BFO CLIF specification label BFO CLIF specification label Person:Alan Ruttenberg Really of interest to developers only Relates an entity in the ontology to the term that is used to represent it in the the CLIF specification of BFO2 shorthand shorthand Description Description An account of the content of the resource. Description may include but is not limited to: an abstract, table of contents, reference to a graphical representation of content or a free-text account of the content. definition textual definition textual definition definition definition definition textual definition textual definition 2012-04-05: Barry Smith The official OBI definition, explaining the meaning of a class or property: 'Shall be Aristotelian, formalized and normalized. Can be augmented with colloquial definitions' is terrible. Can you fix to something like: A statement of necessary and sufficient conditions explaining the meaning of an expression referring to a class or property. Alan Ruttenberg Your proposed definition is a reasonable candidate, except that it is very common that necessary and sufficient conditions are not given. Mostly they are necessary, occasionally they are necessary and sufficient or just sufficient. Often they use terms that are not themselves defined and so they effectively can't be evaluated by those criteria. On the specifics of the proposed definition: We don't have definitions of 'meaning' or 'expression' or 'property'. For 'reference' in the intended sense I think we use the term 'denotation'. For 'expression', I think we you mean symbol, or identifier. For 'meaning' it differs for class and property. For class we want documentation that let's the intended reader determine whether an entity is instance of the class, or not. For property we want documentation that let's the intended reader determine, given a pair of potential relata, whether the assertion that the relation holds is true. The 'intended reader' part suggests that we also specify who, we expect, would be able to understand the definition, and also generalizes over human and computer reader to include textual and logical definition. Personally, I am more comfortable weakening definition to documentation, with instructions as to what is desirable. We also have the outstanding issue of how to aim different definitions to different audiences. A clinical audience reading chebi wants a different sort of definition documentation/definition from a chemistry trained audience, and similarly there is a need for a definition that is adequate for an ontologist to work with. GROUP:OBI:<http://purl.obolibrary.org/obo/obi> PERSON:Daniel Schober The official OBI definition, explaining the meaning of a class or property. Shall be Aristotelian, formalized and normalized. Can be augmented with colloquial definitions. The official definition, explaining the meaning of a class or property. Shall be Aristotelian, formalized and normalized. Can be augmented with colloquial definitions. definition definition has_specified_input has_specified_input 8/17/09: specified inputs of one process are not necessarily specified inputs of a larger process that it is part of. This is in contrast to how 'has participant' works. PERSON: Bjoern Peters PERSON: Larry Hunter PERSON: Melanie Coutot has_specified_input A relation between a planned process and a continuant participating in that process that is not created during the process. The presence of the continuant during the process is explicitly specified in the plan specification which the process realizes the concretization of. PERSON: Alan Ruttenberg has_specified_input see is_input_of example_of_usage editor note editor note editor note 1 IAO:0000116 editor_note editor_note uberon An administrative note intended for its editor. It may not be included in the publication version of the ontology, so it should contain nothing necessary for end users to understand the ontology. GROUP:OBI:<http://purl.obfoundry.org/obo/obi> PERSON:Daniel Schober editor note contributor dc-contributor dc-contributor true uberon has curation status has curation status OBI_0000281 PERSON:Alan Ruttenberg PERSON:Bill Bug PERSON:Melanie Courtot has curation status database_cross_reference database_cross_reference definition source definition source Discussion on obo-discuss mailing-list, see http://bit.ly/hgm99w GROUP:OBI:<http://purl.obolibrary.org/obo/obi> PERSON:Daniel Schober definition source formal citation, e.g. identifier in external database to indicate / attribute source(s) for the definition. Free text indicate / attribute source(s) for the definition. EXAMPLE: Author Name, URI, MeSH Term C04, PUBMED ID, Wiki uri on 31.01.2007 curator notes curator note curator note 1 IAO:0000232 curator_notes curator_notes uberon An administrative note of use for a curator but of no use for a user PERSON:Alan Ruttenberg curator note definition editor term editor definition editor term editor 20110707, MC: label update to term editor and definition modified accordingly. See http://code.google.com/p/information-artifact-ontology/issues/detail?id=115. 20110707, MC: label update to term editor and definition modified accordingly. See https://github.com/information-artifact-ontology/IAO/issues/115. GROUP:OBI:<http://purl.obolibrary.org/obo/obi> Name of editor entering the definition in the file. The definition editor is a point of contact for information regarding the term. The definition editor may be, but is not always, the author of the definition, which may have been worked upon by several people Name of editor entering the term in the file. The term editor is a point of contact for information regarding the term. The term editor may be, but is not always, the author of the definition, which may have been worked upon by several people PERSON:Daniel Schober definition editor term editor has_specified_output has_specified_output PERSON: Bjoern Peters PERSON: Larry Hunter PERSON: Melanie Courtot has_specified_output A relation between a planned process and a continuant participating in that process. The presence of the continuant at the end of the process is explicitly specified in the objective specification which the process realizes the concretization of. PERSON: Alan Ruttenberg has_specified_output alternative term alternative term An alternative name for a class or property which means the same thing as the preferred name (semantically equivalent) GROUP:OBI:<http://purl.obolibrary.org/obo/obi> PERSON:Daniel