED287EF526} The temperature of how cold it feels like based on the rate of heat loss from exposed skin caused by the effects of wind and cold temperatures. windChill {AEB4943D-73A5-45be-91A9-C0DBA3A09D04} Maximum instantaneous wind speed in the 10 minute period preceding a moment in time so long as more than 10 knots of difference has been exhibited between peaks and lulls during that 10 minute time period. 0 value means no gusts during preceding 10 minute period. windSpeedGust {3B9CA816-E9DD-4d8b-A499-F524781BAA20} Wind speed at a moment in time. windSpeedInstantaneous {507CC39E-3D99-407b-BDC3-C223A8143CE1} Peak instantaneous wind speed in the 60 minutes preceding a moment in time as long as peak speed greater than 25 knots. 0 value means speed did not exceed 25 knots during preceding 60 minutes. windSpeedPeak {3EF88313-0BC4-4bed-8E93-BAD793562834} Average instantaneous wind speed over the 2minute time period preceding a moment in time. windSpeedSustained {5BDCE21C-C0DD-4109-A684-0634C501D7C3} Distributed Resource adjustment for a distributed resource that is already deployed committed. DR_ADJUSTMENT {88D3E8D4-20C0-489a-9093-068E8D6CC8D3} Distributed Resource Deployment DR_DEPLOY {363089D0-44BD-4251-97DA-08F1A2D5FBC5} Distributed Resource Release DR_RELEASE {E1091FD6-5614-4b21-BC00-2EBAC0863B24} Shut down instruction type SHUT_DOWN {C54CF1F7-CA46-4aae-B9DE-2130AA3DA9D0} Start up instruction type START_UP {AECF94B1-E588-4524-AE1A-DD7900ECEB33} Contingnency occurance redispatch of contingency reserves CONTINGENCY {145F07A8-BC24-4ef9-8BCF-05AC357466E1} INTERVAL {E69BDCB2-900A-4e6c-AE51-008E4B4EE47A} Operator override MANUAL {9ED4EDCA-C53D-448f-98F6-F44601BEB2E2} Stored energy is increasing. charging {19F34FA8-CFB2-4bbc-8B63-905A12841965} Stored energy is decreasing. discharging {5CD0E68E-41E4-40c8-85CD-498A0BBA1B48} Unable to discharge and not charging. empty {4B8424DA-BED2-454e-BC4A-DAFC677E11B5} Unable to charge and not discharging. full {9AA779C1-DB12-475b-AB95-2028A9EF2645} Neither charging nor discharging but able to do so. waiting {79E0E262-7061-4525-B997-D9234C824409} Based on unit generation characteristics and a cost of fuel. COST_BASED {3C8BD9B5-142A-4b59-B2E3-302068248ED2} Based on prices paid at particular pricing location. LMP_BASED {60982D3F-D14F-4568-86E2-2CB393343FE8} An amount negotiated with the designated Independent Entity. NEGOTIATED {FADE5432-E8BE-4bf0-BD9E-8B2D5619F3E0} B {C4D0EAF7-C494-40a8-84C9-598EA9485F48} L {4792BB9B-5A40-4780-8B68-D52F4281EB61} M {490C9A04-7542-4a77-BA29-E7C96D7B9F8F} O {A21A8DA5-E6E3-4d9a-8549-F0FE59617E57} R {5646D065-FFEC-4a27-9534-66B4E3D0D78E} S {86F8419D-B58B-47d6-B678-7C6C50873CB2} F {033EDE23-864E-4751-9BB0-53611D5DC16D} I {F7255C9A-75D1-4a92-8E19-2DC7B1845F2B} AS {B8F847D2-664E-43a6-886E-6342ADA566F0} ENERGY {A226A539-6CD7-4d1b-992A-CEB50BB0E8CE} RUC {61D1EE41-146B-4dae-BBF1-7C9BEF82459D} Clean CL {49098747-2A88-47b8-A1D6-77A8FBEA25DB} CM {8BCB7E1F-B2FB-49ce-9F69-CBD97A35923B} CV {E5CF645E-38B1-4233-A269-CE5A7A117D04} CX {49A64F56-232D-4136-AAF4-27E21660C949} I {05B0D64E-4EB5-4590-A72E-F42B533043B9} M {1495BE4A-1BFE-4683-83C1-759426CDE994} O {892581DE-44E3-4506-A5B3-53181D981B49} RJ {E76778FA-5D75-4883-84AC-1FA893EC8F58} Replicated RP {77ED80BF-A4C4-4db7-BBF3-9D3EA8E4150F} V {78899B17-1E27-4a20-A713-6157B99766DF} DEFAULT_ENERGY_BID {485E00C2-D4D5-4192-A756-110CA1FF20E5} DEFAULT_MINIMUM_LOAD_BID {5341E9E9-21FF-474c-B677-7EF93EFFCE9B} DEFAULT_STARTUP_BID {2CB5899E-E095-48d9-B2AF-725E1BE9FD3C} Output of requirements bid self schedule type. QUALIFIED_PREDISPATCH {71A8181E-FA3C-47a9-9EFC-E8D17835749F} Qualified predispatch bid self schedule type. REQUIREMENTS {213F51F9-E327-444e-A091-EEE8382D40AE} electronic {9D40AF79-6BCE-4546-8347-CE426C906A98} other {4B3E1B7D-511A-4dac-AB6E-3FAF621EEFC7} paper {96375195-3F19-4e72-B221-BE5667F4D01A} Coordinated. coordinated {036BAB41-592D-433b-B36F-092A7D6E2330} Following. following {3CD1CFD7-EE28-41ac-9047-1B4C3B36ABBA} Bus breaker. busBreaker {4FA244F8-1694-4747-9447-FA257ADFDE3B} Bus tie breaker. busTieBreaker {342FF631-EEB2-4d74-A885-D97702020173} Capacitor or reactor breaker. capacitorOrReactorBankBreaker {1BC876E5-0C72-49dd-917D-47697F53214B} Feeder breaker. feederBreaker {791AEB01-5504-45ce-B008-4A45D2C728F4} Other type of breaker application. other {2412CD72-B6DC-40e0-A74D-F9F413521864} Spare breaker. spare {F770F3AE-6956-41b6-A8DE-9BA9382FEF1E} Stepup transformer breaker for fossil generator. stepUpTransformerBreakerFossil {0CE3C176-B0FC-4fe9-8466-DA7F5A03D47F} Stepup transformer breaker for hydro generator. stepUpTransformerBreakerHydro {8BBD5334-7024-4df4-BB94-6E7DD153D881} Stepup transformer breaker for nuclear generator. stepUpTransformerBreakerNuclear {4FE9C0BF-BDD7-46fa-9BAF-47CEF7A5E106} Stepup transformer breaker for pumped storage. stepUpTransformerBreakerPumpedStorage {5540B1FB-605A-42ad-88F9-12D1D562BD88} Substation transformer breaker. substationTransformerBreaker {E27B9F71-639C-4aa2-AEB0-F3C158F2BD60} Transmission flow gate line breaker. transmissionFlowGateLineBreaker {2B479A74-AD9E-4530-BDF0-3036FA2F0090} Transmission line breaker. transmissionLineBreaker {8C8FF9FE-0B1B-462d-A459-FF5BD1AC68D3} Transmission tie line breaker. transmissionTieLineBreaker {84E245C8-B94C-4076-81AF-1BECF0D14836} Breaker and a half. breakerAndAHalf {0B0C09C4-66E5-48db-85B5-7BBCB3FB2759} Double breaker. doubleBreaker {8D041086-6214-4bc0-8351-D8A680FEC6E3} No breaker. noBreaker {00F5D8BD-3E07-4371-B7A3-29276B241276} Single breaker. singleBreaker {44DB9F68-B210-48a4-9625-F25A2CB91A8C} SF6 blast valve failure. SF6BlastValveFailure {F75C1CC3-1525-4910-8EBA-9CF3011AB144} SF6 puffer valve failure. SF6PufferFailure {1AE66382-078A-472a-9563-4383B19508F2} Blast valve failure. blastValveFailure {30D60A7E-E991-4fc6-B21E-70BFBB425D5D} Bushing failure. bushingFailure {0C2E4CDF-CA9E-4043-9744-D16A8CE5929D} Close coil open shorted failure. closeCoilOpenShortedFailed {598C82C0-1BD0-458f-B62A-4716F7CDD835} Contaminated air. contaminatedAir {40FC0A16-177F-4dc3-ADF8-8A8AC8970E4D} Contaminated arc chutes. contaminatedArcChutes {A4BCADEA-5A86-49f1-BE9B-4DF1829FB387} Contaminated gas. contaminatedGas {F8BD9B53-5B89-45ea-8537-5C2881E649EB} Contaminated gas or air. contaminatedGasAir {D96E9F2F-10EA-4943-8271-C9C9B0F97922} Control circuit failure. controlCircuitFailure {FD4B790B-BB62-481c-834A-D830D73BD35A} Degraded lubrication. degradedLubrication {E7C04C52-E42D-4c34-8EDC-6226AA91F8B1} External or internal contamination. externalOrInternalContamination {635231A2-A6EA-4a16-B927-4907A25B0294} High pressure air plant. highPressureAirPlant {6F6FE842-77C2-4692-8851-9ADAF60B772B} High resistance load path. highResistanceLoadPath {14814CF1-0523-48dc-ADC5-B1518DA4A37F} High resistance path. highResistancePath {DB42A410-F347-4887-BCC4-67FB2747ED48} Interrupter contact failure. interrupterContactFailure {266CD3BD-A7D4-4cda-AFD7-9AAF3028E9FF} Interrupter failure. interrupterFailure {119D2755-1EE4-444a-AFC5-F6A512FF1C99} Linkage failure. linkageFailure {9FAC53B6-5CF0-4489-B539-73D9EB0452F9} Loss of oil. lossOfOil {E69F5C96-B3CC-4f57-AB73-189F070BA74F} Loss of vacuum. lossOfVacuum {9C68430E-7EF3-499d-9499-969960EA5D02} Low gas pressure. lowGasPressure {1A86799C-29CF-49c9-921D-5FF2901268D1} Blast valve failure. mechanismFailure {1AF7B0DB-E199-4396-BF95-2FAFAF6787AE} Mechanism or linkage failure. mechanismOrLinkageFailure {2B69A66D-1E27-4015-AEBA-84BA097AEDED} Oilrelated failure. oilRelatedFailure {8B7758DC-059B-42a9-99E1-60B2CBA41E62} Poor oil quality. poorOilQuality {AE5C859C-3972-4fb9-AD23-971A091DF1A9} Racking mechanism failure. rackingMechanismFailure {71B4D41D-E47C-4b62-A51B-B19694D76A72} Resistor failure. resistorFailure {CA6CD667-DC2F-4b9d-AF5B-024F7FA4AE65} Resistor grading capacitor failure. resistorGradingCapacitorFailure {33D82F13-D3F4-4649-A83C-C7DCA99C9E7D} Solid dielectric failure. solidDielectricFailure {4E8628FE-8199-49e2-9F55-CC4B4146857D} Stored energy failure. storedEnergyFailure {F67A3E04-02F7-4078-8385-967AAEA98C98} Trip coil open shorted failure. tripCoilOpenShortedFailed {5168F141-0FA3-4f48-A286-39806DF28301} External outofservice inspection and maintenance. externalOutOfService {F5FCE584-3E21-4639-A56A-A34F7AC7C767} Internal interrupter inspection and maintenance breaker out of service. internalOutOfService {57B6C89F-DBBB-4e87-AB83-473AC3377D75} Overhaul of breaker interrupter unit. interrupterOverhaul {158D75EA-8DF1-4fdc-8658-25C51D6B5B1E} SF6 gas leak repair. SF6GasLeak {6EF4F61C-7371-4a16-AEEA-C33EDFB90FC8} Air compressor repair. airCompressor {0FC7B2AC-13B8-4421-843C-09D82D9283E0} Auxiliary switch and linkage repair. auxiliarySwitchAndLinkage {765E9B4D-3EFB-408a-BD4E-36E4D344D5A1} Bus connection repair. busConnection {F4A920ED-2048-40bb-AFA9-8A4F5D208E07} Check valve repair. checkValve {F218AEBC-2752-4114-86F2-32D93105B8D9} Close coil repair. closeCoil {DFEB79AD-55B7-421e-A048-5050F76E6C21} Contactor repair. contactor {28593F12-179B-4a07-9E06-6DCF7B1E7B38} Control circuit repair. controlCircuit {48FE5505-F845-4c4a-8474-B580958F193D} Corrosion repair. corrosion {E647042E-9A24-4962-A24E-9847257EF246} Gas density supervision repair. gasDensitySupervision {9D70E59A-B77B-4b9e-A9E2-853A2546BBE3} Heater or thermostat repair. heaterOrThermostat {1E0C0CE0-1955-4671-8F25-9FB6791C70DC} Hydraulic fluid leak repair. hydraulicFluidLeak {7A440D56-E870-41cb-B0D9-95523DADDEAD} Interrupter assembly repair. interrupterAssembly {C356BC95-3673-4ee1-B4C1-5E4979528A07} Other type of repair. other {7BA92C88-9ABF-45d3-B503-5C4E986A9F9D} Position indicator repair. positionIndicator {F3B0D423-453E-4444-9C73-6BF505E4ACA0} Pressure switch repair. pressureSwitch {43C27BDF-C086-40a7-9C98-2C25C18B4742} Pump or motor repair. pumpOrMotor {3D419495-6544-4532-851B-B8FD3F871B85} Relay repair. relay {798D9F89-D529-433e-8BA2-639E167D63B9} Stored energy system repair. storedEnergySystem {4848DA7A-EE14-4f31-8A69-E702FF19ADDA} Trip coil repair. tripCoil {4EB5C04D-B6E6-4298-9687-E300630545FC} Trip control valve repair. tripControlValve {BA2C3D1E-6EF1-455b-90F0-15FBA02D48A7} Wiring repair. wiring {1173068F-6C90-4d1f-9442-D06B4860D0D6} Double bus. doubleBus {4818CA4D-1A75-4e80-9364-CF5DF7873944} Main bus with transfer bus. mainWithTransfer {8DC02787-5BEC-4701-A919-193EEB5A6656} Ring bus. ringBus {51ADB6A4-ED54-49e2-95C0-85BF285C3C8F} Single bus. singleBus {C252873E-93AB-4837-BFA2-72F7ED949063} Compound. compound {9D9E8358-AB7A-4422-8953-3DBDCB84F82C} Oil impregnated paper. oilImpregnatedPaper {10CD10DB-B4DC-4a26-AA55-5FF2BC8EEC16} Other. other {92800D2C-7E59-4f6c-8565-B6E4F0AFC163} Resin bonded paper. resinBondedPaper {2DE129E3-F2CD-4b33-BC93-643531E13034} Resin impregnated paper. resinImpregnatedPaper {7CAAF319-98A0-4acf-A256-7405FFFB4990} Solid porcelain. solidPorcelain {6C222A3A-CD9D-46b0-B6E3-7017F736EB4B} Power factor taptoground. c1 {9F16553C-1F0F-4dc4-B0FC-9A02AA952BAF} Power factor taptoconductor. c2 {3D315ACC-4149-4e7a-9C1F-1322CECD015A} 2000 standard edition. 2000 {EE8F128C-A7A4-421d-AF8E-F5258C786C95} No standard edition. none {CB550EE8-038C-4413-9030-D48F1B870F8E} Unknown standard edition. unknown {EC568586-4BEF-48e9-A26C-9D4EA7AAE9FF} CIGRE Technical Brochure 170 Static Electrification in Power Transformers. TB 170 {499DC4AF-688D-4a03-AF28-D8ED14C2CAF7} Network Service NSR {D77268DB-C24F-4a63-8CAE-D683A246761B} Point to Point PTP {CC2F4EAC-6FE5-46df-BD67-FF94B9969B1B} OBLIGATION {535CCF93-0DC6-447e-9ABA-7D10C49BDFE9} OPTION {15D9CCC4-A640-4a62-90A5-1534EBECCD0A} BUYER {3384C5FD-8154-48d8-B552-EFEADCEAB119} OWNER {CFA1234F-3BC7-420b-BB56-339F2094F834} SELLER {16D5DE62-21E5-402a-BDC1-5A02FC9C900F} AUC {95760A4C-CC9F-4427-B125-C25CB10CC35D} CAP {7D49A152-C6EE-4970-921B-4AB479AEBBF7} CF {D86465B6-F729-4dac-B772-CEE217F681D5} Converted rights. CVR {F5EECC95-3613-4693-837D-6584FE3462B6} Existing Transmission Contract. ETC {56A5FD8C-510D-4f63-BD91-672D1E7B4141} Load Serving Entity. LSE {9965F5FF-AA24-4bab-ABCD-325F0E4DEBED} Merchant transmission. MT {765292DC-3EF7-495f-BCB2-6ECCD211AF47} Transmission Ownership Rights. TOR {54345270-CCE5-494c-939B-0DC995B0DA53} Compacted cable. compacted {2735D553-3002-4c0d-A41D-77481121912B} Compressed cable. compressed {9D6C8350-5DA8-44a8-B2FF-0881164ABBC0} Other kind of cable construction. other {49CD656B-5879-448f-AD49-C147DF7F04CC} Sector cable. sector {AF3E84D0-807D-402a-8F51-5DFF43410CB5} Segmental cable. segmental {7C253CC1-E1E1-477b-8B68-13145A7C3358} Solid cable. solid {BD226CFC-1363-4f43-BAD6-3A7D241A6516} Stranded cable. stranded {F216BAE7-708B-4ebd-B5D4-17F24C8D5AA9} Insulating cable outer jacket. insulating {1580FECE-B730-43a3-8570-826EB7B2897A} Linear low density polyethylene cable outer jacket. linearLowDensityPolyethylene {3B06AF70-4A3B-4037-98B4-4267191D6D24} Cable has no outer jacket. none {3DA67FCE-74C5-4658-9684-C283A4E62B67} Pther kind of cable outer jacket. other {81181A29-4B97-45b0-97D8-A1A4688C6302} Polyethylene cable outer jacket. polyethylene {FF1B423A-B3C1-4d13-B1B6-C6B6C7BCC60E} PVC cable outer jacket. pvc {EE8265E9-086E-4ef1-B1E8-2B35958F50CE} Semiconducting cable outer jacket. semiconducting {D9C413D2-019A-4e6b-8312-0508670EA545} Aluminum cable shield. aluminum {722C6A25-1A40-491f-A9E5-6C3DA2AC6729} Copper cable shield. copper {12EF202C-F149-4f7c-B8DA-A9CE642AEB41} Lead cable shield. lead {902A2C27-89D6-48cb-BAEB-3C2DD386DF0C} Other kind of cable shield material. other {EF55175B-8D53-4d0c-BD36-88FC7A3DEBE4} Steel cable shield. steel {1B36E1B2-B960-4994-9795-841C3C18D30A} Period expressed in cycles. cycle {13B61A3C-5544-4cc5-8B43-1EA43B7BE644} Period expressed in days. day {21E466BC-49FB-4879-A6BC-5FEC2FA69C2D} Period expressed in hours. hour {DB85C617-16AC-422c-81CE-A7D8FD1A91D3} Period expressed in milliseconds. milliSecond {EE757E07-87B5-480f-9E00-B7969E05A944} Period expressed in minutes. minute {C7B9C8CD-CFC8-4787-B340-F58C74315D06} Period expressed in months. month {24443448-EAA9-4891-91CB-81EE4E5D41EE} Period expressed in percycle. perCycle {6BE554C5-8A84-4026-BAA0-69DDAF256277} Period expressed in seasons. season {6F054307-C44C-48a1-BFA0-9F085BD93EC0} Period expressed in seconds. second {B0F50EAA-E0F5-428a-8A02-35D75D9F0220} Period expressed in weeks. week {EE536F4F-389E-43c1-A790-EDB2CEAC1296} Period expressed in years. year {752DC03C-0570-4ee2-A371-6BEB1A6BE7E2} Division operation the input values operands. div {44380763-1E53-4bee-9DCB-5ED5A3E28D75} Multiplication operation the input values operands. mul {AE100BFB-D6AE-44f4-BE5C-0FBB3F0A32B4} Square root operator only one input value operands. sqrt {CE420801-4EF4-488d-A0A5-D4A230931877} Summation operation over the input values operands. sum {7CAEF807-9455-418e-8374-8F626E7DE19F} Calcuation is for fixed period. period {D5D527CE-1E3F-4a35-8614-C20F624980DE} Calculation is for sliding period. sliding {5618A0F1-10AD-40bf-A287-7AFCE4F62CCB} Calculation is for total period. total {DE3A2882-F75F-43f5-9C12-A65345BBA158} Result is average value for period. average {464224C2-0F34-42d4-8284-3EC29BE71E9A} Result is maximum value for period. maximum {89FF1DAD-7B49-43cf-80E7-16F7320E7A34} Result is minimum value for period. minimum {C37136E1-21D7-4480-9C08-7F1A6F9FB96C} Result is RMS value for period. trueRMS {FA73E284-C45D-462a-A35C-0FEF69550891} Any other charge which is not a consumptionCharge or demandCharge. For example debt recovery arrears standing charge or charge for another service such as street lighting. auxiliaryCharge {2F1EAFE1-E83E-4adc-A420-911CC63D4274} The charge levied for the actual usage of the service normally expressed in terms of a tariff. For example usage x price per kWh total charge for consumption. consumptionCharge {B1F74271-06BB-4a98-9524-0FDB71F71ABB} The charge related to the usage within a defined time interval normally expressed in terms of a tariff. For example a maximumdemand tariff will levy an additional charge on top of the consumption charge if the usage exceeds a defined limit per hour. demandCharge {33EBD778-E57F-4c4f-AEB3-1FD25FD6D964} Other kind of charge. other {59011684-2316-491c-9315-3E9827A7BE4B} Any charge that is classified as a tax of a kind. For example VAT GST TV tax etc. taxCharge {8CB6CA84-373D-4700-8F4C-2C15AA98D5E7} AFTER_THE_FACT {BEE41C74-ABDF-4182-96B3-82F202BEF625} PRE_HOUR {201DCC41-A8E6-4f4f-B8B8-C1F07F68DE4E} PRE_SCHEDULE {0E2A1B61-9FFE-461f-AD2C-1B3CE9A34C21} Payment order used by a bank. bankOrder {761F35F2-99F9-4ee0-A8FB-CD82B69E2440} Other kind of cheque. other {E68A776E-E0B0-4269-A463-738743BAAB72} Payment order used by institutions other than banks. postalOrder {B5AC951B-0033-4b4a-B74A-189EEAB73111} Energy Trades at Aggregated Pricing Nodes APN {252A5724-BC88-468f-8999-BEBC5106339D} Converted Physical Energy Trade CPT {575E0B7B-D8F7-465f-B99E-78ED48E74E17} NonSpinning Reserve Trade NRT {D5ADA39F-360A-4158-B8A2-A9FD8F56487A} Physical Energy Tra PHY {07C26D98-DB13-4bc5-8D3D-6AC92BBC46C9} Regulation Down Trade RDT {CBD848D7-A005-4cf8-88B5-BB1FFD9224C3} Regulation Up Trade RUT {AB57CE07-8718-45e0-B461-E01E3BEEF30F} Spinning Reserve Trade SRT {AB1A5DE2-5ABC-40a8-8F20-6014B2014F74} Issue clearance. issue {92B91793-784A-487f-ACED-3F7D8A69BA37} Release clearance. release {04F4B5A7-5A44-48dd-8637-F603EAD2C510} Update clearance. update {831A7582-9199-409c-96F5-1F83E93C159D} altoCumulus {9C8D79CF-8B5B-4726-A502-208EFAB9A13D} altoStratus {4E1A921A-447B-40e5-8F7E-6B8CA623B144} cirroCumulus {ED2BE614-7767-4a1c-AD39-640EEE988429} cirroStratus {46FAE592-9178-4272-B843-473588158091} cirrus {6A7D1D76-C754-41d4-8F0D-F98C07CEC7D2} cumuloNimbus {8EB07A9F-4310-453a-86B2-F78A151E0D5B} cumulus {05447D08-67C9-402b-8695-0782655111F7} nimboStratus {106F6D69-6062-4720-922F-8F893462D07B} other {F60ABC70-B85D-400f-BB50-90C15D82CA57} stratoCumulus {14DAAAA6-BF9F-46b5-B41D-415602269EBC} stratus {D4D08403-EA33-48f4-9DC1-EC7D67C66BE8} toweringCumulus {F969C27E-9FC7-444a-9D6D-8C3EBC955F02} Communication with the device is bidirectional. biDirectional {B143F713-C9FA-41b6-8169-EFC12FFB9190} Communication is from device. fromDevice {2613B7DA-88BB-48e7-84B5-51660B9C703E} Communication is to device. toDevice {04263A1C-FAB4-414d-A9CB-757127539690} Communicates using a public cellular radio network. A specific variant of rf. cellular {0381F4E6-5BF8-49f8-ABC8-4859232EAA0F} Communicates using one or more of a family of framebased computer networking technologies conforming to the IEEE 802.3 standard. ethernet {2AB21062-8E90-4eae-80C2-CCEA4522AC62} Communicates using power line communication technologies conforming to the standards established by the HomePlug Powerline Alliance. A specific variant of plc. homePlug {58085034-38A5-4a4c-BCCC-C65F168B07DF} Communicates using a public oneway or twoway radiobased paging network. A specific variant of rf. pager {41E95511-E5C1-417a-B317-005A4D586DAD} Communicates using a basic wireline telephone system. phone {E23519E7-AA3B-448c-A77C-4C60AC6D0274} Communicates using power line communication technologies. plc {96059140-9F25-4634-8549-04CB327BFDDE} Communicates using private or public radiobased technology. rf {EE14239D-87FF-48f2-B26A-BDACA9901E08} Communicates using a mesh radio technology. A specific variant of rf. rfMesh {0A7C7A0F-951A-4244-8C95-FF5B0E3B27E4} Communicates using radio communication technologies conforming to the standards established by the ZigBee. A specific variant of rf. zigbee {A0DF5D95-1355-432e-AEB0-CB22E842730B} ISO {BD15AFC7-3EF9-49ec-BF27-951587505ACB} SELF {8C75BC58-C27B-4d97-8128-61AAC19BEAE6} UC {6AF267B4-B970-403a-8D7D-4C362042EB51} air {96DEA7BE-8DA8-446f-AA9A-AC6DB4ABBCAD} carbon {D5095FDD-E537-4418-86D2-E78D2AA3D9F0} Methane CH4 ch4 {B0F613C1-5D3E-48f3-98C1-EAFA12F7BEBA} Carbon Dioxide CO2 co2 {025D4E4F-F092-48fa-B390-40F3701903C4} A measurement of the communication infrastructure itself. communication {3C79F608-85DD-45ef-9085-1396FE0D6EB9} The cool fluid returns warmer than when it was sent. The heat conveyed may be metered. coolingFluid {FC7C1BCC-7C39-4834-BE44-36E4D769A9FB} It is possible for a meter to be outfitted with an external VT andor CT. The meter might not be aware of these devices and the display not compensate for their presence. Ultimately when these scalars are applied the value that represents the service value is called the primary metered value. The index in subcategory 3 mirrors those of subcategory 0. electricityPrimaryMetered {F6E81EFA-FEE7-4c53-96EB-5B3A3536D638} All types of metered quantities. This type of reading comes from the meter and represents a secondary metered value. electricitySecondaryMetered {718BB312-7C16-430c-9F9F-CB80A1E62334} Hexachlorocyclohexane HCH hch {94A30E00-5AF4-40ef-A718-9DF4DCDC0708} This fluid is likely in liquid form. It is not necessarily water or water based. The warm fluid returns cooler than when it was sent. The heat conveyed may be metered. heatingFluid {D48E36F6-A36F-497c-A246-707BBEAA36C1} SF6 is found separately below. insulativeGas {E968DC07-265E-41cc-A95E-332E57D0615F} insulativeOil {1D5CA370-2F97-4b5f-9B43-DF72A2800243} Internet service internet {77E021BB-7E43-481c-A4A8-A7E30BACBC66} naturalGas {B8873BB8-19FE-4772-8BE9-5F8165E6E0BE} Not Applicable none {95036860-E113-4c13-8713-E7EFF95F94A4} Reclaimed water possibly used for irrigation but not sufficiently treated to be considered safe for drinking. nonpotableWater {AB92C5ED-069C-4dc7-A7CE-78508603C28A} Nitrous Oxides NOX nox {A1FDCAF2-1E6F-4cbc-9679-654CB60BF052} Perfluorocarbons PFC pfc {4C337D73-5FF2-4c7d-AEFA-EB7FF337CD8F} Drinkable water potableWater {EB71070B-1354-4dce-8AA0-DA1D226BA29D} propane {DCAB146D-8B07-4b5d-8F4D-02822AB956B0} trash refuse {CF5DE8FB-9F20-4deb-B338-FD5959C2172A} Sulfurhexafluoride SF6 sf6 {48BACD9E-5890-427e-9CF0-69F845479FDD} Sulfur Dioxide SO2 so2 {DFEB7875-592C-42f6-947D-DDAEB6449B9D} Water in steam form usually used for heating. steam {96D401ED-3C83-4c22-AD27-430FFE930D53} Television tvLicence {D337EA63-CFE7-4b95-8A80-4562594E8DEF} Sewerage wasteWater {D7396F86-F54F-48c2-8F60-84EA8A566391} escoThrowOver {9839F383-4C31-42b3-AC06-BD0A76C8F307} gral {FA359723-E719-4372-95EF-5AD352E50D2E} other {43098CBF-5123-4744-8DF5-458D4C1FE644} ral {9CBEE8D0-2CED-4eed-A172-A316FD155B08} regulatorBypass {A456FDC2-1DB7-4e65-B434-7572BC318272} throwOver {F34B4D4F-BB87-4c07-8BEF-EA081483574F} ugMultiSwitch {819876BC-0B73-4180-8C07-78DA9C88C91E} accountAllocation {48809184-89E0-4a14-BE67-65BB64A9A0B8} labor {422B882F-1B4B-4e9b-89DF-A0B2F2242D77} material {F7009183-6923-4da1-8640-BD5B17812D5C} other {C10A3AC8-7C1A-4a76-BD7D-D0752854C8FD} travel {0B5303D3-E38D-405c-A7D2-6DC82351DEBF} MAXIMUM {E59D1EFD-CA0B-49ec-ACE8-1F8287A9B29B} MINIMUM {7F8F866D-D9C7-4a5c-A299-E4A6A819EABD} FAST {3378A528-18CC-4b01-A5D4-96D0EF2D2DE1} SLOW {08A6FB04-E930-4729-AEA3-23DCDBB6C2DF} The equipment is to be put into service. inService {52DCF9EB-B100-4dc2-B0BE-82ADA309922E} The equipment is to be taken out of service. outOfService {F296EA90-0E39-4a44-8E31-D31EE6106CB6} CVR Converted contract. CVR {656DAF3E-967D-4927-938B-32B603D6133A} ETC Existing Transmission Contract ETC {953ED153-0420-4bc1-A792-83B235D5B278} O Other O {A49468B9-4905-413c-AB46-8E0DCDA97263} RMR Reliability Must Run Contract RMR {A8352BC5-59FF-419c-B653-2C56845CBEE9} RMT RMT Contract RMT {6B9BBF1C-BC6E-4f39-9878-36638D5237D9} TE Transmission Export TE {83109E91-0FED-4948-A614-B4D69C302E1C} TI Transmission Import TI {36C5DC29-42B3-49cf-918A-ADB63308C9A1} TOR Transmission Ownership Right TOR {C948431C-09A9-4b9a-99D3-928ECC97E804} Used for automatic generation control. AGC {8BA47D6C-F682-4daa-931F-EA232E22DA14} Used for load forecast. Forecast {51A131DD-63D8-4f4c-83C9-29EF59E44962} Used for interchange specification or control. Interchange {94213EA0-368A-49c1-8028-9A905159C854} Air. air {2FBCC200-0408-41d6-8CEE-E179F67B7D47} Hydrogen gas. hydrogenGas {17676572-09DD-43d7-B586-6FE9616CE56E} Water. water {037AFDDD-4C06-4531-B227-53B16C4327A8} forcedAir {D147AC5A-8720-4f39-90A7-7706AD8FE238} forcedOilAndAir {0FD94E57-DE34-464c-87B4-6D44D2AC4F8A} other {CFE99F39-8EF0-4225-B9AD-DE22DC059C41} selfCooling {8C520ABE-D202-4be1-BE64-828848D473FA} Asset model is used experimentally. experimental {A96F7F0E-0C5E-4208-904F-D122561B96F0} Other kind of corporate standard for the asset model. other {A65A8664-53EB-48e0-8C22-C7150493394C} Asset model is used as corporate standard. standard {406E95D0-49CB-487e-84CC-F6C247D1D2C8} Asset model usage is under evaluation. underEvaluation {B7D01BD9-6427-4914-9745-78EDB2B6A0CD} BIDC {382359D5-DF07-4531-A16E-99755138CEFA} PRXC {163741B0-62BD-4bf5-85A9-2E5025832BCD} REGC {A73A6403-F3B2-4ece-B5F0-E9332CB9C283} brief {18369290-A8EB-4156-B6EF-2A75E30F93FB} frequent {1C108A21-3775-478c-B573-04D0B7D8761E} intermittant {1388C8DE-CF15-426e-9247-19C9106E9C6F} isolated {52A8B952-6726-4e53-906F-F8CA791AE3DC} numerous {CAA8B0B8-BA59-4eee-A738-3034F56EC90E} occasional {2A2B94A9-5BFA-407f-98AA-27F4F332C80D} partly {611E6979-73DD-4304-8942-8AC3198CF012} patchy {1D24F216-3616-4ce3-85B2-4FC6BDC13DAC} periodsOf {7534E68B-B76E-445c-B3C4-3234BE49447A} scattered {A51EBC9F-54E5-4ed6-872E-17682A66CED7} widespread {7F190721-6297-4997-A490-43329921D448} the crew is on site at the outage location arrived {8CC94FC5-1D69-4967-8619-2B2060A069BE} the crew has been assigned to work on a task assigned {53E018DA-D710-4f09-BF9F-00002BD6B676} Indicates that the work is awaiting one or more crews to be assigned awaitingCrewAssignment {35D2334A-1728-4adb-9359-A7F3D7DA9C47} the crew has been dispatched to work on an outage enroute {A558BDCD-994E-4835-AB38-81DC1080F516} the crew has corrected the outage in the field. The equipment or other devices may not be energized at this time. fieldComplete {DF4869BC-D3EB-4613-A89B-0282E5289E20} Operating as inverter which is the power receiving end. inverter {4468886F-11CB-49aa-9074-C1F8DF9567DC} Operating as rectifier which is the power sending end. rectifier {E887FDBD-34CA-4523-A6FE-9DFFE716287E} Control is active power control at AC side at point of common coupling. Target is provided by ACDCConverter.targetPpcc. activePower {C8635C3D-D432-4f8f-BF38-470EFEF07A78} Control is DC current with target value provided by CsConverter.targetIdc. dcCurrent {0EF84B22-6683-4531-9627-F98AF4E25A21} Control is DC voltage with target value provided by ACDCConverter.targetUdc. dcVoltage {1E4AB43E-B899-4f70-B996-A90291CB1003} United Arab Emirates dirham. AED {8311768F-16AF-4e99-938E-A7312455ADCD} Afghan afghani. AFN {FB01059D-0487-4902-BCDB-601DE52F9459} Albanian lek. ALL {D63F2DD9-38ED-4576-90EF-A3C6AC696D25} Armenian dram. AMD {4AEDF1C1-57C9-407f-9C63-EC2BFD7C7CB7} Netherlands Antillean guilder. ANG {33CD80A9-E051-47e0-BA68-F73AB5303660} Angolan kwanza. AOA {1592F28E-1DDF-4818-B2DB-74A5513CDEC6} Argentine peso. ARS {A37D65B0-6D69-4510-A379-C78BECA6A8CD} Australian dollar. AUD {B68ED9D0-E666-4c95-B4C8-3A2C8760C838} Aruban florin. AWG {F3D56893-E43C-4c64-A521-D8251B1D5B48} Azerbaijani manat. AZN {F5BF1908-D42F-4c60-ACB1-035341951BD0} Bosnia and Herzegovina convertible mark. BAM {6CB82B96-D67F-40b0-B4E3-0385F61DB8F2} Barbados dollar. BBD {28CFBF64-16AB-45f8-AE26-2C8FBEF9B20F} Bangladeshi taka. BDT {74510D41-0967-4633-80E9-14BF51A24D3E} Bulgarian lev. BGN {F57CC213-32B9-4120-8A78-0FB728D120FD} Bahraini dinar. BHD {1BC0AA85-5F9D-46ef-B4C2-CE7027781E56} Burundian franc. BIF {E9AAD0D3-7F9D-4997-8141-DD6128E5B2CA} Bermudian dollar customarily known as Bermuda dollar. BMD {CA3A6A9C-31DC-4168-ACDE-E1EF5DA3F577} Brunei dollar. BND {994BFD2E-0601-4d44-B269-194EBD9B9E88} Boliviano. BOB {96D55A3A-96D8-4359-B483-FD18C50CA078} Bolivian Mvdol funds code. BOV {A1FF6C66-4F30-4581-91D9-E8CC013BECD2} Brazilian real. BRL {E903CA31-6CD7-4633-89C6-DB537F497A50} Bahamian dollar. BSD {5BDDE8D1-7D3A-448e-AAB7-B809F772F790} Bhutanese ngultrum. BTN {6DD99146-0FA9-4bed-8551-436F4250AEB4} Botswana pula. BWP {A262A244-582D-4e21-AB35-53207EB676A5} Belarusian ruble. BYR {D717C166-A730-4cdc-829F-6609963A3AD5} Belize dollar. BZD {67148F2D-1E44-4fc4-BDED-F067ED615541} Canadian dollar. CAD {60DEBBD0-791B-4542-ABF6-8550366541E4} Congolese franc. CDF {09A4D7FD-DF6C-4476-92BE-45902704EF0B} Swiss franc. CHF {5EFD5A2E-31B9-4aea-84D5-914F1C0A31DC} Unidad de Fomento funds code Chile. CLF {20CAB3A7-59D7-4bfd-A67F-89C803936FDE} Chilean peso. CLP {3C66B994-20A3-45a3-94ED-28738DD41344} Chinese yuan. CNY {550E5C6A-B558-4710-A97A-431C6BB83570} Colombian peso. COP {EDB86E9A-63B1-4423-817C-BAB5A05D9DAF} Unidad de Valor Real. COU {B9FC64A5-B33B-4376-AEE7-54FC483BE070} Costa Rican colon. CRC {2952CAAC-62A1-4b65-8FE3-FD55A4E679C2} Cuban convertible peso. CUC {A0EC7C95-2C97-4db8-A48F-2CBAF5CA9A34} Cuban peso. CUP {734DB065-9B4B-4050-A6A7-7CF77B9A815C} Cape Verde escudo. CVE {D70453A7-76B5-4068-8A7E-1ED3539380E3} Czech koruna. CZK {D5273F1C-3077-490b-ADAE-F7C7B78E8645} Djiboutian franc. DJF {93B97152-61E3-4181-8D8B-89D3E6462250} Danish krone. DKK {34DF27B9-64EE-43bb-BE02-F596A5597F4E} Dominican peso. DOP {127EECB6-674B-4e97-8720-7D7AF2321011} Algerian dinar. DZD {934E831F-DE3F-48aa-BABC-DB31FE9B2161} Estonian kroon. EEK {618FEB6C-A37E-4123-86D2-926014E12DBF} Egyptian pound. EGP {DCAC1DBC-24C0-4b81-A6C7-404445948EA8} Eritrean nakfa. ERN {D9B4813C-E737-41ca-BCC5-D3F709B608AA} Ethiopian