Schober alternative term has_obo_namespace has_obo_namespace Source Source A reference to a resource from which the present resource is derived. The present resource may be derived from the Source resource in whole or in part. Recommended best practice is to reference the resource by means of a string or number conforming to a formal identification system. editor preferred term~editor preferred label editor preferred term editor preferred label editor preferred label editor preferred term editor preferred label editor preferred term editor preferred term~editor preferred label GROUP:OBI:<http://purl.obolibrary.org/obo/obi> PERSON:Daniel Schober The concise, meaningful, and human-friendly name for a class or property preferred by the ontology developers. (US-English) editor preferred label editor preferred term example of usage example of usage A phrase describing how a class name should be used. May also include other kinds of examples that facilitate immediate understanding of a class semantics, such as widely known prototypical subclasses or instances of the class. Although essential for high level terms, examples for low level terms (e.g., Affymetrix HU133 array) are not A phrase describing how a term should be used and/or a citation to a work which uses it. May also include other kinds of examples that facilitate immediate understanding, such as widely know prototypes or instances of a class, or cases where a relation is said to hold. GROUP:OBI:<http://purl.obolibrary.org/obo/obi> PERSON:Daniel Schober example BFO OWL specification label BFO OWL specification label Really of interest to developers only Relates an entity in the ontology to the name of the variable that is used to represent it in the code that generates the BFO OWL file from the lispy specification. creator label label logical macro assertion https://github.com/oborel/obo-relations/wiki/ShortcutRelations An assertion that involves at least one OWL object that is intended to be expanded into one or more logical axioms. The logical expansion can yield axioms expressed using any formal logical system, including, but not limited to OWL2-DL. has associated axiom(nl) has associated axiom(nl) An axiom associated with a term expressed using natural language Person:Alan Ruttenberg Person:Alan Ruttenberg has associated axiom(nl) logical macro assertion on a property A logical macro assertion whose domain is an IRI for a property has associated axiom(fol) has associated axiom(fol) An axiom expressed in first order logic using CLIF syntax Person:Alan Ruttenberg Person:Alan Ruttenberg has associated axiom(fol) logical macro assertion on an object property Used to annotate object properties to describe a logical meta-property or characteristic of the object property. imported from imported from For external terms/classes, the ontology from which the term was imported GROUP:OBI:<http://purl.obolibrary.org/obo/obi> PERSON:Alan Ruttenberg PERSON:Melanie Courtot imported from temporal interpretation https://code.google.com/p/obo-relations/wiki/ROAndTime https://github.com/oborel/obo-relations/wiki/ROAndTime An assertion that holds between an OWL Object Property and a temporal interpretation that elucidates how OWL Class Axioms that use this property are to be interpreted in a temporal context. elucidation elucidation Person:Barry Smith Primitive terms in a highest-level ontology such as BFO are terms which are so basic to our understanding of reality that there is no way of defining them in a non-circular fashion. For these, therefore, we can provide only elucidations, supplemented by examples and by axioms elucidation person:Alan Ruttenberg has part Everything has itself as a part. Any part of any part of a thing is itself part of that thing. Two distinct things cannot have each other as a part. Occurrents are not subject to change and so parthood between occurrents holds for all the times that the part exists. Many continuants are subject to change, so parthood between continuants will only hold at certain times, but this is difficult to specify in OWL. See https://code.google.com/p/obo-relations/wiki/ROAndTime Parthood requires the part and the whole to have compatible classes: only an occurrent have an occurrent as part; only a process can have a process as part; only a continuant can have a continuant as part; only an independent continuant can have an independent continuant as part; only a specifically dependent continuant can have a specifically dependent continuant as part; only a generically dependent continuant can have a generically dependent continuant as part. (This list is not exhaustive.) A continuant cannot have an occurrent as part: use 'participates in'. An occurrent cannot have a continuant as part: use 'has participant'. An immaterial entity cannot have a material entity as part: use 'location of'. An independent continuant cannot have a specifically dependent continuant as part: use 'bearer of'. A specifically dependent continuant cannot have an independent continuant as part: use 'inheres in'. a core relation that holds between a whole and its part has part has_part my body has part my brain (continuant parthood, two material entities) my stomach has part my stomach cavity (continuant parthood, material entity has part immaterial entity) this year has part this day (occurrent parthood) inheres in at all times inheresInAt inheres-in_at (iff (inheresInAt a b t) (and (DependentContinuant a) (IndependentContinuant b) (not (SpatialRegion b)) (specificallyDependsOnAt a b t))) // axiom label in BFO2 CLIF: [051-002] BFO2 Reference: independent continuant that is not a spatial region BFO2 Reference: specifically dependent continuant Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance-level, relation. The BFO reading of the binary relation 'inheres in at all times@en' is: forall(t) exists_at(x,t) -> exists_at(y,t) and 'inheres in@en(x,y,t)'. BFO 2 Reference: Inherence is a subrelation of s-depends_on which holds between a dependent continuant and an independent continuant that is not a spatial region. Since dependent continuants cannot migrate from one independent continuant bearer to another, it follows that if b s-depends_on independent continuant c at some time, then b s-depends_on c at all times at which a exists. Inherence is in this sense redundantly time-indexed.For example, consider the particular instance of openness inhering in my mouth at t as I prepare to take a bite out of a donut, followed by a closedness at t+1 when I bite the donut and start chewing. The openness instance is then shortlived, and to say that it s-depends_on my mouth at all times at which this openness exists, means: at all times during this short life. Every time you make a fist, you make a new (instance of the universal) fist. (Every time your hand has the fist-shaped quality, there is created a new instance of the universal fist-shaped quality.) b inheres_in c at t =Def. b is a dependent continuant & c is an independent continuant that is not a spatial region & b s-depends_on c at t. (axiom label in BFO2 Reference: [051-002]) realized in Paraphrase of elucidation: a relation between a realizable entity and a process, where there is some material entity that is bearer of the realizable entity and participates in the process, and the realizable entity comes to be realized in the course of the process [copied from inverse property 'realizes'] to say that b realizes c at t is to assert that there is some material entity d & b is a process which has participant d at t & c is a disposition or role of which d is bearer_of at t& the type instantiated by b is correlated with the type instantiated by c. (axiom label in BFO2 Reference: [059-003]) is realized by realized in realized_in this disease is realized in this disease course this fragility is realized in this shattering this investigator role is realized in this investigation realizes Paraphrase of elucidation: a relation between a process and a realizable entity, where there is some material entity that is bearer of the realizable entity and participates in the process, and the realizable entity comes to be realized in the course of the process realizes this disease course realizes this disease this investigation realizes this investigator role this shattering realizes this fragility to say that b realizes c at t is to assert that there is some material entity d & b is a process which has participant d at t & c is a disposition or role of which d is bearer_of at t& the type instantiated by b is correlated with the type instantiated by c. (axiom label in BFO2 Reference: [059-003]) concretized by at some time [copied from inverse property 'concretizes at some time'] b concretizes c at t means: b is a specifically dependent continuant & c is a generically dependent continuant & for some independent continuant that is not a spatial region d, b s-depends_on d at t & c g-depends on d at t & if c migrates from bearer d to another bearer e than a copy of b will be created in e. (axiom label in BFO2 Reference: [075-002]) [copied from inverse property 'concretizes at some time'] You may concretize a recipe that you find in a cookbook by turning it into a plan which exists as a realizable dependent continuant in your head. concretized-by_st [copied from inverse property 'concretizes at some time'] you may concretize a poem as a pattern of memory traces in your head [copied from inverse property 'concretizes at some time'] You may concretize a piece of software by installing it in your computer [copied from inverse property 'concretizes at some time'] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'concretizes at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'concretizes@en'(x,y,t) concretizes at some time concretizesAt (forall (x y t) (if (genericallyDependsOnAt x y t) (exists (z) (and (concretizesAt z x t) (specificallyDependsOnAt z y t))))) // axiom label in BFO2 CLIF: [076-001] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'concretizes at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'concretizes@en'(x,y,t) (forall (x y t) (if (concretizesAt x y t) (and (SpecificallyDependentContinuant x) (GenericallyDependentContinuant y) (exists (z) (and (IndependentContinuant z) (specificallyDependsOnAt x z t) (genericallyDependsOnAt y z t)))))) // axiom label in BFO2 CLIF: [075-002] concretizes_st You may concretize a piece of software by installing it in your computer You may concretize a recipe that you find in a cookbook by turning it into a plan which exists as a realizable dependent continuant in your head. b concretizes c at t means: b is a specifically dependent continuant & c is a generically dependent continuant & for some independent continuant that is not a spatial region d, b s-depends_on d at t & c g-depends on d at t & if c migrates from bearer d to another bearer e than a copy of b will be created in e. (axiom label in BFO2 Reference: [075-002]) if b g-depends on c at some time t, then there is some d, such that d concretizes b at t and d s-depends_on c at t. (axiom label in BFO2 Reference: [076-001]) you may concretize a poem as a pattern of memory traces in your head specifically depends on at all times (forall (x y t) (if (and (Entity x) (or (continuantPartOfAt y x t) (continuantPartOfAt x y t) (occurrentPartOf x y) (occurrentPartOf y x))) (not (specificallyDependsOnAt x y t)))) // axiom label in BFO2 CLIF: [013-002] (forall (x y z t) (if (and (specificallyDependsOnAt x y t) (specificallyDependsOnAt y z t)) (specificallyDependsOnAt x z t))) // axiom label in BFO2 CLIF: [054-002] (forall (x y t) (if (and (Occurrent x) (IndependentContinuant y) (specificallyDependsOnAt x y t)) (forall (t_1) (if (existsAt x t_1) (specificallyDependsOnAt x y t_1))))) // axiom label in BFO2 CLIF: [015-002] A pain s-depends_on the organism that is experiencing the pain specificallyDependsOn BFO2 Reference: specifically dependent continuant\; process; process boundary s-depends-on_at (forall (x) (if (exists (y t) (specificallyDependsOnAt x y t)) (not (MaterialEntity x)))) // axiom label in BFO2 CLIF: [052-001] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance-level, relation. The BFO reading of the binary relation 'specifically depends on at all times@en' is: forall(t) exists_at(x,t) -> exists_at(y,t) and 'specifically depends on@en(x,y,t)'. (forall (x y t) (if (specificallyDependsOnAt x y t) (exists (z) (and (IndependentContinuant z) (not (SpatialRegion z)) (specificallyDependsOnAt x z t))))) // axiom label in BFO2 CLIF: [136-001] BFO 2 Reference: An entity – for example an act of communication or a game of football – can s-depends_on more than one entity. Complex phenomena for example in the psychological and social realms (such as inferring, commanding and requesting) or in the realm of multi-organismal biological processes (such as infection and resistance), will involve multiple families of dependence relations, involving