birr. ETB {4D239045-36DB-47ca-AD25-DC0767B702D2} Euro. EUR {C3D20097-F8ED-4a1f-A9F0-6DF9E427E2BB} Fiji dollar. FJD {078B47FC-790C-4a80-8C9D-30087552BD79} Falkland Islands pound. FKP {FFD30DFB-C207-4997-96E7-A0274F6DB9C1} Pound sterling. GBP {006204B2-3B69-49f1-87B0-99312D364461} Georgian lari. GEL {43CDA5FE-3792-4187-995A-C28FCFE4B0A6} Ghanaian cedi. GHS {C762140A-49DF-4c09-9D98-5673E48F95A9} Gibraltar pound. GIP {D1FE9E47-C3AB-48c5-8941-05758FB8C73A} Gambian dalasi. GMD {CD90076F-18D6-405c-B248-6B166EAA42D2} Guinean franc. GNF {3C97A67D-C22B-49c1-B45D-B3830CB2C13C} Guatemalan quetzal. GTQ {C3E7DE88-4BA3-4163-90B2-CF3C04007DB3} Guyanese dollar. GYD {8D072E8C-EEC7-4b87-9F42-3BEA2B33700F} Hong Kong dollar. HKD {BE4C99E3-6486-4818-937D-671741A07115} Honduran lempira. HNL {D29BC449-C8B9-47ec-BDBD-DF15B269B65F} Croatian kuna. HRK {EC700002-6F09-4a69-BE82-A2D2E94B9E10} Haitian gourde. HTG {5B8C90EA-50EC-4d5b-8120-570F98DB11D9} Hungarian forint. HUF {A9FC7F7B-BD91-4cfc-BA7D-0FB991824F36} Indonesian rupiah. IDR {1A0A4950-3866-4eb0-888B-712F87BE8ACD} Israeli new sheqel. ILS {6B94E8B6-2848-4ed1-8B2C-C033013642B5} Indian rupee. INR {08E2A85B-7695-414e-B468-DE797E59EDCA} Iraqi dinar. IQD {3CFF7B10-1EF6-4c8d-A9DA-CAFEE767CA11} Iranian rial. IRR {90A33AC2-32A7-496b-9B02-00D30F9425E7} Icelandic krna. ISK {C576CCC9-AD7D-4c0d-A72E-A491AB26C8AF} Jamaican dollar. JMD {ABCE69F9-8E78-4515-9E2A-FA4C70D70418} Jordanian dinar. JOD {E8CB7ED5-6DD2-4f9a-B320-6BC5C118C10B} Japanese yen. JPY {5471E94F-BE53-4ee9-A711-2AC90244D1D4} Kenyan shilling. KES {4F5A5DBE-D0B7-4b5b-9CB6-809C3850DBE0} Kyrgyzstani som. KGS {03306F76-3BEE-48ef-BB80-478F197550E7} Cambodian riel. KHR {D5B86766-EB12-45df-8172-A94A04940BF8} Comoro franc. KMF {50D48764-48CE-464c-9E48-38503CC6F25A} North Korean won. KPW {8B1467AD-623E-4020-A26E-4AA27C3C6075} South Korean won. KRW {CB7B371F-F72E-477f-A3F6-8FEFEFD7A99D} Kuwaiti dinar. KWD {2394B184-0E47-447f-A13C-0C69A2706198} Cayman Islands dollar. KYD {D88FF880-FC0B-4ef3-9CEA-40D459A40539} Kazakhstani tenge. KZT {E2399A59-2B6E-45f9-9FAC-E4D799D64A0C} Lao kip. LAK {7B9EEDAD-83FD-4147-B2B8-671D73B87678} Lebanese pound. LBP {69A852C5-ED56-48ff-A08A-893E6B52D7C8} Sri Lanka rupee. LKR {39F04FBC-7A7B-4f82-8D11-60391EDCBDFA} Liberian dollar. LRD {7ADF3BC1-033D-4dc7-B2FE-629CCD1240CD} Lesotho loti. LSL {9F868853-D68D-481b-A785-A430A0B9AF9E} Lithuanian litas. LTL {63A336EE-9B6E-417a-A25E-85C2DA15EF35} Latvian lats. LVL {89A13F2D-9FC3-4218-8573-89653B8FD5AC} Libyan dinar. LYD {E470BDA3-9985-4b92-ABEC-B4B35F3176D2} Moroccan dirham. MAD {DF5743DB-E0B2-4dea-9419-BAD992BD9E8A} Moldovan leu. MDL {0DDF9E55-B409-428a-A68F-783623DE7101} Malagasy ariary. MGA {AA41FDC6-714F-4ceb-813C-5383624A7E17} Macedonian denar. MKD {5EE0BC1C-E12E-4357-8C9C-308693E9B604} Myanma kyat. MMK {9B82E309-721E-46fc-9A2A-7B39C741A3D5} Mongolian tugrik. MNT {A795B587-AD16-4a4a-B8D5-64C42499C69A} Macanese pataca. MOP {BDA58344-8BD8-4b8a-B625-452623B8F726} Mauritanian ouguiya. MRO {4562AF34-2197-4b1f-95BA-9E9227445DF9} Mauritian rupee. MUR {44EDF874-F3D7-4e82-B28C-D023F1194499} Maldivian rufiyaa. MVR {1F2F920D-CD52-47d0-AC8D-C538B5C21AB6} Malawian kwacha. MWK {BE3EC824-D76D-43ba-81CE-1AE454F922C4} Mexican peso. MXN {D1D1FC8D-DA05-4e23-B014-57071E0F0018} Malaysian ringgit. MYR {B1DC20F0-1417-40ee-AEA3-26ADF3BDDBE8} Mozambican metical. MZN {22188237-E195-4385-9246-27371700629A} Namibian dollar. NAD {E0DC0D79-C74B-415e-BB1B-DD49A784E030} Nigerian naira. NGN {D3F3C26B-CC43-4c17-9986-98F0FD50337F} Cordoba oro. NIO {EC9DF490-2CCA-4f91-ACE9-C5D570FA2393} Norwegian krone. NOK {E6F2DF01-C818-41e4-85DD-7607D1060F79} Nepalese rupee. NPR {5A687CAD-5670-4cb7-B013-ED56004592D0} New Zealand dollar. NZD {9F158607-8615-434f-8DC5-7BE0EE7932D8} Omani rial. OMR {B5F0D3C0-4A76-497a-8D57-7346A8A4FF60} Panamanian balboa. PAB {1C281135-BD47-4d3b-9BAF-24F62343F378} Peruvian nuevo sol. PEN {D77761B6-BD9A-48b7-8647-F969174B827B} Papua New Guinean kina. PGK {49C0D37A-F1C2-4b89-8825-67A202FAF1C1} Philippine peso. PHP {28D08385-3612-421a-9892-6D5B7F0F5755} Pakistani rupee. PKR {0C43307C-30C1-48e1-A5F5-F7815FD1061B} Polish zloty. PLN {E1502883-E84C-4b69-8754-0E0D8F6F0541} Paraguayan guaran. PYG {FE57212E-2EB2-4ca9-BA01-D0B0B89EB39E} Qatari rial. QAR {518AE7C8-AABE-4514-86E7-B1E98ABE8666} Romanian new leu. RON {1965570A-1DF4-447f-A71B-90023BEAC168} Serbian dinar. RSD {77012A2B-0161-41e8-AB66-CCB6960BF0E7} Russian rouble. RUB {A677E20A-9FF6-4cd7-88FF-A862704AB5A9} Rwandan franc. RWF {C8036589-4CFD-4467-8FCE-4B3EADCE7FDE} Saudi riyal. SAR {C3A5DF37-CB42-4ef7-88B4-548557EC41B8} Solomon Islands dollar. SBD {CD30CB39-454B-4bfe-8273-79AD119DCD0A} Seychelles rupee. SCR {61803DBD-73B1-4b87-8CD3-4CA3979170ED} Sudanese pound. SDG {1E0C75F9-76EE-4476-AB27-6D80D5F6BEF3} Swedish kronakronor. SEK {7AD17FA7-8042-468a-9A4E-5A31A4F24858} Singapore dollar. SGD {052FA818-D6EE-497e-9F6E-FA732781A281} Saint Helena pound. SHP {524D8445-4F6D-42d9-B8D3-8E879FD58D48} Sierra Leonean leone. SLL {205D4979-6002-406a-A6B5-221F6776ED70} Somali shilling. SOS {C53B8253-FBFB-429f-BF42-5D498E2B5FF7} Surinamese dollar. SRD {D0B98BEE-00E7-4b90-BB2C-D8408C5F0A27} So Tom and Prncipe dobra. STD {084AC846-EC27-4458-BD38-023AC6DC37AB} Syrian pound. SYP {F25FA2B4-6A4C-4438-BC83-6AE73E69B688} Lilangeni. SZL {66A2C3AE-1447-49cd-B92E-C3A29F1B9A7B} Thai baht. THB {C511B839-D3F0-4e15-BD80-F9F1E1EA4FA3} Tajikistani somoni. TJS {AE51E72D-CCB5-4870-9FD4-51A55259C6DF} Turkmenistani manat. TMT {C862B797-6B08-45f6-93E9-F561F63FCE04} Tunisian dinar. TND {D7CA53B9-8DBF-45a9-9D7E-9F989A5F9B93} Tongan paanga. TOP {36E56606-AFB8-4f89-BC80-7C7AC374AF1C} Turkish lira. TRY {2158C7AC-F5AD-4f0e-BC14-8CB3E969A689} Trinidad and Tobago dollar. TTD {02F344FD-F2C4-4daa-A3C4-D23CEB062C9C} New Taiwan dollar. TWD {5BA60238-098D-4a4c-BBB0-674669A73713} Tanzanian shilling. TZS {76249704-5DD8-47f5-8DAC-2EAA6E24FE28} Ukrainian hryvnia. UAH {4E68F4B3-C55C-4e8d-89C1-ADE21CBD0672} Ugandan shilling. UGX {EEFD1900-19F1-4760-BDED-DE34161C9F32} United States dollar. USD {F8F87BEA-4269-49de-B28F-8DC130EC9AAC} Uruguayan peso. UYU {03676FCF-6C91-465f-8A8E-4E571BCE9BDD} Uzbekistan som. UZS {887E3DEF-310A-4f6b-89D9-DBBA9059E978} Venezuelan bolvar fuerte. VEF {3CAF99DC-92D0-4808-A1EB-03AE3F8F8391} Vietnamese Dong. VND {E2D7E769-E4E7-42a5-86D3-E2B0B44033D1} Vanuatu vatu. VUV {FDC3A68E-4BA2-4b69-A0FD-1209C3C5AC3E} Samoan tala. WST {1E764ADE-1E5F-42ed-B4D6-937E133B689F} CFA franc BEAC. XAF {1AA2CC12-FACD-436c-AD73-FED872AA7770} East Caribbean dollar. XCD {214A7E04-0943-4f38-AFD6-3BE0580483A0} CFA Franc BCEAO. XOF {EFB2A7B8-B9C9-4c9c-A244-9D10086829AF} CFP franc. XPF {1083709A-0F74-4a5d-A9CD-DA129B5853D5} Yemeni rial. YER {B7ECDF90-9201-40eb-9B03-A8698A81AE3C} South African rand. ZAR {73C9E782-D310-4f6f-943E-05382AE412FF} Zambian kwacha. ZMK {C1A242CF-29D6-44a6-9EF5-A16DF42A2C2C} Zimbabwe dollar. ZWL {DCF62BC1-0B87-44a6-9DEA-A241F73BA296} ACTIVE {D99F06E5-09C9-44bc-8769-CA84E41C4D44} INACTIVE {6CC2D3CB-2B80-4da8-94BE-5BD55A4DCB4B} The Yaxis values are assumed constant until the next curve point and prior to the first curve point. constantYValue {FC48CB26-36DB-4228-8203-0B5F1CDF4A73} The Yaxis values are assumed to be a straight line between values. Also known as linear interpolation. straightLineYValues {C87B3CE1-F526-4e92-A292-0238CA829EA0} Consolidated bill from energy service supplier ESS. consolidatedEss {39A91264-B15E-404f-9574-132CB0827D0B} Consolidated bill from utility distribution company UDC. consolidatedUdc {98DD2388-CD25-49ae-AAD0-5D8676258208} other {292B7ACC-47D8-4f18-A324-B2F3F4425BD5} Separate bills from ESS and UDC. separateEssUdc {AB5DF4A3-6DBA-4404-8730-32F96D2297E0} Commercial industrial customer. commercialIndustrial {EC2ED083-2201-478d-B1A6-86DBAEA90845} Customer as energy service scheduler. energyServiceScheduler {B82F97A2-DEF2-4a5b-B483-A250EC222B81} Customer as energy service supplier. energyServiceSupplier {FFBBED52-2D6E-4eb1-AEF5-D232600FFB93} enterprise {59A143B2-3F2E-4a71-96A1-5E6BDB5AD175} Internal use customer. internalUse {08F89276-2BCD-4707-A33C-37906D4F2177} Other kind of customer. other {77F956BF-AD13-44b5-8CC6-E6F5AC29474B} Pumping load customer. pumpingLoad {754B8EEB-8A10-4024-8CA3-E3ACECBD84B6} regionalOperator {6BD3C61D-00C7-47bc-B1C8-07C3B453FE72} Residential customer. residential {8BF12334-C823-49f4-9363-2DE043980AE6} Residential and commercial customer. residentialAndCommercial {6A17FEE4-95A0-4d29-AF9A-863B63410AFE} Residential and streetlight customer. residentialAndStreetlight {DB100B72-C153-47ae-9E44-255DD4B84BDA} Residential farm service customer. residentialFarmService {463934FD-988D-46b6-B1D2-00854AABDB2A} Residential streetlight or other related customer. residentialStreetlightOthers {A66F5FB0-F221-402a-A663-E5573E90C010} subsidiary {25A9FB6D-F363-4474-A3AD-0BF9C41FEEB7} Wind machine customer. windMachine {576A1B72-9FB2-45f8-8064-5FE18E5B5023} DAM {56D6B5E1-BB8C-4a98-AFC1-C345954DD74F} Bipolar operation. bipolar {AAAD7D9F-9637-4dfc-95BC-0980D8C08508} Monopolar operation with ground return. monopolarGroundReturn {ACBACA8D-7817-4bb6-9775-7025BF6DFE29} Monopolar operation with metallic return. monopolarMetallicReturn {941FD023-3DAB-4c02-9F05-E4A56F884CA4} Middle pole. The converter terminal is the midpoint in a bipolar or symmetric monopole configuration. The midpoint can be grounded andor have a metallic return. middle {05BB3BFF-DB86-48b8-84D2-2C60BE4A89FE} Negative pole. The converter terminal is intended to operate at a negative voltage relative the midpoint or positive terminal. negative {398B4A2E-72D3-482e-B61A-20AC1CEC80E6} Positive pole. The converter terminal is intended to operate at a positive voltage relative the midpoint or negative terminal. positive {9E7235FE-D9EA-4f9d-BB58-8FDAE5188207} activePower {16846A16-80B1-410b-BDDF-3C8A816CB6E9} apparentPower {F637F32F-F3A8-4698-A605-EBE478971F6F} decreasingRampRate {D4314977-8AB6-491d-B138-032D89D5518E} highFilterBiDirectionalRegulation {FFF8F724-58AE-412d-BE7A-E2D25B2A547F} highFilterDownRegulation {989D2F3F-AB15-41cf-981C-7FC775A6FCB0} highFilterUpRegulation {9F7E46C8-B921-4120-98C1-C8AFC29C0DB3} increasingRampRate {DC389771-ECB1-4fba-AD22-7062EA4BEC37} lowFilterBiDirectionalRegulation {1153C4D8-5FBB-411f-898F-8F66900EB543} lowFilterDownRegulation {D53EFD5E-ADD6-415c-AEC7-D7ECD9F2F3CA} lowFilterUpRegulation {E7994ABD-F21E-4da0-8EE6-6FBA9ED6D9C7} reactivePower {EDDAE413-7BC8-479f-8CE0-9B8D196C2A5B} voltage {3EB87DF4-5242-4fc8-B1AC-88A8DF89CCB8} Current in Ampere. A {7A9AC903-BD3E-4f5d-8C29-6C343D7D5E29} Amperehours Amperehours. Ah {C5456A5A-C31B-4fb6-A2F5-04D727CA2DF1} Ampere seconds As. As {0B81B14F-8427-4f74-A191-F0F3A8E91064} Energy British Thermal Unit. Btu {4272AE09-251E-44d5-97D8-DBB7DC50D99B} Frequency in Hertz 1s. Hz {0B4DB8BE-FF24-479c-B066-0F5785433049} Quantity power Q. Q {5AAEE5FB-FD71-4d90-98B7-F243410E8789} Quantity energy Qh. Qh {C7E89DB8-40F6-4555-8D3A-E1181DC8DA0A} Electric potential in Volt WA. V {7F2A4D6F-A670-47a6-B904-385DF96D8BDF} Apparent power in Volt Ampere See also real power and reactive power. VA {AC621C92-D10D-4327-A43E-AC55D1B4EA41} Apparent energy in Volt Ampere hours. VAh {D86E2C84-3496-42cf-A9B7-9C458C442405} Reactive power in Volt Ampere reactive. The reactive or imaginary component of electrical power VIsinphi. See also real power and apparent power.Note Different meter designs use different methods to arrive at their results. Some meters may compute reactive power as an arithmetic value while others compute the value vectorially. The data consumer should determine the method in use and the suitability of the measurement for the intended purpose. VAr {978031C4-430D-4c95-907C-6BB23BD29E64} Reactive energy in Volt Ampere reactive hours. VArh {73A57724-8DC2-48b5-8087-1F6DF19A04E3} Power factor PF the ratio of the active power to the apparent power. Note The sign convention used for power factor will differ between IEC meters and EEI ANSI meters. It is assumed that the data consumers understand the type of meter being used and agree on the sign convention in use at any given utility. VPerVA {305F5C22-1D7C-43aa-89F1-792DEDBA7938} Power factor PF the ratio of the active power to the apparent power. Note The sign convention used for power factor will differ between IEC meters and EEI ANSI meters. It is assumed that the data consumers understand the type of meter being used and agree on the sign convention in use at any given utility. VPerVAr {C6315AC6-FE12-4cb6-B5AE-C2229F89DBF2} Volthour Volt hours. Vh {986EFCBC-ACFF-4fee-92C2-E797D9B4C075} Volt second WsA. Vs {5F8BE774-D837-4c05-A670-8865D62CA98E} Real power in Watt Js. Electrical power may have real and reactive components. The real portion of electrical power IR or VIcosphi is expressed in Watts. See also apparent power and reactive power. W {88827AD2-825E-4561-835A-FCC66786029F} Active power per current flow watt per Ampere. WPerA {FDA22034-0417-468a-B6BA-99F47A3B2B9A} Ramp rate in Watt per second. WPers {CF56506A-6925-4011-B563-B25A7B50CDCF} Real energy in Watt hours. Wh {AECB659C-2929-4fd4-9CB6-611FEB942AE4} Plane angle in degrees. deg {0402C11E-2D61-4e84-B620-785C4BCFFE29} Relative temperature in degrees Celsius.In the SI unit system the symbol is C. Electric charge is measured in coulomb that has the unit symbol C. To distinguish degree Celsius form coulomb the symbol used in the UML is degC. Reason for not using C is the special character is difficult to manage in software. degC {5702078E-2D9F-4441-9D76-5AFBBEF47ABA} Time hour 60 min 3600 s. h {EBF5C74E-A549-45ca-A24C-E1756F0CB824} Time minute 60 s. min {DF1873F1-242E-4af4-9E9F-435AC692BFBF} Electric resistance in ohm VA. ohm {7210C686-6570-4986-91A9-439908D873F6} Electric resistance per length in ohm per metre VAm. ohmPerm {1C636B7F-E4DA-49e2-8E45-AEA912B85644} resistivity Ohm metre rho. ohmm {2D664514-077E-4aee-8122-AFB07985B33C} Reciprocal of frequency 1Hz. onePerHz {93D18B7A-147C-4b9c-9CB8-91486487AD51} Time in seconds. s {427AE896-5C28-4244-AC66-01B9BEBF1CF0} Energy Therm. therm {7BE76D3D-808C-4771-BC8B-5C5F5DCA273D} 1985 standard edition. 1985 {EE91301E-96D2-446a-82F3-1BBF8A6CAB6E} No standard edition. none {06B2CE9F-588E-4048-9DE7-8593FFF6F644} Unknown standard edition. unknown {BD10835E-942F-4fc0-846B-5C1F43AE5013} Testing of insulating oils detection of corrosive sulfur silver strip test. 51353 {BEF784C3-0C79-445f-B3F7-E6B9261C20D1} other {71AC187C-F9B4-44e9-B115-DC13871025CF} rural {E4DC627B-8653-44c3-A8B8-0BB848A9403E} urban {3BBBAB00-F35D-4f18-84C4-701BEC60674F} mutuallyExclusive {6FD4EB93-7C76-4fb2-852F-D7B757F09279} required {D2ED798D-6450-412c-83C1-DB19C24F93B6} Asset in service in deployment location. inService {A79605AE-1FDE-4ce6-B0A8-CC72C003E6B3} Asset installed in deployment location. installed {E60BF94D-CEDA-4c1c-AED5-5FD421354FCF} Asset not yet installed in deployment location. notYetInstalled {627634B0-2A41-4a49-B2E4-CEA6841D0E4B} Asset out of service but in deployment location. outOfService {32292C31-E903-42d6-9DD2-82158F90753A} Asset removed from deployment location. removed {E2BE4454-DDC6-4d4f-97EB-30C2232B82A4} asBuilt {2B622818-B982-49e6-AFC0-21364C0F58E7} estimated {BC90302C-9240-4719-ADF4-C5EFC251C1C1} other {329D5311-29A2-41c8-9439-379E6847B7E8} ACCEPT {1071F454-0B01-4d88-B1A9-D4D4B53BDFC2} CANNOT {9ED8C001-83F5-4ff1-96C4-905BDC3AF661} DECLINE {DA97D25B-DB8E-48ce-9EE0-458D3BE852C9} NON_RESPONSE {CE2988E2-7F9E-4178-A17C-D8AA14CEE3F8} OK {DCABCC4E-140A-48f6-8807-8FC491B45A1A} PARTIAL {3DF8C302-06D0-4474-B8D7-6C4991B3831C} ACCEPT {67686126-E2CB-4e48-992F-1EACB8CE3A75} DECLINE {EA86A318-3546-4df4-B0DC-0A93FCE89462} NON_RESPONSE {D5478280-898C-42ae-B75E-C2076DCC0124} PARTIAL {22C3C156-2898-44fb-B72B-4386353EEC14} Purchase {C43B78C4-4061-4a6d-8888-2256590E1C01} Sale {7102FB8C-5965-48b6-9EC9-2711603AD86C} No edition. none {D365D144-68E2-4fcf-B9A9-6E50739DE4A2} Unknown edition. unknown {FBBC3B95-21AB-4897-93C0-4C27835E6A8D} Doble test for methanol. methanol {3E9C24E8-2A00-4e7f-ADE6-1F119F7F4A07} Electrical power feedback connection indicated as 1 in the block diagrams of models e.g. GovCT1 GovCT2. electricalPower {BC2A261C-5068-4631-B279-99A4F9E0BB68} Fuel valve stroke feedback true stroke connection indicated as 2 in the block diagrams of model e.g. GovCT1 GovCT2. fuelValveStroke {D95E8F20-CE3E-40bd-A1E2-840A5BCE31D5} Governor output feedback requested stroke connection indicated as 3 in the block diagrams of models e.g. GovCT1 GovCT2. governorOutput {42BC2DD8-FD94-4cc6-AC91-F6F216D77A1F} No droop signal feedback is isochronous governor. none {C7116843-752E-4c73-B359-E75742ADE854} Standard edition A. A {67A8D173-9DFA-4895-8C3C-8DE4202932F3} No standard edition. none {9A744E76-F1D4-492a-924D-E49949AA73B7} Unknown standard edition. unknown {58A8B8ED-677E-4239-81D5-EC62223BCF1A} Polychlorinated Biphenyls PCBs by Gas Chromatography. 8082 {E0F67E32-9C8F-4ee5-8EB7-5293B70F3D65} there is a high confidence that the ERT will be accomplished high {EC986F30-302E-4878-9F23-CBC5B06D5726} there is a low confidence that the ERT will be accomplished. low {0BB19AB3-97BF-4e32-B6D0-088799866080} Carbon dioxide. carbonDioxide {3A38B1C7-DD00-48b8-944B-489B28AC27A3} Carbon disulfide. carbonDisulfide {27FBACE6-1691-47bb-8EED-0F36BB97B019} Chlorine. chlorine {30F01FEF-25A6-4ed2-88C2-1B946BE9F667} Hydrogen sulfide. hydrogenSulfide {54FAC8F0-49CD-4fe0-9AE2-404E630ED5FD} Nitrogen oxide. nitrogenOxide {65B3C938-9474-4876-A9C2-0EFC9A4E5E30} Sulfur dioxide. sulfurDioxide {330E0354-FC40-4a19-B79C-9476E052537E} Calculated. calculated {5C476043-4FEB-4865-AE0B-0A957DCBE044} Measured. measured {4E6AD84B-AD5A-4788-A299-9BBF0EBDC6A7} Autonomous application of daylight saving time DST. autonomousDst {89185290-3ABB-4929-8102-E26E02AB7A97} Demand response functions. demandResponse {25940B91-4EDC-44bc-8BF2-7D2FFC0C27B8} Electricity metering. electricMetering {C2C830B2-6688-4e2c-B8A9-C19699937ABF} Gas metering. gasMetering {DD6A2F15-32F6-4cd2-8344-0B68A6B133EA} Presentation of metered values to a user or another system always a function of a meter but might not be supported by a load control unit. metrology {60C7E244-4C14-427d-9884-EB81E742B371} Onrequest reads. onRequestRead {AA742E86-0366-4fcf-BE07-BE973FEF0BE5} Reporting historical power interruption data. outageHistory {00A999B1-5594-478d-ABC7-24D20AB7E033} Support for one or more relays that may be programmable in the meter and tied to TOU time pulse load control or other functions. relaysProgramming {E60E6DF7-0E1F-49b2-A219-47FA09233379} Detection and monitoring of reverse flow. reverseFlow {51C01548-842F-4d92-BB5F-52B46F3EE8C8} Water metering. waterMetering {1B2B3A3D-8041-4f2b-A538-B4A70F159225} BOTH {618E030E-C1A4-4530-8E4D-9BFE7EC5D57A} RETAIL {04CA382D-1E55-4380-8F9A-31CB848598FD} WHOLESALE {75DCBF8C-F60E-4697-B615-B7C2C45AC719} Dynamic DYN {7BC0044E-A62D-44ff-844C-0D9F2DC1884A} Firm FIRM {8D6A544A-51D7-4584-9EBE-3F40BBA0BF20} Non Firm NFRM {8F523AF2-46C9-48a8-8E7E-9EB445DCD33B} Wheeling WHL {90FE3401-1EE9-4225-8ECB-7B88274A5909} Approve approve {6B8894C2-9131-4213-9F82-0DA151E04186} Deny deny {C8F7969E-94CA-4313-BDAA-43869A7423AB} Study study {9F4ED503-4E1A-460f-A703-B8BC65EE6442} DABE {C792829A-AE02-47e1-A4A5-00EC8BCE821B} DAPE {97F745E6-475A-4128-84AA-85D11545A674} DASE {88B3625D-E11C-4243-BFC6-3FE04C72FD07} DMLE {C4ABC213-ECA2-4819-8A8C-73C33753C1DE} DSSE {1862577C-AD95-49a4-95D5-5D018074D69C} EDE {E3EC007B-D3A2-4122-BAF1-7B791D68754F} HASE {C76DBEF3-62B6-4aa3-8E65-709E6CB9858C} MLE {D6E89F06-1109-41ad-A757-0363AE434A4F} MSSLFE {586DF6CD-66D9-4a24-BF47-DE2B5AE6207B} OE {9B4358B1-8259-450b-B00C-968DD9B5EB77} PE {A1B265AD-541E-43a2-9AF0-9A299C96B40E} RE {F53BC610-F2BF-4dba-9C0E-6AAB82116117} RED {D7287F00-9152-4adf-822E-24EA8AC00AF7} RMRE {B67535FF-EF13-45c3-B5BA-28C73729F957} RTSSE {C2E46EA1-53E5-4f57-8D55-53CD7E31F5BE} SE {4AE02265-C422-4ffc-918B-7C36A5E88292} SRE {A6812534-0C0A-4285-A6F7-9BD76D7B76DA} TEE {D2C7FCE1-3505-4f64-9CDB-BDBC3A993D8A} ConsumerLoad {C738867D-4693-4286-867F-861FB8A30460} IndustrialLoad {77AF1E70-4145-483e-98E0-429E85846C6B} Other {EAC4E5FD-FC38-4a11-A1DA-22A3A0A4BCF7} PVpark {81C32E01-A018-4946-A7F3-545FEFFBF0F4} WindPark {BDD60AA4-3664-4745-BA20-A78CCEA7468E} Cloud cover in octa. cloudCover {48420231-0ED9-4eb4-9044-A51AB391ED3D} Equipment is in. In {F63F1D22-FFE2-493c-8807-DC4EA4CD0ADF} Equipment is out. Out {CB939500-A150-4e40-BC2C-190E8E2EBF54} estimate {F7DBB07C-4DE9-4f10-B3E2-DBD2C78895C3} normal {F773052E-96B2-4a76-93D3-222ABD43D867} reversal {F0F3E268-6254-4cd0-93C9-D186D8E5923D} statistical {A5534DDC-9263-420d-82CC-8BEE9CF14909} purchase {67D7AA0A-0221-444d-8A06-2C572A5F3EB1} sale {84878F2E-3F1D-49e6-A5DA-B7C05A9AD640} initial {BC996AFA-AAB6-4931-9DD8-EA8849CCB8D0} other {0D84BC3E-6F30-424c-A8D2-B043C293F118} recalculation {06E8B37B-10EE-44e6-828F-5B1A80D5CB28} Ignore UEL signal. ignoreUELsignal {559092A6-4A5E-4770-8565-FF15421513CC} UEL input added to error signal. inputAddedToErrorSignal {0167BCCC-21F3-4f5d-8DD7-0F3121597F8F} UEL input HV gate with error signal. inputHVgateErrorSignal {DF248D9F-D976-4c79-A740-E1AB4C2EE954} UEL input HV gate with voltage regulator output. inputHVgateVoltageOutput {87F6AC0B-8BAE-4846-A7D3-88449AE441F2} The exciter field current is used. fieldCurrent {20B5EA6E-9205-4b2a-A9D2-D87DE23F2E91} The voltage regulator output voltage is used. It is the same as exciter field voltage. fieldVoltage {F1321EE5-BA25-4ff0-8170-9C6BB353C6B8} The output voltage of the exciter is used. outputVoltage {77C43C4E-60C1-448f-88C2-F3C339747521} The connection is after UEL. Corresponds to iOELini 2 on the ExcST6B diagram. afterUEL {9E3FE06F-CA3A-4170-A559-6586DF11FF44} The connection is before UEL. Corresponds to iOELini 1 on the ExcST6B diagram. beforeUEL {26C343DF-DEE4-4c49-B64A-FE4704AE4C7D} No OEL input is used. Corresponds to iOELini not 1 and not 2 on the ExcST6B diagram. Original ExcST6B model would have called this iOELini 0. noOELinput {123C25C6-1786-4cfb-826D-F45069298025} The signal is added to iVrefi. Corresponds to iOELini 1 on the ExcST7B diagram. addVref {C4866047-697D-477a-B572-C858FE0C3477} The signal is connected into the input iLVGatei. Corresponds to iOELini 2 on the ExcST7B diagram. inputLVgate {6F4F940D-1730-4555-B3DE-0843F9A6A8B0} No OEL input is used. Corresponds to iOELini not 1 and not 2 and not 3 on the ExcST7B diagram. Original ExcST7B model would have called this iOELini 0. noOELinput {2BC3480F-7146-4a72-89B7-1E72D021533C} The signal is connected into the output iLVGatei. Corresponds to iOELini 3 on the ExcST7B diagram. outputLVgate {1A8BEBCF-ABA1-4dd7-87B2-32FB6C469A00} The signal is added to iVrefi. Corresponds to iUELini 1 on the ExcST7B diagram. addVref {484B9178-2FF5-40c7-BC72-98F0BCB06A29} The signal is connected into the input iHVGatei. Corresponds to iUELini 2 on the ExcST7B diagram. inputHVgate {0601B4EF-4E06-49ec-BEBC-5991132231E6} No UEL input is used. Corresponds to iUELini not 1 and not 2 and not 3 on the ExcST7B diagram. Original ExcST7B model would have called this iUELini 0. noUELinput {17EC1C75-1ECE-4bdc-BD5D-453C0626C03B} The signal is connected into the output iHVGatei. Corresponds to iUELini 3 on the ExcST7B diagram. outputHVgate {E69D40DF-4CDF-486f-A4F8-D323F2D87DA1} Day Ahead DA {2A9F2715-E924-435d-9E7D-B9108E9BDF0D} Real TIme Hour Ahead Execution HASP {9630866A-2872-4844-AA17-37D76DB6E5EF} Real Time Dispatch RTD {2FE092F5-B88F-4dd6-9A74-B3E7D32F3DB2} Real Time Predispatch RTPD {113E94E7-BAFB-4e2d-8109-F30C718FAF31} Static synchronous compensator. statcom {A81C68C3-49E6-4f08-836A-FF6BAF663CC7} Static VAr compensator. svc {0BD922B5-5E5C-4255-AB32-8888C7508ECE} Thyristorcontrolled phaseangle regulator. tcpar {04BF8754-86EE-448f-9121-6CF8BC1CBFE6} Thyristorcontrolled series capacitor. tcsc {5475CE0E-2D5F-479c-9B1A-82FDE57C0605} Thyristorcontrolled voltage limiter. tcvl {FC54D9A2-BE08-48d9-BA43-AAD8D0EA9030} Thyristorswitched braking resistor. tsbr {6AE5268E-0487-43be-8AED-0A5C2C6BF983} Thyristorswitched series capacitor. tssc {08BE63AA-8E2B-4f50-9CC9-BA99533F2FAE} Unified power flow controller. upfc {7DE813CF-898B-4174-9815-0E55C6B4DB01} Over 200 mph 3second gust. five {B6CE21C4-206F-4ffb-B4A8-2B8F4EF1D9D6} 166200 mph 3second gust. four {9F2C3F06-566E-48e4-81BE-E96C4B13ED05} Unknown. minusNine {C58CB0C9-8DDC-4fe0-96F8-6F637C6A20BF} 86110 mph 3second gust. one {41738BD9-42E6-4fdd-BE91-4269D53B29C9} 136165 mph 3second gust. three {EF5CCCFB-0DBB-4951-87C6-902DA6D7CB14} 111135 mph 3second gust. two {A43B85BA-B8A0-42e2-9744-36B1B6FDD07D} 6585 mph 3second gust. zero {2DA63F9D-7EF4-414d-8D2E-54618ADBB66B} Distribution pole top. distributionPoleTop {1B8A8E2A-5F92-47a3-BEF8-81132D38388C} Distribution substation. substationDistribution {E7CE089E-70FC-4778-B994-867E827EEA8F} Fossil plant substation. substationFossilPlant {DA3FF0DC-3997-4461-AFBB-68237F433F0A} Hydro plant substation. substationHydroPlant {F35BF7D4-D8BE-4ea4-9745-CA88394227EE} Nuclear plant substation. substationNuclearPlant {D2879425-A999-4912-B276-05D7C4F90E05} Subtransmission substation. substationSubTransmission {6DE7DE36-4555-43b5-ABD9-884BD1C6BDE2} Transmission substation. substationTransmission {55457CBB-825F-4f25-BFCE-DD75B54E19F6} Isolated via breaker operation. breakerOperation {06661926-D180-416c-8D65-A1612577FA6B} Isolated by equipment burning in the clear. burnedInTheClear {EECE93A8-ED38-44c3-AEE1-7165D32AC3BD} Isolated by fuse. fuse {3D29DEE3-27DA-4064-8632-38C72564C562} Isolated by manual operation. manuallyIsolated {270BD360-091B-4ab5-9303-2618A17F3CEC} Isolated by other action. other {1EC7CF42-99C2-4d26-AC5C-F12D161DDFC3} automatic {3911F5AE-C79B-4de1-AD6E-1CEE19755DB1} manual {80A7AB2F-D6AF-4b99-A25F-29E605FF7E45} other {4060BA6B-AE6A-4e6e-9118-6D9E21463ACD} remote {C290C62F-E51E-4fad-A010-02399EB8839B} 1 RMR Condition 1 unit 1 {47FF9B69-84E9-4365-858C-5E4736558216} 2 RMR Condition 2 unit 2 {AEF47561-C2FB-49fd-BD1A-4835A0FEDAA8} N not an RMR unit N {C4A525C9-E823-4cf1-8C55-ADDEC1D7E0A5} Delivered or Imported as defined 619682.Forward Active Energy is a positive kWh value as one would naturally expect to find as energy is supplied by the utility and consumed at the service.Forward Reactive Energy is a positive VArh value as one would naturally expect to find in the presence of inductive loading.In polyphase metering the forward energy register is incremented when the sum of the phase energies is greater than zeroimg srcHTS1.PNG width209 height16 border0 altgraphic forward {CD793FD7-51EF-410b-8F30-123CD3F6E989} Typically used to describe that a power factor is lagging the reference value. Note 1 When used to describe VA lagging describes a form of measurement where reactive power is considered in all four quadrants but real power is considered only in quadrants I and IV.Note 2 When used to describe power factor the term Lagging implies that the PF is negative. The term lagging in this case takes the place of the negative sign. If a signed PF value is to be passed by the data producer then the direction of flow enumeration zero none should be used in order to avoid the possibility of creating an expression that employs a double negative. The data consumer should be able to tell from the sign of the data if the PF is leading or lagging. This principle is analogous to the concept that Reverse energy is an implied negative value and to publish a negative reverse value would be ambiguous.Note 3 Lagging power factors typically indicate inductive loading. lagging {94EA88FF-0299-48cf-90F3-074DFF34EC23} Typically used to describe that a power factor is leading the reference value.Note Leading power factors typically indicate capacitive loading. leading {E34D26B3-6DE2-4cd4-BD6E-30221A5D516B} Forward Reverse See 619682.Note In some systems the value passed as a net value could become negative. In other systems the value passed as a net value is always a positive number and rollsover and rollsunder as needed. net {710A918A-8F9B-45c6-B0CE-114D2743954E} Not Applicable NA none {FFA0B12F-050B-4ba8-A9B5-B4B6332A8EC8} Q1 minus Q4 q1minusQ4 {0BE7A9F1-B563-4d5c-82FC-08121925B92D} Reactive positive quadrants. The term lagging is preferred. q1plusQ2 {B3C84D0D-C497-4798-8FEF-E8D15AF898F3} Quadrants 1 and 3 q1plusQ3 {7276E72B-3337-4d25-921B-5AD2AC7C97F5} Quadrants 1 and 4 usually represent forward active energy q1plusQ4 {0F22200A-A507-4c74-A7C2-AF654813DD1C} Q2 minus Q3 q2minusQ3 {A81A05BE-5DED-47e0-B3ED-D7D4C742691F} Quadrants 2 and 3 usually represent reverse active energy q2plusQ3 {F53D76DF-03AF-41b7-8CEC-94F6BD6AD694} Quadrants 2 and 4 q2plusQ4 {995C631E-A068-447c-85F5-A6F0D3B57664} Q3 minus Q2 q3minusQ2 {CB577B09-2DFF-49c7-9A45-833EE066E945} Reactive negative quadrants. The term leading is preferred. q3plusQ4 {E8172E8F-3A81-4389-831F-5F470E201FAC} Q1 only quadrant1 {37C6835D-D3A8-411c-90D3-35A3A32720F8} Q2 only quadrant2 {97D06D32-09EB-47a3-B003-E384C2763045} Q3 only quadrant3 {ACA00D9F-02DA-4bb0-94D7-63623EBB865E} Q4 only quadrant4 {8D2ECAE0-6EBD-4b5c-84F3-02960D9DEDC0} Reverse Active Energy is equivalent to Received or Exported as defined in 619682.Reverse Active Energy is a positive kWh value as one would expect to find when energy is backfed by the service