both continuants and occurrents [1, 4, 28 BFO 2 Reference: S-dependence is just one type of dependence among many; it is what, in the literature, is referred to as ‘existential dependence’ [87, 46, 65, 20 BFO 2 Reference: the relation of s-depends_on does not in every case require simultaneous existence of its relata. Note the difference between such cases and the cases of continuant universals defined historically: the act of answering depends existentially on the prior act of questioning; the human being who was baptized or who answered a question does not himself depend existentially on the prior act of baptism or answering. He would still exist even if these acts had never taken place. If b is s-depends_on something at some time, then b is not a material entity. (axiom label in BFO2 Reference: [052-001]) If b s-depends_on something at t, then there is some c, which is an independent continuant and not a spatial region, such that b s-depends_on c at t. (axiom label in BFO2 Reference: [136-001]) If occurrent b s-depends_on some independent continuant c at t, then b s-depends_on c at every time at which b exists. (axiom label in BFO2 Reference: [015-002]) To say that b s-depends_on a at t is to say that b and c do not share common parts & b is of its nature such that it cannot exist unless c exists & b is not a boundary of c and b is not a site of which c is the host [64 a gait s-depends_on the walking object. (All at some specific time.) a shape s-depends_on the shaped object an entity does not s-depend_on any of its (continuant or occurrent) parts or on anything it is part of. (axiom label in BFO2 Reference: [013-002]) if b s-depends_on c at t & c s-depends_on d at t then b s-depends_on d at t. (axiom label in BFO2 Reference: [054-002]) one-sided s-dependence of a dependent continuant on an independent continuant: an instance of headache s-depends_on some head one-sided s-dependence of a dependent continuant on an independent continuant: an instance of temperature s-depends_on some organism one-sided s-dependence of a process on something: a process of cell death s-depends_on a cell one-sided s-dependence of a process on something: an instance of seeing (a relational process) s-depends_on some organism and on some seen entity, which may be an occurrent or a continuant one-sided s-dependence of one occurrent on another: a process of answering a question is dependent on a prior process of asking a question one-sided s-dependence of one occurrent on another: a process of obeying a command is dependent on a prior process of issuing a command one-sided s-dependence of one occurrent on multiple independent continuants: a relational process of hitting a ball with a cricket bat one-sided s-dependence of one occurrent on multiple independent continuants: a relational process of paying cash to a merchant in exchange for a bag of figs reciprocal s-dependence between occurrents: a process of buying and the associated process of selling reciprocal s-dependence between occurrents: a process of increasing the volume of a portion of gas while temperature remains constant and the associated process of decreasing the pressure exerted by the gas reciprocal s-dependence between occurrents: in a game of chess the process of playing with the white pieces is mutually dependent on the process of playing with the black pieces the one-sided dependence of an occurrent on an independent continuant: football match on the players, the ground, the ball the one-sided dependence of an occurrent on an independent continuant: handwave on a hand the three-sided reciprocal s-dependence of the hue, saturation and brightness of a color [45 the three-sided reciprocal s-dependence of the pitch, timbre and volume of a tone [45 the two-sided reciprocal s-dependence of the roles of husband and wife [20 occupies spatial region at some time occupiesSpatialRegionAt BFO2 Reference: spatial region (forall (r t) (if (Region r) (occupiesSpatialRegionAt r r t))) // axiom label in BFO2 CLIF: [042-002] located-at-r_st (forall (x y r_1 t) (if (and (occupiesSpatialRegionAt x r_1 t) (continuantPartOfAt y x t)) (exists (r_2) (and (continuantPartOfAt r_2 r_1 t) (occupiesSpatialRegionAt y r_2 t))))) // axiom label in BFO2 CLIF: [043-001] (forall (x r t) (if (occupiesSpatialRegionAt x r t) (and (SpatialRegion r) (IndependentContinuant x)))) // axiom label in BFO2 CLIF: [041-002] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'occupies spatial region at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'occupies spatial region@en'(x,y,t) BFO2 Reference: independent continuant b occupies_spatial_region r at t means that r is a spatial region in which independent continuant b is exactly located (axiom label in BFO2 Reference: [041-002]) every region r is occupies_spatial_region r at all times. (axiom label in BFO2 Reference: [042-002]) if b occupies_spatial_region r at t & b continuant_part_of b at t, then there is some r which is continuant_part_of r at t such that b occupies_spatial_region r at t. (axiom label in BFO2 Reference: [043-001]) exists at exists-at existsAt BFO2 Reference: entity BFO2 Reference: temporal region b exists_at t means: b is an entity which exists at some temporal region t. (axiom label in BFO2 Reference: [118-002]) has occurrent part [copied from inverse property 'part of occurrent'] Mary’s 5th birthday occurrent_part_of Mary’s life [copied from inverse property 'part of occurrent'] the first set of the tennis match occurrent_part_of the tennis match. [copied from inverse property 'part of occurrent'] BFO 2 Reference: a (continuant or occurrent) part of itself. We appreciate that this is counterintuitive for some users, since it implies for example that President Obama is a part of himself. However it brings benefits in simplifying the logical formalism, and it captures an important feature of identity, namely that it is the limit case of mereological inclusion. (iff (hasOccurrentPart a b) (occurrentPartOf b a)) // axiom label in BFO2 CLIF: [007-001] [copied from inverse property 'part of occurrent'] BFO2 Reference: occurrent o-has-part hasOccurrentPart [copied from inverse property 'part of occurrent'] b occurrent_part_of c =Def. b is a part of c & b and c are occurrents. (axiom label in BFO2 Reference: [003-002]) [copied from inverse property 'part of occurrent'] The process of a footballer’s heart beating once is an occurrent part but not a temporal_part of a game of football. b has_occurrent_part