onto the utility network.Reverse Reactive Energy is a positive VArh value as one would expect to find in the presence of capacitive loading and a leading Power Factor.In polyphase metering the reverse energy register is incremented when the sum of the phase energies is less than zeroimg srcHTS1.PNG width209 height16 border0 altgraphicNote The value passed as a reverse value is always a positive value. It is understood by the label reverse that it represents negative flow. reverse {7234A8E8-7C70-44d4-A497-95D2E2A7A293} Forward Reverse See 619682.The sum of the commodity in all quadrants Q1Q2Q3Q4.In polyphase metering the total energy register is incremented when the absolute value of the sum of the phase energies is greater than zeroimg srcHTS1.PNG width217 height16 border0 altgraphic total {DA938311-D058-496b-A6D2-5686F4D52512} In polyphase metering the total by phase energy register is incremented when the sum of the absolute values of the phase energies is greater than zeroimg srcHTS1.PNG width234 height16 border0 altgraphicIn single phase metering the formulas for Total and Total by phase collapse to the same expression. For communication purposes however the Total enumeration should be used with single phase meter data. totalByPhase {03FEC082-6E82-40bb-BD2B-5E881A9153B6} Forward direction. Forward {3710B80E-1200-4491-B0C2-7151A873E74B} Reverse direction. Reverse {B472A601-A911-49e5-B001-78A407B4B74A} Electromechanical and electrohydraulic regulator Cflag3. electromechanicalElectrohydraulic {A6361EFE-054B-4ad3-96BC-A12067766DB7} Mechanichydraulic regulator with transient feedback Cflag2. mechanicHydraulicTransientFeedback {F8F54CFB-B7B4-4889-9A34-B9D25BFEABE6} Mechanichydraulic regulator with tachoaccelerometer Cflag 1. mechanicHydrolicTachoAccelerator {628C3010-E835-4b2d-AAA6-C44F09B9B815} Bio Gas Landfill Sewage Digester etc. BGAS {E0427B18-C8E2-4f7a-9D7E-80703535A198} Biomass BIOM {FBD9AF03-11AC-40c3-8382-2D101D7ED850} Coal COAL {A65E7474-2A90-4bec-848C-0A007AA98FE9} DIST {C4A436EB-1915-48ff-B935-FFC31453B603} GAS {51C39BFF-B9FF-459e-B3EF-472E28D88D81} GeoThermal GEOT {D54DDB78-A2CB-4d4f-8687-D8CF3E81409C} HRCV {57B5AEB5-C9F9-451e-AAE2-F64C21377E08} Natural Gas NG {733A69FE-9000-45cf-9AA6-1A9FD6743132} NonNatural Gas NNG {F788EFF2-4BA8-4e64-AAF0-4E085053CB5F} NONE {9E85CA32-0527-437d-99EB-FA207B936850} Nuclear NUCL {9F508CEF-0012-4f63-81C6-352D85760D26} OIL {604B2B03-BE98-4b36-B30B-7194E71082D8} Other OTHR {EFBB22A2-300F-43f3-971C-4F725A947F93} Solar SOLR {687D0F0E-9827-4322-BB16-A828233FF14F} Waste to Energy WAST {862129C4-8F60-4ddb-B4A1-75B416EA2B8D} Water WATR {1DB47B93-1D35-4ca5-9A34-D704EC5DE7D3} Wind WIND {1EE3B826-A7F5-4712-8F3F-01ED68EC1FF7} Brown coal lignite. brownCoalLignite {A5DEF850-4095-4c6f-822A-70E2C3A2004B} Generic coal not including lignite type. coal {48574203-A20C-471d-86F8-40A310D86D9C} Coal derived gas. coalDerivedGas {A54D2137-25F9-4e6c-8911-9D168CEA13B0} Natural gas. gas {A584C64F-24D8-456e-849B-A836063EB741} Hard coal. hardCoal {18FE649C-B794-4ced-AFCD-8FDDA6DDCF80} The fuel is lignite coal. Note that this is a special type of coal so the other enum of coal is reserved for hard coal types or if the exact type of coal is not known. lignite {740E6D2B-C458-4553-B915-458358AE74A8} Oil. oil {B8642718-8910-450f-B0F8-6FAFB7AE4E7B} Oil Shale. oilShale {59454BB2-4DFB-459f-9CC2-8F20D3201589} Any fuel type not included in the rest of the enumerated value. other {ECB2760B-5351-4506-9B61-1921945E171C} Peat. peat {FB22A039-D8DB-40bb-B5DD-FEEC6E3DA434} A logical AND operation. True when all input are true. and {3294F454-7555-4da2-ABA3-2D1082306483} A logical NAND operation. False when all input are true. nand {5135B7ED-80E3-4484-90F5-29A0ADA2F9B7} A logical NOR operation. False when one or more input are true. nor {AA8B0FDC-1F10-428d-B4D1-8EF586685EE3} A logical NOT operation. Only one input and true input will give false out and false in will give true out. An inverter. not {ED49693E-176B-4bab-9612-10B18FFB3FA1} A logical OR operation. True when one or more input are true. or {3181B9BA-C507-4c6b-A24F-9CF1460986B6} A logical XNOR operation. The function is the inverse of the exclusive OR XOR gate. All input false or true will give true. Otherwise false. xnor {57D32F58-2F60-411e-A14E-6A8BBB3CBACF} A logical XOR operation. All input false or true will give false. Otherwise true. xor {4AE8A92E-060A-4678-B472-271DF3203B3B} Pulse control mode. pulse {86003E6B-2E51-439f-B483-DC6898431E72} Setpoint control mode. setpoint {27334956-C1AD-4ba5-96A4-84E29F956435} Off of automatic generation control AGC. offAGC {DD41B9BB-A11A-4b4a-A4C6-4B462E41DDE0} On automatic generation control AGC. onAGC {5ADBF694-909C-487c-9134-2295C1A3E8E6} Plant is controlling. plantControl {F4C5FBF2-28B3-437f-85EF-F574071C790C} Not available. unavailable {BFBC77D6-2D86-48c1-B93F-9293533DCD34} Exponential recovery model. exponentialRecovery {6E645C61-4229-4d95-8E10-2200FEF19D41} Load adaptive model. loadAdaptive {DE516437-5564-4f69-BC30-EDAFBE685E94} Flash rate in strikeshourkmsup2sup. lightningDensity {16D8CCB2-EC26-4a23-A076-66449B807D4A} seismicEastWest {4D8E1140-A53A-4406-A904-FD3BAD1DA9E7} seismicNorthSouth {D7848E12-FB06-4b2b-B53F-353D88B297F5} seismicVertical {F5BF2676-7444-4115-8E6C-CCB790693F29} snowPackDepth {DDAA7C0F-13E4-4149-B7F6-B84345724AF2} temperature {1A7F75E1-5FCD-4900-B09B-EF2B7DC51F1B} Francis or Pelton model. francisPelton {B07B361E-CA8F-4433-B86C-E065EA2CDBDA} Kaplan model. kaplan {C55953FA-6545-4f55-9CB6-97FDC94F1F05} Simple model. simple {4FF834A7-38D6-4440-83EE-6111ED481385} Able to generate power but not able to pump water for energy storage. generator {2BEF7548-AC7A-47f6-8AFB-D8FD5594FC5A} Able to both generate power and pump water for energy storage. pumpAndGenerator {3965BBB3-D7F3-4a66-82A7-BB51C80B93CD} Pumped storage. pumpedStorage {BE3E5F7B-A1C9-4b87-8B73-8A3502814C19} Run of river. runOfRiver {62BDEA10-C6A6-4107-9567-CE47AAD0E560} Storage. storage {7B020F75-B69C-4fe7-A06E-B47EB5E4316F} Francis. francis {08B0B97B-5C23-4a52-95D7-B97A28E4BFD2} Kaplan. kaplan {A132B48C-1981-425d-ABA0-888B87DD1BB3} Pelton. pelton {F7A8B1D2-22DB-450d-8A83-D21AC557BE19} floodLevel {2D00B88D-8831-4e21-B324-A7F2F4575929} stormSurgeHeight {6127D110-1979-4aad-89D0-8C58216ACB47} surfaceTemperature {1F42CB38-B2EE-4157-8BED-9CD3BF4BD682} waterTemperature {5612E922-E82E-4fe1-A946-3E261B672D1B} waveHeight {5646466D-9C1A-4e25-9044-139C64DB951A} Indicates that the remote is not allowed to change the value of the ICCPPoint. readOnly {3D227F82-FAA2-443e-BF9D-11B833D56EC3} Indicates that the remote can not only get the value but may also change the value of the ICCP Point. readWrite {D2DCEFAB-B7C8-4879-A23A-12F2DA28E7A2} Indicates that an ICCP discrete type is to be conveyed. discrete {CAC01C8F-AF3C-46ed-BC32-BCD0F25F39AE} Indicates that an ICCP packed Protection Event is to be conveyed. packedProtectionEvent {69EE703E-1530-4188-89C7-049534854D58} Indicates that an ICCP real type is to be conveyed. real {BCAE2A02-D851-444a-8983-C2F2C017A8F0} Indicates that an ICCP single Protection Event type is to be conveyed. singleProtectionEvent {2F27C9F8-55BA-4a14-8466-5306BF3856AA} Indicates that an ICCP state type is to be conveyed. state {0365C0D5-6134-4798-B9B1-9DA50D9453B5} Indicates that an ICCP state supplemental type is to be conveyed. stateSupplemental {41821425-CA04-408d-A5CC-8B6712378AAE} Indicates that only extended information is to be provided. extended {BCAB25F4-4D61-4fa5-BA85-D1700494BF67} Provides quality timestamp and extended information. extendedwithQualityTime {72463474-1088-4bec-86E6-74B2C4DC877D} Indicates that no quality is conveyed with the ICCP point. none {8ED33AF9-9BB8-4c92-955A-2212386EBD25} Indicates that quality and a timestamp are to be provided. qualityAndTime {3315A761-4AE5-4716-BB0F-C096EEEA083A} Indicates that only quality is to be provided. qualityOnly {BD8502A8-E49B-40e9-9957-D93C4F889E37} InterControl Centre scope available for exchange between the control centres in the bilateral table. iCC {C51D23B8-119D-46ba-8525-B2CB963D76C0} Virtual Control Centre Scope globally available. vCC {C9BFD40B-5151-4a57-9423-08E21004EBB6} 1963 edition. 1963 {6C40DD5F-EEC2-4db4-941B-C17385861F61} 1967 edition. 1967 {ACF457D4-C318-4c58-848E-DB4C9C06105D} 1973 edition. 1973 {0A9F53B1-8D38-494d-984F-34FDFEDAB3FC} 1974 edition. 1974 {5FF2DEC1-F0A5-4cd7-A445-70CB232780E4} 1977 edition. 1977 {EFF13CB9-A4E9-45dd-8BD8-1FCE43121154} 1978 edition. 1978 {6F53E5C1-A3F9-4fc0-BCCC-41D6A63DD3C5} 1979 edition. 1979 {2ECD5FF4-1590-4439-9210-556F9E2B1F6E} 1985 edition. 1985 {2EC67A28-9880-4140-885B-E447EF622C96} 1989 edition. 1989 {59764745-EC73-45f3-B32B-34CC461EB258} 1992 edition. 1992 {FC285C33-424F-4c6d-86EF-0F3F3037483B} 1993 edition. 1993 {6408E23E-521D-453f-B7FE-6F68AB10D0E7} 1995 edition. 1995 {F6F560F7-F343-4ecc-955F-935D6E4DE92F} 1997 edition. 1997 {250F5AD3-B5CD-4dc2-9B67-7C0CD555C011} 1998 edition. 1998 {05A74BEA-920E-4329-BD5D-FE9E90E029E3} 2004 edition. 2004 {42970755-F31B-43ba-B11D-5DF2CC42C27E} 2005 edition. 2005 {83B8A508-9C62-4932-BC28-97FE211FB403} 2007 edition. 2007 {366342B9-3F23-4d40-8825-38D9C9483C76} 2008 edition. 2008 {59A2835A-D246-49e9-9ECF-665503B5751A} 2010 edition. 2010 {31F782D4-570D-4e76-AC68-87C24E967552} 2011 edition. 2011 {E60793A5-9F55-4633-8312-3B8C1BB49C0B} 2012 edition. 2012 {E9AC03BF-07A0-4fc1-8EAF-0E99818C49E6} 2013 edition. 2013 {4374CC1D-CB96-48dd-8554-4D18A15631A6} No edition. none {36EFE84B-2EE9-4631-AE9A-DA16B135D4FC} Unknown edition. unknown {BEB9F61F-4E47-4759-8665-4E087A9CC221} Insulating liquids Determination of the breakdown voltage at power frequency Test method. 60156 {FB1C4E31-440F-4cff-844F-D7A5F6DC6AF2} Electric strength of insulating materials Test methods Part 1 Tests at power frequencies. 60243-1 {F18E897E-6F33-4016-A339-127492AF9BD5} Electric strength of insulating materials Test methods Part 2 Additional requirements for tests using direct voltage. 60243-2 {6110D1B7-9389-4f6d-9E09-567216EB7D41} Electric strength of insulating materials Test methods Part 3 Additional requirements for 1250 s impulse tests. 60243-3 {C5323E68-4987-4cdb-B258-681095C8ADC2} Insulating liquids Measurement of relative permittivity dielectric dissipation factor tan d and d.c. resistivity orMeasurement of relative permittivity dielectric dissipation factor and d.c. resistivity of insulating liquids orRecommended test cells for measuring the resistivity of insulating liquids and methods of cleaning the cells. 60247 {BC32E158-944B-47ca-A983-BDF6F57A21FD} Mineral insulating oils in electrical equipment Supervision and maintenance guidance. 60422 {D156A8FF-05D3-4a02-80AD-90B82E0B3638} Measurement of the average viscometric degree of polymerization of new and aged cellulosic electrically insulating materials. 60450 {371C1052-92D6-4bfd-BFF8-5287754AECC0} Oilfilled electrical equipment Sampling of gases and analysis of free and dissolved gasses Guidance orOilfilled electrical equipment Sampling of gases and of oil for analysis of free and dissolved gases Guidance orGuide for the sampling of gases and of oil form oilfilled electrical equipment and for the analysis of free and dissolved gases. 60567 {6DE8D074-80C5-41c1-8C95-1E00437864D4} Detection and determination of specified additives in mineral insulating oils orDetection and determination of specified antioxidant additives in insulating oils. 60666 {805CAC3D-3CEB-46b3-9C2E-5901FCB817D1} Insulating liquids Oilimpregnated paper and pressboard Determination of water by automatic coulometric Karl Fischer titration. 60814 {1F623371-B981-4349-8341-9C0B283FF25E} Insulating liquids Methods for counting and sizing particles orMethods for counting and sizing particles in insulating liquids. 60970 {3114A245-3F26-4217-8508-6BFD26D92CFD} Determination of polychlorinated biphenyls PCBs in mineral insulating oils by packed column gas chromatography GC.Withdrawn. 60997 {8439596B-813B-420d-A97E-E8BC2535E489} Unused hydrocarbon based insulating liquids Test methods for evaluating the oxidation stability. 61125 {D109DE8F-7C7D-444e-8A26-33E32CB5A35E} Mineral insulating oils Methods for the determination of 2furfural and related compounds. 61198 {97527D59-A690-4722-AC91-81E738186806} Insulating liquids Contamination by polychlorinated biphenyls PCBs Method of determination by capillary column gas chromatography. 61619 {56AD72DB-1A18-43a7-ABB1-DB5A5C726F46} Mineral insulating oils Determination of kinematic viscosity at very low temperatures. 61868 {3FDEC366-2C13-480d-817C-E62523D893E3} Insulating liquids Test method for detection of potentially corrosive sulphur in used and unused insulating oil. 62535 {57FD7C74-46DC-4c7c-AA33-DBA703DC5EC8} Test methods for quantitative determination of corrosive sulfur compounds in unused and used insulating liquids Part 1 Test method for quantitative determination of dibenzyldisulfide DBDS. 62697-1 {F9A106D9-1756-4f32-A836-F75BFE098A96} Fluids for electrotechnical applications Unused natural esters for transformers and similar electrical equipment. 62770 {0F37F434-5CC8-43dc-BBCB-12A0814E7958} 1978 standard edition. 1978 {C48DE724-26A7-44bd-BB82-2211318C01C3} 1995 standard edition. 1995 {781594C5-996E-4b52-A567-B71C7DB024F0} No standard edition. none {656296F3-4690-4d32-A9AC-EC9CC88D53E1} Unknown standard edition. unknown {B8D79C61-F556-4476-87F2-362C779D84BF} IEEE Guide for Diagnostic Field Testing of Electric Power Apparatus Part 1 Oil Filled Power Transformers Regulators and Reactors orIEEE Guide for Field Testing Power Apparatus Insulation. 62 {87F8704C-DE01-4a2d-AAC8-FF671EDAFC56} Indicates that IPv4 dotted decimal notation is in use. iPv4 {C6E2D879-BD9B-480f-B88C-177152D07A87} Indicates that an IPv6 dotted decimal is in use. iPv6 {8FC243AE-6376-439f-8FB1-8BE08FF478D0} 1973 standard edition. 1973 {EF88839F-468A-4458-A717-AF45A85E88BD} 1974 standard edition. 1974 {68D54C41-1FF0-4df6-B329-A054959AAE95} 1976 standard edition. 1976 {305E1FE7-E0E6-4216-B54E-538751FECD46} 1983 standard edition. 1983 {C6B5BC71-056E-4e84-A399-C9989D9DC72B} 1985 standard edition. 1985 {CF00A108-C167-4338-8943-6DFBE46C8141} 1988 standard edition. 1988 {F213E179-6DC7-434f-A573-B286B3E60DDA} 1992 standard edition. 1992 {65757644-E100-415a-A6FA-61070B293B8E} 1993 standard edition. 1993 {FBACB0A8-4F16-4bb6-84B2-6E29D7E153E9} 1994 standard edition. 1994 {76A7CAE4-767E-487a-BB9A-74E6CA65AD75} 1998 standard edition. 1998 {E6B765CA-0256-48d7-BF3A-F4B5E1150C7C} 2000 standard edition. 2000 {50C9162E-DB9A-416b-A59B-F29C467AB5F4} 2002 standard edition. 2002 {76D79666-6437-417b-A719-54F9488AE2B4} 2005 standard edition. 2005 {6EA02042-5B56-481c-9D7A-E01066296B06} 2008 standard edition. 2008 {D776E6B6-6CBD-4b01-8C6F-81D7BD1FBB4C} No standard edition. none {BDACDF86-1F57-44c8-9A3C-AC6868B7ED3C} Unknown standard edition. unknown {E108B7AE-5430-47a0-B3C6-CFD22F39BA7A} Paper and board Determination of tensile strength. 1924 {038CABD9-D397-404f-9AA7-F86D74E7A62C} Paper and board Determination of tensile properties Part 1 Constant rate of loading method. 1924-1 {211EC0AB-ADE7-40ac-80EA-FBE9AA5A4966} Paper and board Determination of tensile properties Part 2 Constant rate of elongation method 20 mmmin orPaper and board Determination of tensile properties Part 2 Constant rate of elongation method. 1924-2 {F88FCE9F-5932-463c-B297-50401665FA3D} Paper and board Determination of tensile properties Part 3 Constant rate of elongation method 100 mmmin. 1924-3 {02EBBC00-9D9C-45be-8CCB-0A9BE005DF4A} Determination of flash and fire points Cleveland open cup method copied directly from ASTM D92. 2592 {E4DD2545-ACAC-482e-ABF6-F830B1EB3B2B} Determination of flash point PenskyMartens closed cup method copied directly from ASTM D93 orPetroleum products and lubricants Determination of flash point PenskyMartens closed cup method copied directly from ASTM D93 orPetroleum products Determination of flash point PenskyMartens closed cup method copied directly from ASTM D93. 2719 {A8857633-0860-4853-A03E-7D080F705D5B} Petroleum products Determination of pour point orPetroleum oils Determination of pour point. 3016 {683E0BD5-B0B6-4bfb-B5D2-2A68B40B7A6D} Petroleum products Transparent and opaque liquids Determination of kinematic viscosity and calculation of dynamic viscosity. 3104 {87851F07-10A9-49ee-8F5C-780717B18384} Crude petroleum and liquid petroleum products Laboratory determination of density Hydrometer method orCrude petroleum and liquid petroleum products Laboratory determination of density or relative density Hydrometer method. 3675 {084666C0-E494-4050-B517-C344E8802C7E} Air gap line mode. ifag {7C8FAC4A-E06D-4cef-A07D-F6A953EB89BD} Full load system mode. iffl {94A0A534-CDD3-4cf6-8B58-0ADD44897655} No load system with saturation mode. ifnl {43B52704-9509-44bc-80D8-CFFF578F695E} Asset is deployed in use or is being put into use. inUse {11E437C2-410A-4b92-A930-B8FF66A4B722} Asset is not ready to be put into use. notReadyForUse {9F7FC0C7-8DCA-4016-8E17-E1C0855470B9} Asset is ready to be put into use. readyForUse {94AE9535-ACD7-4cad-ACA9-D0B476B11CB1} Input signal is amplitude of remote branch current. branchCurrent {EA532B35-5113-49e8-9394-7A91FDA6C9D7} Input signal is bus voltage frfont color0f0f0fequency. This could be a terminal frequency or remote frequency.font busFrequency {41AFCD63-391E-4207-8B2B-46DBFD9DA43C} Input signal is deviation of bus voltage frequfont color0f0f0fency. This could be a terminal frequency deviation or remote frequency deviation.font busFrequencyDeviation {05B69A90-D260-4f3f-B50C-C8CA58C23660} Input signal font color0f0f0fis bus voltage. This could be a terminal voltage or remote voltage.font busVoltage {ADF7172C-4782-435d-BCB6-8F77B8228143} Input signal is derivative of bus voltagfont color0f0f0fe. This could be a terminal voltage derivative or remote voltage derivative.font busVoltageDerivative {7257D0BA-639A-4c57-B1A6-B16C8B4A5413} Input signal is generator field current. fieldCurrent {2686F02C-A18A-49f8-A9EB-67492C02D8E3} Input signal is generator accelerating power. generatorAcceleratingPower {34DD5A5C-2473-47c3-B770-96AA87561AA6} Input signal is generator electrical power on rated iSi. generatorElectricalPower {858F5C6A-A7C5-435f-8254-D8CE92928486} Input signal is generator mechanical power. generatorMechanicalPower {A75FF07F-1834-4878-93CC-D2769DF9C6C6} Input signal is rotor or shaft angular frequency deviation. rotorAngularFrequencyDeviation {35873D9C-65AB-4ad0-80E1-A71AC07B91D6} Input signal is rotor or shaft speed angular frequency. rotorSpeed {55B94FB1-BF83-4636-B004-54286AB61A17} Analog value represents air pressure. AirPressureReading {697A35EB-DAF0-4d91-BA07-27CBEA21D045} Analog value represents SF6 gas pressure. SF6PressureReading {1A251ABC-F75E-4576-9A35-9A9B2BB75C95} Analog value represents High Pressure system air pressure. airPressureHPSystemReading {C8D05575-CF9B-4dc1-809F-020F9F90CC0A} Analog value represents Low Pressure system air pressure. airPressureLPSystemReading {46FBE798-84A1-409b-87C7-DEC98CD137CC} Analog value represents reading from compressor hour meter. compressorHourMeterReading {C946674D-E3F7-4beb-BE3D-0F5D3047E449} Are bushing oil levels OK? bushingOilLevelsOK {26A07024-E8C9-49de-B820-796087C21F97} Check oil level OK? checkOilLevelOK {BB3D5FE7-AB46-4c73-A12C-9DD6208EE6A9} Is the control cabinet heater on? controlCabinetHeaterOn {8661753A-2EEC-4b50-87C1-500AD33DF35F} Is the circuit switcher gas indicator normal? gasIndicatorNormal {A301BA6C-4FF2-4286-B174-362599883C31} Hydraulic fluid level OK? hydraulicFluidLevelOK {8590E228-356A-4bf0-A1CE-1B9B76F59476} Is the hydraulic oil level OK? Can apply to any individual pole. hydraulicOilLevelOK {70FF69F1-3ACE-45c0-9C79-4EC04A1C8A49} Count of ??. lowToHighPressureCount {B2F50519-0295-4182-8A9A-044C3B563273} Count of motor operations. motorOperationsCount {90B38379-EFAF-4e90-B30F-142DFF2904BD} Are the oil tank levels OK? oilTankLevelsOK {CB488747-8299-4b00-9783-8082D62E91C8} Count of operations. operationCount {E278D34E-5008-4ba5-BA16-7116BC6725F5} Count of pump motor operations. pumpMotorOperationCount {DCD0DA78-7D31-4869-AB3C-6EAA87195EF1} Is the spring pressure reading OK? Can apply to whole breaker or any individual pole. springPressureReadingOK {C35955CF-DD43-4319-A82A-02CB18F84EF3} Any visible damage andor oilairSF6 leaks?. visibleDamageOrLeaks {5915F358-4EB7-4868-8943-087CC7612EAE} heavy {5C10B536-BE0A-4207-AADB-D6B4919B66E8} light {C91C763D-DF3D-490a-BEA6-99D4FA6A15C1} veryHeavy {F3AB44A4-D010-488a-A4B7-D2C0999E77F9} veryLight {2197CD09-4DDB-4792-AF2E-CD0D47E17BB4} Export. E {9B132EC1-7471-46b5-9DAE-F706D912335A} Import. I {35CD5C12-3FBF-450e-995B-263794822645} Air blast. airBlast {439D64B2-44BF-4356-BABD-35CF23C7DD1A} Air magnetic. airMagnetic {32245187-CE72-4d0e-9FA1-86837885C9ED} Bulk oil. bulkOil {ED69C14F-5D6C-4e6c-BE73-B27A9281D597} Gas single pressure. gasSinglePressure {9FD11CC8-2CF9-4932-9C5E-94F0749D4622} Gas two pressure. gasTwoPressure {F3CDEEB2-B785-4ffc-ABCC-EDB354DDFCBC} Minimum oil. minimumOil {0E05A09C-F553-4332-BA29-D6C0E2ACA13D} Vacuum. vacuum {8A6B23DC-D402-4075-B940-700632ACA3D8} CREATED {CA98E320-D1A1-447d-BCF7-8C80199C6D6A} DELETED {9F3E3C7D-39AA-4f3e-9BED-31713D86BB5C} MODIFIED {66FEB25D-CB7A-4db3-8483-CE6F1E2458B2} CRITICAL {8F49D069-7ECD-4188-9E73-10BC7CA5F0F3} NONCRITICAL {FA8F410A-80DA-492f-853A-AAC80AD95073} END {C8DCE124-4544-4ce8-B2DB-C565987C8C0B} NA {4AB8F0EB-1230-4ba7-88CF-F86C960F0661} START {92081147-2EF6-4509-863F-4791DE776839} other {58F6042A-5F4B-4c9d-AF42-E7004EDF54A0} wires1to1 {AC2CE61E-F33E-401f-9FF8-BE73E458C745} wires2to1 {DAF59B3A-D567-44b7-8BD3-B43C8EEED312} wires3to1 {D125FC51-3FE1-46a9-BF7C-CC58C8BC2211} airNoFilling {6DA48504-873F-4af4-B794-4D931FE9C4A8} asphaltic {E984DAFF-A8A0-4b3e-BD42-022E592562C4} bluefill254 {908E4924-90A4-4d43-A252-BF2EA0FC2B02} epoxy {9EF99651-A0F5-40ed-81B0-748BCB2B3CB8} insoluseal {9CFAE881-3753-4a98-B1FC-E57B8FF06441} noFillPrefab {18AD660B-1C46-4ef5-AB8E-5C2E1883CD2F} noVoid {4DB06DA1-CF67-429e-81D1-F1ECC7C7BF2B} oil {2FAA85E6-724F-4732-AC5E-494F6D8C43DB} other {B4C8A436-28EA-4bc1-83B7-73AD5ED75FD4} petrolatum {D19861D8-B783-4291-9AA7-AD823797BAB1} GEN {7FAB9B8B-7532-45b0-9FA4-6298B99D7FF3} PUMP {3606DFF3-D324-4b28-9B8B-C29453FEE6E8} No standard edition. none {8EAE8589-7F4C-457f-B6F3-86739BAC9176} Unknown standard edition. unknown {7B57D3A6-E478-46b8-A76E-AA3200619E66} Laborelec test for methanol. methanol {8F5FBE00-AD7B-43f2-96AD-217C455D87EA} Site enclosed within a building. building {67DCE805-4247-4ad7-B365-62D0787C624C} Site with a customer. customerPremise {496053EF-0382-42cc-A0AC-19FAAA6F2659} Storehouse for supplies that also serves as a station for supporting crews. depot {9C30687D-9953-4dc7-A51E-670014F23FBC} Property owned or used by an external party that is not a customer. external {39552784-6DB4-4f92-ACB7-D45728C21028} Substation where the distribution and transmission networks meet and hence have mixed ownership and mixed operational control. gridSupplyPoint {38548786-DB4F-47b2-A804-8ECDCFD1D709} Place of storage e.g. a warehouse to put aside or accumulate material and equipment for use when needed. store {612C0577-35D6-43d1-96BC-A4D6374B8FF5} Transmission network switchyard. substation {A5A09EE3-5DDE-45b4-BDD8-9CE2C39FBBED} DOWN {8B1226B5-7E32-485e-9432-8612E6396267} UP {CE7FE6A3-0323-4003-9150-39DC3A70417E} Load forecast zone. LFZ {8D14D495-45C6-4986-AB4A-ACEC57D6ADC0} Metered sub system zone. LZMS {31BD165F-1498-48a5-9BE1-F6EB29A11217} The center of a phenomenon. Will typically be used with a Location with a single PositionPoint instance. center {48F9D82B-2E5C-4fc6-8FFD-3452747E4F42} The area or line of a phenomenon not the center. Will typically be used with a Location with multiple PositionPoint instances. extent {84105F6B-7EC8-41c9-A54B-73646078A162} Primary area to which an environmental alert applies. primary {1F2896EE-F037-4a98-B5D9-1F4AE9227124} Secondary area to which an environmental alert applies. secondary {80D1D265-3034-4723-87ED-B0FD7F2E2AC4} additionalQcurrent {AA661E5D-4401-4389-AC25-124FFFD607A8} vdcol {27865F62-75B8-4890-8C34-E14411877CB9} 1 Global Price Test. 1 {FDC66BF1-A6BD-4eea-B570-491325115632} 2 Global Conduct Test. 2 {8D2B54DF-3AD8-4a18-AE1C-DA9B72759D7C} 3 Global Impact Test. 3 {E50EEB6E-78DD-4a7a-B7D0-23DF2F40971C} 4 Local Price Test. 4 {511EFF13-F58F-4ee6-B523-65A7CD349616} 5 Local Conduct Test. 5 {EF7331F0-C5BC-40f6-BDE1-EE5EA363B982} 6 Local Impact Test. 6 {A820611B-740C-409e-AA9A-0A754E1347F1} Alternate. ALTERNATE {3767513C-D390-421c-B566-09767EE6C7E8} Normal. NORMAL {071E16C4-EC06-4c17-97C8-3FE0A1D2FE7D} Disabled D {2682B075-D08A-480d-AEFE-4BCBCD2DA6EA} Failed F {BAE18119-8F79-48c1-B646-4FC1D5B70416} Passed P {424596AA-F856-47ef-944C-37AB4E29E056} Skipped S {F45936F6-6934-41c4-98FC-B9BED6A2DEB0} ADD {9AD56F7C-4DB4-4b3e-BBCD-AA0FF37FD185} CHG {C6E1D0AA-E653-46e1-8ADE-874BF869C382} ADD {8AD03AB0-8584-41c4-8DAB-C8C2822E71B5} CHG {28F0D965-155B-4f82-A4BD-7EE8CC32A0FE} DEL {33CE8BA7-B545-4e47-BBDF-8E85356A890E} ACT {E606B8DC-9E76-4681-AC5A-D5B0AB7210F8} INS {170F3937-9051-44e5-8FFA-89B32A5D5E63} Captured during the billing period starting at midnight of the first day of the billing period as defined by the billing cycle day. If during the current billing period it specifies a period from the start of the current billing period until now. billingPeriod {28162C5F-9EFB-409b-8225-74B78FCF5FD8} Daily period starting at midnight. If for the current day this specifies the time from midnight to now. daily {6C5410FE-15C4-45e4-8A0E-82A4096B2755} Monthly period starting at midnight on the first day of the month. If within the current month this specifies the period from the start of the month until now. monthly {2D1A8FB6-F055-4722-83CD-5F635DA9A53B} Not applicable. none {C6DD668D-8A3B-4c0f-BF18-FAE2795C13DD} A season of time spanning multiple months. E.g. Summer Spring Fall and Winter based cycle. If within the current season it specifies the period from the start of the current season until now. seasonal {E16B0E47-C091-4102-8DB4-B720B51C41C5} For the period defined by the start and end of the TimePeriod element in the message. specifiedPeriod {6FD557E1-D896-4b49-A78B-8DE8F6B82670} Weekly period starting at midnight on the first day of the week and ending the instant before midnight the last day of the week. If within the current week it specifies the period from the start of the week until now. weekly {DCA2FC51-06DF-4c01-8B48-D0856FB531B5} The status of the event is currently in a active state.Active when sysdate is equal or greater than to planned start time active {4C2BB19C-52F4-4e4a-9BF9-FCFBA2004FAD} The status of the event is currently in a cancelled state.Cancelled stopped before planned start time or planned end time cancelled {D1CB8463-1E0C-43c1-9659-FE5BFD1B42A6} The status of the event is currently in a completed state.Complete when sysdate is equal to the release time completed {0BE48B1A-92DC-4b2b-ADD3-E9735F0321FA} The status of the event is currently in a planned state.Planned sysdate is less than planned start time planned {BE413E48-A31E-44f6-889C-E4EDD2E45CC5} Existing Transmission Contract. ETC {3247DD84-D4B6-4b1d-B9C0-E98636E8F96D} Low price taker. LPT {9667293F-931E-429d-8F09-95C381A7F31D} Price taker. PT {2ED80949-CC54-4bb0-9C17-BADEEA697806} Resource adequacy. RA {44B27D30-E018-4427-B5F5-CAE48C7B3B02} Regulatory must run. RGMR {EA731F57-231A-4522-BE53-E77B5C7DE1CF} Reliability Must Run. RMR {A5AB1431-B8E9-488a-BB18-48B8D8A6C56E} Reliability must take. RMT {44727B77-9603-497d-A746-DACE6A7D790F} Self provision. SP {0EE88180-E190-4676-B9AB-905ABFE754E7} Transmission Ownership Right. TOR {59A5180A-2003-45c5-B29B-396173559A5D} energy type EN {84FDD6C9-9164-4db2-9D18-8EECAC447C21} Load following down LFD {2E6263D4-2AAD-4a37-AFE8-279BFAB0A798} Load following up LFU {CBD339B7-E081-4f57-982F-10D07957C3CD} non spinning reserve NR {AAC473EC-8B17-4ce8-9C37-C128EFF445BD} Residual Unit Commitment RC {4F694BBC-9CD5-49e7-B5B7-417A5150E557} regulation down RD {41FBA785-6B63-4f90-B22B-E55AB80ED8FA} Regulation REG {9F43267F-10A6-494f-8122-E50723D913C7} regulation up RU {87151667-13A8-495b-B332-044839661E8D} spinning reserve SR {5A5F9766-1686-4062-9277-CE70A4EB97A3} AS {2CC70FE0-F349-43e2-BDC8-9DD0F0AE0A66} non spinning reserve NR {B038941C-3CDC-437f-A354-C818DA8B6291} regulation down RD {4E11B343-DEFE-44ba-995E-6D25BE73C961} regulation up RU {9D6B9050-8F20-4a71-A928-A4EBD6073A72} spinning reserve SR {CA75DF6A-0F81-4c98-A1AB-D1740C4BA88A} A party that has a contract proving financial security and identifying balance responsibility with the Imbalance Settlement Responsible of the Market Balance Area entitling the party to operate in the market. This is the only role allowing a party to nominate energy on a wholesale level.biAdditional informationibThe meaning of the word balance in this context signifies that the quantity contracted to provide or to consume shall be equal to the quantity really provided or consumed. Equivalent to Program responsible party in the Netherlands. Equivalent to Balance group manager in Germany. Equivalent to market agent in Spain. BalanceResponsibleParty {C3AAFCCE-2962-407b-B63E-29590C2914A1} A