c = Def. c occurrent_part_of b. (axiom label in BFO2 Reference: [007-001]) has proper occurrent part [copied from inverse property 'proper part of occurrent'] b proper_occurrent_part_of c =Def. b occurrent_part_of c & b and c are not identical. (axiom label in BFO2 Reference: [005-001]) o-has-ppart hasProperOccurrentPart b has_proper_occurrent_part c = Def. c proper_occurrent_part_of b. [XXX-001 has spatial occupant at some time r-location-of_st [copied from inverse property 'occupies spatial region at some time'] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'occupies spatial region at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'occupies spatial region@en'(x,y,t) [copied from inverse property 'occupies spatial region at some time'] BFO2 Reference: spatial region [copied from inverse property 'occupies spatial region at some time'] BFO2 Reference: independent continuant [copied from inverse property 'occupies spatial region at some time'] b occupies_spatial_region r at t means that r is a spatial region in which independent continuant b is exactly located (axiom label in BFO2 Reference: [041-002]) has specific dependent at some time [copied from inverse property 'specifically depends on at some time'] one-sided s-dependence of one occurrent on multiple independent continuants: a relational process of hitting a ball with a cricket bat [copied from inverse property 'specifically depends on at some time'] reciprocal s-dependence between occurrents: a process of increasing the volume of a portion of gas while temperature remains constant and the associated process of decreasing the pressure exerted by the gas [copied from inverse property 'specifically depends on at some time'] one-sided s-dependence of one occurrent on multiple independent continuants: a relational process of paying cash to a merchant in exchange for a bag of figs [copied from inverse property 'specifically depends on at some time'] the one-sided dependence of an occurrent on an independent continuant: football match on the players, the ground, the ball has-s-dep_st [copied from inverse property 'specifically depends on at some time'] BFO 2 Reference: S-dependence is just one type of dependence among many; it is what, in the literature, is referred to as ‘existential dependence’ [87, 46, 65, 20 [copied from inverse property 'specifically depends on at some time'] a shape s-depends_on the shaped object [copied from inverse property 'specifically depends on at some time'] one-sided s-dependence of a dependent continuant on an independent continuant: an instance of headache s-depends_on some head [copied from inverse property 'specifically depends on at some time'] the three-sided reciprocal s-dependence of the pitch, timbre and volume of a tone [45 [copied from inverse property 'specifically depends on at some time'] one-sided s-dependence of a process on something: an instance of seeing (a relational process) s-depends_on some organism and on some seen entity, which may be an occurrent or a continuant [copied from inverse property 'specifically depends on at some time'] a gait s-depends_on the walking object. (All at some specific time.) [copied from inverse property 'specifically depends on at some time'] To say that b s-depends_on a at t is to say that b and c do not share common parts & b is of its nature such that it cannot exist unless c exists & b is not a boundary of c and b is not a site of which c is the host [64 [copied from inverse property 'specifically depends on at some time'] BFO 2 Reference: the relation of s-depends_on does not in every case require simultaneous existence of its relata. Note the difference between such cases and the cases of continuant universals defined historically: the act of answering depends existentially on the prior act of questioning; the human being who was baptized or who answered a question does not himself depend existentially on the prior act of baptism or answering. He would still exist even if these acts had never taken place. [copied from inverse property 'specifically depends on at some time'] reciprocal s-dependence between occurrents: in a game of chess the process of playing with the white pieces is mutually dependent on the process of playing with the black pieces [copied from inverse property 'specifically depends on at some time'] the three-sided reciprocal s-dependence of the hue, saturation and brightness of a color [45 [copied from inverse property 'specifically depends on at some time'] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'specifically depends on at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'specifically depends on@en'(x,y,t) [copied from inverse property 'specifically depends on at some time'] reciprocal s-dependence between occurrents: a process of buying and the associated process of selling [copied from inverse property 'specifically depends on at some time'] one-sided s-dependence of one occurrent on another: a process of answering a question is dependent on a prior process of asking a question [copied from inverse property 'specifically depends on at some time'] one-sided s-dependence of one occurrent on another: a process of obeying a command is dependent on a prior process of issuing a command [copied from inverse property 'specifically depends on at some time'] BFO 2 Reference: An entity – for example an act of communication or a game of football – can s-depends_on more than one entity. Complex phenomena for example in the psychological and social realms (such as inferring, commanding and requesting) or in the realm of multi-organismal biological processes (such as infection and resistance), will involve multiple families of dependence relations, involving both continuants and occurrents [1, 4, 28 [copied from inverse property 'specifically depends on at some time'] the one-sided dependence of an occurrent on an independent continuant: handwave on a hand [copied from inverse property 'specifically depends on at some time'] A pain s-depends_on the organism that is experiencing the pain [copied from inverse property 'specifically depends on at some time'] the two-sided reciprocal s-dependence of the roles of husband and wife [20 [copied from inverse property 'specifically depends on at some time'] one-sided s-dependence of a process on something: a process of cell death s-depends_on a cell [copied from inverse property 'specifically depends on at some time'] BFO2 Reference: specifically