party that markets the difference between actual metered energy consumption and the energy bought with firm energy contracts by the Party Connected to the Grid. In addition the Balance Supplier markets any difference with the firm energy contract of the Party Connected to the Grid and the metered production.biAdditional informationibThere is only one Balance Supplier for each Accounting Point. BalanceSupplier {C78D24CF-E285-4270-965B-5728D3B695C5} The party responsible for invoicing a concerned party. BillingAgent {89884C08-822F-41a3-82E2-EDF24B5A9408} A party that is selling or buying energy on a firm basis a fixed volume per market time period. BlockEnergyTrader {D1FFF02D-6B19-4b61-84FD-E81DB80EB8B3} A party acting on behalf of the System Operators involved responsible for establishing a coordinated Offered Capacity andor Net Transfer Capacity NTC andor Available Transfer Capacity ATC between several Market Balance Areas. CapacityCoordinator {07C9BB84-2FFC-440d-BD2A-CA570A6011A7} A party that has a contract to participate in the Capacity Market to acquire capacity through a Transmission Capacity Allocator.The capacity may be acquired on behalf of an Interconnection Trade Responsible or for sale on secondary capacity markets. CapacityTrader {02736890-4C9D-4f0c-BEF5-CEC6C6A2947D} A party that consumes electricity.biAdditional informationibThis is a Type of Party Connected to the Grid. Consumer {5F4CF05F-EDF9-40d6-AD2E-5CF8B617D222} A party who can be brought to rights legally and financially for any imbalance between enegry nominated and consumed for all associated Accounting Points.biAdditional informationibThis is a type of Balance Responsible Party. ConsumptionResponsibleParty {E374757E-BCB6-4615-823C-3F2FD03DA6F3} Responsible for 1. The coordination of exchange programs between its related Market Balance Areas and for the exchanges between its associated Control Areas.2. The load frequency control for its own area.3. The coordination of the correction of time deviations. ControlAreaOperator {5FE2B642-B6A7-45ca-8B6F-80B6B3C0D470} Responsible for 1. The coordination of exchanges between its associated Control Blocks and the organisation of the coordination of exchange programs between its related Control Areas.2. The load frequency control within its own block and ensuring that its Control Areas respect their obligations in respect to load frequency control and time deviation.3. The organisation of the settlement andor compensation between its Control Areas. ControlBlockOperator {13E5A3B1-E672-4e46-96C2-141E63500859} Responsible for 1. The coordination of exchange programs between its related Control Blocks and for the exchanges between its associated Coordination Center Zones.2. Ensuring that its Control Blocks respect their obligations in respect to load frequency control.3. Calculating the time deviation in cooperation with the associated coordination centers.4. Carrying out the settlement andor compensation between its Control Blocks and against the other Coordination Center Zones. CoordinationCenterOperator {5C328593-F3DE-48f7-9952-E6D4771886E7} A party responsible for providing access to the grid through an Accounting Point and its use for energy consumption or production to the Party Connected to the Grid. GridAccessProvider {EA8B33C1-4301-4788-8AC9-69AA5129A049} A party that operates one or more grids. GridOperator {9C7A11A9-11B9-4737-BF28-D021A67BB9A4} A party that is responsible for settlement of the difference between the contracted quantities and the realised quantities of energy products for the Balance Responsible Parties in a Market Balance Area.NoteThe Imbalance Settlement Responsible has not the responsibility to invoice. The Imbalance Settlement Responsible may delegate the invoicing responsibility to a more generic role such as a Billing Agent. ImbalanceSettlementResponsible {F77A0704-FAE2-477c-802F-B41D94F8D339} Is a Balance Responsible Party or depends on one. They are recognized by the Nomination Validator for the nomination of already allocated capacity.biAdditional informationibThis is a type of Balance Responsible Party. InterconnectionTradeResponsible {6B56CF05-A488-4a93-8EB1-02E2393458EE} Responsible for the management of the available tenders for all Acquiring System Operators to establish the order of the reserve capacity that can be activated. MOLResponsible {3C9539D6-111F-43e3-8B62-B529FBDEBBB7} Market Information Aggregator A party that provides market related information that has been compiled from the figures supplied by different actors in the market. This information may also be published or distributed for general use.biNoteibThe Market Information Aggregator may receive information from any market participant that is relevant for publication or distribution. MarketInformationAggregator {EBE5F0AA-F215-440d-BFAD-1B7CBBDB05FA} The unique power exchange of trades for the actual delivery of energy that receives the bids from the Balance Responsible Parties that have a contract to bid. The Market Operator determines the market energy price for the Market Balance Area after applying technical constraints from the System Operator. It may also establish the price for the reconciliation within a Metering Grid Area. MarketOperator {502E0B4B-A89A-413d-89ED-FDD192274734} A party responsible for keeping a database of meters. MeterAdministrator {1D3A8167-ECE2-42b8-9454-8CDB35A41C49} A party responsible for installing maintaining testing certifying and decommissioning physical meters. MeterOperator {FAA20AD9-FB5B-4501-A787-97D0DD3D190C} A party responsible for the establishment and qualification of metered data from the Metered Data Responsible. This data is aggregated according to a defined set of market rules. MeteredDataAggregator {2C5A1408-092A-454e-B08C-E188B64D8D66} A party responsible for meter reading and quality control of the reading. MeteredDataCollector {A40556A4-583A-45bf-A2D1-4760B3F18324} A party responsible for the establishment and validation of metered data based on the collected data received from the Metered Data Collector. The party is responsible for the history of metered data for a Metering Point. MeteredDataResponsible {8585EAA7-125E-439e-A242-3488CEA7D086} A party responsible for registering the parties linked to the metering points in a Metering Grid Area. They are also responsible for maintaining the Metering Point technical specifications. They are responsible for creating and terminating metering points. MeteringPointAdministrator {D874249D-7BA9-4766-93FB-69D566D569B5} Has the responsibility of ensuring that all capacity nominated is within the allowed limits and confirming all valid nominations to all involved parties. They inform the Interconnection Trade Responsible of the maximum nominated capacity allowed. Depending on market rules for a given interconnection the corresponding System Operators may appoint one Nomination Validator. NominationValidator {6ECFA6CF-938D-4ab3-A439-E4950CE7AECE} A party that contracts for the right to consume or produce electricity at an Accounting Point. PartyConnectedToTheGrid {0A55202E-7915-4d74-B842-0872C94551CC} A party that produces electricity.biAdditional informationibThis is a type of Party Connected to the Grid. Producer {0A69244F-6CA0-4041-A4B7-2B936282C568} A party who can be brought to rights legally and financially for any imbalance between energy nominated and produced for all associated Accounting Points.biAdditional informationibThis is a type of Balance Responsible Party. ProductionResponsibleParty {5295D5CD-7B08-4a2c-A9B2-B378EC2379DA} A party that is financially accountable for the reconciled volume of energy products for a profiled Accounting Point. ReconciliationAccountable {D8B612FD-28C2-4f05-848B-673540A80EA8} A party that is responsible for reconciling within a Metering Grid Area the volumes used in the imbalance settlement process for profiled Accounting Points and the actual metered quantities.NoteThe Reconciliation Responsible may delegate the invoicing responsibility to a more generic role such as a Billing Agent. ReconciliationResponsible {ED6D640F-0676-4936-B789-0CE8B7B53B8C} Informs the market of reserve requirements receives tenders against the requirements and in compliance with the prequalification criteria determines what tenders meet requirements and assigns tenders. ReserveAllocator {11ACC95C-C10D-4f92-9B3C-A79A0BAAF98B} A role that manages a resource object and provides the schedules for it ResourceProvider {7BC08364-DBDA-4270-9EBA-F9CCC2F9C80B} A party that is responsible for the schedule information and its exchange on behalf of a Balance Responsible Party. For example in the Polish market a Scheduling Coordinator is responsible for information interchange for scheduling and settlement. SchedulingCoordinator {CDE73D24-C773-4f2b-96B5-81F2BED00CF6} A party that is responsible for a stable power system operationincluding the organisation of physical balance through a transmission grid in a geographical area. The System Operator will also determine and be responsible for cross border capacity and exchanges. If necessary they may reduce allocated capacity to ensure operational stability. Transmission as mentioned above means the transport of electricity on the extra high or high voltage network with a view to its delivery to final customers or to distributors. Operation of transmission includes as well the tasks of system operation concerning its management of energy flows reliability of the system and availability of all necessary system services. definition taken from the ENTSOE RGCE Operation handbook Glossary.biNote ibadditional obligations may be imposed through local market rules. SystemOperator {33BE69AC-8297-44f5-B851-558A8A8AA806} A party who can be brought to rights legally and financially for any imbalance between energy nominated and consumed for all associated Accounting Points.biNoteibA power exchange without any privileged responsibilities acts as a Trade Responsible Party.biAdditional informationibThis is a type of Balance Responsible Party. TradeResponsibleParty {7F3CFB82-BCF0-4d92-A2D0-66B430A492EA} Manages the allocation of transmission capacity for an Allocated Capacity Area.biFor explicit auctionsibThe Transmission Capacity Allocator manages on behalf of the System Operators the allocation of available transmission capacity for an Allocated capacity Area. They offer the available transmission capacity to the market allocates the available transmission capacity to individual Capacity Traders and calculates the billing amount of already allocated capacities to the Capacity Traders. TransmissionCapacityAllocator {2D069218-BCC1-4d3f-A09C-3FC861E8EF69} Balancing authority. balancingAuthority {6F8E5D0C-AA40-4652-84ED-734FE0456570} Competitive retailer. competitiveRetailer {47422C7D-9502-434b-A65F-93BE7F5C7A64} Compliance monitor. complianceMonitor {55D7DADB-E06D-40c3-9523-46AF9D210630} Distribution provider. distributionProvider {1D7318DD-9F0A-4696-AD89-E38B341E8289} Energy service consumer. energyServiceConsumer {7DBB846A-EF6A-47a4-95B1-E9498A09ACF5} Generator merchant operator. generatorOperator {46D65467-7BCA-4297-8EAB-33972815ABC4} Generator merchant owner. generatorOwner {AD6BC660-035D-42e8-A3B6-40E275A44252} Interchange authority. interchangeAuthority {1BB3808E-DD50-4b18-94E2-4260BA6D00EB} Load serving entity. loadServingEntity {E08742CC-D417-4316-8F4F-14A94AA3062D} Planning authority. planningAuthority {7CCC8875-5825-4beb-AB81-7C79D07586F9} Purchasing selling entity. purchasingSellingEntity {6A3633A7-C229-4a45-8902-EF16F1E7F8FF} Reliability authority. reliabilityAuthority {FE1C5B36-D7F5-44b4-9148-460099C3B111} Resource planner. resourcePlanner {DECFE64A-128D-4fab-88FF-FEFF49BA9669} Standards developer. standardsDeveloper {145C576B-7AEC-41a6-A042-14D96D8D284A} Transmission operator. transmissionOperator {01891C0C-584C-4ef9-B912-AFFF978864B5} Transmission owner. transmissionOwner {4644887E-B97D-4f8c-9202-EB28D140DAB7} Transmission planner. transmissionPlanner {391C235F-10F4-431b-B99F-47C1DF90529B} Transmission service provider. transmissionServiceProvider {782264D2-A4DA-438e-9C0A-74AE63AC1917} retrieveDefaultBidCurves {7B8AE87C-DBFA-429f-B709-B18CFF5C1B07} retrieveMPMResults {E682D0D6-D08E-41ee-92A6-814BECC08875} retrieveMarketAwards {FDDFF250-969C-4ded-B643-F90CBF4749D0} retrieveSchedulePrices {FD40E494-5006-4153-8C9A-D0D091DBBFA2} retrieveStartUpShutDownInstructions {E80C54F1-0F55-4f3c-AE50-5DE95F2C56C6} DAILY_INITIAL_CREDIT {C10A8321-A95A-4599-86B7-45C92A1B4763} DAILY_INITIAL_MARKET {F59526BC-DB61-4af9-8837-D6C0D04E70CD} DAILY_RECALC_MARKET {2F7B123B-4769-4d4f-B1AC-B5271A6EB53D} MONTHLY_INITIAL_MARKET {97F00589-DE57-4b78-B405-3B0E29EC6413} MONTHLY_RECALC_MARKET {5C4FA3CE-DCBD-4ceb-B255-290EDBA9FE58} APPROVED {315D7F8F-E6FD-46e6-B883-3C5C8534FD2D} CANCELLED {D4B7FA95-EDEA-4a57-82CA-1FDCCFB5BDCD} CREDIT {91FBE1AC-3FF6-4872-8944-CEABD56ACAF6} MARKET_INITIAL {5E013820-A7D8-4c30-9A39-F39B3997D7B3} MARKET_RECALC {39E196A2-664D-49ee-AAAC-7C1210098BCB} CHARGE_CODE_INTERVAL_DETAIL {F1450606-E0F3-4a4c-9BA0-348751736D99} CHARGE_CODE_INTERVAL_TOTAL {F68050B4-7262-4fd9-87F5-24A67465DEC3} CHARGE_CODE_SUMMARY {B07C77C4-2A17-46b6-BA9D-182D6364289B} CHARGE_GROUP {670CA605-301D-4800-8223-456D19A2C95C} PARENT_CHARGE_GROUP {4F59B72D-237C-4f8f-B603-4CFE96D00F6F} TRADE_DATE {3E50D4A6-C1C0-4cbd-A032-BA5595E68694} Day ahead market. DAM {891C81EB-EFFA-4daf-88A7-7C23075ABDC1} Hour Ahead Market. HAM {CC7C140B-8ADC-406a-9A2B-DB818199FCCB} Real time market. RTM {D86CA228-F06F-404e-B74C-D7C2F0BFF312} Residual Unit Commitment. RUC {F0871DEA-187F-4824-94B9-7DF280295FBE} alarm {05117A15-F6B9-4afc-80E2-F629DE04F313} apTitle {98BB83F2-90C6-48cc-A24C-103171AC55E7} apparentPowerFactor {58A0AFF5-AF60-42c9-A5F2-E5188887CA6B} applicationContext {55D45962-8A66-4ae6-9C81-53685ECBC7D9} assetNumber {B5ED47AE-1EEC-4472-A36E-41DF53F69185} Sound audibleVolume {F097DC53-5922-43d6-9AF8-30C3A5BD03E8} bandwidth {99BBE4CB-AEED-4162-8CC1-EFB92DBC37AF} batteryCarryover {C797A830-2789-47ce-8F7D-3DDBA06A6BE1} batteryVoltage {7C57F241-E053-4f1b-8036-A17BC4E99315} Customers bill for the Currency billCarryover {81081589-01C7-4d3a-9F89-1ED6D050F9F9} Customers bill for the previous billing period Currency billLastPeriod {71FFA09F-7A87-4418-8F54-AAC9458D4DD5} Customers bill as known thus far within the present billing period Currency billToDate {7C3C4FC9-4BB0-4330-BE9B-1FCA267DC4DA} broadcastAddress {2D67DD04-6B76-4901-AE47-9AF725DECC07} Monthly fee for connection to commodity. connectionFee {ED14BAE0-2268-444e-B6CF-C31DE30C98B2} funds currency {8B89DA89-364F-46be-98EC-F5DFABFBC6DA} current {E0FFAD2C-EA19-4430-A535-CA283C65EA31} currentAngle {7657045A-3CC5-4f5b-99FF-8AA902980DC2} currentImbalance {F4DDD642-4A25-4869-A3B3-DAB913D74D03} dataOverflowAlarm {025D27AA-62C2-4b71-956E-7B8793999A09} date {91C98943-F59E-4bb9-B27A-7490DB70659E} demand {866C50B1-FA08-4bb9-8304-EE2B093CAB80} demandLimit {3EC7B1D3-8352-4d1a-9E46-78783FBAFB52} Usually expressed as a count as part of a billing cycle demandReset {5AC65D48-EADA-401a-9EDF-3BCB6680BE39} deviceAddressType1 {BBF4F2A3-D67A-48fa-A50F-F056513B19BD} deviceAddressType2 {7BCC0028-1DE3-434b-BEAA-4B5269E3BD54} deviceAddressType3 {329A1FF7-ED64-4add-AFA0-AC8A962F6919} deviceAddressType4 {8A5F710F-A513-47e9-980B-821FD50A2070} deviceClass {15962859-2CEB-4054-9A26-F5FBF41C9154} diagnostic {661A1965-6185-4e78-9116-21D6634B8240} distance {9CF555B8-7DAB-4039-AB95-5D32FF713FD5} distortionPowerFactor {82B97F23-C84C-48cf-AAB0-041B3D3BD0BA} distortionVoltAmp {86C7BBF9-44E4-4e10-9DE6-12889D799486} electronicSerialNumber {549DB8C1-9805-4551-9D16-4B5C9F607913} emergencyLimit {D73C721F-2071-4622-97F5-8DDF43116E42} encoderTamper {844E86D1-4C66-4731-9F5C-1218382E8F1C} endDeviceID {DEC70F34-E0D8-47e2-B77E-F3D77D021932} energization {8173F83A-6024-4e58-ADA0-21C556F8AD01} energizationLoadSide {EE6B728B-F159-44b3-847E-EF5CCB7634AF} energy {B7C5FA71-4287-47bb-80FF-11895754CFA6} fan {043B948C-5304-42a2-9897-41DC3730AF09} frequency {2AC7B5F3-51D0-4bce-85A2-52C846583022} Usually expressed as a count frequencyExcursion {166B730D-7474-450f-B5B8-7B893D55A5FF} Dup with currency fund {979802BB-6839-41c7-A7B9-7C66B787ACE7} groupAddressType1 {A52137D6-BF83-4bc0-89BC-3995C1584CA2} groupAddressType2 {9D572AE4-C074-4f47-979B-0F7A5447FE48} groupAddressType3 {D604E907-DAF5-4609-8559-78FD13D6A8B8} groupAddressType4 {C74916B4-A1BF-4e83-A5E9-6C13F618793D} ieee1366ASAI {3BB6E245-644A-4106-9AA4-CF8B4520B944} ieee1366ASIDI {1EEF193B-F325-42db-BBD1-BF797D32AFAA} ieee1366ASIFI {8AC78E50-A22C-4418-8A57-FD83200D111E} ieee1366CAIDI {EE23D646-BB5A-45f0-9B1A-2237BF83034D} ieee1366CAIFI {828B66D7-3C0B-45f3-8354-81F14BF13DDB} ieee1366CEMIn {CDC7A9B1-DB9E-49f7-8159-DDD58BA3E193} ieee1366CEMSMIn {6EBBB932-1EDD-4978-BD0E-6C752B0C2CD4} ieee1366CTAIDI {5BE8E8D4-D9E3-48eb-9140-211D1CC2BD11} ieee1366MAIFI {6BE27834-6BA6-4d18-A73A-BF34E790F5B4} ieee1366MAIFIe {CA24A732-69A3-40fe-A950-66307FE00633} ieee1366MomentaryInterruption {FF86B079-98E1-4a0c-A475-F6318C686479} ieee1366MomentaryInterruptionEvent {BC89B694-0463-47f0-9A26-2D74FA8A2DC9} ieee1366SAIDI {8578BE8E-D331-4103-B9FA-4C2055924E4B} ieee1366SAIFI {587227E1-1B9A-4a96-B9DC-D200B343BFDE} ieee1366SustainedInterruption {7ABCFF59-918B-4d25-8CB5-1E174BC59C4C} interruptionBehaviour {CFEF4250-3157-4615-B158-963047D71AAA} inversionTamper {0FDAAD03-9DDF-46d5-BE13-DFAB9CDB5EEA} ipAddress {C08F20E3-8DA6-4980-A3C8-69854E045D3B} lineLoss {4D1C3394-86F2-4b3a-8AAD-8CCE5DB05840} loadInterrupt {0457FBD8-1745-4497-A736-57B7ECB1965E} loadShed {665B7741-441E-42e5-AB06-334DF7C6DB84} loss {AAD1916A-8901-4df2-8B13-D2DD46949CEF} macAddress {E8078C59-9F25-48f7-8B8B-1BC1F1B107E8} maintenance {6E9E2794-EFFC-49a1-92AA-3A1FC31EE5A1} mfgAssignedConfigurationID {D4957BD3-06E9-48c4-9FF5-40E9EA28FD17} mfgAssignedPhysicalSerialNumber {C5770970-3FD2-43b2-8DD1-DF6ED9D6CCD9} mfgAssignedProductNumber {955721EB-726A-4c00-910F-D3561D355D6C} mfgAssignedUniqueCommunicationAddress {FC08E73E-030C-4fd9-9A2A-FB401D32B220} multiCastAddress {BF332DF4-730D-4b8b-9841-B5EF900224C1} negativeSequence {530B37FA-8F9C-4b1a-B77F-26568E1D3FC1} Not Applicable none {A8C17956-A6B8-4dc0-9B05-7AD306CF5F09} oneWayAddress {6E43CE9D-7DED-4c32-B74B-3DF9AFB64F45} phasorPowerFactor {BE7FF6D2-8569-4a69-B818-6BB9FE23259D} phasorReactivePower {2D682D1F-69E5-4c41-AC65-A232E10B2C61} physicalTamper {668C70FE-5949-4c4d-9B6F-A2F0F992B357} positiveSequence {96655FEA-A000-447e-B4BF-0DE1E641F4C4} power {2BF37ADD-3D10-4b45-9575-393011957CFA} powerFactor {89FAFC96-8EAE-45b4-A7D9-20B7315321BF} powerLossTamper {312A6578-6368-4470-BD01-B6AE8E86D1D4} powerOutage {50AAD20B-9A44-435d-8A3F-D731A324D661} powerQuality {7B77AD18-8BFC-45f6-9480-285A07A597F8} powerRestoration {D4DDC66D-1F46-4029-91E2-0E6A60D98BAE} programmed {24F2A245-F872-46ab-9AB1-BCAB7343E2C1} pushbutton {28889F35-2E5D-4d8e-9417-42597468AE0D} quantityPower {01EC9370-E48D-4118-82FD-4C9BCC646B14} relayActivation {3B2A6779-B31C-4f8b-8503-B779C567C855} Usually expressed as a count relayCycle {86A3F1F1-358C-4200-B0EE-1472FD17DC39} removalTamper {261FE025-3811-4f89-A6CB-8C92260F697A} reprogrammingTamper {24BF3BDF-32CF-4c35-BC6D-6A06EF5BCEF3} reverseRotationTamper {9081F63D-CCA7-4ece-993F-E9414038DAF4} or Voltage Dip sag {16A415AB-DD55-4f3a-A099-D27C52424764} signalStrength {F9581512-600A-46d9-A979-022325235626} Moved here from Attribute 9 UOM signaltoNoiseRatio {C0053855-8BAD-4b82-BF9F-54B2BBFCA9F4} swell {9AC24DC5-3AAF-43f9-B0E4-1947A25E5212} switchArmed {593799CD-9C73-407e-8F5C-529CE83C0F46} switchDisabled {A7A218EB-49E6-471f-B9B6-DD1B6FB2BF87} switchPosition {3B07AED9-B7F7-459f-9DA1-CE772896BC3C} tamper {0EEFFEB7-AE56-49ee-8141-140C2464F9B7} tapPosition {6FE20EBA-5937-4e59-9E6D-62BD5C39B5B7} tariffRate {8341A8D8-F25A-49c1-9259-E344B0F5796C} temperature {182F45AD-76DC-498e-AB6A-0F846D2D2D5D} totalHarmonicDistortion {EAC4C364-818A-4ed7-9750-462A77940FC8} transformerLoss {9AB763A5-D1D2-4f4e-A14A-3BF24584114E} twoWayAddress {47425F63-88C0-4754-A309-960A8DFFAD91} unipedeVoltageDip10to15 {1249526E-96A8-4e8a-89AF-8DAFC5B6EEAB} unipedeVoltageDip15to30 {56F576F9-3BCA-4cc2-BFFA-565DA30FDDA1} unipedeVoltageDip30to60 {6AAD26C4-D28B-4f62-9E71-FC830C6B5C68} unipedeVoltageDip60to90 {EBAAB024-7FCA-43e6-B360-138DB91855D9} unipedeVoltageDip90to100 {A7AC5005-F2B0-4c86-81FB-3F9191183827} voltage {DE5DC474-9698-4aee-B5A6-A7662EDB0634} voltageAngle {097F8B43-8E05-4d0b-8C1E-07A51ECD1CBC} voltageExcursion {1DE4684C-4D0B-429f-AC49-B2F1EA0CB02C} voltageImbalance {1B063BBE-B148-46c7-95FA-CE2702CCDA43} Clarified from Ed. 1. to indicate fluid volume volume {8CEC360C-DB0A-4adc-8E09-1FD720940B6F} volumetricFlow {F23A8B8D-6428-4a0d-BF2B-ABBB395102E3} watchdogTimeout {331DE91B-0BA0-461c-AF04-48AE75428225} zeroFlowDuration {B6BC7C99-ECCE-41b0-AC18-BCA23FB4B875} zeroSequence {C96341A5-8F44-49a8-B4D8-FBCBCB616571} ACE {0FA0B70E-B0B3-4950-ADEA-51006178823A} GMOL {57EF2852-62CF-4ff8-837B-3ECB59BD9BCB} GNOL {9ED2A822-6B02-4d66-9B23-36B0F547B26F} GO {4D7E5067-F201-4561-9990-6E884C861C2C} GR {0712319C-5F8C-482e-9170-643FAE255A3C} GS {799D8013-F4E8-4172-96A9-043A882C525A} INADV {B5D73677-D880-44ba-9A7D-008E2C7C890B} OARL {1E5EC7EC-0D1B-40de-9DD2-237189AEC425} PF {EEA27A15-26B8-4721-A4F3-3DB1F3D48658} PIAL {14D3339E-3F29-42fc-AA00-1F548C83545C} PIL {A00F6BD6-9947-412f-A60C-E58AC8F0F265} PIML {AE387939-FB22-4e61-B82C-EFB09D47C9F6} POAL {EA03C42C-0AB3-4448-8CD2-C337AE09451E} POL {097C6448-17B5-491a-8DCA-0FB47AF2972E} PP {0DB7C1D0-C76F-400b-B310-D19CC9B97F27} SL {252ACA0D-1FE6-4409-B6A3-2FB09E740BDB} 15minute fifteenMinute {D6F06CAD-18C9-42d8-B9CA-B4510C490D1D} 5minute fiveMinute {035A25E5-6AB6-4c0d-9F0B-51D0008468CE} 10minute Fixed Block fixedBlock10Min {4B9E4326-E713-4699-A8C5-F39FDBC372E8} 15minute Fixed Block fixedBlock15Min {FF8E972C-1C3E-4f40-A8A2-21A3CFA846B6} 1minute Fixed Block fixedBlock1Min {C1B1F10A-0D80-419d-B0E4-529254D5AE82} 20minute Fixed Block fixedBlock20Min {E2E2DE00-07AE-44fa-B2A9-B314E19E6B4E} 30minute Fixed Block fixedBlock30Min {60A8C17B-21E4-4c63-B678-D76C410E8B76} 5minute Fixed Block fixedBlock5Min {425B16A1-D79F-4194-99AB-C8DF00838CD4} 60minute Fixed Block fixedBlock60Min {03AF44AE-3CDF-4f9b-B555-3E7A3C21E82C} Not applicable. none {FD4D33BC-3EC1-4919-A63F-FB7A8A81E70D} 1minute oneMinute {E9FC29CB-8963-4e4f-9D05-B6B7623D1973} Within the present period of time present {2C3BBDC9-D044-4da8-98E7-A30DBBEFD232} Shifted within the previous monthly cycle and data set previous {D7A26C99-5F5E-4630-9D4D-0093EE51C739} 10minute Rolling Block with 1minute subintervals rollingBlock10MinIntvl1MinSubIntvl {80729BDD-6E54-4315-A46F-1C7E6DEA4481} 10minute Rolling Block with 2minute subintervals rollingBlock10MinIntvl2MinSubIntvl {9C0B7FA4-1728-42ac-8660-B52F7FF214CC} 10minute Rolling Block with 5minute subintervals rollingBlock10MinIntvl5MinSubIntvl {55EE1F3C-E336-4977-BEA2-735627D947D9} 15minute Rolling Block with 1minute subintervals rollingBlock15MinIntvl1MinSubIntvl {1A8CF1B9-6B10-4a67-B66C-6FB0391BD734} 15minute Rolling Block with 3minute subintervals rollingBlock15MinIntvl3MinSubIntvl {5F3B4D4C-A2EF-4a15-848E-8446F357358E} 15minute Rolling Block with 5minute subintervals rollingBlock15MinIntvl5MinSubIntvl {02859A96-6A9B-4059-92E9-D35E8FCFE795} 30minute Rolling Block with 10minute subintervals rollingBlock30MinIntvl10MinSubIntvl {50BF1585-FFC2-4a0e-84C5-DFF0431C65BC} 30minute Rolling Block with 15minute subintervals rollingBlock30MinIntvl15MinSubIntvl {17B2B4EA-B1FC-4fc0-93A8-DCC85B394C13} 30minute Rolling Block with 2minute subintervals rollingBlock30MinIntvl2MinSubIntvl {09A15EB1-45C5-4ef4-AB64-A36D34694C13} 30minute Rolling Block with 3minute subintervals rollingBlock30MinIntvl3MinSubIntvl {DECD7909-66E5-4e90-84A7-26C550779BCC} 30minute Rolling Block with 5minute subintervals. rollingBlock30MinIntvl5MinSubIntvl {E4655F7C-69FE-48e7-9CB8-A7EE26A5C2E8} 30minute Rolling Block with 6minute subintervals rollingBlock30MinIntvl6MinSubIntvl {AADD0246-C750-492c-B0D0-CFFD49FA2FC3} 5minute Rolling Block with 1minute subintervals rollingBlock5MinIntvl1MinSubIntvl {46FC902F-1526-4e05-90AE-462779745425} 60minute Rolling Block with 10minute subintervals rollingBlock60MinIntvl10MinSubIntvl {D17B3727-8E4A-4344-927F-29E312B9FC07} 60minute Rolling Block with 12minute subintervals rollingBlock60MinIntvl12MinSubIntvl {C3D911B2-0EC8-459e-B27D-8C0CD3917C69} 60minute Rolling Block with 15minute subintervals rollingBlock60MinIntvl15MinSubIntvl {11186874-64B9-4b12-8BAD-D094049618BB} 60minute Rolling Block with 20minute subintervals rollingBlock60MinIntvl20MinSubIntvl {12A9FDE0-6E63-4c4b-B0C1-99C1498BAD9F} 60minute Rolling Block with 30minute subintervals rollingBlock60MinIntvl30MinSubIntvl {4B5CD310-43A1-449c-A8F6-8A5D967809B7} 60minute Rolling Block with 4minute subintervals rollingBlock60MinIntvl4MinSubIntvl {87E5F8B5-BC33-4cf0-B5FF-AA00BFE2B33B} 60minute Rolling Block with 5minute subintervals rollingBlock60MinIntvl5MinSubIntvl {F7D738DD-991D-41d0-ACA8-7EBE050725C6} 60minute Rolling Block with 6minute subintervals rollingBlock60MinIntvl6MinSubIntvl {ABD861D9-2A96-46fb-BB20-8DB0398E4556} 60minute sixtyMinute {87EA2C65-C6EC-45b5-8240-E478D2951D8D} 10minute tenMinute {9118A5F7-C0D1-4e25-8C90-7E58E237AA7C} 30minute thirtyMinute {BAE50016-8363-490a-9BEC-ADDD4D25303A} 3minute threeMinute {1C373062-F881-42bc-8EDB-EB29B082D3CC} 20minute interval twentyMinute {AEADF8B1-8239-4360-B86C-EBE77218365C} 24hour twentyfourHour {F330DEE2-455E-45a5-B6D0-FF8A83912F87} 2minute twoMinute {CE9A4ADD-E32A-4471-BB5C-1B18DDE7BD5E} Medium is SF6. SF6 {DF7BF9ED-BCB9-4e1c-9B4C-33AB52B81700} Medium is SF6CF4. SF6CF4 {4661C9CD-9C00-4b59-82E9-E7D6044F405A} Medium is SF6N2. SF6N2 {99F5728F-1618-4f4c-82C1-04A7F55F7C23} Medium is air. air {C3038E60-FBA6-4499-B567-25B7BDA528D8} Medium is gas. gas {AA7F3DEB-B805-4dbe-BB34-13C7073D49C9} Medium is liquid. liquid {C4CEFD70-56D3-4edb-84B0-E4973AA3A1FE} Medium is mineral oil. mineralOil {15DFC023-8E5A-4fb3-A697-991C381F80FD} Medium is solid. solid {4D23B971-5C5E-4798-BD1E-0E65920C3D01} Current transformer ratio used to convert associated quantities to real measurements. ctRatio {5CF26FCC-C93E-42e3-9199-8ECEE905CEBE} Test constant. kE {04F87E33-EFA9-46c8-84AE-FF608FF3E610} Meter kh watthour constant. The number of watthours that must be applied to the meter to cause one disk revolution for an electromechanical meter or the number of watthours represented by one increment pulse for an electronic meter. kH {9F98A4FA-F8F7-403b-A2E0-DDCEB442D097} Register multiplier. The number to multiply the register reading by in order to get kWh. kR {79D140FB-40E1-49ab-B547-9C04DFE6CD9B} Potential transformer ratio used to convert associated quantities to real measurements. ptRatio {518587B2-0F99-4f5e-A3FD-990234AB31E3} Product of the CT ratio and PT ratio. transformerRatio {6C6C20A7-B87F-4f67-96F2-3C752E5FC3B3} estimate {D4B2F902-D305-4f78-85E0-A9E0EE37735F} normal {B5303E13-E217-4b2e-9F81-8F9A3C83886C} reversal {3FAD5137-496A-4d70-BCF4-1CE734C0A184} statistical {1B860D7A-EED5-42cc-A673-6FEB822A51BD} electronic {3444A4A4-A234-4eba-90D8-E7899BB6CDA2} other {A883656D-E14E-451c-83B5-97CC1CEC13E2} paper {4A84C70E-BBC0-4423-B132-21B8C024AF48} initial {CE02D575-68E5-4c34-97BB-C257910ADAA8} other {5359109E-9CA5-4438-B8FF-10CD7C697C16} recalculation {CD86A29F-B313-4177-9803-4A299DD912B9} Branch_Group_Derates {B0748A31-6B84-4fb4-88AB-B7DFBFEA3F71} Day_Ahead_Final_Market_Info {2454CB72-19E5-44f7-8D45-653E1F41A53C} Day_Ahead_Forecast_Information {317BB24D-A41C-4f3e-A01D-05899872F77D} Day_Ahead_Interim_Market_Info {45BCBE7D-ED94-4ca3-A2D4-744D49ADCD4C} Day_Ahead_RMR {40F50181-25A9-4497-A6F6-36E3CA79907A} Forecasted_UDC_Direct_Access_Load {0A57D14D-1863-4d53-A4E0-E5D213A036E3} Hour_Ahead_Market_Info {F51F15AA-AAC5-484a-A4F1-CBD3C83A57D6} Hourly_Expost_Market_Info {9EDA9C91-E50E-48ae-AAB9-A968F6E5CCDD} Public_Bid_Data {67F61CAF-B6F1-448b-B7EA-0699FBAE8F1F} Ten_Min_Expost_Market_Info {D7661E86-B02D-4429-9EE3-18FE5BC4A3D4} Notify customer if estimated restoration time changes. etrChange {775E6A45-3F58-4ce8-9A1D-CCD38F954693} Notify customer that a crew has been dispatched to investigate the problem. informDispatched {FCF11AD0-2E2E-4090-8159-7DFCCB5D436F} Notify customer for the first time that estimated restoration time is available. initialEtr {E9A8A82A-DF8D-45bc-9F78-18CC88889579} Notify customer of planned outage. powerOut {11257F70-AD72-4382-B39D-EEC832576F1E} Notify customer when power has been restored. powerRestored {8AC6D3E4-059C-4bd2-BAD5-53802F86E8B5} BIDS_PUBLIC {18021C7D-99BE-4279-A88A-A9E0985226CB} AS_CLEAR_ASMP_IFM {2E8CFF15-E5B6-4191-982D-B86351F30165} AS_CLEAR_ASMP_RTM {48DBC876-EA71-472c-BAE7-51B975659882} AS_CLEAR_COST_IFM {9DDB4483-C773-477b-9E64-434701A0E25F} AS_CLEAR_COST_RTM {08E90DC9-335E-4b7d-ABC8-6173E1551CF2} AS_CLEAR_MW_IFM {37FC4749-7088-4e95-B76A-B6FFF824B59F} AS_CLEAR_MW_RTM {521A08EE-1E39-4ce2-B5A4-2AE20FE04577} AS_GEN_TOTAL_MW_IFM {C8B542B9-8757-4c8c-B5C1-AEAFCFAD4D2A} AS_GEN_TOTAL_MW_RTM {32D17334-EB68-45f7-8D43-FD0C80DDB257} AS_IMP_TOTAL_MW_IFM {714C30C8-05B6-42a8-ACDE-E3EC4BE64DD5} AS_IMP_TOTAL_MW_RTM {5E2F989B-AFC4-4045-A320-3E52460BB9C9} AS_LOAD_TOTAL_MW_IFM {F5BAC623-64D8-4317-9BE0-B5357638F3FD} AS_LOAD_TOTAL_MW_RTM {F736A69A-7F6A-4b75-9965-CDAAE07EA9D2} AS_REGION_REQ_MAX {A4A68180-5223-45e8-863E-E3CB8FB57A33} AS_REGION_REQ_MIN {1B765314-5A49-4729-9B07-956CD0C572C9} AS_REGION_value {BAFB24A0-70BD-482d-A72D-88F70A09C3EF} AS_SELF_MW_IFM {B5749992-2766-4486-ACD8-02511D973D00} AS_SELF_MW_RTM {4D5EEC4E-A5E1-42b5-9C33-8A92E17E8078} AS_TOTAL_MW {9A2CE2CD-F409-43be-BC58-2A412F8B5421} AS_TOTAL_MW_IFM {257A914F-4FC7-406b-8FE1-12A36535692A} AS_TOTAL_MW_RTM {43868FFD-AA45-48bb-A8BF-D75F47C45748} AS_TYPE {D78BFF46-D910-4d9d-B024-B53FDFEA8D3B} AS_USER_RATE {4C080795-5CB7-4c64-B61E-0848D21A50CE} CA_value {0CD1AA78-28D6-4766-A61F-FE8524CDE2A7} CMMT_MINLOAD_MLC {CEE6EEA4-9A94-48de-970C-2F93817106E4} CMMT_MINLOAD_MW {E7357460-7603-43f6-8B26-213F823B6BF5} CMMT_RA_MLC {036A7F3E-B07B-4356-A7A6-CD412B85C055} CMMT_RA_MW {C8D43172-7B85-4ade-BE38-9C3963DDE7CE} CMMT_RA_START_COST {30304291-D682-436e-8BF4-C04B0D447E49} CMMT_RA_UNITS {AD4DD57D-3E94-431c-9777-D34C46B06F52} CMMT_TOTAL_MW {EDB4940D-CCA0-48be-A10D-AEE406EADC7C} CMMT_TOTAL_START_COST {FB439EC5-0718-4ed5-B7D6-A0DD1737734E} CMMT_TOTAL_UNITS {275D9B5D-4BBD-4a36-B595-E88D98766B2D} CRR_CAT {27BDE6D2-F88B-4205-BAF3-F0E99F6F76F5} CRR_MARKET_value {070963AD-54A5-4a60-A1A9-164E8F26975B} CRR_MW {04782716-A95E-4926-99B7-D5A6A02BEB08} CRR_NSR {7DAE537B-ECAE-4436-A120-B12FB1ED9772} CRR_OPTION {1766F92D-2E3C-4fa6-80A6-C6E03A4B55D4} CRR_OWNER {0CB22477-0F0D-41ab-9EA9-EDB0B6D1EF7C} CRR_SEGMENT {0F47BB99-F9A0-4b3d-BA54-668E54947588} CRR_TERM {B78149BB-4F0E-4c7b-8639-3BCC666C7D94} CRR_TOU {16544807-F1A8-4630-9706-EF944B10F43D} CRR_TYPE {48ECB90A-2B4D-4086-A964-C665A9DB06F4} ENE_EA_DA {073705D0-AEC7-4cba-A333-1275CC5944CA} ENE_EA_EXCEPT {98D778F5-C29F-46d2-BE92-2D2C2D8E9B86} ENE_EA_HASP {8DE1B880-1055-4bc3-8BCF-481DD31F8D41} ENE_EA_MLE {7A21BF8C-7CD3-4a97-8A5C-25B7E3E815BF} ENE_EA_MSSLF {5A36CCD1-26BC-4a6c-8EAB-AAADDA7A9B75} ENE_EA_OPTIMAL {6C6A5CC7-244E-451a-AE28-BECF953F2248} ENE_EA_RAMP_DEV {D06BF3B9-24BA-420b-9FCE-62E7B96A6D3C} ENE_EA_RAMP_STD {1E991D65-3474-4214-8DA8-96261557E233} ENE_EA_RESIDUAL {E1D190E7-3D8F-4c0f-B050-D81B117B3472} ENE_EA_RMR {D9186BC8-24B6-45a6-AFA5-0626476FCE7D} ENE_EA_SELF {2B81F461-C161-4e9e-8ED9-A7459DE8C6A6} ENE_EA_SLIC {8D1D8C4F-1344-493f-9AC0-FC1719A1E6A1} ENE_EXP_CLEAR_HASP {33B98FA2-CFB7-49d6-83A3-5261714A555A} ENE_EXP_CLEAR_IFM {DC8D38AB-4F13-4c0c-BA42-1919C9822FF7} ENE_EXP_CLEAR_RTM {FC4380BD-10B4-438a-994C-AD70641B3327} ENE_GEN_CLEAR_HASP {EC1C50F9-C708-4803-9F93-4434374F7376} ENE_GEN_CLEAR_IFM {8084580F-AA87-4526-8207-29E65EA3A15C} ENE_GEN_CLEAR_RTM {295DF91B-BD3C-4913-9176-31A40EEB376C} ENE_IMP_CLEAR_HASP {C73FE58F-20E4-4296-BD09-8CBE5C91826F} ENE_IMP_CLEAR_IFM {21C664D5-AE09-4e37-A24E-9D4A0BC8898A} ENE_IMP_CLEAR_RTM {2D0D0668-7357-42d7-8D17-26C2A1577A52} ENE_LOAD_ACTUAL {FC5ED093-0418-4ffb-B498-745C85C2E9F8} ENE_LOAD_CLEAR_HASP {E3523D98-12B9-44c1-AC52-1F2DCE418A6C} ENE_LOAD_CLEAR_IFM {69375CA9-8DE6-41e3-B201-C83753ABF346} ENE_LOAD_CLEAR_RTM {4ED04167-4E5B-4a2b-BA9A-9E1F1235B10E} ENE_LOAD_FCST {2B253B65-EB44-42f2-855E-CA3E2CCAED1F} ENE_PEAK_HOUR {51149821-CAB8-433a-BE67-FA9362FEA810} ENE_PEAK_LOAD {0338BDF5-6679-43a2-9C23-2B27A0204F88} FUEL_REGION_value {E758E815-122C-4e25-ABDE-1C3E668322B3} INVT_DATETIME {74A003DD-4AD4-457e-B2F3-BB999B772F00} LOAD_ACTUAL {91B9803A-555E-47b1-B56F-407E8DB9372E} LOAD_CLEAR_RTM {B038256E-1660-4142-85BD-9CC3AF510505} LOSS_TOTAL_COST_HASP {AB51AB38-3C5D-424e-83AC-707D100C804D} LOSS_TOTAL_COST_RTM {C9B7D55A-63FD-42d2-BC6B-3E28FCF40ADE} LOSS_TOTAL_MW_HASP {2F455BBA-9B45-4078-AF26-9C51D00AAD1D} LOSS_TOTAL_MW_RTM {7A5390BA-2A05-462f-87C6-6AD3A12E3BE1} MPM_FLAG {4EDA2810-F86B-43a5-9BEA-D33EDA0325CE} OP_RSRV_TOTAL {FF1020A7-1497-4d86-93AA-5264E2109016} PRC_NG {CAE3C8F7-E277-42bc-A1E2-97D1C0A17461} PRC_SHADOW {5341F983-4F0C-48e9-B467-CAA1A139DC64} RATING_ATC {60D742DF-091B-41e7-87DD-5FFA67058F6C} RMR_DETER_DAM {7FC6AAF5-1ACC-44ff-AB2A-45BC758C6582} RMR_DETER_HASP {23DD2C8F-7CC1-481a-8C5F-02C3B4D45E70} RMR_DISPATCH_DAM {5106A14C-0022-4e88-AD02-B7BBBF863590} RMR_DISPATCH_HASP {A5B1B54A-E5A1-42d6-AC27-5FA3C5A46ECC} RMR_TOTAL {AFCBC8AF-F454-49a1-BCFA-F638D5953B18} RMR_TOTAL_AVAIL {43DF13E3-4047-44dc-B15A-53AC038FD9C8} RUC_GEN_CLEAR_RUC {B2C9FB6E-DF77-4cfe-B115-4AD059ABEB8D} RUC_IMP_CLEAR_RUC {13692770-5299-4ac0-AB72-7A90F5F5E3EF} RUC_LOAD_CLEAR_RUC {28328698-AE40-45b6-96A5-6DD0DCA888DF} RUC_ZONE_value {B0921A65-6B7E-4b56-B8EB-7E58A7748A7E} TAC_AREA_value {A84AE2C9-8A9E-4745-9A77-3ACCDE3106C6} TINTRFCE_value {C2751E36-8AFF-4d6d-9AF6-7D850C401E9A} TRNS_AS_IMPORT {57008B36-61FB-45b9-8D35-9CA735DF54D0} TRNS_ENE_IMPORT {FBF66399-ECE7-4836-917A-BDDA227C0164} TRNS_EQUIP_value {7F7F3C58-9C27-47f9-953C-B3B94E81DA7B} TRNS_RATING_CBM {E38A48C6-5CBA-4f34-9555-6D8984745E49} TRNS_RATING_DIRECTION {E0711C9E-F059-49d6-8323-A5F022F5F59B} TRNS_RATING_OTC {AD2FA295-3E0F-4e51-91B7-615548A22C06} TRNS_RATING_OTC_DERATE {20A4ECEC-E3CF-4a2c-B112-9A1AEB47922A} TRNS_RATING_TTC {AB623898-24A8-451b-BC52-65E013308666} TRNS_TI_value {0BC4577F-1271-447c-9F68-BCAB09DC8133} TRNS_TR_ENTMTS {99DBC1EA-0DEE-4b3c-B7F0-34D8C3A4BFC8} TRNS_TR_USEAGE {594DC69D-776B-46cc-8BA4-4DE5FCDCEC67} 1000 {C986739E-C86E-4da5-98A0-72AF4935C47F} 1001 {A8649B2E-EC90-4e11-88DD-A197D60C5B7F} 1002 {8E2AD261-A921-4508-A780-FF2D8D7F60EB} 1003 {B4D3D296-DF22-472e-8D29-ECAA620A1658} 1004 {A56485DA-9489-40ca-AABA-177BFEFD21A2} 1005 {B9F5A68C-EAA1-4d60-BA50-E9C797430D7D} 1006 {25AAA862-252A-4e53-B04B-82435385A09F} 1007 {8F7F8A7D-329E-4f3b-9C1A-7C8D0542C470} 1008 {20FBEF8E-E763-47c6-A0F3-28143F7EB32D} 1009 {3E458A89-1AEE-4ee2-A7C2-28C78C01F819} 1010 {45142394-638A-4819-AE00-165E1B8216BB} Data can be requested for period of 31 days only {7838A32F-3704-42df-B34A-F6FDB1A3B7CD} Exceptions in reading and writing of XML files {B6DBEA9A-CFED-4ae5-AE40-0300095C641F} No data returned for the specified selection {9D2D920A-C6FB-46de-81D5-9C0C3916F7E8} Out of memory exception {DF99D021-20BA-414f-B047-4A16A1E5B82B} Required file does not exist {95DA1954-9FC5-494d-8FF8-DA924C530792} System Error {6EC0E8B2-4065-43fe-B086-48F0B67C6260} Timed out waiting for query response {6B42E03B-7A4E-4f79-B76A-AB1C79DD8050} Validation exception during transformation of XML {A6359D27-2EE7-4b63-89F5-930B32E809BD} BEGINNING {7A75AF40-D20B-4cf8-B66D-5A4C53029E66} ENDING {A5DB6B5C-AC20-48b1-A12B-E664B4E4B212} All {67200F17-1B4E-46ff-874B-8FA398CB5282} HASP {DA52FA87-FFFE-4f91-80DE-89D45E92F159} IFM {5E255E83-FFC0-4009-A048-BBA343087B9C} RTM {7CAB301C-0EC8-43f2-9534-9F5004384E4F} RUC {1ACB976D-66FD-4bfb-933A-ADF6D089E23E} ATL_APNODE {7E0CA6F5-030A-413a-938D-732DA4529CAD} ATL_AS_REGION {CEA744C5-2B0D-4aae-80CC-26B14DEF3336} ATL_AS_REGION_MAP {7B808D00-C8FE-40a1-A856-FDBAF654BED0} ATL_HUB {FA36F4CE-B6DC-4d55-A371-8D4A6BD31B90} ATL_LAP {7EE9A877-C73A-412e-AFDC-3F7E735C88EE} ATL_LDF {64B42CC6-6573-4821-A47A-2D88821F84FA} ATL_PNODE {E2F83E42-427A-4c63-9574-45DBC9DC7BE2} ATL_PNODE_MAP {9EFD9A90-6E3B-47b4-9672-670B4727FE0D} ATL_PUB {93733BE2-6729-40f6-B88B-CA7E452B4D19} ATL_PUB_SCHED {BFF4AE5B-AFA4-460f-8C51-4C91721E6A05} ATL_RESOURCE {04D24827-0BCE-4921-9A94-12D067A59EED} ATL_RUC_ZONE {22960D28-CC9B-4bd4-94C4-B6B574A9FD1A} ATL_RUC_ZONE_MAP {0BAA6A21-0C44-427a-A69B-C915D045122C} ATL_STAT {BF040F44-1AB7-47bb-A39D-E2368C8CEFE5} ATL_TAC_AREA {9F7239F7-28C3-411f-A521-4FF75CCF8F6C} ATL_TAC_AREA_MAP {1943DB54-782D-4108-B160-0AB3581007B9} ATL_TI {F13ACE5D-3311-4ab9-90FE-A3FB6892EECA} ATL_TIEPOINT {DF9A2AC0-7217-4982-AD20-ECAB42DD8691} ATL_XREF {961B0A52-D629-414a-A2B4-92F9B9DFD952} FACTOR {56429AA9-A280-495a-BCB9-D76FCB1D5B32} FLAG {E8B65F78-DAA5-4e1c-9685-44B2455C9231} INTEGER {FE78990C-1F68-4d05-B564-94D04FE8F980} MW {339C93A7-547D-4de4-8E7B-E26A489E843E} MWh {781CE34A-5B6C-40fb-B341-DFEF47816A2B} AS_DA_RESULT {8955B217-9509-4476-B6A9-1A9737AB8C3D} AS_OP_RSRV {013C3489-2F56-4d2d-9789-8585D590A9A8} AS_REQ {16631B8B-6486-494a-8B04-D356B36BE46C} AS_RTM_RESULT {6825AFA9-1B31-4ae7-B52F-5DB8860A3CA7} BIDS_PUBLIC {3481F87A-B4CC-466b-85ED-D9094CC14235} CMMT_RA_MLC {82420050-AB03-4032-B757-8966990E3888} CMMT_RMR {E4AB8091-E2CE-4cfc-ABE9-2E9DB281F6C3} CRR_CLEARING {A5614979-9D5F-438c-A579-915E2EF79A8B} CRR_INVENTORY {EC971F76-6FEC-4c99-A144-72A0910BF891} ENE_EA {46301463-ABC4-4eec-BA83-FAE8DB6FF301} ENE_HASP {D85AF969-E14D-4104-98C1-93FBFB6E43F5} ENE_IFM {53D2DFB2-959F-4f7b-B357-478A70A65145} ENE_MPM {715317F3-7BC4-43d0-9447-A2A1AD4127F3} ENE_RTM {4C30E21C-CD97-4385-927E-F1D988712DC8} ENE_RUC {AC4DD8D0-B4B2-459a-80F7-15714A8A7BAE} LOSS_DA_HASP {F37C10BD-396D-4a5e-BE42-826D37DC6348} LOSS_RTM {33DCFBCF-9E3B-4e68-A131-01E1325BBA34} PRC_AS {B6DC23AE-2E50-4990-BB19-034E63F1DDA7} PRC_CNSTR {C9EAB6F0-CA89-44ff-AE83-6DA7766AE6F9} PRC_FUEL {686ECF58-5E09-4c8d-923F-AF3C24D752B3} PRC_HRLY_LMP {918D8904-1AF3-4996-B00D-9F98FC593D4D} PRC_INTVL_LMP {1213AFB9-4FC1-4159-916A-83030C56EB12} SLD_FCST {9B9B3C0F-0009-4878-947A-780E259A3F6D} SLD_FCST_PEAK {95B54F49-E58F-43ca-8352-F101DA8837F4} SLD_MKTS {35847140-CCB3-451b-96E0-169C8519404A} TRNS_ATC {CCD0D373-1073-4006-8D67-A5E6941E1F50} TRNS_OUTAGE {051BD6ED-0738-46a3-A8D7-8F76F58E903A} TRNS_USAGE {02BD54BA-6448-41f2-8903-DCD574869D92} Data_Transfer_Procedure_Initiated {6E9421EA-1B6D-4751-BEF8-ADCF623164E7} Data_Transfer_Succesful {7E0F0AAB-90B1-400c-97AF-39CFFC4B2A52} Forced_Termination {7EC533D0-8B75-48d8-876C-021D5CD58897} Obsolete {901E9AB5-0506-4086-AD64-B670C04FD4C1} Push_Failed {3CAB7B92-80DA-475d-9164-9A37CDB57264} Valid {61A40579-ACCF-4eb0-A555-48E9228E52B6} Acid neutralization number in milligram of KOHgram. acidNumber {EA62968A-5836-4912-96FC-D1B2066EC918} Dibenzyl disulfide DBDS concentration in ppm specificially in milligramkilogram. additiveDBDS {348F2398-5748-4dc0-A2CF-0CA495441945} Concentration of aromatic compounds determined using infrared spectroscopy in percent. aromatics {8DE4C341-723B-44c5-9EFF-FB49D6B9F8EA} Concentration of carbonyl compounds aldehydes and ketones determined using infrared spectroscopy in percent. carbonyl {8071333D-BBFF-4d8e-B4CF-ED26FAD85499} Density in grammillilitre. density {7D9CF1D6-DB57-442e-8596-5E64A181F4D9} Dielectric breakdown for electrode gap size and temperature specified by selected standard in kV. dielectricBreakdown {6E579A27-6C31-4a23-96FA-FFB537C8A4D4} Fluid dissipation factor in absolute value not a percentage. Multiplying this value by 100 would result in dissipation factor percent. dissipationFactor {10310F7C-E017-4ae2-9AF4-1AF5D55ADC71} Fluid dissipation factor in percent. Commonly used in Asia. Dissipation factor is also known as loss factor or tan delta. dissipationFactorPercent {14443118-BE6B-4030-A2F4-F250623CC4C5} Duration of oxidation stablity test performed according to IEC 61125 method C. This value should accompany values resulting from testing according to IEC 61125 method C to allow interpretation. Standard specified values are 164 332 and 500 but others can be used if agreed upon. duration61125MethodC {E4BDAD84-6AB0-406a-BB77-726250FD48E9} Fire point in C. Fire point is when fire is sustained oil catches fire. Can only be done by means of open cup test which is commonly used in US. firePoint {88C700D3-1CF7-49fc-AF7E-3B216DB0E76B} Flash point in C determined via closed cup test. Flash point occurs when enough vapors have accumulated to sustain a flash. Closed cup is used in Europe. flashPointClosedCup {DCDC3FC8-0FF6-48e0-8481-6CB822DC246D} Flash point in C determined via open cup test. Flash point occurs when enough vapors have accumulated to sustain a flash. Open cup is used in US. flashPointOpenCup {5717DFAC-6AA3-439c-AF80-2383593F35A2} Oxidation induction time in hours. Typically performed on new oilbut can be done on used oil. inductionTime {4C7519DB-230F-422d-B528-97CA2B58B91D} Amount of inhibitor used in oxidation stablity test performed according to IEC 61125 method C. This value should accompany values resulting from testing according to IEC 61125 method C to allow interpretation. inhibitor61125MethodC {31B73E18-783C-4ea0-B3BE-FB3932F4878A} Interfacial tension in dynecentimetre or milliNewtonmetre which are the same. interfacialTension {D7C9525A-5061-4496-A50D-44E79E7D322C} Kinematic viscosity in millimetre2second. Kinematic viscosity is the ratio of absolute or dynamic viscosity to density. kinematicViscosity {D7137F7C-2881-457d-8393-A05821F19E68} Measure of oxidation stability in hours. oxidation {515348B1-0E0D-4ccb-8E09-A4195CC31512} 26ditertiarybutyl paracresol and 26ditertiarybutyl phenol concentration in percent by weight. oxidationInhibitorD2668 {D227B5FC-FCE5-4776-9D09-0FEE9E6F2706} 26ditertiarybutyl phenol DBP oxidation inhibitor concentration in percent by weight. oxidationInhibitorDBP {BFC0A627-0D2F-4b32-8FDA-9A02C72AEDB9} 26ditertiarybutyl paracresol DBPC oxidation inhibitor concentration in percent by weight. oxidationInhibitorDBPC {55583D98-5A0F-4cba-9CE3-82E86D899035} Metal passivator BTA content in milligramkilogram. passivatorBTA {FFF7B11A-49C9-45cc-AF9C-880575B68238} Total passivator content in milligramkilogram. passivatorContent {E0753296-A772-4444-BB51-A67E9F2CC8F3} Irgamet 39 metal passivator content in ppm specifically milligramkilogram. passivatorIrgamet39 {8EF918C2-5374-44d1-A6B0-CBC8CAD24133} Metal passivator TTA Irgamet39 in solid form content in milligramkilogram. passivatorTTA {83D3CF86-D8F4-4c9a-919D-82A0EB3C5685} Characterization of the carbontype composition of insulating oils by petroleum origin. petroleumOrigin {440F6C36-3BC3-41fc-8FE0-A07E549AD208} Pour point in C. The pour point of a liquid is the temperature at which it becomes semi solid and loses its flow characteristics. pourPoint {6F9848EC-066F-4195-85F7-A66AD42AF418} Pour point in C determined by automatic method. The pour point of a liquid is the temperature at which it becomes semi solid and loses its flow characteristics. pourPointAutomatic {163297AB-0341-4a14-9572-FB241DE6E728} Fluid power factor at specified temperature in percent. Commonly used in US. Note Fluid power factor is very similar to fluid dissapation factor but fluid power factor is cosine of the phase angle between an AC voltage applied to oil and the resulting current where dissipation factor is the tangent. For values up to 0.005 fluid power factor and dissapation factor are very close. There is a conversion equation between the two. powerFactorPercent {E3056614-86DA-47a2-9928-58E512BF58E0} Resistivity at 90C in gigohmmetre. resistivity {859EE86C-2EDD-40cd-AAC5-AF9C3257295E} Sediment and sludge in percent. sedimentAndSludgePercent {A843C22C-1A80-46e5-8449-5B3059CEFD86} Sludge in percent by mass. Typically performed on new oilbut can be done on used oil. sludge {5F669E6A-2BE1-491f-9A43-F6B1FD8B61D1} Soluble acids in milligram of KOHgram. Typically performed on new oilbut can be done on used oil. solubleAcids {52381B9E-55E3-4fdb-9E01-C6D743ED208C} Specific gravity corrected to 15C. Also known as relative density. It is a ratio of density of tested oil to density of water at a specific temperature. specificGravity {53990F3A-B60E-49db-AEEF-543D0CEE6D16} Static electrification tendency in microcoulombs per metre3. Also called static charging tendency and electrostatic charging tendency ECT. staticElectrification {6BB070EC-F9A8-46cd-B9F1-6BEF3DB2CFD0} Total acids soluble plus volatile in milligram of KOHgram. Typically performed on new oilbut can be done on used oil. totalAcids {64510F91-6AD6-4d69-AA89-8358309FD2B9} Volatile acids in milligram of KOHgram. Typically performed on new oilbut can be done on used oil. volatileAcids {8F4A4022-A015-44b8-B70B-63062F12ACB2} Fluid color index number. Color numbers are expressed in 0.5 intervals and value specified is lessthan. For example a value of 2.5 means the color index number is between 2.0 and 2.5.Possible values 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0 7.5 8.0. colorNumber {47B514FF-F464-4e62-90CE-CEFCCAA496E2} Fluid color index on the platinum cobalt scale. Possible values 5 10 15 20 25 30 35 40 50 60 70 100 150 200 250 300 350 400 450. colorNumberPlatinumCobaltScale {1B07B7C0-0BBF-4720-BE97-F983A56953E0} Corrosive sulphur test result using silver strip test.Possible values absent present. corrosiveSulphurBy51353 {315CA497-944C-42a0-9496-A7523CA85EC2} Corrosive sulphur test result using covered copper conductor deposition test.Possible values potentiallyCorrosive nonCorrosive. corrosiveSulphurBy62535 {AEFD7B93-FC55-45a1-9D4A-BA0BC783D178} Corrosive sulphur test result using bare copper strip test.Possible values corrosive nonCorrosive. corrosiveSulphurByD1275 {50CD2F88-BB28-4ea5-8E28-259278AC0647} Sludge precipitation test results.Possible values present notPresent. sludgePrecipitation {9A8C7490-BE9C-403c-9028-B6B038EAAB87} Tarnish level indicated by corrosive sulphur test.Possible values 1A 1B 2A 2B 2C 2D 2E 3A 3B 4A 4B 4C. tarnishLevel {1DA9473F-9733-4b10-8CD9-FA4EB83E70DF} C2H2 concentration in ppm specifically in microlitrelitre. acetylene {D757B45E-1A01-4eda-983B-B00C1E3ABF71} C4H10 concentration in ppm specifically in microlitrelitre. butane {8FA00F89-C563-4f6a-A724-813779AFFB1C} C? concentration in ppm specifically in microlitrelitre. carbon {BAA8601B-D854-4cb7-B43A-62A11724DB69} C3 concentration in ppm specifically in microlitrelitre. carbon3 {FD66D149-B950-4a3c-8E94-8D5D2B12F925} C4 concentration in ppm specifically in microlitrelitre. carbon4 {47D2CCF6-8BF3-4bfa-97CD-1CE2F6DF61ED} CO2 concentration in ppm specifically in microlitrelitre. carbonDioxide {3CFB3884-BCE4-4e01-BDFC-EF5B74320700} CO concentration in ppm specifically in microlitrelitre. carbonMonoxide {EC4225E4-10CC-432c-A855-48CD2FDD8C62} Equivalent Total Combustible Gas ETCG percent.An estimate calculated from the dissolvedgas concentrations and the oil sample temperature of what the TCG would be in a gas space in equilibrium with the oil. ETCG reflects what the TCG would be in air spaces near the oil. equivalentTCGPercent {9B15B421-69B6-47b2-96B6-4C811143D0A8} Estimated Safe Handling Limit ESHL in percent. Estimated safe handling limit is an estimate of the lower flammability limit LFL of the combustible gas mixture which the dissolved gas in the oil would give off by the oil if exposed to air. Expressed in percent like the equivalent total combustible gas percent it is calculated from the dissolvedgas concentrations the oil sample temperature and the lower flammability limits of the individual combustible gases. estimatedSafeHandlingLimit {D6A254A2-816D-47a2-A4A0-E7A1AA451AF6} C2H6 concentration in ppm specifically in microlitrelitre. ethane {A9B4300D-FB25-4898-8CFD-AE3949929F58} C2H4 concentration in ppm specifically in microlitrelitre. ethylene {F3747D79-11C0-4757-A542-8498D4127999} Measured composite of dissolved fault gas concentrations in ppm specifically in microlitrelitre. Relative sensitivity H2 100 of concentration CO 15 4 of concentration C2H2 8 2 of concentration C2H4 1.5 0.5 of concentration. hydran {C6BC71B4-C7C8-432b-B9F6-54DF65F63687} Predicted hydran value in ppm specifically in microlitrelitre calculated based on individual measured dissolved gas concentrations. H2 100 of concentration CO 15 4 of concentration C2H2 8 2 of concentration C2H4 1.5 0.5 of concentration hydranPredicted {8240D451-33B1-417e-BDFD-ED4F7803D3BB} H2 concentration in ppm specifically in microlitrelitre. hydrogen {69B8250F-0E6C-4db1-B6D6-A532243DA5A5} isoC4 C4H10 concentration in ppm specifically in microlitrelitre. Isobutane is also known as methylpropane. isobutane {30B0ECE9-507A-4620-BBB8-8A36B263F982} CH4 concentration in ppm specifically in microlitrelitre. methane {87B8A5B3-259E-4a71-AD91-71345085515A} N2 concentration in ppm specifically in microlitrelitre. nitrogen {D6B5FF9F-1720-4f78-AEEF-8BACB0EF00D5} O2 concentration in ppm specifically in microlitrelitre. oxygen {9179BBA2-489B-40c9-B97F-E899A4CFED32} C3H8 concentration in ppm specifically in microlitrelitre. propane {43AD7A4F-7613-4fcd-8B51-6C62FD3CD90D} C3H6 concentration in ppm specifically in microlitrelitre. propene {18ED09E8-916A-4a46-97BA-71214DE98105} Total Combustible Gas TCG measured in headspace in percent by volume. totalCombustibleGasPercent {59569A7A-B7B7-4de7-BF4D-8582DD24AFA3} Total dissolved combustible gas concentration in ppm specifically in microlitrelitre. Calculated by adding the ppm of combustible gasses hydrogen H2 methane CH4 ethane C2H6 ethylene C2H4 acetylene C2H2 and carbon monoxide CO. totalDissolvedCombustibleGas {E97A1E46-CE98-4be1-BCB3-75F60A695FC8} Total dissolved gas in oil in percent by volume. Derived from the total area of all the gas peaks in the chromatogram. totalDissolvedGasPercent {B7A63877-2518-44cc-9153-37A32056F92D} Sum of concentrations of methane ethane and ethylene in ppm specifically in microlitrelitre. Used in some diagnostic gas ratios especially THGacetylene which compares heat gas to arcing gas. totalHeatGas {5DC499DF-E61E-4986-BA0F-1BF2CF889100} Total partial pressure in Pa.Calculated value reflecting total of partial pressures of all combustible gasses. totalPartialPressure {D834A885-C0A9-45b3-9536-7DEFDF7E2C32} Aluminum concentration in ppb specifically in microgramlitre. aluminum {17DCA08D-62B6-4148-9B9E-E313AC70B4AC} Aluminum concentration of particles larger than 0.45 microns in ppbspecifically in microgramlitre. aluminumParticulate {F46760EB-7042-424d-914E-9FADB9A002AB} Barium concentration in ppb specifically in microgramlitre. barium {762E4BD5-6BF7-4791-8FAD-EBA3D37B7E10} Boron concentration in ppb specifically in microgramlitre. boron {72161B34-917C-44e4-B9A1-1FBFAAC5AD9C} Cadmium concentration in ppb specifically in microgramlitre. cadmium {49B16F68-43AA-4fcd-AED1-B786D46A7AE2} Calcium concentration in ppb specifically in microgramlitre. calcium {0172B0DC-DCF5-48bb-AD04-7656ED1535E4} Chromium concentration in ppb specifically in microgramlitre. chromium {7D087ACE-558C-46c0-8A53-1F06A0C82B3F} Copper concentration in ppb specifically in microgramlitre. copper {1CCE608D-DC85-444a-A16F-85E381C8F009} Copper concentration of particles larger than 0.45 microns in ppbspecifically in microgramlitre. copperParticulate {9A628B6D-BD54-49e6-A59B-E84CB4049EB1} Iron concentration in ppb specifically in microgramlitre. iron {9F595E14-F28E-4925-862F-C8A7726C2B04} Iron concentration of particles larger than 0.45 microns in ppb specifically in microgramlitre. ironParticulate {9D33052E-0563-4f02-A18C-0C634638CBD8} Lead concentration in ppb specifically in microgramlitre. lead {F9A54FFB-6B17-4d3e-88A6-3A9060D0D6FE} Lead concentration of particles larger than 0.45 microns in ppb specifically in microgramlitre. leadParticulate {280F0251-EBA9-41e0-B23A-B4DEC74E9FBE} Lithium concentration in ppb specifically in microgramlitre. lithium {BC7DB6A9-1F3C-4e1a-B3F8-C080ACF60D2B} Magnesium concentration in ppb specifically in microgramlitre. magnesium {0E2FAF32-F948-45e0-975D-F2373BD69979} Molybdenum concentration in ppb specifically in microgramlitre. molybdenum {753E261C-2C69-4541-B9D9-5A7B4D41EBB5} Nickel concentration in ppb specifically in microgramlitre. nickel {89189794-32FB-4a4d-BA21-0B6CF4F91795} Phosphorus concentration in ppb specifically in microgramlitre. phosphorus {73689953-2083-4f9e-96F1-A8D037932AAB} Silicon concentration in ppb specifically in microgramlitre. silicon {70F85A0A-C182-4bf4-B8EF-6DCB432FC79B} Silver concentration in ppb specifically in microgramlitre. silver {C8527BE1-A94E-47ff-BD57-BBA548FF42A2} Silver concentration of particles larger than 0.45 microns in ppb specifically in microgramlitre. silverParticulate {062B08F8-82A6-466b-BCED-72BCABB350C6} Sodium concentration in ppb specifically in microgramlitre. sodium {0BA34E08-C4B6-4035-AC38-ACC9301C678C} Tin concentration in ppb specifically in microgramlitre. tin {FD171027-DC47-4a48-9A05-BD6E21C3E45B} Titanium concentration in ppb specifically in microgramlitre. titanium {13CD8AA7-F0D6-4262-A932-AB292E665BE8} Tungsten concentration in ppb specifically in microgramlitre. tungsten {9F966012-108B-496f-A399-E39D7F50F68E} Vanadium concentration in ppb specifically in microgramlitre. vanadium {32889D93-83D0-4e61-A2C2-5F5FDF14152C} Zinc concentration in ppb specifically in microgramlitre. zinc {70A2B5AC-9580-4edf-AEC3-08BB84A14204} Zinc concentration of particles larger than 0.45 microns in ppb specifically in microgramlitre. zincParticulate {472236F7-C8F7-41f7-B6DC-0FBF382A7E5C} Dew point in C. Is usually a negative value. dewPoint {4FDA2D66-EDBE-474c-A873-38BE9CA39010} Relative saturation of water in fluid in percent. relativeSaturation {18C50D2D-9673-4aec-A152-0765E797C91A} Calculated relative saturation of water in fluid in percent. relativeSaturationCalculated {65D8B50E-0102-4a32-8A4B-A9E5D0D426BC} Moisture measured via coulometric Karl Fischer titration in ppm specifically milligramkilogram. waterContent {6B374D99-6372-4af3-B8ED-AA2D8C1FC9CD} Water content by aluminum oxide sensor in ppm specifically milligramkilogram. waterContentMonitoredViaAluminumOxide {50ECF030-05FA-4ed1-B2F3-D9BBB8597192} Water content by capacitance sensor in ppm specifically milligramkilogram. waterContentMonitoredViaCapacitance {946F3767-AD07-49bb-B1D4-D6974E72909E} Water content by infrared sensor in ppm specifically milligramkilogram. waterContentMonitoredViaInfrared {2A92752E-FFE4-431e-9580-EBEAB277E31E} Water content by other sensor in ppm specifically milligramkilogram. waterContentMonitoredViaOther {CEC833FE-C79C-44c8-B382-2F599A35B3DA} Concentration of Aroclor 1016 in ppm specifically in mgkg. aroclor1016 {A28795EE-953F-4f0c-8307-B7E56800B9F3} Concentration of Aroclor 1221 in ppm specifically in mgkg. aroclor1221 {5F3DE9EE-CF65-43eb-A462-DA095A2BC4DB} Concentration of Aroclor 1242 in ppm specifically in mgkg. aroclor1242 {8097DF99-75A3-4132-A566-79DAFA51A7C0} Concentration of Aroclor 1254 in ppm specifically in mgkg. aroclor1254 {446426F1-9751-4204-9939-FEE4E1C95E5F} Concentration of Aroclor 1260 in ppm specifically in mgkg. aroclor1260 {C5171055-5800-433f-8AB0-C3A3BAB98538} Total arochlor PCB content in ppm specifically in mgkg. Is the sum of Aroclor 1221 Aroclor 1242 Aroclor 1254 Aroclor 1260 Aroclor 1016. totalPCB {81470642-F1AB-4053-8226-0B72C5C2D5EC} Possible values blank 50 50. testKitPCB {861A70F8-2810-4ed7-83F0-59827C8CDF4A} 2acetylfuran 2ACF in ppb. Also known as 2acetylfuran furyl methyl ketone 2furyl methyl ketone methyl 2furyl ketone and 12furanylethanone. acetylfuran {A076A658-82BC-4bb8-A0B8-9C0DB7EC0C50} Direct measurement of degree of polymerization DP unitless. degreeOfPolymerization {584EC2A1-D383-4e02-BEEA-631686EC49A3} Calculated degree of polymerization DP calculated using the Chendong equation unitless. degreeOfPolymerizationCalculated {986495CC-A919-4b2e-AF60-6D516184F3B2} Concentration of ethanol in ppb specifically microgramkilogram. ethanol {D7969551-DCE1-4f96-B717-913113BF0EEF} 2furaldehyde 2FAL in ppb. Also known as 2furfural 2furaldehyde 2furanaldehyde fural furfuraldehyde furaldehyde and 2furancarboxaldehyde. furfural {0346BDA9-5F5B-4d4a-9F30-1B03AEC3E449} Furfuryl alcohol 2FOL in ppb. Also known as 2furyl alcohol 2furfurol 2furylmethanol 2hydroxymethylfuran 2furancarbinol furancarbinol 2furanmethanol furanmethanol furfural alcohol and alphafurylcarbinol. furfurylAlcohol {FBA23766-2F78-4eea-94CC-EB08A04D1CAD} 5hydroxymethyl2furaldehyde 5H2F in ppb. Also known as 5hydroxymethyl2furfural 5hydroxymethyl2furaldehyde 5hydroxymethylfurfuraldehyde and 5hydroxymethylfurfural. hydroxymethylfurfural {F270D195-B6B4-4a9c-8EC4-7FD3AAC49E3B} Concentration of methanol in ppb specifically microgramkilogram. methanol {084035F9-F071-46a2-BB07-A94E1FC405F3} 5methyl2furaldehyde 5M2F in ppb. Also known as 5methyl2furfural 5methyl2furaldehyde 5methyl2furfuraldehyde and 5methylfurfural. methylfurfural {F697DD40-AD0D-4f5b-A829-6F2839CEF7B5} Dielectric breakdown of solid electrical insulating materials in kV. solidInsulationDielectricStrength {9F6CB3D7-68F3-4144-BC21-891B0C5F1A77} Tensile strength in kilonewtonsmetre. tensileStrength {3BE11B10-FB4F-455f-B9BC-4DD9E233F3A0} Total furan in ppb. Is the total of the concentrations of 5hydroxymethyl2furaldehyde 5H2F furfuryl alcohol 2FOL 2furaldehyde 2FAL 2acetylfuran 2ACF 5methyl2furaldehyde 5M2F. totalFuran {23C788DC-BD88-4474-BB28-4CF458B88ED6} Percent of particles which are carbon. carbonPercent {7E5477A1-717F-40c2-A994-CAC82E3460E2} Count of particles 100 microns and larger in a 1 millilitre sample. count100Plus {83B5CE60-B87E-4a18-8FDA-9174FA526DE8} Count of particles 10 microns and larger in a 1 millilitre sample. count10Plus {37037689-A25F-46eb-A03B-377E77F665BE} Count of particles 14 microns and larger in a 1 millilitre sample. count14Plus {F9A2C61C-CA7C-4e83-BA96-DDFF88016C85} Count of particles 15 microns and larger in a 1 millilitre sample. count15Plus {DFE34C41-2794-42f2-85AF-7D9BD748E3C9} Count of particles 21 microns and larger in a 1 millilitre sample. count21Plus {87ABB61C-CF9E-4eb0-BD21-2E55AF15DEF5} Count of particles 25 microns and larger in a 1 millilitre sample. count25Plus {A3251E03-D5E2-43d1-98CF-D7E553899876} Count of particles 2 microns and larger in a 1 millilitre sample. count2Plus {57F2E7CD-82AB-4007-805F-75EB227E6515} Count of particles 38 microns and larger in a 1 millilitre sample. count38Plus {9D27BF17-B560-4963-9767-5C23E5867A08} Count of particles 4 microns and larger in a 1 millilitre sample. count4Plus {047DF64A-51D3-4c29-B440-17137F69995F} Count of particles 50 microns and larger in a 1 millilitre sample. count50Plus {9D5C842D-CC06-4804-BA81-5F4AC9E8BBDD} Count of particles 5 microns and larger in a 1 millilitre sample. count5Plus {812E35B4-2FF3-46e1-8485-D24B4FD04F58} Count of particles 6 microns and larger in a 1 millilitre sample. count6Plus {2CA82AC8-FAB8-45d8-A32B-2955157B12FA} Count of particles 70 microns and larger in a 1 millilitre sample. count70Plus {69FF824C-AAB7-43a9-ACC9-A165F2F6EBD5} Percent of particles which are fibres. fibrePercent {A9B745E7-1D84-4507-AB0E-A5FDBF6FF20B} Percent of particles which are metal. metalPercent {E0F10A4B-6DD3-49eb-B1E8-D32A834D1F07} Percent of particles which are other. otherPercent {C8E19E3E-DE56-428e-BE46-7E7B4545E3A5} Opacity of oil.Possible values any integer. opacity {5177807E-E432-4f65-B5EC-F9DA8566A1A7} conservator {44468FDF-C4CB-4009-8705-0BD6913907E4} freeBreathing {91047A63-123F-4e79-B978-915993393481} nitrogenBlanket {7ADCF0D8-FAB0-45fe-9832-763BA8D473E5} other {5D27AC3C-794B-4fbd-8761-0C42E4208C60} Sample from oil drainage device. oilDrainageDevice {BA582242-B982-4797-96E4-F962ABBA20FB} Sample from oil sample valve. oilSampleValve {78E02C57-D480-46c7-97FB-4BCE6E297962} Sample from other location. other {DFED0D11-8F3E-4be3-BAFD-74453B34901D} Oil temperature from infrared gun. infraredGun {E6EFCA57-C82C-4ee9-B977-F0E48B707F0C} Oil temperature from other souce. other {BE3FF80D-2962-49de-BE7F-90F70EE1BF69} Oil temperature from top oil temperature gauge. topOilTemperatureGauge {385BE143-64A3-4a91-AA3D-4E1B7D07EC2B} OFF {8317AAAF-E696-4f4d-AA5F-2874B62B8BA8} ON {D5222E54-0451-499a-A8D8-10D39D5CBED6} Capacitor trip mechanism. capacitorTrip {91566335-73B3-4962-AD98-8ED4D1E96F4A} Hydraulic mechanism. hydraulic {8C776FD3-1DD0-4e28-A633-E5DEA4C770E7} Pneudraulic mechanism. pneudraulic {A59CDB4F-9E17-40a7-B48E-45FF323AA5FA} Pneumatic mechanism. pneumatic {5488E724-D43E-4c80-BF95-696A82A3FB4A} Solenoid mechanism. solenoid {D5D6DEBE-7D83-4db2-8F14-A0D915166610} Spring mechanism. spring {29994947-AF3C-4653-B4C7-37F9643D34BD} Spring handcrank mechanism. springHandCrank {A4AF5A3E-D8F2-48f1-A1B8-73CB6965AEC7} Spring hydraulic mechanism. springHydraulic {BCB70AEF-9FAA-4c5c-B3C5-C52719A6B513} Spring motor mechanism. springMotor {C36B74D4-2D36-4984-9BE2-96A617F3E6F2} An absoluteValue limit means that a monitored absolute value above the limit value is a violation. absoluteValue {C37E3F49-FDC5-4924-A75A-7A4B7D05C856} High means that a monitored value above the limit value is a violation. If applied to a terminal flow the positive direction is into the terminal. high {DEB6E936-5033-4498-989C-D433460E5D3E} Low means a monitored value below the limit is a violation. If applied to a terminal flow the positive direction is into the terminal. low {1A441FD0-B158-4b91-A4F9-2F83E7EBA2B2} BILL_TO {BEFE95F4-26E6-4c55-89C3-D90DF7CC8316} PAY_TO {20AC10BF-F46A-4771-83B1-C88AD43422BC} PROVIDED_BY {0E9D0A8F-F5F8-4d66-AB08-585D7B772597} SOLD_TO {9E87CA03-C6A0-49a0-8773-8C277B35C9CE} CUSTOMER {755C4158-0E07-4c6e-AD71-07EF3CF2A026} RTO {67BA88D5-17C2-4a50-A771-D198F59BB75F} For 2D diagrams a negative orientation gives the lefthand orientation favoured by computer graphics displays with X values increasing from left to right and Y values increasing from top to bottom. This is also known as a left hand orientation. negative {6D82C240-A79A-4526-8D68-5EB815024164} For 2D diagrams a positive orientation will result in X values increasing from left to right and Y values increasing from bottom to top. This is also known as a right hand orientation. positive {860B40F5-247F-42ae-9737-7FE0EC735E60} This outage was caused by an animal is was unplanned. As such it is treated as a forced outage and is probably classified as trouble with a Trouble Ticket as well as a workservice order. The primary difference between this and an unplanned outage is the reason for the outage. If an animal caused this and perished as a result the utility may have other actions that are required to be taken by the EPA or other groups with whom the utility has an agreement. animal {6A838872-9EF8-4d63-9C8E-1843DE84D1CC} lightingStrike {815AEFC6-65C1-4542-B332-A7624897CE80} lineDown {C5493BB6-87C3-4a7b-A960-1193D6B9D548} poleDown {8A6D9D6D-1EA9-4ba2-8DFA-33AA85571B0B} treeDown {1F2D83D5-38A8-4925-BE4C-D2D741C089E3} The outage has been fully restored the crews have been released and the outage is shown as closed closed {7AD31E5D-F74F-4d20-883B-8F37F3F9674A} the outage has been verified confirmed {C25C7C45-AC9E-492c-AC84-68A1C56F7730} Some of the usage points affected by the outage have been restored but other usage points are still out of power. partiallyRestored {DABA1CC0-3186-47a9-A1CB-3567E15739F3} the outage may not be real since it has not been verified it is only thought to be an outage. predicted {4BB374BE-D703-4f05-8B67-209BC2BD3CA6} All usage points associated with the outage have been restored restored {CF0793F6-AC4F-4c31-BF02-A8CB5561A60C} Power system resource state change to in service. inService {0BED646D-9B8E-414d-A839-985B3FCE06B8} Other power system resource state change. other {AF8D6D63-7555-4599-9373-48C99361041B} Power system resource state change to out of service. outOfService {35587599-4E23-472e-9884-059331D3413E} Power system resource state change to pending add. pendingAdd {D08E54ED-D1FB-4fe7-AB1D-6D39615186AB} Power system resource state change to pending remove. pendingRemove {13C5B546-C97A-4168-A19E-8FEA5167FED3} Power system resource state change to pending replace. pendingReplace {5BC2039C-C41D-48f8-BD82-D823A3CE3F81} Unknown power system resource state change. unknown {4B4EE721-021C-4d27-88CE-0AE70B0A4CE4} L {C57DA898-83BE-4b5f-B48A-CB695FF4F22F} N {5BFC27F8-7F56-448a-A345-81DA5F59F3BB} S {80813ED0-7F84-45cc-8A85-634F1CCDE8FD} Y {7C2E5A54-A21C-436d-9A77-C94E07477BBC} Day Ahead DA {C27F9DF9-1FEC-45f1-A6B2-AC21F81152BE} Hour Ahead Security Constrained Unit Commitment HA-SCUC {98899724-42B5-443e-8B59-9DAB3B80F145} Market Power Mitigation Pass 1 MPM-1 {3571C009-9F21-4bd9-A211-7C6DDC2AB36D} Market Power Mitigation Pass 2 MPM-2 {D96663A7-147F-45a3-AD20-D54D52229203} Market Power Mitigation Pass 3 MPM-3 {A20138CA-2268-4121-B49F-28B02D440A94} Market Power Mitigation Pass 4 MPM-4 {DBDB0279-3DB6-4e8c-BA93-BB35737A24FB} Real Time Economic Dispatch RTED {0E0B0D6B-93C7-4c97-A4DC-B0BF5FAB081E} Real Time Pre Dispatch RTPD {70D24C43-D27B-4366-99D4-773904682700} Residual Unit Commitment RUC {282BCB80-3D13-47e1-94F1-49A3FEDE13C6} Automatic positioning. automaticPositioning {0420A9CF-DFDA-4acc-B5D2-C297FAD7A7EE} Fixed position. fixed {7C2450DE-D888-4741-A3B2-6598BE34F25E} Manual positioning. manual {279C3FB6-957B-4817-9ACE-1CCBE44C3D83} Phase A. A {EA5174F8-A73C-4f4b-96AA-54EAFB16BC9F} Phases A and B. AB {77216F5E-3863-424c-91CD-4597AE97B61E} Phases A B and C. ABC {5A6F7D82-6A2C-4eb3-90BC-8F77AAD9D50F} Phases A B C and N. ABCN {8E38EE25-FD5C-4b01-938C-008998EDA526} Phases A B and neutral. ABN {C5F9ED62-CB15-4c15-98DB-6593686F63E2} Phases A and C. AC {598C4480-5C39-4889-8BD1-D1D2BCEB4DEA} Phases A C and neutral. ACN {0396E7F5-6112-49e7-A7C8-7B7FA0214AA7} Phases A and neutral. AN {9B41A289-EDF6-4728-AABE-B11D2E617549} Phase B. B {DF516C67-D4FE-4a6b-9FE7-54E54036C7CA} Phases B and C. BC {8124AC36-FD4D-4b64-A414-6F9B8D350469} Phases B C and neutral. BCN {F494A423-E865-4c3d-8C83-180728F30A66} Phases B and neutral. BN {2780D899-5467-4920-8DAA-117051620D3A} Phase C. C {8E5E8952-BD3F-4b06-A218-7A1EE85598D0} Phases C and neutral. CN {DEB66611-AEAD-4b57-8CBD-65D1931709CE} Neutral phase. N {177D92A8-237D-4ec7-99BF-6BBE2AA2CE9E} Unknown nonneutral phase. X {18C21147-5A05-4e89-857C-07DED480CDD7} Unknown nonneutral phase plus neutral. XN {C97339FF-B1B1-4b27-9F89-F1224B83DFCD} Two unknown nonneutral phases. XY {88204DE0-8923-4886-8C42-955E3147E39B} Two unknown nonneutral phases plus neutral. XYN {BE6C0B89-4F67-41fa-B56D-1195F07B82E0} No phases specified. none {39811306-A5CF-49f9-9D71-313B1B5BC519} Secondary phase 1. s1 {50FB82A9-B3F5-4a7b-AF43-2EC84E06D953} Secondary phase 1 and 2. s12 {939E2E11-8FE6-4d66-A048-8F990F9BEBF6} Secondary phases 1 2 and neutral. s12N {2E31EA79-AFF2-45bf-82E3-DD2DD070FDB6} Secondary phase 1 and neutral. s1N {7CBBF307-75C0-4255-B181-0BB16E0B4A23} Secondary phase 2. s2 {DD0F804D-9672-4043-8B7A-9937AC0C3BAB} Secondary phase 2 and neutral. s2N {16119B57-3431-4045-A8EB-1618E844A397} The fault is when the conductor path is broken between two terminals. Additional coexisting faults may be required if the broken conductor also causes connections to grounds or other lines or phases. lineOpen {9D8DAA9D-0BC6-4f21-9E79-942AE0908070} The fault connects the indicated phases to ground. The line to line fault impedance is not used and assumed infinite. The full ground impedance is connected between each phase specified in the fault and ground but not between the phases. lineToGround {D1E5958A-98F4-49f3-9C1E-AA42781D5B9E} The fault connects the specified phases together without a connection to ground. The ground impedance of this fault is ignored. The line to line impedance is connected between each of the phases specified in the fault. For example three times for a three phase fault one time for a two phase fault. A single phase fault should not be specified. lineToLine {9A278CD5-0F0C-4b56-930C-34CE03649D27} The fault connects the indicated phases to ground and to each other. The line to line impedance is connected between each of the phases specified in the fault in a full mesh. For example three times for a three phase fault one time for a two phase fault. A single phase fault should not be specified. The full ground impedance is connected between each phase specified in the fault and ground. lineToLineToGround {98041BF3-DBA9-4d80-AE9A-D52C72ACDAB0} Delta connection. D {BB7AE92B-4282-499f-A237-2EFB5550CF18} Ground connection use when explicit connection to ground needs to be expressed in combination with the phase code such as for electrical wirecable or for meters. G {9B904A86-646C-4eb0-AC5A-C855B6963581} Independent winding for singlephase connections. I {B1808795-7E5F-440e-A7D2-68D61720928F} Wye connection. Y {78F5E336-DE68-4bcd-8E5D-D60B2D772116} Wye with neutral brought out for grounding. Yn {4204851F-78EC-4f27-AEF3-587D5A6D43ED} Active power in the branch group. activePower {4B8ABF82-7789-4db0-A0E0-746D3BFC8D76} Reactive power in the branch group. reactivePower {E85C2AFB-94D2-4a61-AF0D-D26EA7E3744D} Compare load flow result against the active limit for active power for the given equipment. activePowerLimit {1FA22B75-D95A-40fd-B873-4B2B665556EA} Compare load flow result against the active limit for apparent power for the given equipment. apparentPowerLimit {A8A9669B-FC34-4585-854F-FE0E7253734B} Check if all terminal on the equipment is connected. connected {2CE1D76F-674E-440f-933C-A23AC1BB0E7D} Compare load flow result against the active current limit for the equipment. currentLimit {BA7E9107-A354-4481-A0CC-9C3A5BCA2F7D} Check if equipment is in service True if in service otherwise false. inService {BB7FEF75-898C-492c-A2C5-2025359F85D6} Compare load flow result against rated current on the equipment switch. ratedCurrent {901676EC-7A3C-4153-B6FA-DBF80512F875} Compare load flow result against the active voltage limit for the equipment. voltageLimit {D332FA38-D0BE-4b18-86D1-36A58291C5E9} Active Power on the Terminal. activePower {5C716C7B-B930-4b51-A02C-6731F9C7AEED} Apparent Power on the Terminal. apparentPower {ECC1F568-D75F-4e3d-B418-81A21D8D7E80} Reactive Power on the Terminal. reactivePower {13A962FA-D94D-4f28-B9A4-17CF1EAFECF5} Voltage on the Terminal. voltage {55790E55-C496-4a60-AB26-149F6686AEB0} asphalt {31D20CB5-C814-4965-BD5C-B79D9AF627A2} cement {7A4F578A-2AD1-4d5e-866D-7BDCCF0D4F31} dirt {0841FF5D-16CA-4a2a-9D9E-6799C33CC2D6} other {F41D75A1-4E9D-48e6-B846-5A6D35EF593C} unknown {E20B6327-A5D2-4afe-BAE9-289D70558D8C} cellon {A2EA2FA2-1485-490b-BDA3-3CD1D2438F90} chemonite {8CB4DBB9-8375-42b6-9DA4-C29F31E57CDE} creosote {C1514E50-98C7-4511-A391-D19681D82FA8} naphthena {717910B6-037F-42c7-8A05-A9A482A0EB7E} other {3546A7B9-AAEB-483f-A59C-2D9373C3E143} penta {71380ED0-F52C-4aab-A2DC-6CEC05CC4686} unknown {2FC4A079-5104-4aec-A31E-3863FD0E9608} butt {86CAB461-E417-48fb-AE02-D44961FD6038} full {7D17719A-C580-48b9-8EF1-A3939226DC76} grayStain {D46F9F7F-1C7C-46e0-A008-F02E98D0D64C} greenStain {B36B51BD-55CF-4d35-A760-12D9A3999EAA} natural {4B94C982-FB02-4568-9CC7-6CD1E09EE8AB} other {907F4C1C-0D88-45c7-8BB9-6B308200841C} penta {581D336E-6187-4f39-9F55-1AC25F03DB23} unknown {E58EFF04-5D7D-4537-9CF1-B13084F169F8} The potential transformer is using capacitive coupling to create secondary voltage. capacitiveCoupling {79BD0A18-3776-4e24-A1E3-892D9282521C} The potential transformer is using induction coils to create secondary voltage. inductive {12D1E9BA-EEE1-4e7b-B541-B68DBAD67316} N {B27CD0FE-55CB-4c21-B881-37E0D5A10810} S {9BA66A24-5312-4961-A992-47DA30B9546B} Y {E2E6B20E-E24E-4bfd-9B1C-B10B82B2E239} capacity {494B44FF-E452-48a2-948D-D9971DFD4ADE} congestion {3FAB4EA1-8E89-4960-9416-C7E17F38C649} delivery {4A77CB5C-DE76-4320-B78E-C919D428EA5A} loss {0DF6DFF6-C44D-449b-A99D-CCEEC663C702} mileage {F22056B0-071C-44c2-BFB9-5D7CB11F28C4} system {EAFCBB60-124D-4a10-8948-6E052DFFC96A} total {007473BE-0665-4619-9D1E-59F1781D0F7B} Diagnosis procedure. diagnosis {B4EEEAA5-C3A6-4dc2-ADBA-61F3418FC54E} Inspection procedure. inspection {34182161-5EB5-4641-B07B-6A17ED569570} Maintenance procedure. maintenance {3E821F9E-89FE-43f7-8889-489B582E74F3} Other procedure. other {42AC1AFC-7EF1-4947-B2DA-C71EF2AF72D9} Test procedure. test {21C67CBB-313E-45d5-9569-9B61A2BD6E15} cancelled {8DB13B5B-7E69-4ee5-82E8-C9C0E58EA5E1} closed {FF011FD6-C4CE-4da8-8FA0-CA62F984D683} draft {989B9186-7078-438f-A2E0-5B9897CDDEA8} frozen {E405B658-EB96-41cc-8F12-AA68AF19E188} The adjustment is in percentage of the active value. byPercentage {8C25683F-4822-4d54-9F44-54DDD0FB6B74} The adjustment is in given by a value that defined the changes that will be done to the active value. byValue {533E9ED9-C4E1-4c5b-99F9-93DC74554FA2} The equipment will operating on a value given by a measurement. measurement {F148ECFB-3B36-41fb-9F48-77E78108FC10} The equipment will operate on the new value. setValue {D6C00622-4AA1-4625-86A6-70D758C6D52E} M {DECD0EB4-7450-4c82-8C01-993B8B97A80B} R {19104108-1220-444b-A907-6C7C28C25D14} Fixed ramp rate independent of rate function unit MW output 0 {8EF01E39-F3B1-43b5-AF63-0CB7585DFFCE} Static ramp rates as a function of unit MW output only 1 {92B022BA-8AF4-44e8-A7C0-27DE6621ECBE} Dynamic ramp rates as a function of unit MW output and ramping time 2 {392FD8BE-A293-447a-A118-67F032BC1A4D} BEST {CB755C64-A2A6-4af9-9497-E7282F8C02A3} not applicable NA {FCEC1981-B42E-4801-B496-A2E2DA1CB02F} NORMAL {0B90C498-47C9-4dcc-8A61-05FF615F2AA2} WORST {FB0F6D6C-FFC0-4192-88DF-F3240C6EC478} Intertie ramp rate. INTERTIE {7A6702A8-B8D7-43f8-8A43-A2798E28A656} Load drop ramp rate. LD_DROP {11B5352F-6DC7-4f5e-BB35-4BB034EFE48E} Load pick up rate. LD_PICKUP {00BC8032-8654-45a9-9D49-445086D1CF28} Operational ramp rate. OP {2C3F2698-584E-42c3-AEC2-C8625FDB50D3} Operating reserve ramp rate. OP_RES {7585C660-FE66-4c47-A347-28315A490BA6} Regulating ramp rate. REG {69842421-78FD-43f9-9BE0-642E9A93AE35} Randomisation of start andor end times involving the operation of one or more devices is controlled by default settings for the devices. default {28F2A4D6-D3F1-4505-8C4B-27B4285F513D} End time of an event or control action affecting one or more devices is randomised to prevent simultaneous operation. end {81A71A6C-FD52-42dc-801F-6994A3CDCF84} Neither the start time nor the end time of an event or control action affecting one or more devices is randomised. none {8AA87276-306D-44d3-B217-7C38E51BE204} Start time of an event or control action affecting one or more multiple devices is randomised. start {5F840059-4252-4ed6-983C-5C5F9C52EC2A} Both the start time and the end time of an event or control action affecting one or more devices are randomised to prevent simultaneous operation. startAndEnd {ECF539C1-7136-46fa-9049-DD80BB3210DF} Readings taken or to be taken in response to a billingrelated inquiry by a customer or other party. A variant of inquiry. billing {09401BE6-FE52-4ea5-A24A-F41856E49CEB} Readings taken or to be taken in conjunction with the resetting of one or more demand registers in a meter. demandReset {BFE93BAB-5090-44d1-B007-60F586394D11} Readings taken or to be taken in response to an inquiry by a customer or other party. inquiry {058CBE99-8C7D-4845-9198-88353070D22D} Readings taken or to be taken in conjunction with installation of a meter. installation {9CA1F132-A17F-4742-AD9E-C6EE7C240E3B} Readings taken or to be taken to support management of loads on distribution networks or devices. loadManagement {F92A3C79-CC78-482a-B0ED-AB79101CF541} Readings taken or to be taken to support research and analysis of loads on distribution networks or devices. loadResearch {DBEF3365-7D15-4c37-8A9E-D9F2633AD687} Readings taken or to be taken in conjunction with a customer movein event. moveIn {74701108-3C53-415b-B0B0-19DD4B9C8422} Readings taken or to be taken in conjunction with a customer moveout event. moveOut {125F5BB7-4B21-4e16-99C0-FA3ED897CBE0} Readings taken or to be taken for some other reason or purpose. other {81BDD9E5-1086-47a5-B25C-DD9DFAC8BE9D} Readings taken or to be taken in conjunction with removal of a meter. removal {945EA388-BBA1-4678-B0A5-437E15FFC2A5} Readings taken or to be taken in conjunction with a connection or reconnection of service. serviceConnect {8692463B-89B4-4638-9CB9-B5F7D6D4981B} Readings taken or to be taken in conjunction with a disconnection of service. serviceDisconnect {02139504-E7A5-439f-B3A6-B5DDE7DA6410} Active power is specified. activePower {23C9B050-DB74-4e78-9212-041967CED311} Admittance is specified. admittance {83F69075-D350-4d2c-92B3-50D45A81B4B3} Current flow is specified. currentFlow {D83AA372-A200-4733-B949-55A809B646A2} Power factor is specified. powerFactor {A87A2181-9C85-44c6-BC3D-475CF25AD958} Reactive power is specified. reactivePower {A7F50821-D173-4ff1-96AC-7E854C3ACFF5} Control switches onoff based on the local temperature i.e. a thermostat. temperature {93B6C68E-61A6-4d4d-9C47-B3A366DF03DF} Control switches onoff by time of day. The times may change on the weekend or in different seasons. timeScheduled {558EACEC-1091-4287-88D2-ED67E6966AF0} Voltage is specified. voltage {563504F4-8FFE-4006-8A61-4820A3502302} breaker {6174DE04-2654-4823-985E-52C8D2EC711F} fuse {26A41C3C-64CF-497e-9F1F-56E08D0018D8} line {76D76D68-1859-43ca-B6F1-85FE86906F69} other {D48DE01F-619B-4541-AFF7-DFD91403EB04} recloser {C96483D4-3293-4a3e-AE76-FAB62500C90D} sectionner {84B959E5-C71C-456f-B243-411880B0CD6E} switch {E8CAF199-AFC0-46af-8484-ADBB623A6090} transformer {C9B2D6B2-42C0-4fd0-9985-26DF85C76D32} centreEarth {C55CBB28-B6F8-4f04-A7C0-F7C8E59D3AD6} ground {5AE55206-50AE-4d31-B491-D39E79DE756D} seaLevel {70A96BF3-AD87-4725-81C7-18C26A1271DF} Remedial Action Plan RAP. rAP {841B98AA-E6BE-46de-877B-6B203BC9929F} Remedial Action Scheme RAS. rAS {BCC849F2-CE8B-49f5-9347-F1C0D5B99015} Input is branch current amplitude from remote terminal bus. remoteBranchCurrentAmplitude {C49FE8D2-9333-4728-B57E-F9DB826A4757} Input is frequency from remote terminal bus. remoteBusFrequency {C6DF2D38-4523-42d8-9934-7C24B7F01D5E} Input is frequency deviation from remote terminal bus. remoteBusFrequencyDeviation {D3F46905-3B27-401f-840B-8AFFBE0EA043} Input is voltage from remote terminal bus. remoteBusVoltage {A9AD26D4-D7B8-4dd1-B5B1-90ECF07AD473} Input is voltage amplitude from remote terminal bus. remoteBusVoltageAmplitude {ADC6015D-1B75-4967-B9C1-7497E00BD416} Input is branch current amplitude derivative from remote terminal bus. remoteBusVoltageAmplitudeDerivative {A3DA99C1-FC9E-4ae3-9DC8-F51A15BF38B8} Input is voltage frequency from remote terminal bus. remoteBusVoltageFrequency {2F466BEB-1E65-4226-933C-341820F28D03} Input is voltage frequency deviation from remote terminal bus. remoteBusVoltageFrequencyDeviation {97379F4C-D3FC-460d-BCF1-2C189D9E8712} Input is PU voltage derivative from remote terminal bus. remotePuBusVoltageDerivative {FF2F5379-4C06-43bc-AEB4-79F6A051BA14} Control centre. ControlCenter {A70EC582-6B62-4b43-8D83-AAA23EE4A510} Intelligent electronic device IED. IED {2FAC3243-3420-4667-B5DD-DD59D1F07345} Remote terminal unit. RTU {C9761387-5835-4c50-8FFC-1F3291CD3B65} Substation control system. SubstationControlSystem {EF67D5C8-C18E-432e-8C52-DE99E5935742} Station automatically reports. automated {0A3570DC-2C56-4bf9-A3BC-1E250E4739FB} Station must be physically visited to gather observations. manual {9B0A5C6D-EEA6-4fc1-AC5D-3AFB350E5663} Station must be queried to obtain observations. queried {55141AE8-E9E7-4119-97B9-6B1679D56DBA} ISO {EC33FEBB-FF63-4198-B438-8B152B97249C} MP {901CEDF4-6D98-4dee-93DC-9AA8EEB6A7C6} Contingency CONT {2ED7AAF3-D1CE-4bff-8D5B-E7C3AADB6190} Operating Reserve OPRSV {F065C0E5-814C-4731-865B-A0FF13B929BC} Regulation REG {A62AB657-033E-481d-A150-9BA19FF62D37} CSNK {E1A26E38-B082-4006-8D27-CB95976B7B07} CSRC {952CC0F6-4423-4393-BC62-A6FE83D4806A} LSE {DDBEE3AC-92E3-4de0-8F9C-5FEEA1D174E2} RMR {ABF73CE4-7ED8-4978-B471-23D2836BC035} SC {6C05AB4E-4B4C-4fe4-87DA-B0DABD385AB7} Flexible Offer. FO {405DF98D-8549-46e1-A20C-92BADEE6A817} Must Offer. MO {B4EC320E-2AAA-4642-A3D9-8CB1C0582C73} Non spinning reserve. NR {E49F573F-9AA9-4002-9CC8-BF09D749BAB0} Resource Adequacy. RA {6C55D24A-4C20-4d2c-8AD4-36CBA39C11F2} Regulation Down. RD {BDCF6571-EC59-4b68-97AE-DD2592A6D1D1} Reliability Must Run. RMR {3CC88E37-0DF1-4291-8F39-093DD48C5380} Regulation Up. RU {C431AFAB-FE3D-47ad-9DE7-B3F76A1786FE} Spinning reserve. SR {F2E22B52-9E13-4ebb-88C5-54FD0910D8E9} DAM {EEA14BB5-0C46-4928-AFD1-E8602A6B793E} Generic GT {0E46739C-B680-4320-BB8F-76716350FF7F} RC {D268FB6A-DA08-4637-98D0-94E4DA584FA4} RTM {D5D472A2-E5B9-4271-B106-F46900291BC2} Black start BLACKSTART {7F815B7D-4C21-4238-A603-398434985122} Capacity {E897D16F-796B-4f45-B1DC-ADA5CFFED6A5} Demand Side Reponse DSR DemandSideResponse {871DA605-AB36-4479-AFED-E0FED8B0D5C5} Energy {219290EC-60A8-43a5-9201-BEB72D4C2420} Intermittent resource IntermittentResource {8DD28F31-D87A-41dc-87E2-E76A6FE68F75} Non Spinning Reserve NR NONSPIN NonSpinningReserve {06E99502-D384-4016-A07A-135341EA9260} Regulation Down RD REGDN RegulationDown {1576E704-0207-40aa-B956-D46B2A199B7D} Regulation Up RU REGUP RegulationUp {C18C59F7-A569-4c59-9A60-801E482592E5} Reliability Must Run RMR ReliabilityMustRun {601F121C-5038-421c-B526-91789899CC6B} Reliability unit commitment RUC ReliabilityUnitCommitment {CB9D7A1D-CFC1-4a41-9947-857071DC166D} Spinning Reserve SR RRSPIN SpinningReserve {C21007EE-E737-4356-81E2-45FA81F950E4} Synchronous Condenser SYNCCOND SynchronousCondenser {C1A4372C-0DA5-443f-A744-02233F6B6229} Generic Type GT {81D89297-3A1F-415d-BD86-2BB8E0736E04} Intermittent Resource IR {62336D5B-DDE5-4d06-9E32-40499043A297} GenericRegulationSpinningNonspinningIntermittent Resource NR {789D6DBF-3289-4bdb-918C-2DF3B5578E92} Regulating RG {4B9FEA56-345F-476a-9C83-25621E2F9F3D} Spinning Reserve SR {4352FA85-E196-46d7-9D00-3FC838A4BCCF} LOWER {CF547BDC-DA9E-40f2-9ECB-0E6DFAD3D68F} UPPER {79E8ED6A-DD7D-444e-B1F0-C69BB877E7DB} Resource registration is active Active {6DD1BFAE-F76F-46f9-BF9B-C9C2B28A359F} Resource registration status is decommissioned Decommissioned {4061C09F-B7F7-4f19-B557-BD47637103BA} Resource registration has been suspended Mothballed {AC33702B-C6EC-49fa-BB2B-04C4C7AA46D5} Registration status is in the planning stage Planned {AE4F7E67-BEC9-4298-8404-ED705A8697AE} Actual. Actual {5C60DD53-9B42-4e5b-93D6-44F35E175EE9} Contingency. Contingency {90ECA92B-3B94-4ffb-9078-B4872950CCB5} Flowgate actual base case FG_act {EA4A49E9-04DF-4fe4-BC3C-0F8D0E3D1CFA} Interface. Interface {4B735140-B468-4e65-A97A-E4F94CF625C4} Retired due to environmental reasons. environmental {93C1426C-D3E5-4d69-956E-DA85EB30A7E6} Retired due to excessive maintainance issues. excessiveMaintenance {365EF4C8-7EC1-4328-B01B-E81EF2500D3D} Retired due to facility upgrade. facilitiesUpgrade {EDE28E56-E708-4428-A6D0-35DB1230461B} Retired because of failure. failed {297E10AD-46C6-4ec9-9B34-7A7F438014E9} Retired due to obsolescence. obsolescence {B9F097FD-782A-4f56-A47C-3FD08BCA531B} Retired due to other reasons. other {A6ED8064-9321-461e-AA0C-67FEE3F00053} Retired and sold. sold {97A6F21C-E45F-4d86-84AD-724745CE3B8F} Commercial revenue. commercial {3F11FCF7-BB43-43eb-8C68-FCFA84C28228} Industrial revenue. industrial {A863A2D9-DE9E-4505-9A5D-81EE54FC0934} Irrigation revenue. irrigation {84545366-9BBF-42c3-A57C-7F0619C3176E} Nonresidential revenue. nonResidential {010E8E86-7A0E-4ced-A464-7D4852453839} Other revenue kind. other {4F23130D-2BC1-4874-9355-5BB460BECDC2} Residential revenue. residential {24E5488F-4E2C-4dde-A82A-A44977329DE3} Streetlight revenue. streetLight {14E83C5D-CCD8-4d25-B086-A56E81F95FB3} Customer risk score. customerRisk {BA90BF1F-788F-4154-92E8-B0623B9FCD00} Financial risk score. financialRisk {37E40816-D083-483f-88DF-9BA68D251EDC} Safety risk score. safetyRisk {0E3994A5-849C-4bc5-80DF-E580AD1FC616} Round rotor type of synchronous machine. roundRotor {67CB8B97-107B-40bc-8BFD-21812D8CCE2D} Salient pole type of synchronous machine. salientPole {3D4CFF27-DA7C-4073-B80B-790D600A5036} Reactive power control. reactivePower {1090360B-E8A3-4e71-B538-629F660CB01B} Voltage control. voltage {34BA1F29-A5C7-4f29-89FF-B8186FCF7B87} Glass can container. glassCan {A022AA80-D1EF-48d9-B0C9-BC243A6DCD2B} Metal can container. metalCan {D7D5BCA6-5BB5-42b1-9A06-FD06E43CFE5B} Syringe. syringe {5938B3A5-8254-4d88-922A-14E1E38B5EE4} Exponential scale. exponential {332B5C30-08A4-4e89-84C8-D215E949DFAC} Linear scale. linear {A0DCBD6C-A616-44a6-BE00-BAFAFED94E8D} F {8F28E40A-BE99-4fdc-8A0F-8C0FB91A465B} P {D91DCF8F-AFFB-433a-8924-E7CFE27C5C17} R {E0149A66-D0F6-4ffc-A7E2-CEB756CB19EF} Seal is broken. broken {24F77781-F3C9-4862-AF1E-AF413F8E0C43} Seal is locked. locked {3D0A12C2-3CF1-4821-AB3C-7F646ACF4934} Seal is missing. missing {DB741A15-5087-4fc9-8C22-E46B268E43F6} Seal is open. open {D14BA5DD-8A6D-4cf4-837F-553119D2CA28} Other kind of seal condition. other {0B1562FA-592F-4a8c-AC96-06DBA12A3194} Lead seal. lead {F5621AC0-6891-4a99-ACC0-4B5FBC69D8ED} Lock seal. lock {609E80A5-1B4C-4dfa-80D9-2457F4B0846B} Other kind of seal. other {1C12FE57-1A7E-43f3-9FD0-849EBD08FD08} Steel seal. steel {9BD65DAC-06E2-4117-A850-1F076F52E20D} CONSULTATIVE {4E191ABB-4BA8-4c84-BC80-B1DAF017E057} COST {014C9B4A-2343-44b1-8CF8-77831D8C5555} Existing transmission contract. ETC {49205AF0-D100-4c00-99B9-85502ABB7E5B} Transmission ownership right. TOR {2A9C5C05-F87E-4d66-B643-D981638B5E5D} BAS {73FE9AAC-7DC0-4c61-BD2E-19D014DB8570} ETC {FF45B09C-ECE4-43a1-8EBD-1C91F6AD7FE5} IFM {0F60909D-7AC3-4cc6-A6A7-89BDC0AB8C33} LOF {C05288FD-AC61-4e11-9C43-BC7A062B9C4E} LPT {1D4D3176-7F4D-4105-8D91-0F31205EBDC3} PT {CFDA88B0-7DCE-44ee-B10A-2764798FD5FF} RA Obligations RA {7E9E7FBB-7727-4442-BC95-8F9568653924} RMT {0D10027B-C981-4795-982A-1CB77645AC7B} SelfProvision SP {32C520AC-9CE0-4bd4-A8EF-090BAB632840} TOR {2BF1554E-0155-4146-AFAD-F954E89E1629} WHL {EB6BFE36-8341-4cad-95B4-9A32F204ABC2} BAS {AFCEBF48-8017-4c7c-A3B3-626C475C10A1} ETC {128BEA1C-F08F-4264-A493-AC2B371A9DF3} LOF {BC24C35F-48CF-45b9-A86C-CAF529075D52} LPT {0F73B998-642B-46d3-9744-7B9FB339DD0D} PT {F90327F9-5926-4f36-8CD0-6AF837F28A0A} RA Obligations RA {DB8F0DCF-F7ED-4b10-A050-1359EE4D2A60} RMT {4012001F-7258-4c69-ACE7-5D1FADFBCE01} SelfProvision SP {3E0BE79A-C7E9-4c6c-976E-0618E164CC38} TOR {80E3370C-8FC7-4490-A2E8-F110E3524069} WHL {32AB532D-F943-4d34-8785-1B1795719C61} Existing transmission contract. ETC {99DCC81B-438A-4643-84E2-68194F67AAF4} Low price taker. LPT {6DD5221B-EEC5-4c40-A546-590FBFF4C8ED} Transmission ownership right. TOR {511B0078-3A69-4783-8B7C-6CC2E1E2857D} Base Schedule BAS {2B6A306B-C1DE-40d7-8671-C59AA137AE49} ETC {595D5F81-623F-40ed-A84C-E2ED32D390B2} IFM {7B361B1F-ABD8-4b14-B784-8808DB996FC1} Layoff schedule LOF {95BD61E0-0875-44c5-B6EF-46042D0636F0} ORFC {58776BDA-808F-48a8-8C34-795246613DBD} PT {99F046A7-4103-475a-A359-BD19728675B6} PUMP_ETC {B2A5F062-6172-4cf4-9B75-C6ED5F230C67} PUMP_TOR {E6CDCE4C-A18E-4305-B377-89C9FE185F34} RA Obligations RA {A7170F2D-9F2D-41fc-BDE3-6EDA12EB19B1} RGMR {C212A076-AB49-45e0-93CA-7E5C621CD226} RMR {4426F2E9-6D96-4162-81CC-F33628D323DD} RMT {30CB3C2D-2BBB-4239-A44F-1888B278AFD1} RUC {45BC35BE-880A-47a3-A80E-7CA7590799B2} SelfProvision SP {7D27275C-A8E1-4c67-AB7B-99198E432AA1} TOR {CFD2B9EE-1BB4-4f3b-AD48-3BEA16EC9C98} WHL {9B485B3D-97BF-422a-AA30-D7B768939118} RMR {EBAEAF0C-EF0F-4eb7-A701-E37E12D65922} Air service. air {6EA2B7D5-877E-40f9-A417-2540E85DB19C} Electricity service. electricity {7F85E37C-53E2-4945-B940-7AFF43790F0D} Gas service. gas {29A7BD4A-0D46-4974-BD81-5B3C9675EB6D} Heat service. heat {70542D24-37A9-4815-ABF0-08DBD4466147} Heating fluid