dependent continuant\; process; process boundary [copied from inverse property 'specifically depends on at some time'] one-sided s-dependence of a dependent continuant on an independent continuant: an instance of temperature s-depends_on some organism has spatiotemporal occupant occupied-by [copied from inverse property 'occupies spatiotemporal region'] BFO 2 Reference: The occupies_spatiotemporal_region and occupies_temporal_region relations are the counterpart, on the occurrent side, of the relation occupies_spatial_region. [copied from inverse property 'occupies spatiotemporal region'] p occupies_spatiotemporal_region s. This is a primitive relation between an occurrent p and the spatiotemporal region s which is its spatiotemporal extent. (axiom label in BFO2 Reference: [082-003]) occupies spatiotemporal region occupies BFO 2 Reference: The occupies_spatiotemporal_region and occupies_temporal_region relations are the counterpart, on the occurrent side, of the relation occupies_spatial_region. occupiesSpatiotemporalRegion p occupies_spatiotemporal_region s. This is a primitive relation between an occurrent p and the spatiotemporal region s which is its spatiotemporal extent. (axiom label in BFO2 Reference: [082-003]) part of occurrent [copied from inverse property 'has occurrent part'] b has_occurrent_part c = Def. c occurrent_part_of b. (axiom label in BFO2 Reference: [007-001]) BFO2 Reference: occurrent (forall (x) (if (Occurrent x) (occurrentPartOf x x))) // axiom label in BFO2 CLIF: [113-002] (forall (x y t) (if (and (occurrentPartOf x y t) (occurrentPartOf y x t)) (= x y))) // axiom label in BFO2 CLIF: [123-001] occurrentPartOf (forall (x y z) (if (and (occurrentPartOf x y) (occurrentPartOf y z)) (occurrentPartOf x z))) // axiom label in BFO2 CLIF: [112-001] o-part-of (forall (x y t) (if (exists (v) (and (occurrentPartOf v x t) (occurrentPartOf v y t))) (exists (z) (forall (u w) (iff (iff (occurrentPartOf w u t) (and (occurrentPartOf w x t) (occurrentPartOf w y t))) (= z u)))))) // axiom label in BFO2 CLIF: [125-001] (forall (x y t) (if (and (occurrentPartOf x y t) (not (= x y))) (exists (z) (and (occurrentPartOf z y t) (not (exists (w) (and (occurrentPartOf w x t) (occurrentPartOf w z t)))))))) // axiom label in BFO2 CLIF: [124-001] BFO 2 Reference: a (continuant or occurrent) part of itself. We appreciate that this is counterintuitive for some users, since it implies for example that President Obama is a part of himself. However it brings benefits in simplifying the logical formalism, and it captures an important feature of identity, namely that it is the limit case of mereological inclusion. Mary’s 5th birthday occurrent_part_of Mary’s life The process of a footballer’s heart beating once is an occurrent part but not a temporal_part of a game of football. b occurrent_part_of c =Def. b is a part of c & b and c are occurrents. (axiom label in BFO2 Reference: [003-002]) occurrent_part_of is antisymmetric. (axiom label in BFO2 Reference: [123-001]) occurrent_part_of is reflexive (every occurrent entity is an occurrent_part_of itself). (axiom label in BFO2 Reference: [113-002]) occurrent_part_of is transitive. (axiom label in BFO2 Reference: [112-001]) occurrent_part_of satisfies unique product. (axiom label in BFO2 Reference: [125-001]) occurrent_part_of satisfies weak supplementation. (axiom label in BFO2 Reference: [124-001]) the first set of the tennis match occurrent_part_of the tennis match. proper part of occurrent (iff (properOccurrentPartOf a b) (and (occurrentPartOf a b) (not (= a b)))) // axiom label in BFO2 CLIF: [005-001] b proper_occurrent_part_of c =Def. b occurrent_part_of c & b and c are not identical. (axiom label in BFO2 Reference: [005-001]) o-ppart-of properOccurrentPartOf [copied from inverse property 'has proper occurrent part'] b has_proper_occurrent_part c = Def. c proper_occurrent_part_of b. [XXX-001 temporal part of t-part-of (iff (temporalPartOf a b) (and (occurrentPartOf a b) (exists (t) (and (TemporalRegion t) (occupiesSpatioTemporalRegion a t))) (forall (c t_1) (if (and (Occurrent c) (occupiesSpatioTemporalRegion c t_1) (occurrentPartOf t_1 r)) (iff (occurrentPartOf c a) (occurrentPartOf c b)))))) // axiom label in BFO2 CLIF: [078-003] (iff (properTemporalPartOf a b) (and (temporalPartOf a b) (not (= a b)))) // axiom label in BFO2 CLIF: [116-001] temporalPartOf (forall (x y) (if (properTemporalPartOf x y) (exists (z) (and (properTemporalPartOf z y) (not (exists (w) (and (temporalPartOf w x) (temporalPartOf w z)))))))) // axiom label in BFO2 CLIF: [117-002] b proper_temporal_part_of c =Def. b temporal_part_of c & not (b = c). (axiom label in BFO2 Reference: [116-001]) b temporal_part_of c =Def.b occurrent_part_of c & & for some temporal region t, b occupies_temporal_region t & for all occurrents d, t (if d occupies_temporal_region t & t? occurrent_part_of t then (d occurrent_part_of a iff d occurrent_part_of b)). (axiom label in BFO2 Reference: [078-003]) if b proper_temporal_part_of c, then there is some d which is a proper_temporal_part_of c and which shares no parts with b. (axiom label in BFO2 Reference: [117-002]) the 4th year of your life is a temporal part of your life\. The first quarter of a game of football is a temporal part of the whole game\. The process of your heart beating from 4pm to 5pm today is a temporal part of the entire process of your heart beating.\ The 4th year of your life is a temporal part of your life the process boundary which separates the 3rd and 4th years of your life. your heart beating from 4pm to 5pm today is a temporal part of the process of your heart beating projects onto spatial region at some time st-projects-onto-s_st spatial projection of spatiotemporal at some time s-projection-of-st_st projects onto temporal region st-projects-onto-t temporal projection of spatiotemporal t-projection-of-st occupies temporal region spans occupiesTemporalRegion p occupies_temporal_region t. This is a primitive relation between an occurrent p and the temporal region t upon which the spatiotemporal region p occupies_spatiotemporal_region projects. (axiom label in BFO2 Reference: [132-001]) has temporal occupant [copied from inverse property 'occupies temporal region'] p occupies_temporal_region t. This is a primitive relation between an occurrent p and the temporal region t upon which the spatiotemporal region p occupies_spatiotemporal_region projects. (axiom label in BFO2 Reference: [132-001]) spanOf span-of