service. heatingFluid {872097F7-04A9-4183-8B84-5AB064173457} Internet service. internet {89425E98-6977-4c45-A1D5-2503401443BF} Natural gas service. naturalGas {C9194C7B-CAC6-451c-8B33-9EFC7EE9D52B} Other kind of service. other {D68430F7-15F7-411d-BB9C-2F621E810228} Propane service. propane {5CBFA9A4-11D9-428e-A61E-B4966F202D4A} Rates e.g. tax charge toll duty tariff etc. service. rates {EFD8A796-7B1E-4d44-8C65-BFECC4CABBC2} Refuse waster service. refuse {A9EF0C5F-F8D5-4835-9AFC-7638A4897D21} Sewerage service. sewerage {AE59843D-C3DF-4411-BEC5-39C9B7889501} Steam service. steam {BAC861E1-7AA2-44a2-BDCE-644F80C624DD} Time service. time {43D17447-FF5C-4002-B5BA-69C6B0C8DC55} TV license service. tvLicence {05AF4975-59AC-416b-8819-D5AEC405FC7D} Water service. water {4A2E4707-7C89-44b8-AB92-AFAA39137545} Current transformer ratio used to convert associated quantities to real measurements. ctRatio {8CCE45CF-9B38-4236-9B61-F2C3CA587FC8} Voltage transformer ratio used to convert associated quantities to real measurements. ptRatio {F768471A-51F5-4093-8E9F-0E84AD144DF8} Product of the CT ratio and PT ratio. transformerRatio {5CF72AAB-CB7C-4cd0-9F45-1A597458FC3D} Salient pole 1 in IEC 60909. salientPole1 {C6224E17-3C55-41b4-96B0-A7D760836509} Salient pole 2 in IEC 60909. salientPole2 {45389D96-7D96-435f-B054-391491734D26} Turbo Series 1 in IEC 60909. turboSeries1 {C330D074-B02F-46e4-B49E-2F5AAF36FFE0} Turbo series 2 in IEC 60909. turboSeries2 {F5BECE1F-74CA-4c01-8AD2-6093E28CC2AF} fixed {E2EEC3F1-49C1-4d81-BB2B-09839E687C37} localOnly {4AE4E7F0-DF5A-4f36-B980-F7F60E44EC5D} remoteOnly {29DDFAFE-5682-49f8-B9AA-F80ADBE3FA20} remoteWithLocalOverride {7B40D412-6D0F-4f91-A609-07ACC7DFDD8B} current {59C4859C-A809-4cbc-A9C5-AF2DCF5DC8E6} none {A9E6A720-8379-4788-93E8-8669DF42B249} powerFactor {0423B958-8C0F-4ee3-BAFD-F949A9C07892} reactivePower {57531641-5175-4c05-AA18-6141E897E0EB} temperature {59E3E447-A9CF-484d-A056-4D6E52E2BE91} time {0027B6DD-FEFC-49b9-9C6C-3945C9B3B565} voltage {8550A25E-2926-423f-A26F-E3FE0CB36E2B} Phase A. A {C02D22F4-5CA2-437e-9F27-95F4BFC8B870} Phase B. B {321F86C8-F9F3-4a29-B0C8-BE4329CC578A} Phase C. C {75A291F3-4B98-4d53-ADC8-6A8C31AEBF8D} Neutral. N {544E8D1F-5B68-4435-8096-1BA22C0AC0BA} Secondary phase 1. s1 {DFA995B4-25EF-448a-973F-A013ADC35EA7} Secondary phase 2. s2 {B1ED33EE-4FE9-48c2-A80B-25B1A8576E26} apprentice {84B8E457-6590-4d5d-8060-B0F847F93A11} master {03D4595F-C2A2-4ced-9C89-E47BE1AA3C3F} other {A09B1665-0095-4b5b-9BB8-AC9420B00613} standard {9E2D8894-497F-4705-99FD-D5D45F95AC48} The value contains a default value. DEFAULTED {A72974EF-B5C3-4d7b-8CA5-3C16B95E4A1C} The value is provided by input from the process IO or being calculated from some function. PROCESS {1BA84003-B2F9-4264-97A4-C7A0AD5541D1} The value is provided by input of an operator or by an automatic source. SUBSTITUTED {AFA40328-DD9C-4cd1-BB9B-4AC747AF3117} CSNK {5875D1FC-3543-48b0-AFE7-0E3E0A89DE1B} CSRC {EBC677F3-DD28-4bd3-897A-DD44B93551A3} Neither {877AA270-EF3B-4d45-A240-7901310A34FE} Sink {DC2E1C7C-659C-4c94-9A37-6D169CF8B82A} Source {E0542BA6-140D-4eb7-8E83-961562953215} magneticFieldDirection {E827C7EB-B9FB-4f6d-8004-9A43BA187E51} magneticFieldStrength {1BEF64C9-72D6-4e2a-A720-5884AE778DD4} EASTERN {57669F56-1591-4eb8-A92E-C5C5C7744197} PJM {10C81FCB-4AA3-483e-AD8B-CDADB06A8FE0} RFC-SR {12AA8018-F28B-47a8-8C74-65798754AC77} SOUTH-S {21BFC07D-92C7-4ce9-8211-4955E6E4511A} AA {5569BB81-07B2-45a6-979F-1A704621F0FB} CA {4133A2EF-39F8-47ba-9345-4E5C85AFD71F} RZ {4A563DAC-C63D-4d80-A403-B16B2BD84F2A} The load is represented as a constant impedance. ConstantZ equations are used for active and reactive power and no attributes are required. constantZ {B1BBDC91-9A07-4bad-9063-52E92C620FC6} This model is an exponential representation of the load. Exponential equations for active and reactive power are used and the following attributes are requiredkp1 kp2 kp3 kpf ep1 ep2 ep3kq1 kq2 kq3 kqf eq1 eq2 eq3. exponential {514F69B7-F201-40b6-A6EE-D54CDB2A09B0} This model integrates the frequencydependent load primarily motors. ZIP1 equations for active and reactive power are used and the following attributes are requiredkp1 kp2 kp3 kpfkq1 kq2 kq3 kqf. zIP1 {D902D0A5-4BA2-423a-B1AA-FCC601F95001} This model separates the frequencydependent load primarily motors from other load. ZIP2 equations for active and reactive power are used and the following attributes are requiredkp1 kp2 kp3 kq4 kpfkq1 kq2 kq3 kq4 kqf. zIP2 {33B98922-364D-47a8-992D-5EF6DE24F0EC} highPressureSodium {6288DB78-C40C-42cc-A0B2-31B2835A1555} mercuryVapor {8EE3F5B7-CC88-41d4-ACC6-317426F195CB} metalHalide {7950134B-7889-4378-9590-D3D2CE552AA3} other {1F4B7C50-3902-434c-B6D8-543542AF4903} concrete {3C9441EE-16E2-4e19-A998-70F6929D0BB9} other {478A01F9-B40C-4ecf-A476-B0D58CF5E754} steel {3BDCE7BB-70EA-4bd8-9183-768E4F6E6BDE} wood {C3D3746E-7135-4836-96CF-AFF53CC0AA47} anchor {E8DBBCAC-5BF8-4242-AF88-0055B09949C0} guy {E2F2C63E-073C-423d-AFC3-15A088DB2651} lse {F8249DFD-3B4F-4bb9-8FEA-011EDFF53695} mdma {83236180-1B98-4e79-B9AD-63111CB7AAD5} msp {2983E6CC-5243-4499-807E-16AEA952110F} Other kind of supplier. other {8B8FB194-E726-45df-9EA8-599524E26A75} Entity that sells the service but does not deliver to the customer applies to the deregulated markets. retailer {965EE54C-D4E5-4b6a-A6B3-8D9B2A4618F8} Entity that delivers the service to the customer. utility {D8BF1314-1DA4-4522-B101-25B6100F041C} Close the switch. close {3492915F-C6CA-4315-ADC6-B3CBF8240948} Disable automatic switch reclosing. disableReclosing {E5F6008A-56A0-4f1f-BB3E-86D94F6A360D} Enable automatic switch reclosing. enableReclosing {86E39986-025E-400b-B435-93EB055DCD20} Open the switch. open {6A4C2BE8-9771-457b-9011-D9023B75840F} Closed status. Closed {DB8AF56A-9984-474f-840B-4C3B1132576E} Open status. Open {99FE3FFC-2570-4e44-AE1B-304CA36679D9} Indicates the synchronous machine can operate as a condenser. condenser {AB175867-D096-4c32-9722-1B571D44A22E} Indicates the synchronous machine can operate as a generator. generator {EC04A0D2-3B94-4d7b-B3F1-F2A3321B7BC4} Indicates the synchronous machine can operate as a generator or as a condenser. generatorOrCondenser {1077F20F-1198-4e1b-87A6-5BAAA6B34F72} Indicates the synchronous machine can operate as a generator or as a condenser or as a motor. generatorOrCondenserOrMotor {E147ABB7-F0AA-4ddc-9DAF-14BF3F50DA4F} Indicates the synchronous machine can operate as a generator or as a motor. generatorOrMotor {653D9CA7-A063-4851-9E36-B7B85BE1BE10} Indicates the synchronous machine can operate as a motor. motor {C5DA8C90-AC9E-48b6-A58A-DF9A0352F3A0} Indicates the synchronous machine can operate as a motor or as a condenser. motorOrCondenser {F1D15583-2559-4100-B262-83DB325BA34F} Subtransient synchronous machine model. subtransient {D2B83ED1-6190-4d28-B8E7-4227C3C9F4DC} Simplified version of subtransient synchronous machine model where magnetic coupling between the direct and quadrature axes is ignored. subtransientSimplified {3A6850C7-98D5-4f40-8A3D-4A7E868646EC} Simplified version of a subtransient synchronous machine model with no damper circuit on the directaxis. subtransientSimplifiedDirectAxis {4AC186DC-E7A7-4064-A694-2B08B9AB3463} WECC type F variant of subtransient synchronous machine model. subtransientTypeF {47A8D174-4052-46b2-B7EC-60F89AF73616} WECC type J variant of subtransient synchronous machine model. subtransientTypeJ {11F5A58F-E9C4-4922-8C3A-B3548106982F} Operating as condenser. condenser {4138AC1B-4414-4b66-BFA5-953427ABCA45} Operating as generator. generator {BC2CBA19-B1E8-498a-A688-965827939158} Operating as motor. motor {C66DF514-4509-4123-B2FB-C834F58BDAE3} OASIS {1614F4FA-DC58-4748-AEFA-C6A5A3C353E1} 2009 standard edition. 2009 {866762AB-80D1-4cc5-918F-603AAC6212D7} No standard edition. none {679360AA-4175-481a-BCD8-5B12022AAFBD} Unknown standard edition. unknown {8AC947B6-D624-4f24-9DC5-608D01E70C2B} Tensile properties of paper and paperboardusing constant rate of elongation apparatus Test Method TAPPIANSI T 494 om13. T494 {39735D76-E128-4ae8-8082-ADC61EDF59A9} TR chain CHAIN {7EC5F6D5-6BF2-4264-BA1A-9CEF645F1901} Individual TR INDIVIDUAL {2BAA1F74-5482-4e66-8A97-B9E70517BC1D} Place the tag. place {1F2B4888-B888-4453-87C4-FF46E0BF28A9} Remove the tag. remove {5589EE0A-54B5-4c67-A575-76B57246B24E} Verify the tag. verify {8A8D68F1-45FB-4e1d-9F2F-400A797ACB9D} connect {A85F295B-6F75-4993-B5D6-8985A1376E75} disconnect {9339ED3C-0246-4e08-B5E6-A1336053C123} Place the jumper close or the cut open. place {7963F759-746C-4bc0-AEC7-6CF5CD8D24A7} Remove the jumper open or the cut close. remove {6D0261B3-86EF-4d7a-B612-E429DD2757B0} Payment method by means of a credit or debit card. card {EB9C23F6-71E3-4cc8-8E01-F0D70826C5BA} Payment method by means of cash. cash {B76A01E5-26C2-4dc6-A20F-5FBEDBFECE23} Payment method by means of a cheque. cheque {2F7326F2-1F28-4e7e-8675-57AD5A2C115A} Other payment method such as electronic finds transfer. other {CF959005-095D-45b5-A172-3AD3265A4E81} Payment method is not known. unspecified {790101EC-F330-454f-94CB-59761E1C67BF} equalTo {E5E79651-7C27-4bf2-A184-073C288EC394} greaterThan {6C844909-3462-44e5-8F8A-CADB305421A5} greaterThanOrEqualTo {A0449644-F621-4910-82BC-69313F63E8B9} lessThan {F7342CD5-A8DF-43d5-8C7A-45F1683641EC} lessThanOrEqualTo {C36070E8-A220-47be-9CFD-16C35FE5900B} 60567 by displacement method. 60567ByDisplacement {DF88F1D5-FCD9-44a2-BA45-9E87CAEB4658} 60567 by partition method. 60567ByPartition {80D2E977-655D-449d-A16B-5B2C2A04520D} 60567 by vacuum method. 60567ByVacuum {768C23E8-CF13-4921-9F90-D550A2DB9C15} Automatic method. 60970Automatic {57D5F352-0502-44d5-AFEE-C074AA9FB95E} Manual method 1. 60970Manual1 {A5057FB6-9915-40bb-A4E7-6A676A088A28} Manual method 2. 60970Manual2 {CEC3A5A0-4F0E-4e0c-9BA7-DBD1FECCDA50} 61125A method. 61125A {6EEF5CEA-3C50-466c-9E79-22AEC47A840F} 61125B method. 61125B {1E68C35F-2919-4068-9BA3-585C95D2A8B5} 61125C method. 61125C {24C8FDA4-8CF2-44d2-8479-47308684A0E8} 62270 Annex A method. 62270AnnexA {33BAA4B6-2E09-4c1a-9E55-39E21A7CD27F} 62535 Annex A method. 62535AnnexA {4824E07B-F510-42a3-8657-A4D89ACB324E} 62535 main method. 62535Main {22753C2E-740A-4900-AD4A-16543E706A5D} D1275A method. D1275A {1492AD6C-7FC1-419b-858D-3164BA0AE8AF} D1275B method. D1275B {EA5F9250-615F-44de-88A8-85BF52E8CB63} D3612A method. D3612A {E650E64D-3338-4982-8985-0B48A62F3F48} D3612B method. D3612B {33061CDE-F0E2-456c-82E4-675DF511209C} D3612C method. D3612C {2FDB250C-E5A4-416e-8C82-F6BD26F25898} Test after oil treatment. postOilTreatment {10758EB0-1E39-4d04-A5F9-2A537B1BB051} Test after operation fault. postOperationFault {07435789-F631-42f7-B535-DBC56CB030C3} Test after repair. postRepair {245106B8-8BB4-4d87-96DB-6B3312241910} Routine test. routine {81745C5B-8821-4382-9F02-5CF947360DA0} Testing done at temperature of 0C. 0C {E55D9D27-FFC5-4a4f-9298-A9E13DCA5476} Testing done at temperature of 100C. 100C {E71C37D6-C2DF-42e8-92C3-D418946E91FF} Measurements taken at 164 hours. 164hours {82137C06-6409-4190-B360-A106F37ECCB3} Specimen of 1 mm thickness used in testing. 1mm {38F63DD2-1DD1-4450-B29A-FDD5F3D9FB66} Testing done at temperature of 25C. 25C {CF2513D1-6E62-4c1b-8564-A7CD30AAFE9C} Specimen of 2 mm thickness used in testing. 2mm {8E5ED28F-123F-4fed-B828-1A1B8A5012DD} Testing done at temperature of 30C. 30C {65AEAB95-EEDA-46d9-B797-2ECECB73CCF2} Testing done at temperature of 40C. 40C {32F7242A-1BC1-4d15-ACA3-06D2963DBFC5} Measurements taken at 72 hours. 72hours {A6F50234-20EB-4edd-A06D-AC80A73590A3} Testing done at temperature of 30C. minus30C {0D56AD99-0AA6-4591-9204-29E419012920} Testing done at temperature of 40C. minus40C {51F39982-607D-48df-890D-C08F4D08FD5A} D {C07A0BF9-11C9-4ed6-AE95-0A19DEA01D99} M {C94268B9-71F8-49fa-9D85-4985053F3E84} Y {9F43F113-B47E-459b-B0C8-3C751EFD3843} h {A3361B00-3D72-4b97-B457-4292B65D6EA4} m {3D949A55-3AA5-4498-A2AB-AA8974BAE280} s {7457AF6C-8640-4c8a-85D2-87C11898044A} Time of use spans the entire day 24 hours. 24HR {22E0AE7A-C07A-48fc-8A22-1B64249CE481} Time of use spans only the off peak hours of the day. OFF {4D774394-42E4-4200-B3BF-CE893AA30688} Time of use spans only the on peak hours of the day. ON {9C383024-9360-4804-A45D-096111963E57} days {E320A2D6-5EBE-4a1f-900C-00C76137BDB9} hours {B2861A11-FEB4-407c-B915-234AA74C0AD6} minutes {E7DAE93F-3B21-48f0-95CD-5D9F9B4D4F8E} months {B9CFEC0E-E1B2-4e83-9848-D5B44B094FC6} seconds {0917C0D7-DD4D-4afd-8187-88ABACE6EB58} weeks {10C5D223-B544-42dd-B5E4-11736234708A} PPT {7391CC41-8C1B-4a6d-9EB7-B87B9512810B} suspension {8E4C7375-37F8-4b4e-B708-6DDB1253A96E} tension {8B89CFF7-DB29-4632-8D8D-32DEE264CAF5} Energy Trades at Aggregated Pricing Nodes APN {E0016452-D191-48bc-9533-899BD0465C96} Capacity type trade CAP {EA2686A6-AFC4-4632-905D-8EBD9D35AF45} NonSpinning Reserve Trade NRT {3CEA8060-928C-4907-A763-501F200601C5} Physical Energy Tra PHY {258939C5-EB12-492b-807B-16F435C2D04B} Regulation Down Trade RDT {888EE4F7-0921-4bd7-87C2-6CB82D7D2C4F} Regulation Up Trade RUT {75207216-0165-489e-B315-00821A960691} Spinning Reserve Trade SRT {F6E55637-66CB-49f1-A2D0-1AEBCE3C8DBD} CI {3C6AD60E-E234-49c6-A060-FF679E166E8D} CM {3363021F-709F-40e5-8FF3-B6F9ABC5CA8A} CV {B71C58A2-235F-4f87-91D5-21AE5F6B8D0B} CX {488782A2-49FA-445f-897C-35A0201FD12E} I {92C11A8D-1822-46f0-A1CE-41D33655A708} M {141B1E04-49F0-4c6b-A68C-C2BABB01ED46} MT {74A2ED7D-00E1-4fd3-8E59-9635836AE96C} O {47172D34-3A20-4233-AE11-9FD6867B6FF2} RJ {E25FB5E6-02AD-42bc-8CA7-B8849DF94AC6} U {E55E1057-5AD9-48bd-8EF2-63A77B6BD400} V {4455793E-623A-43a4-91FC-A57FAF32C090} Ancillary Services Trade. AST {617D05A1-2FC0-48a6-97A2-FE2F739B51C1} InterSC Trade. IST {0B562154-C774-473e-B2DD-ACC435874123} Unit Commitment Trade. UCT {00C840ED-00F9-40e9-A0E5-4BF9537FF36E} Payment against a specified account. accountPayment {E46E5360-A240-44c6-9506-17B5AB2C2BD7} Payment against a specified auxiliary account. auxiliaryChargePayment {56BAFDD2-5B84-4ddc-8FCF-D7683645C581} Payment against an item other than an account. diversePayment {67D0C643-F379-4c17-BD45-019906C1D72B} Issue of token that will alter the meter configuration. meterConfigurationToken {CD4C6814-8926-476e-A037-15FDED5C581C} Other kind of transaction. other {8E8D6006-5874-4a2d-AC8C-F197B63D0DBB} Payment for a service. serviceChargePayment {43AB867F-0D25-4618-9DA4-C2160EA1E91B} Payment for a tax. taxChargePayment {E90820C2-6C5F-4298-85B8-50CEC8E1FA9A} Cancellation of a previously issued token. tokenCancellation {17BBAC42-3DEA-4be8-8F76-B1B3DB949148} Exchange of a previously issued token for a new token. tokenExchange {73447643-6838-42f8-A7C0-DA1304CA3849} Issue of a free credit token where the donor is the supplier. tokenFreeIssue {7B64DDBC-C5C1-4f70-8205-848406680782} Issue of a free credit token where the donor is a 3rd party. tokenGrant {C54424FD-76CD-46d5-AECA-CD4362203D45} Payment for a credit token sale to a customer. tokenSalePayment {6612C594-2FC1-4191-AB6C-0E4AE2A7F0C4} Reversal of a previous transaction. transactionReversal {2F1128AE-DA20-495f-AF3D-DFA9ADF66DC7} Transformer between one distribution voltage level and another distribution voltage level. distribution {8090DA52-12AF-4704-8B78-1C9C27FF05BD} Transformer is generator stepup transformer. generatorStepUp {EB14DC9F-8667-4a55-AC96-FC9938358957} Transformer between bus at one transmission voltage level and a bus at another transmission voltage level. transmissionBusToBus {BBC6C67F-344C-4383-921A-6EEF35829419} Transformer between bus at transmission voltage level and bus at distribution voltage level. transmissionBusToDistribution {7C0EDE59-1CCE-40a8-B719-1CD26C6E88F9} aerial {D2C5029A-F5D2-48f0-BB2A-1727B7355C48} dryType {0B432449-9CF3-4593-A288-C5A417FC42A4} network {B22AA9A7-A6F9-4af7-AE3D-8B99DDFB98CF} onePhase {F169D0F5-5688-46ef-903E-7E00DA9E3173} overhead {14EAE77C-1B3D-4942-A790-937E3B84476B} padmountDeadFront {523B0CB7-F3B0-40ac-8E54-AEE9778ADF80} padmountFeedThrough {8C883EBA-574B-4d3d-8F99-5414BE00EF05} padmountLiveFront {93F3FBA1-BDF2-4c3d-896E-B685586D099A} padmountLoopThrough {D08D952F-48BE-4bb3-A653-C126F2522159} padmounted {ABA1CB94-11D4-4cda-A13A-48CC6EEE12A8} subway {4E88151A-3B4E-48ee-B37C-5AF70E93A2C7} threePhase {37602A9A-DE94-440d-AE2B-8F7D95D549F0} underground {A3059163-9E99-465c-A229-C763EC1CC1E3} unknown {31313C0D-A923-47e9-AD3A-B2756894C575} vault {286CCE7F-E091-4bca-A9B0-D44AE5BAABA0} vaultThreePhase {30ECF0EE-7DC8-4e63-B662-18C4897C7C84} Reactive power flow control. reactive {91A7C3F0-A2E6-4199-9B38-5EF91B1046A2} Voltage control. volt {21799345-8131-44e5-90A0-6BC1BB534ABB} core {42FE2CEF-3FD8-4acb-8119-388DCE5A4006} shell {7E11FABD-CB5B-458a-9672-19DE58380E32} Bushingcaused failure. bushingFailure {3C0B66F6-B1E4-4231-A28F-FE0889D2F1F9} Lossofoilcaused faliure. lossOfOil {07F9AAB4-837B-44bc-B5AF-0481683DDBF1} Oilrelated failure. oilRelatedFailure {7C0960AB-9A72-4a19-9ED9-D819CA491449} Oil qualityrelated failure. poorOilQuality {BBE4F5CA-38F8-4ffc-94ED-722F1523F0FB} autotransformer {FAFF03FE-3C7E-4cbc-90D5-0A1F20019505} other {AE18D8C5-355E-4cc7-A9B4-738871F729D8} powerTransformer {2CD73C03-A1CB-4d74-A4DC-0A244B976231} secondaryTransformer {7F9626DB-A1BB-4699-A3B7-FD6E7558C511} voltageRegulator {C5B3CFA5-5A87-4b57-A536-1712F28D9A38} Message transmission mode whereby messages or commands are broadcast to unspecified devices listening for such communications. anonymous {A75D62A0-7361-4c54-BA1A-7D68EC07F0FE} Message transmission mode whereby messages or commands are sent by both normal and anonymous methods. both {EE4F3450-0583-4ebe-B83F-A61D8CC609D0} Message transmission mode whereby messages or commands are sent to specific devices. normal {8B33CD7F-F151-408b-B147-B5E2C9992550} The customer is reporting a line down lineDown {32CD8B40-0684-4476-96DB-EB25EA135D0E} The customer is reporting an outage. powerOut {0D243793-6AEE-48af-A4A1-D51FFE6B9762} Trouble call received by customer service representative. call {082F4DA0-389D-4879-8BE5-F7103D5DB45A} Trouble reported by email. email {C447B6E0-5BA5-49ca-A32B-A836324D5D47} Trouble reported through interactive voice response system. ivr {37E8A66F-9052-4249-AE73-F0EDBD9C666B} Trouble reported by letter. letter {5A807F00-9C57-4678-A748-FEE2CF766BF5} Trouble reported by other means. other {53E43CD9-13AE-455f-A787-ED4B7B81A9E0} Issue 1 standard edition. Issue 1 {41908510-563A-4b57-9DF0-70D5DD632615} No standard edition. none {6513F6BD-BE4F-476e-B757-32FB3A212825} Unknown standard edition. unknown {94D658C2-8AD2-4c0b-8B07-B3BA329F5160} FACTOR {6A3BAC50-47DF-4eea-A4AB-12983425D0D8} FLAG {A0321D15-6C47-4fe1-AF34-E53C8C5CDA78} INTEGER {2AAAB5CD-C589-4762-B435-BEC5EB398623} MW {F17AA320-EF72-4b9a-AF9C-CB71DCFE1CA8} MWh {F3876877-FCF6-4b60-BD26-1E30FC168250} The value is estimated. estimated {C7AF5086-A42A-49ac-8765-7D59D8AF24D3} The value is interpolated. interpolated {404AC095-654C-4202-B423-6E2C5B9EBD73} The value has standard uncertainty consistent with National Weather Service practises given the instrument and manner of observation. standard {2F92A1B0-9D8D-44eb-A8F1-783B801E6B8D} The process of value calculation or measurement is unknown. unknown {AEEB8600-47CB-482d-8718-3D3915667785} burd {ECBA1B04-6EDD-4378-87A9-489A2CC4D3F0} enclosure {549FB75A-0B49-4ff6-8442-D4D61BCCFAF4} handhole {4E93AE2D-33DE-4d9a-8ED5-265823380E2C} manhole {C0C69252-1324-4966-8D72-7ADD56391659} pad {406ACAD2-B752-44d7-8811-96D5EAD8B930} pullbox {8EF36903-EDD0-4b3c-8B09-099AF5E71C24} subsurfaceEnclosure {D5411441-F0C0-4827-A3AE-8F3D3610864D} trench {B4F6415B-86B3-482b-8A5D-905EA1E819AC} tunnel {40653B9F-85A4-4b97-9731-914F0B76E155} vault {EDA87E74-1A2E-41c4-88DB-F4027DD6D998} Exa 1018. E {EADD578E-ADB6-4afc-989D-DCF868A74262} Giga 109. G {351B5D79-6203-48e5-9D9E-ECD7FB7CA8A6} Mega 106. M {F956FDD6-8C6E-427d-A51A-22A1D75BE1C3} Peta 1015. P {F9AB8FD6-E2CB-4696-BDCE-16836A065FD4} Tera 1012. T {F5185FB9-24E6-47c6-BB4D-259FDF678329} Yotta 1024. Y {B128FAC5-FF4E-48ae-BE52-0FF516C25214} Zetta 1021. Z {FCD1EF70-ACFA-4653-AEC4-086E460EA46C} Atto 1018. a {BBFD0505-6323-496c-95F7-818D6498EA5A} Centi 102. c {1219082C-9AED-439c-B862-8CA874195BA0} Deci 101. d {4E630955-DF5D-403d-A377-7ED5FF85978D} Deca 101. da {EF522AAA-193D-4781-BDBD-4817C84E8558} Femto 1015. f {099282D3-03AC-4193-AB3D-71ABF7D63497} Hecto 102. h {A5B3106F-3B4E-4e44-A883-09DAE8804156} Kilo 103. k {C868627C-3B72-4bc8-879D-E177E9059A22} Milli 103. m {E7A60C22-3D12-49c5-8F18-870B1A39A1AA} Micro 106. micro {FF8E9CD6-A459-47ab-A71E-E69857742CE1} Nano 109. n {EA61DA27-05DF-41c7-B459-F1194928062C} No multiplier or equivalently multiply by 1. none {C352D73C-B9DC-4e7d-B1DB-5BE6D4BAE868} Pico 1012. p {90F83546-DD55-4cf8-9E01-DD8F69D74A8D} Yocto 1024. y {9AC37B70-6AC3-46ed-B408-8C4885FE483B} Zepto 1021. z {78644DE9-99FB-4811-B5D9-B23A0DB2728D} Unit is not on regulation. 0 {F851FDDA-449A-44ee-B750-95A0DDE3AB91} Unit is on AGC and regulating. 1 {A1950399-0868-43c3-959F-002E636C73EE} Unit is suppose to be on regulation but it is not under regulation now. 2 {512DC8F9-859C-4f12-AD97-2BDC6AE2110D} Current in amperes. A {EA92BC2E-3B95-470e-A50B-8BB500136F86} Amperes squared A. A2 {D45ED57B-D0FD-4496-A516-CD82E8DCD2C0} Amperesquared hour amperesquared hour. A2h {0A2E81E6-2C43-43dd-A6CB-8915611FB6F2} Ampere squared time in square amperes As. A2s {856A3A12-D5A5-4d1c-AC5F-2C618DE8BDB7} Current ratio of amperages. Note Users may need to supply a prefix such as m to show rates such as mAA. APerA {84D9395E-1931-48aa-974A-43B3C1895E8F} Am magnetic field strength amperes per metre. APerm {27499686-8D79-40b7-9E0E-44D9212938E7} Amperehours amperehours. Ah {4E2BC900-EA78-4b89-9479-A12680EC133B} Ampere seconds As. As {3FBD0254-1CEA-4fd9-9A11-EA68D8AD96D2} Radioactivity in becquerels 1s. Bq {6A58DADF-F9D2-4be4-BA67-51992495709D} Energy British Thermal Units. Btu {2C7C1B15-F2F1-463e-926B-90C565D92696} Electric charge in coulombs As. C {EC257654-B700-4c74-A3E0-FA2B685C13D5} Exposure x rays coulombs per kilogram. CPerkg {16EEBE18-1F4A-433c-AEDB-8542AAC26A6A} Surface charge density coulombs per square metre. CPerm2 {78F3FB2B-9D65-4d98-BE54-D640D628ABB5} Electric charge density coulombs per cubic metre. CPerm3 {C372C81F-C15D-42a4-8CD7-42D8F243F69F} Electric capacitance in farads CV. F {9D72A1D6-75D9-4e00-B3B4-42D7DD0990FE} Permittivity farads per metre. FPerm {EBCAD9B1-5855-460c-BE72-4577117C7A0B} Magnetic flux density gausses 1 G 104 T. G {AD411764-B9AE-4720-B402-AE5C70F66A92} Absorbed dose in grays Jkg. Gy {60C8424D-7177-444c-BEF0-8E6AC1D1077B} Absorbed dose rate grays per second. GyPers {6C97FDC2-E63A-40ee-AF9E-361A9E4ADC3D} Electric inductance in henrys WbA. H {AE11FF61-9894-434b-AF7E-E30B3D6A4124} Permeability henrys per metre. HPerm {6CF0793D-A3E0-4f8f-863F-9C1032665065} Frequency in hertz 1s. Hz {8E14F483-DBE2-46c3-9308-1DF800CD2FF2} Frequency rate of frequency change. Note Users may need to supply a prefix such as m to show rates such as mHzHz. HzPerHz {12B11EAF-4BB5-4d5c-A2BB-D78A02327104} Rate of change of frequency in hertz per second. HzPers {98C8F3E1-139E-482e-8C78-EF21E8A15A38} Energy in joules Nm CV Ws. J {97A3FB98-8A5D-4b95-8473-5D3EDE289822} Heat capacity in jouleskelvin. JPerK {0A532BE2-CF36-4726-A14D-1EC97FD37B6D} Specific energy Joules kg. JPerkg {05214191-21C9-4b98-A8E5-CD63EAD7FB35} Specific heat capacity specific entropy joules per kilogram Kelvin. JPerkgK {5C1D5E18-724F-4348-A871-610428006C41} Insulation energy density joules per square metre or watt second per square metre. JPerm2 {1484901D-B114-4df8-8FBD-892ED2DDC36D} Energy density joules per cubic metre. JPerm3 {643ABAE5-C491-445d-B0DA-FDD3381A7871} Molar energy joules per mole. JPermol {082C9B4F-A2B0-48b3-A976-4551C7B0B9D5} Molar entropy molar heat capacity joules per mole kelvin. JPermolK {C86FC880-4592-4126-ACD6-C0CFE6151C19} Energy rate in joules per second Js. JPers {8D0EFD06-CE71-454a-AF72-A37FF1988C0E} Temperature in kelvins. K {1E8C279F-B121-451f-B8D7-7B9F1EF080DF} Temperature change rate in kelvins per second. KPers {4AA28097-6E2C-4e6f-A7DE-F0813968DFAE} Length nautical miles 1 M 1852 m. M {95D59B4E-F7D2-4202-AEE3-BBE1602128E2} Magnetic flux maxwells 1 Mx 108 Wb. Mx {9D86ACE7-4F18-419a-B862-85D2D7165A51} Force in newtons kgms. N {68AA121A-1847-446b-A6B2-F7180AC83772} Surface tension newton per metre. NPerm {05284484-23B5-4903-9FD7-2E7CF0E166B5} Moment of force newton metres. Nm {62F46160-46EA-47c2-9E8D-DC44F5BCFEA7} Magnetic field in oersteds 1 Oe 1034p Am. Oe {79B7C736-028D-4eab-9A0D-DEE3E6A963F8} Pressure in pascals Nm. Note the absolute or relative measurement of pressure is implied with this entry. See below for more explicit forms. Pa {BD782A7D-D539-4f4f-BAAF-44DFDC18CE40} Pressure change rate in pascals per second. PaPers {468B93E2-D504-4668-B698-6C438CC555FF} Dynamic viscosity pascal seconds. Pas {2B45021A-F7A2-4f33-B105-918CA01B627D} Quantity power Q. Q {67586835-9551-42fb-ABF8-3F4CFA5032F2} Quantity energy Qh. Qh {8908E051-4BDB-42f6-A2FB-126358F6952F} Conductance in siemens. S {C593555B-266C-4ac6-8F80-E91F045DFA89} Conductance per length Fm. SPerm {A1442E6B-3261-4ae2-B466-2788281713C6} Dose equivalent in sieverts Jkg. Sv {C408842C-136F-455f-B998-6A661EEA20AF} Magnetic flux density in teslas Wbm2. T {12E9D418-34B0-4978-8012-CEBBB3154B37} Electric potential in volts WA. V {0A273035-181C-482c-9526-6673DE4AF59F} Volt squared WA. V2 {BADD342F-47DF-44a9-A9A2-C2923A48DBAB} Voltsquared hour voltsquaredhours. V2h {AC926E85-C4E0-4512-84B1-8DFEC4D0C8E5} Apparent power in volt amperes. See also real power and reactive power. VA {D3EB929D-C57F-40a8-86DC-2F5CAACB6A71} Apparent energy in volt ampere hours. VAh {B65C6290-E53E-4bee-B674-A2E166EB4D77} Reactive power in volt amperes reactive. The reactive or imaginary component of electrical power VIsinphi. See also real power and apparent power.Note Different meter designs use different methods to arrive at their results. Some meters may compute reactive power as an arithmetic value while others compute the value vectorially. The data consumer should determine the method in use and the suitability of the measurement for the intended purpose. VAr {F38DF57D-7E97-4af9-984E-40820470C5EC} Reactive energy in volt ampere reactive hours. VArh {DD5193A4-8564-4426-8FA1-98F3A50327FA} Magnetic flux in volt per hertz. VPerHz {18DE9C0C-CE23-4b20-8779-CEEB07E6BD9E} Voltage ratio of voltages. Note Users may need to supply a prefix such as m to show rates such as mVV. VPerV {E32A4356-EE83-4a56-A630-882387CC00C8} Power factor PF the ratio of the active power to the apparent power. Note The sign convention used for power factor will differ between IEC meters and EEI ANSI meters. It is assumed that the data consumers understand the type of meter being used and agree on the sign convention in use at any given utility. VPerVA {F5914562-B809-455b-98A8-CECAA59EE125} Power factor PF the ratio of the active power to the apparent power. Note The sign convention used for power factor will differ between IEC meters and EEI ANSI meters. It is assumed that the data consumers understand the type of meter being used and agree on the sign convention in use at any given utility. VPerVAr {F205CACD-712B-46f0-B7D7-170EEF3B59A3} Electric field strength volts per metre. VPerm {72E72CF2-2E55-4c96-B72F-D2D0C602ED65} Volthour Volt hours. Vh {133A1DDB-6E5C-4edc-8788-0FEADD99F7AF} Volt seconds WsA. Vs {4ADBB794-4439-4590-B83E-30CC81BB588F} Real power in watts Js. Electrical power may have real and reactive components. The real portion of electrical power I178R or VIcosphi is expressed in Watts. See also apparent power and reactive power. W {41B0F1BC-E69B-4ca1-A565-ECBC27B49095} Active power per current flow watts per Ampere. WPerA {BD554F27-BD42-42e8-A102-327C8B95F611} Signal Strength ratio of power. Note Users may need to supply a prefix such as m to show rates such as mWW. WPerW {07C055AF-FF95-4a33-AFA4-CC2E9E87038C} Heat flux density irradiance watts per square metre. WPerm2 {74F16DEB-1187-4180-82E7-C9730606F991} Radiance watts per square metre steradian. WPerm2sr {09253D8A-34A7-49be-88AF-87147A5EAB64} Thermal conductivity in wattmetres kelvin. WPermK {6A7D3263-4D03-4d39-B90C-38C100BD95FF} Ramp rate in watts per second. WPers {35FB6E73-2730-4ae7-A67E-58DC67D68D70} Radiant intensity watts per steradian. WPersr {9A57C4F9-ECB2-4273-8741-9A36085DA221} Magnetic flux in webers Vs. Wb {6F7B9EE5-AFA0-4cbc-B2A9-E3942BD3772F} Real energy in watt hours. Wh {D0065D4C-31BE-42b1-9588-806157D3000D} Plane angle minutes. anglemin {79557E1F-CC74-431a-8A0D-6BD70094B0B2} Plane angle seconds. anglesec {9C734EB4-BFFF-482e-95B2-B7446E3D8FFB} Pressure in bars 1 bar 100 kPa. bar {9516CB35-2CC3-4b7a-8BBA-BB329514810B} Luminous intensity in candelas. cd {E12E81A8-81B6-4286-B477-2A91F984C4FC} Data rate baud in characters per second. charPers {28E0BFBE-2F7A-43d1-BB99-DCCBF7ADC265} Number of characters. character {8187AD67-24E6-4cc1-931D-FC0964171586} Power factor dimensionless.Note 1 This definition of power factor only holds for balanced systems. See the alternative definition under code 153.Note 2 Beware of differing sign conventions in use between the IEC and EEI. It is assumed that the data consumer understands the type of meter in use and the sign