during which exists during-which-exists [copied from inverse property 'exists at'] b exists_at t means: b is an entity which exists at some temporal region t. (axiom label in BFO2 Reference: [118-002]) [copied from inverse property 'exists at'] BFO2 Reference: entity [copied from inverse property 'exists at'] BFO2 Reference: temporal region bearer of at all times Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance-level, relation. The BFO reading of the binary relation 'bearer of at all times@en' is: forall(t) exists_at(x,t) -> exists_at(y,t) and 'bearer of@en(x,y,t)'. BFO2 Reference: independent continuant that is not a spatial region BFO2 Reference: specifically dependent continuant (iff (bearerOfAt a b t) (and (specificallyDependsOnAt b a t) (IndependentContinuant a) (not (SpatialRegion a)) (existsAt b t))) // axiom label in BFO2 CLIF: [053-004] b bearer_of c at t =Def. c s-depends_on b at t & b is an independent continuant that is not a spatial region. (axiom label in BFO2 Reference: [053-004]) bearer-of_at bearerOfAt has disposition at all times (iff (hasDispositionAt a b t) (dispositionOf b a t)) // axiom label in BFO2 CLIF: [069-001] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance-level, relation. The BFO reading of the binary relation 'has disposition at all times@en' is: forall(t) exists_at(x,t) -> exists_at(y,t) and 'has disposition@en(x,y,t)'. a has_disposition b at t =Def. b disposition_of a at t. (axiom label in BFO2 Reference: [069-001]) has-d_at hasDispositionAt has specific dependent at all times has-s-dep_at specifically depends on at some time s-depends-on_st (forall (x y t) (if (and (Occurrent x) (IndependentContinuant y) (specificallyDependsOnAt x y t)) (forall (t_1) (if (existsAt x t_1) (specificallyDependsOnAt x y t_1))))) // axiom label in BFO2 CLIF: [015-002] BFO2 Reference: specifically dependent continuant\; process; process boundary (forall (x y t) (if (specificallyDependsOnAt x y t) (exists (z) (and (IndependentContinuant z) (not (SpatialRegion z)) (specificallyDependsOnAt x z t))))) // axiom label in BFO2 CLIF: [136-001] specificallyDependsOn (forall (x y z t) (if (and (specificallyDependsOnAt x y t) (specificallyDependsOnAt y z t)) (specificallyDependsOnAt x z t))) // axiom label in BFO2 CLIF: [054-002] (forall (x) (if (exists (y t) (specificallyDependsOnAt x y t)) (not (MaterialEntity x)))) // axiom label in BFO2 CLIF: [052-001] A pain s-depends_on the organism that is experiencing the pain Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'specifically depends on at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'specifically depends on@en'(x,y,t) (forall (x y t) (if (and (Entity x) (or (continuantPartOfAt y x t) (continuantPartOfAt x y t) (occurrentPartOf x y) (occurrentPartOf y x))) (not (specificallyDependsOnAt x y t)))) // axiom label in BFO2 CLIF: [013-002] BFO 2 Reference: An entity – for example an act of communication or a game of football – can s-depends_on more than one entity. Complex phenomena for example in the psychological and social realms (such as inferring, commanding and requesting) or in the realm of multi-organismal biological processes (such as infection and resistance), will involve multiple families of dependence relations, involving both continuants and occurrents [1, 4, 28 BFO 2 Reference: S-dependence is just one type of dependence among many; it is what, in the literature, is referred to as ‘existential dependence’ [87, 46, 65, 20 BFO 2 Reference: the relation of s-depends_on does not in every case require simultaneous existence of its relata. Note the difference between such cases and the cases of continuant universals defined historically: the act of answering depends existentially on the prior act of questioning; the human being who was baptized or who answered a question does not himself depend existentially on the prior act of baptism or answering. He would still exist even if these acts had never taken place. If b is s-depends_on something at some time, then b is not a material entity. (axiom label in BFO2 Reference: [052-001]) If b s-depends_on something at t, then there is some c, which is an independent continuant and not a spatial region, such that b s-depends_on c at t. (axiom label in BFO2 Reference: [136-001]) If occurrent b s-depends_on some independent continuant c at t, then b s-depends_on c at every time at which b exists. (axiom label in BFO2 Reference: [015-002]) To say that b s-depends_on a at t is to say that b and c do not share common parts & b is of its nature such that it cannot exist unless c exists & b is not a boundary of c and b is not a site of which c is the host [64 a gait s-depends_on the walking object. (All at some specific time.) a shape s-depends_on the shaped object an entity does not s-depend_on any of its (continuant or occurrent) parts or on anything it is part of. (axiom label in BFO2 Reference: [013-002]) if b s-depends_on c at t & c s-depends_on d at t then b s-depends_on d at t. (axiom label in BFO2 Reference: [054-002]) one-sided s-dependence of a dependent continuant on an independent continuant: an instance of headache s-depends_on some head one-sided s-dependence of a dependent continuant on an independent continuant: an instance of temperature s-depends_on some organism one-sided s-dependence of a process on something: a process of cell death s-depends_on a cell one-sided s-dependence of a process on something: an instance of seeing (a relational process) s-depends_on some organism and on some seen entity, which may be an occurrent or a continuant one-sided s-dependence of one occurrent on another: a process of answering a question is dependent on a prior process of asking a question one-sided s-dependence of one occurrent on another: a process of obeying a command is dependent on a prior process of issuing a command one-sided s-dependence of one occurrent on multiple independent continuants: a relational process of hitting a ball with a cricket bat one-sided s-dependence of one occurrent on multiple independent continuants: a relational process of paying cash to a merchant in exchange for a bag of figs reciprocal s-dependence between occurrents: a process of buying and the associated process of selling reciprocal s-dependence between occurrents: a process of increasing the volume of a portion of gas while temperature remains constant and the associated process of decreasing the pressure exerted by the gas reciprocal s-dependence between