convention in use by the utility. cosPhi {3FF3E24E-53F5-45ae-8408-47C453D360C2} Amount of substance Counter value. count {45989859-38C4-4d11-A5CF-7DD5EFB0E7F7} Time in days day 24 h 86400 s. d {5A45829C-D0A2-45cc-A862-689B13D34708} Sound pressure level in decibels. Note multiplier d is included in this unit symbol for compatibility with IEC 6185073. dB {5FEFCFB2-EFE9-4969-8832-5AB856D1D9BC} Power level logarithmic ratio of signal strength BelmW normalized to 1mW. Note multiplier d is included in this unit symbol for compatibility with IEC 6185073. dBm {D3D3EFF1-D398-4bbf-B71E-947636027C51} Plane angle in degrees. deg {4FEE2708-57BD-4ab8-BF2C-504B62A5358F} Relative temperature in degrees Celsius.In the SI unit system the symbol is C. Electric charge is measured in coulomb that has the unit symbol C. To distinguish degree Celsius from coulomb the symbol used in the UML is degC. The reason for not using C is that the special character is difficult to manage in software. degC {9266DB6A-744E-4939-896F-B84E928D14EE} Volume cubic feet. ft3 {CF1F601E-EF72-4b25-A464-82800437A9B1} Concentration The ratio of the mass of a solute divided by the mass of the solution. Note Users may need use a prefix such a to express a quantity such as gg. gPerg {E7AD0FC3-F546-4d24-AB93-27B09C22F271} Volume in gallons US gallon 1 gal 231 in3 128 fl ounce. gal {A1611ECE-DA95-4e1c-A2AD-AF799F5994BB} Time in hours hour 60 min 3600 s. h {38CFF289-C542-4313-987C-62BAAB914148} Area hectares. ha {A0047B54-799B-4a83-BC4B-B34DE2214F66} Catalytic activity katal mol s. kat {92141CD6-2C4A-4ecb-A300-08FC15945FFF} Catalytic activity concentration katals per cubic metre. katPerm3 {2AA4DD24-932C-4726-9E04-2A190E13D25D} Mass in kilograms. Note multiplier k is included in this unit symbol for compatibility with IEC 6185073. kg {E8CD3F4B-2301-4f19-BBDF-6D20CD945743} Weight per energy in kilograms per joule kgJ. Note multiplier k is included in this unit symbol for compatibility with IEC 6185073. kgPerJ {9740266F-DE31-4a0a-B60E-5B341A44FDB3} Density in kilogramcubic metres kgm. Note multiplier k is included in this unit symbol for compatibility with IEC 6185073. kgPerm3 {BDA99721-EF6C-465b-A531-083BB5A339E7} Moment of mass in kilogram metres kgm first moment of mass. Note multiplier k is included in this unit symbol for compatibility with IEC 6185073. kgm {7EF2DD04-E97D-43d0-8EF5-A0C71B65B30F} Moment of mass in kilogram square metres kgm Second moment of mass commonly called the moment of inertia. Note multiplier k is included in this unit symbol for compatibility with IEC 6185073. kgm2 {D18A5CA3-5F86-4f15-AF52-313ED1C0FCA9} Speed knots 1 kn 18523600 ms. kn {76B3AB3B-A772-48a3-87A9-CC2655C20055} Volume in litres litre dm3 m31000. l {3D491A25-7CCF-4251-9579-D569948EE574} Volumetric flow rate litres per hour. lPerh {2611249E-07C4-481b-96AF-3912056F7A39} Concentration The ratio of the volume of a solute divided by the volume of the solution. Note Users may need use a prefix such a to express a quantity such as LL. lPerl {3C51034A-1DF4-4f24-9021-DEFB86D27C69} Volumetric flow rate in litres per second. lPers {FEA615F0-27A6-43e5-AB75-C6C2954D09CC} Luminous flux in lumens cdsr. lm {593D68AB-754E-46e4-8BB0-56BE19944355} Illuminance in lux lmm. lx {234076FB-B88A-4249-9CFF-8F30847685B6} Length in metres. m {5D4DDF01-7840-42a2-9106-C5CA5D41D1F2} Area in square metres m. m2 {A675331A-7D99-4e64-910D-A537BB8CEAAA} Viscosity in square metres second ms. m2Pers {4C077318-15E4-40e9-81AF-94A22098B3AA} Volume in cubic metres m. m3 {ACC84E95-39F4-4acf-A99C-F0F50B37A605} Volume cubic metres with the value compensated for weather effects. m3Compensated {232385E4-F5BB-4699-A93F-10C49C822329} Volumetric flow rate cubic metres per hour. m3Perh {D3CF2309-7272-4d0c-9977-D83D3FDA4054} Specific volume cubic metres per kilogram v. m3Perkg {0E1D3CF6-01AC-4cd4-BBCE-19D25E34BE91} Volumetric flow rate in cubic metres per second ms. m3Pers {49157E6B-5DF9-4c4a-91DF-A99100A9959A} Volume cubic metres with the value uncompensated for weather effects. m3Uncompensated {EAA81876-9511-48ce-9CC1-8E744D558E43} Fuel efficiency in metres per cubic metres mm. mPerm3 {B76349C8-69F4-433e-A6F4-9A709F4BAEE3} Velocity in metres per second ms. mPers {AA6472CE-DFB5-446a-A9E7-52A5CE50CEF8} Acceleration in metres per second squared ms. mPers2 {57C47608-7060-4960-B368-B53B6FDE195C} Time in minutes minute 60 s. min {5E4420E6-9C1E-4e9c-ABE3-CDDD28FEF17F} Pressure millimetres of mercury 1 mmHg is approximately 133.3 Pa. mmHg {A3459B23-0BDB-4e8f-822B-1D0EDD223D18} Amount of substance in moles. mol {AE67CF4C-C8D9-446d-AF20-8BFC19C17C18} Concentration Molality the amount of solute in moles and the amount of solvent in kilograms. molPerkg {6D617CFF-CBD4-4c43-B8DF-7356CB496160} Concentration The amount of substance concentration c the amount of solvent in moles divided by the volume of solution in m. molPerm3 {6E337AE9-1E58-41d7-A865-080C8E7E029B} Concentration Molar fraction the ratio of the molar amount of a solute divided by the molar amount of the solution. molPermol {9723639D-4BA1-4756-952E-605DBFAF2057} Dimension less quantity e.g. count per unit etc. none {F14E9D40-A805-4840-B04C-34CD7BD279CC} Electric resistance in ohms VA. ohm {1DD847A9-4242-4c5d-98D6-8BF40A3F14C2} Electric resistance per length in ohms per metre VAm. ohmPerm {2BDD18E5-7E62-4f66-AF25-21B7AB95AA3A} Resistivity ohm metres rho. ohmm {D0950984-9A0E-482a-9DE1-16F420DAE9CC} Reciprocal of frequency 1Hz. onePerHz {46A68760-C92B-49b5-9BED-F01BFEDAD997} Wavenumber reciprocal metres 1m. onePerm {B8367965-284B-4e08-8567-055B00DAEDBA} Concentration in parts per million. ppm {EAC82D26-6F54-4556-90EE-430E28882551} Plane angle in radians mm. rad {90D4CFED-C041-47b2-9BD3-B4F34BA5FD95} Angular velocity in radians per second rads. radPers {D02F038B-E180-44e1-94C9-0EF927B2FF01} Angular acceleration radians per second squared. radPers2 {2C2CD44E-2697-496e-8976-75216FBF43F4} Amount of rotation revolutions. rev {67CE50F0-C29B-444d-AC79-8A344CFCD3D8} Rotations per second 1s. See also Hz 1s. rotPers {B1F4EE35-083B-4d1f-A153-F7C65D67770D} Time in seconds. s {D53EB49C-18D1-430f-BBB5-C7ED93CCFC2B} Time Ratio of time. Note Users may need to supply a prefix such as 181 to show rates such as 181ss. sPers {6536A446-4A67-45c0-A68E-517D8F75A6CF} Solid angle in steradians m2m2. sr {EDB8BF68-BB72-4cac-9576-DCC78C57DBB1} Energy therms. therm {D9814FF0-29BF-4ccd-8F0F-0203764EDD8E} Mass in tons tonne or metric ton 1000 kg 1 Mg. tonne {13E05807-8D00-40c0-8826-9D508FD4E0DE} Combined Cycle CCYC {1BCD98DE-D22A-49d0-A306-3293748AEE95} Gas Turbine GTUR {28A92343-D74A-4f77-BF1E-7366E5B6977D} Hydro Turbine HYDR {0EB0C43C-209C-4a8b-A2C0-38B00569598A} Other OTHR {7A3CA9A5-C61E-42c2-85F8-2929ABEF8BE7} Photovoltaic PHOT {2ED6BB53-16D4-4196-8422-FDA15CA8AB1D} Hydro PumpTurbine PTUR {7B7D6AF2-5A24-4092-803F-858CBA938DEE} Reciprocating Engine RECP {E735EFEF-208E-4896-8C82-BEB39E9CE84A} Steam Turbine STUR {B487EB67-3DAB-4502-8153-3B5A4BDBE9D9} Synchronous Condenser SYNC {2FC904CD-0592-47d3-9692-B5E20681C895} Wind Turbine WIND {73C0CADB-5893-4383-966A-B9AACA595028} FLAG {AF663099-83AE-46a1-A806-E7FC1555CDFB} MW {59027ED3-980B-41c7-B8F4-53E60E84BF5B} The usage point is connected to the network and able to receive or send the applicable commodity electricity gas water etc.. connected {17FA1E04-B8F5-4e75-A5AE-A4B9961AB9C2} The usage point has been disconnected through operation of a disconnect function within the meter present at the usage point. The usage point is unable to receive or send the applicable commodity electricity gas water etc. A logical disconnect can often be achieved without utilising a field crew. logicallyDisconnected {3B889020-3D2B-4c5b-8293-487E1DB4F11C} The usage point has been disconnected from the network at a point upstream of the meter. The usage point is unable to receive or send the applicable commodity electricity gas water etc.. A physical disconnect is often achieved by utilising a field crew. physicallyDisconnected {FAF8C3E7-6CCD-4d51-B83D-E70FC1AB16F7} The value is marked good if no abnormal condition of the acquisition function or the information source is detected. GOOD {6929D040-2986-40d3-81FA-B02D410FDB69} The value is marked invalid when a supervision function recognises abnormal conditions of the acquisition function or the information source missing or nonoperating updating devices. The value is not defined under this condition. The mark invalid is used to indicate to the client that the value may be incorrect and shall not be used. INVALID {44F0D4CA-67C3-42a2-9AD6-B4C7F032EE3A} The value is marked questionable if a supervision function detects an abnormal behaviour however the value could still be valid. The client is responsible for determining whether or not values marked questionable should be used. QUESTIONABLE {ED216555-F577-4c42-9E86-FF8AFBA02D0A} Contractor vehicle. contractor {D97F5E8C-A431-495a-967C-0735426EE4F7} Crew vehicle. crew {8C670F08-5610-46a5-85C1-1AA8F5CB0F08} Other vehicle. other {49A2B67C-734A-488e-96F1-FA84D1B5BA6B} User vehicle. user {D83E1081-541C-44d5-B87D-02107C9FBC12} Control is real power at point of common coupling. The target value is provided by ACDCConverter.targetPpcc. pPcc {1B0F9D15-341D-482a-92CA-2F87FD68CFD2} Control is active power at point of common coupling and local DC voltage with the droop. Target values are provided by ACDCConverter.targetPpcc ACDCConverter.targetUdc and VsConverter.droop. pPccAndUdcDroop {1FAEF8C2-B58F-4a82-B07C-AF01ED672BB4} Control is active power at point of common coupling and the pilot DC voltage with the droop. The mode is used for Multi Terminal High Voltage DC MTDC systems where multiple HVDC Substations are connected to the HVDC transmission lines. The pilot voltage is then used to coordinate the control the DC voltage across the HVDC substations. Targets are provided by ACDCConverter.targetPpcc ACDCConverter.targetUdc and VsConverter.droop. pPccAndUdcDroopPilot {026AFB0C-5BA9-42fd-AC2D-C825D86EFA8E} Control is active power at point of common coupling and compensated DC voltage with the droop. Compensation factor is the resistance as an approximation of the DC voltage of a common real or virtual node in the DC network. Targets are provided by ACDCConverter.targetPpcc ACDCConverter.targetUdc VsConverter.droop and VsConverter.droopCompensation. pPccAndUdcDroopWithCompensation {5433041C-16FD-4f7e-BF43-1289EA1FC438} Control is phase at point of common coupling. Target is provided by VsConverter.targetPhasePcc. phasePcc {EC265815-0658-4950-BF62-F505124EFCFD} Control is DC voltage with target value provided by ACDCConverter.targetUdc. udc {DA24FCF6-C1CE-42c3-8138-A3788B84DA92} Control is power factor at point of common coupling. Target is provided by VsConverter.targetPowerFactorPcc. powerFactorPcc {845E8692-0146-4b18-BBD0-8E17B26F5D9C} No explicit control. Pulsemodulation factor is directly set in magnitude VsConverter.targetPWMfactor and phase VsConverter.targetPhasePcc. pulseWidthModulation {9B3E5597-1865-4cac-9211-2C407D533F36} Control is reactive power at point of common coupling. Target is provided by VsConverter.targetQpcc. reactivePcc {5E2A3C32-97E0-4c8e-AD27-9EA00490046B} Control is voltage at point of common coupling. Target is provided by VsConverter.targetUpcc. voltagePcc {14625573-690D-425b-AA5B-9510C347DDD9} No edition. none {E8ABE143-FBD6-4a9c-BB51-3945E126A644} Unknown edition. unknown {E87A1C28-FA6D-4850-92F3-1EDADC89E986} BD weather code Blowing Dust. blowingDust {E0F531C0-5044-42a8-BC6B-2DDF802FDF43} BN weather code Blowing Sand. blowingSand {2DC4BDEB-1736-460b-8B42-E58F401E9C73} BS weather code Blowing Snow. blowingSnow {7A468B9B-B623-4ff2-800F-5CDA34C0D9C9} cloudy {EFD8ED93-8155-4714-86B4-E48E0AD52096} L weather code Drizzle. drizzle {F0151170-3B33-4e03-A328-A6418F7D42F9} F weather code Fog fog {45476FA6-93BC-4a48-A00F-D3BD5CFBCD7A} ZL weather code Freezing Drizzle. freezingDrizzle {44A69511-3719-4fe1-A52B-A99845EB3820} ZR weather code Freezing Rain. freezingRain {E01BBF5B-9957-40cf-B7F8-DC9405236771} ZF weather code Freezing Spray. freezingSpray {6ED0709C-E261-4848-A8AB-CC5F6ACFE9AA} FR weather code Frost. frost {2AA1FC87-E332-4e2b-A809-483FDB580470} A weather code Hail. hail {742B73D2-767D-4ead-8C13-741A65BEF5F4} H weather code Haze. haze {07E7D561-3CC8-462a-B6E4-FC88A6BFCAB3} IC weather code Ice Crystals. iceCrystals {CE5A7979-58F6-4dd8-857B-04F5730AA689} IF weather code Ice Fog. iceFog {4DEC155B-1E90-4763-8801-D49430C0AA48} BR weather code Mist mist {2D039197-0D46-4690-87B9-576677817FE5} R weather code Rain. rain {A8CA7E19-1018-49b3-85AA-22CE71A710C4} RW weather code Rain Showers. rainShowers {F17519D7-E93E-4905-8C37-7E52A34B916F} RS weather code RainSnow Mix. rainSnowMix {D2DF3E7B-73CB-44e7-939F-3AF047AFAA07} IP weather code Ice PelletsSleet. sleet {28F215C8-D2BC-4517-81E3-9217CB8B34DE} K weather code Smoke. smoke {2716FE7C-54E7-4eb5-8BA4-40EBBCD6BBF3} S weather code Snow. snow {B65013C4-F0CC-417c-AA75-7FB0D67DE414} SW weather code Snow Showers. snowShowers {AD6D8ECF-CDB2-405c-81D9-5539DC162EA0} SI weather code SnowSleet Mix. snowSleetMix {CEA3B9B9-BDAE-4703-B2E5-CD0FD5F591E9} sunny {048C1A03-785A-4a6c-A21A-830537499F49} T weather code Thunder Storms. thunderStorms {0C130E5A-6648-4302-A4FD-C6C263B47F59} VA weather code Volcanic Ash. volcanicAsh {4729552E-6CC0-4021-AAC6-D6080DB92D9E} WP weather code Water Spouts waterSpouts {F4BE6152-6379-4f1f-9ECF-EBB25B3C7852} WS weather code Wintry Mix. wintryMix {046461B0-656F-4468-843C-3DDFC9765B6A} The wind generating unit is located offshore. offshore {CAA438A7-EAA7-4595-809E-A1F07F043FFD} The wind generating unit is located onshore. onshore {BDE56A86-D849-42ab-8F4B-97BD16312617} Lookup table for voltage dependency of active current limits isubpmaxsubusubWTsub. It is used for the current limitation model IEC 614002712015 5.6.5.8. ipmax {1B14E732-2D2F-42b6-A00A-432346B25E31} Lookup table for voltage dependency of reactive current limits isubqmaxsubusubWTsub. It is used for the current limitation model IEC 614002712015 5.6.5.8. iqmax {36FEFE58-B86F-4eb1-8FD8-E43156818740} Power vs. speed lookup table omegap. It is used for the P control model type 3 IEC 614002712015 5.6.5.4. omegap {66683139-71CE-4174-B0E2-CD8ACC10862A} Power versus speed change negative slip lookup table psubrrsubdeltaomega. It is used for the rotor resistance control model IEC 614002712015 5.6.5.3. prr {B748FE52-33B7-4d36-9921-3A03A7B89E1A} Power vs. frequency lookup table psubWPbiassubf. It is used for the wind power plant frequency and active power control model IEC 614002712015 Annex D. pwp {9D027ECB-7A49-433a-9DE5-09918986DA1C} Lookup table for active power dependency of reactive power maximum limit qsubmaxpsubp. It is used for the QP and QU limitation model IEC 614002712015 5.6.5.10. qmaxp {E6370B95-DC95-494c-B457-8D67EAB70295} Lookup table for voltage dependency of reactive power maximum limit qsubmaxusubp. It is used for the QP and QU limitation model IEC 614002712015 5.6.5.10. qmaxu {690E4283-8B00-40f5-86EB-E4E18E6C497B} Lookup table for active power dependency of reactive power minimum limit qsubminpsubp. It is used for the QP and QU limitation model IEC 614002712015 5.6.5.10. qminp {23F94943-3723-4277-943C-3D57681DDD5F} Lookup table for voltage dependency of reactive power minimum limit qsubminusubp. It is used for the QP and QU limitation model IEC 614002712015 5.6.5.10. qminu {36C3CF45-F5C9-4914-9D6D-766DF38E805F} Look up table for the UQ static mode qsubWPsubusuberrsub. It is used for the voltage and reactive power control model IEC 614002712015 Annex D. qwp {D2A36A3B-2056-41d1-897D-6B8F821716FE} Crowbar duration versus voltage variation lookup table TsubCWsubdu. It is a casedependent parameter. It is used for the type 3B generator set model IEC 614002712015 5.6.3.3. tcwdu {282BB811-4873-4a71-91B7-7934CD548ABE} Lookup table to determine the duration of the power reduction after a voltage dip depending on the size of the voltage dip TsubdsubusubWTsub. It is a typedependent parameter. It is used for the pitch control power model IEC 614002712015 5.6.5.1. tduwt {176DA674-D6E3-4806-B463-BFD90B8DABDF} Disconnection time versus overfrequency lookup table TsubfoversubfsubWTsub. It is used for the grid protection model IEC 614002712015 5.6.6. tfover {9A943F84-5C84-47e0-B4DF-9D984C2231D6} Disconnection time versus underfrequency lookup table TsubfundersubfsubWTsub. It is used for the grid protection model IEC 614002712015 5.6.6. tfunder {5C8F9AB5-4885-4232-9719-E9A3DB66F802} Disconnection time versus overvoltage lookup table TsubuoversubusubWTsub. It is used for the grid protection model IEC 614002712015 5.6.6. tuover {1747CDAB-23E9-46c5-838D-70F6BF628D61} Disconnection time versus undervoltage lookup table TsubuundersubusubWTsub. It is used for the grid protection model IEC 614002712015 5.6.6. tuunder {8B0C6E5C-9164-4cc6-9E24-1BCA284CEF9A} Power factor reference. powerFactor {59D81CFD-D491-4d68-9E89-62DCB57FFFFF} Reactive power reference. reactivePower {8748EB26-424E-4d1d-9276-F92E7AAC8286} UQ static. uqStatic {F4C3853A-1AED-4286-8CE6-4E6C4375B803} Voltage control. voltageControl {2E7704D8-5D74-4eb1-8EF2-3F7F213800DF} Open loop reactive power control only used with closed loop at plant level iMiisubqGsubisub subequals 2. openLoopReactivePower {6494681E-5E28-467b-85C6-46C752181AFF} Open loop power factor control iMiisubqGsubisub subequals 4. openLooppowerFactor {D4C1AF17-29B7-4ce7-8D62-9D6BF4D945A4} Power factor control iMiisubqGsubisub subequals 3. powerFactor {25ED6E82-C16F-4cac-B91D-E54B0D0AE271} Reactive power control iMiisubqGsubi equals 1. reactivePower {B57EAEC9-8F65-495e-8807-23746951BB08} Voltage control iMiisubqGsubi equals 0. voltage {3FD39FB0-3F40-42a6-899D-5A8120A15EFD} Voltagedependent reactive current injection iMiisubqUVRTsubi sub subequals 0. mode0 {EE1CFEEC-B6FE-4121-914F-2048E4E2B1C9} Reactive current injection controlled as the prefault value plus an additional voltage dependent reactive current injection iMiisubqUVRTsubi equals 1. mode1 {6AEDB696-9494-4d56-AF04-5683FA0929F1} Reactive current injection controlled as the prefault value plus an additional voltagedependent reactive current injection during fault and as the prefault value plus an additional constant reactive current injection post fault iMiisubqUVRTsubisub subequals 2. mode2 {9F30B7A5-E21A-4739-91FA-A9A94E53EFD3} Autotransformer common winding. A {473A99ED-036B-405f-A0A4-EBED23928C49} Delta. D {B17A24C7-3B0F-4024-AC56-16CA61D533E6} Independent winding for singlephase connections. I {FF8C5784-060C-4954-B55D-43105F992714} Wye. Y {CEEF48C7-F053-4f14-92EA-5D90C5DC84CA} Wye with neutral brought out for grounding. Yn {BBAF2E36-E868-4c4f-BFB9-00666ED78C08} ZigZag. Z {E5F532C8-F2D1-43c4-92D4-4E9EE6DA107D} ZigZag with neutral brought out for grounding. Zn {FFDB7590-ADFD-4c08-9BFC-84349F427C0A} nomex {509B53BA-6E56-4101-A477-FA94D70E5103} other {7187EF04-71F4-4748-91E6-E515722C4D4B} paper {1CD6E7B1-7CCA-43f0-A857-1F18F72D6B84} thermallyUpgradedPaper {8EF25822-D7C1-48c8-A97B-5E033ACFC16C} Asbestos and varnished cambric wire insulation. asbestosAndVarnishedCambric {30E375BA-C4B3-4505-968E-B8BA20914E5E} Belted pilc wire insulation. beltedPilc {62F9A2B8-02B3-4b5a-9AA6-B99CEC1EB596} Butyl wire insulation. butyl {A5F33528-CC25-4812-9088-E60D3BFA49AF} Crosslinked polyethylene wire insulation. crosslinkedPolyethylene {E912D943-F76D-46a4-B7FF-BF3871515F13} Ethylene propylene rubber wire insulation. ethylenePropyleneRubber {4A0619A9-20BD-4ad4-BB89-E88F7E74C948} High nolecular weight polyethylene wire insulation. highMolecularWeightPolyethylene {0030F678-8470-4671-9E25-968B0DE137CF} High pressure fluid filled wire insulation. highPressureFluidFilled {D5DDABAF-1CA9-454f-A87C-F361B7E6A72D} Low capacitance rubber wire insulation. lowCapacitanceRubber {5E43F710-8E6F-4fd0-AF8E-472D3E02EB4A} Oil paper wire insulation. oilPaper {74E898D3-1C82-4efd-9AD9-9405B755DC60} Other kind of wire insulation. other {7B2FF0B3-BBC2-4bfd-B2BA-96566F74904E} Ozone resistant rubber wire insulation. ozoneResistantRubber {A345779F-3C98-4c51-AED3-A9FF9B9C9A55} Rubber wire insulation. rubber {A9074515-1B3D-4b1e-99CA-5A869A2D844D} Silicon rubber wire insulation. siliconRubber {D0FAEC04-3EEF-4020-AA92-FD1C7735718D} Tree resistant high molecular weight polyethylene wire insulation. treeResistantHighMolecularWeightPolyethylene {D79DA710-F1DE-403e-9677-E4E201D8D310} Tree retardant crosslinked polyethylene wire insulation. treeRetardantCrosslinkedPolyethylene {B1222D86-1336-4d6d-A202-D418B9EF825C} Unbelted pilc wire insulation. unbeltedPilc {8FC1D561-1C31-408d-A2C9-7DF76D85010B} Varnished cambric cloth wire insulation. varnishedCambricCloth {B0089617-3C80-4a82-8986-4EF1D2D92106} Varnished dacron glass wire insulation. varnishedDacronGlass {6DD767E3-93CA-46df-9E4C-2073C8E8574B} Aluminumalloy conductor steel reinforced. aaac {39B47590-4B8E-4006-933C-BB396BA23217} Aluminum conductor steel reinforced. acsr {95FD7B5D-209E-4eec-ACF6-E5387757BD08} Aluminum wire. aluminum {433A8D99-E844-4f17-B01B-966253FB305B} Aluminumalloy wire. aluminumAlloy {2DF0A3CB-A604-4590-937D-226D68C40908} Aluminumalloysteel wire. aluminumAlloySteel {815E84F9-FF5C-4af3-9991-24FE3D56F69B} Aluminumsteel wire. aluminumSteel {3D69894B-4569-4d20-87C9-1FC3311C6A63} Copper wire. copper {5A0B6132-86F0-4609-B74F-6F758C8D48EF} Other wire material. other {8399FECD-92B0-4ba6-B8B4-A9E6BFEE034D} Steel wire. steel {EE3F58B1-30B5-4cdd-922B-787F07F820D8} Wire is used in medium voltage network. distribution {1D3D45DD-FA7F-4b23-A21B-1D58DFD712C5} Other kind of wire usage. other {2839FD65-EDFD-4f48-BA7B-BC43D0E31CA7} Wire is used in low voltage circuit. secondary {0A9700A4-0FA1-46c8-A160-215D1948D37B} Wire is used in extrahigh voltage or high voltage network. transmission {251491DC-9AA3-40ff-B7BF-EBDDB07F0FF6} Leave it in place but not use it. abandon {7FA3F3CC-3E4E-420b-9615-2DFD8BB74777} Install. install {40169EBA-0A02-44f3-92F7-F8259E78710A} Remove. remove {9324515E-CCC0-43f4-9EC3-34E7485652B5} Remove from one and install at another loctation. transfer {0897113E-B76D-431d-9267-9D696261C8EF} Connect work. connect {3FA4216F-8D0F-4431-BC82-527FC8EAA23F} Construction work. construction {8D54A546-D558-4f4a-9956-9E08914DCE06} Disconnect work. disconnect {393EAA45-F074-4d5a-9B7E-11F96BD3D2E5} Inspection work. inspection {B46F330B-57F7-437a-BEC7-A351FED8156C} Maintenance work. maintenance {FD3759D2-C1A2-4257-9F40-6E140ABD77C6} Other kind of work. other {B9E44DCD-DBE4-4dfe-890E-D0075166BF20} deprecated use connect instead Reconnect work. reconnect {84DE3CB2-18EA-4c2f-822E-220F1E646221} Work related to asset refurbishment. refurbishment {8FE308D7-B3FC-4595-BB6B-5A7A82026FB5} Repair work. repair {999D4469-232D-43e9-A6FC-73964D88CE63} Service work. service {43BD79B9-6970-4e52-BDFF-2100D6C7CAAD} Test work. test {AB40C564-85E2-4e48-AEA5-3293DF4E6556} Work has been approved. approved {5057A818-AA07-42cc-B8D9-5161B3184BA2} Work has been canceled. cancelled {339A9CC2-A20C-4f36-A400-DC0A4DA4DC7D} Work has been closed typically by a person responsible for work management and is ready for billing. closed {94C97DAF-02F0-4272-9CD6-05474493D9F3} Work has been completed i.e. crew can leave the work location and is available for another work. completed {0EC9B67B-F060-4a1b-B467-B49B39A923EE} Crew has been dispatched. dispatched {2B5AD67C-0F2A-4df4-A7BC-7E474A0ACF41} Crew is en route. enroute {138C75A7-0B81-4d97-B8DD-400537A3F2CE} Work is in progress. inProgress {F93942E8-4EB4-44e2-9554-AC8608E6B90F} Crew is on the site. onSite {88CA861D-1421-4b0d-95D4-8544F332671F} Work has been scheduled. scheduled {2040A7AE-92D2-4cf3-B314-9FA9B71CE87F} Work approval is pending. waitingOnApproval {155E917C-9579-4a94-B495-8778F313BD20} Work has been waiting on material. waitingOnMaterial {9E154373-CA89-4d23-A4E8-35E02879B016} Work needs to be scheduled. waitingToBeScheduled {F6D6D000-2B03-4ea3-B407-BD24173C98FA} Work task deals with exchange of assets. exchange {621F815D-BDFD-4146-B45B-2B89546DD621} Work task deals with installation of assets. install {C1B2174E-EDB4-4f10-94AC-2B0D2D8D93CA} Work task deals with investigation about assets. investigate {8F3A049B-17B4-459a-90C0-B09C9EC8914C} Work task deals with removal of assets. remove {BC9FE20F-8CD0-41a8-9F75-A4DFC190B9B2} NO {C27DE8FD-732D-43d2-8898-B8547130FB91} YES {54A6BEC9-5CFC-4269-B252-C9637B123FF1} electricalNetwork {3AFEA97D-AD07-41a9-ACFD-16E587A739F0} other {E6101D62-B54A-477f-AFF4-0272B089D193} specialRestrictionLand {A32EA834-850F-4f37-AA6C-A22D845D5E8F} weatherZone {358B578F-209E-4907-92C5-24125B55397D} ancillary service region ASREGION {FC92FB19-420E-4a12-AEFF-E983621A8366} designated congestion area DCA {AC9A4301-6B37-4f8a-9FF7-CEA88CFEACD5} load zone LOADZONE {E61398DB-F658-455f-82D1-922521ED8DC6} RUC zone RUCZONE {4F49BEA5-63C7-4056-A767-FBCBEA225868} trading hub TRADINGHUB {C9AD4D89-E529-4224-B327-E34939FA7C10} P {B597DE19-45A9-465c-9EE2-78E4E364093B} S {3FB723A8-1F76-4af7-8BDA-40C03E71A11F} 002005 standard edition. 00(2005) {8E71FBCF-DBF3-49c9-9967-26454CD26F66} 002005e1 standard edition. 00(2005)e1 {492864FA-7E00-459c-82D4-6CF125C1B384} 002010 standard edition. 00(2010) {7E2BEAC7-1B86-44ac-A426-5360F245151C} 01a2007 standard edition. 01a(2007) {D1459C58-520F-4614-8A84-D4BA20088BC4} 022007 standard edition. 02(2007) {D05C679E-3ABF-4e5e-AEDE-AD8A2352FA14} 022008 standard edition. 02(2008) {4695E6BF-1D27-4155-B014-D7756AC3DF35} 022009 standard edition. 02(2009) {72AFF8DB-D2C3-425a-AC88-EC736CAE706F} 022012 standard edition. 02(2012) {499EA67F-E4A1-4bc5-B6EF-620DACE97DD5} 022014 standard edition. 02(2014) {6D8F26A3-CC28-42ab-BC5D-D3F637E641E7} 032008 standard edition. 03(2008) {0BE5F928-B640-4f9d-A293-393DE4A7BC81} 032014 standard edition. 03(2014) {304E5600-257A-4878-9934-C0A163F9FC43} 052010 standard edition. 05(2010) {FC587458-2610-4269-86E0-00C3A70D4172} 05a2010 standard edition. 05a(2010) {F8553908-77C2-4fe0-9DC2-5AD71584CCEB} 072013 standard edition. 07(2013) {2D8A66F7-8686-45cb-BE7B-8AF068F25471} 092013 standard edition. 09(2013) {8B3383FF-7319-4b40-AD5E-9C1F9A85A435} 831996e1 standard edition. 83(1996)e1 {EB31ABEF-1D7C-48fa-8B6C-107A42A70AF6} 851990e1 standard edition. 85(1990)e1 {5FC570FD-5F8D-403d-BA30-F4CEBAB8CB16} 871995 standard edition. 87(1995) {69881E1E-A36D-4f36-8C5A-9A6EE2266023} 941999 standard edition. 94(1999) {393A76C1-DDA2-4698-A158-C932ED9F3ED1} 942004 standard edition. 94(2004) {DE9031C7-1757-4117-A170-A6B096545B80} 942010 standard edition. 94(2010) {FC9BC22B-8B02-4ddb-9C40-64A022614730} 952000e1 standard edition. 95(2000)e1 {11863897-3E93-46ca-9E5F-B7D505CE7468} 962002e1 standard edition. 96(2002)e1 {609D38A3-1DB0-48ed-9C92-1FA434A93959} 972002 standard edition. 97(2002) {07E839ED-6AE6-4188-8A60-18A768EB7DF4} 972003 standard edition. 97(2003) {96B550A9-B221-4d58-8F41-991D303CC49C} 972008 standard edition. 97(2008) {8507490C-DEB7-4af4-8B2E-C76E0DC378B8} 97a2004 standard edition. 97a(2004) {5C3E48A5-0386-4f40-B78A-04C139F44C29} 992004e1 standard edition. 99(2004)e1 {807093CF-9225-4b19-AB6C-CB62731FB75F} 992005 standard edition. 99(2005) {9331F749-46B7-4087-BA5F-927D7ABAB456} 992009 standard edition. 99(2009) {2AF29F7E-263E-4367-858B-F1538F914D3F} 99a2004 standard edition. 99a(2004) {E25F80DB-8008-4c8d-AC3D-CCC9E634873C} Standard Test Method for Dielectric Breakdown Voltage of Insulating Liquids Using Disk Electrodes. D877/D877M {0DA468BD-5566-49ff-8FB5-F9122970CFB1} 1992AMD12004 edition. 1992/AMD1:2004 {B3D5B8FD-8789-49cc-BB51-4B1B6A3A01E7} 1992COR11992 edition. 1992/COR1:1992 {A421FB2D-F914-43d0-BD70-9871661C1ECC} 2004AMD12007 edition. 2004/AMD1:2007 {2DB7F596-4CA0-471d-8489-BABC58A14F40} 2004AMD12007CSV edition. 2004/AMD1:2007CSV {D05BF832-5BD0-487e-BA3F-6CAB7C2ED64B} 2013COR2013 edition. 2013/COR:2013 {21F1B9DD-5635-4955-BC70-2700405BEBE6} 1994Cor11997 standard edition. 1994/Cor1:1997 {46C29A8B-7D65-4c48-B67B-375DAA93418E} TTC/ATC_Forecast_Information {9BBAE60F-FD55-46ef-8E37-8F0FFAEB7E54} TTC/ATC_Hourly_Forecast {00CE4FBD-34B0-438b-9F64-9D5E61803B29} Invalid date format, please use valid date format {611AFA4F-B38E-46f2-8B4E-D8EF1B1A4C33} Report name does not exit, please use valid report name {89AF40DD-8AE2-4947-B74E-1F870F24570B} N/A {82DDC1B9-A1BE-408e-8111-36A97CE0D2EB} % {B9832992-2022-4f15-A831-D6E9B30EB3E3} US$ {BC6E1FD8-7FDA-4ff4-B646-182111BE5BE6} US$/MW {9CBB2EBF-97E8-4516-86FC-4188CE427A6B} US$/MWh {090D37CE-759A-4c79-9936-C4398FF7EC63} Ministry of Defence Defence Standard 0550 Part 65Issue 1 METHODS FOR TESTING FUELS LUBRICANTS AND ASSOCIATED PRODUCTS. 05-50 (Part 65) {FAEFFDEB-AFE9-49a8-B9D4-B1F97AA6CB42} $/lb {208BE661-4C4A-4f07-A89C-6EFB5E779134} $/mmBTU {53AD8C77-7160-4df3-9B85-4DDA4B1EDEBB} % {D63881DE-E79A-4c3c-BC21-F4C08FC5DD68} US$ {54A6B44F-1629-4b9b-99AE-00A11BAD2A8E} US$/MW {911183F5-E1A7-4550-961C-E35A7CFC2053} US$/MWh {02CDE6BC-CF46-4cb4-B62B-492A4CC4BC48} Westinghouse Engineering Procedure 121254E. 12, 1254E {4CA3075B-F105-4fa7-B804-C5269A6D5143} The quantity value.The association role provides the information about what is expressed. quantity {27D567FF-4381-4fc8-9618-8623FDCD30FF} {E4139F38-C2AF-497b-B916-ECD41EA35023}.SupplierEnd