occurrents: in a game of chess the process of playing with the white pieces is mutually dependent on the process of playing with the black pieces the one-sided dependence of an occurrent on an independent continuant: football match on the players, the ground, the ball the one-sided dependence of an occurrent on an independent continuant: handwave on a hand the three-sided reciprocal s-dependence of the hue, saturation and brightness of a color [45 the three-sided reciprocal s-dependence of the pitch, timbre and volume of a tone [45 the two-sided reciprocal s-dependence of the roles of husband and wife [20 part of continuant at some time (forall (x y t) (if (and (continuantPartOfAt x y t) (not (= x y))) (exists (z) (and (continuantPartOfAt z y t) (not (exists (w) (and (continuantPartOfAt w x t) (continuantPartOfAt w z t)))))))) // axiom label in BFO2 CLIF: [121-001] (forall (x y z t) (if (and (continuantPartOfAt x y t) (continuantPartOfAt y z t)) (continuantPartOfAt x z t))) // axiom label in BFO2 CLIF: [110-001] continuantPartOfAt (forall (x y t) (if (and (continuantPartOfAt x y t) (continuantPartOfAt y x t)) (= x y))) // axiom label in BFO2 CLIF: [120-001] BFO2 Reference: continuantThe range for ‘t’ (as in all cases throughout this document unless otherwise specified) is: temporal region. (forall (x y t) (if (and (continuantPartOfAt x y t) (IndependentContinuant x)) (locatedInAt x y t))) // axiom label in BFO2 CLIF: [047-002] BFO2 Reference: continuant (forall (x y t) (if (exists (v) (and (continuantPartOfAt v x t) (continuantPartOfAt v y t))) (exists (z) (forall (u w) (iff (iff (continuantPartOfAt w u t) (and (continuantPartOfAt w x t) (continuantPartOfAt w y t))) (= z u)))))) // axiom label in BFO2 CLIF: [122-001] [copied from inverse property 'has continuant part at some time'] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'has continuant part at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'has continuant part@en'(x,y,t) (forall (x t) (if (Continuant x) (continuantPartOfAt x x t))) // axiom label in BFO2 CLIF: [111-002] (iff (ImmaterialEntity a) (and (IndependentContinuant a) (not (exists (b t) (and (MaterialEntity b) (continuantPartOfAt b a t)))))) // axiom label in BFO2 CLIF: [028-001] BFO 2 Reference: Immaterial entities are in some cases continuant parts of their material hosts. Thus the hold of a ship, for example, is a part of the ship; it may itself have parts, which may have names (used for example by ship stow planners, customs inspectors, and the like). Immaterial entities under both 1. and 2. can be of zero, one, two or three dimensions. We define:a(immaterial entity)[Definition: a is an immaterial entity = Def. a is an independent continuant that has no material entities as parts. (axiom label in BFO2 Reference: [028-001]) BFO 2 Reference: a (continuant or occurrent) part of itself. We appreciate that this is counterintuitive for some users, since it implies for example that President Obama is a part of himself. However it brings benefits in simplifying the logical formalism, and it captures an important feature of identity, namely that it is the limit case of mereological inclusion. Mary’s arm continuant_part_of Mary in the time of her life prior to her operation [copied from inverse property 'has continuant part at some time'] b has_continuant_part c at t = Def. c continuant_part_of b at t. (axiom label in BFO2 Reference: [006-001]) c-part-of_st Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'part of continuant at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'part of continuant@en'(x,y,t) b continuant_part_of c at t =Def. b is a part of c at t & t is a time & b and c are continuants. (axiom label in BFO2 Reference: [002-001]) continuant_part_of is antisymmetric. (axiom label in BFO2 Reference: [120-001]) continuant_part_of is reflexive (every continuant entity is a continuant_part_of itself). (axiom label in BFO2 Reference: [111-002]) continuant_part_of is transitive. (axiom label in BFO2 Reference: [110-001]) continuant_part_of satisfies unique product. (axiom label in BFO2 Reference: [122-001]) continuant_part_of satisfies weak supplementation. (axiom label in BFO2 Reference: [121-001]) if b continuant_part_of c at t and b is an independent continuant, then b is located_in c at t. (axiom label in BFO2 Reference: [047-002]) the Northern hemisphere of the planet Earth is a part of the planet Earth at all times at which the planet Earth exists. has continuant part at some time [copied from inverse property 'part of continuant at some time'] BFO2 Reference: continuant c-has-part_st [copied from inverse property 'part of continuant at some time'] b continuant_part_of c at t =Def. b is a part of c at t & t is a time & b and c are continuants. (axiom label in BFO2 Reference: [002-001]) [copied from inverse property 'part of continuant at some time'] the Northern hemisphere of the planet Earth is a part of the planet Earth at all times at which the planet Earth exists. hasContinuantPartAt [copied from inverse property 'part of continuant at some time'] Mary’s arm continuant_part_of Mary in the time of her life prior to her operation [copied from inverse property 'part of continuant at some time'] BFO 2 Reference: a (continuant or occurrent) part of itself. We appreciate that this is counterintuitive for some users, since it implies for example that President Obama is a part of himself. However it brings benefits in simplifying the logical formalism, and it captures an important feature of identity, namely that it is the limit case of mereological inclusion. Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'has continuant part at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'has continuant part@en'(x,y,t) [copied from inverse property 'part of continuant at some time'] BFO 2 Reference: Immaterial entities are in some cases continuant parts of their material hosts. Thus the hold of a ship, for example, is a part of the ship; it may itself have parts, which may have names (used for example by ship stow planners, customs inspectors, and the like). Immaterial entities under both 1. and 2. can be of zero, one, two or three dimensions. We define:a(immaterial entity)[Definition: a is an immaterial entity = Def. a is an independent continuant that has no material entities as parts. (axiom label in BFO2 Reference: [028-001]) [copied from inverse property 'part of continuant at some time'] BFO2 Reference: continuantThe range for ‘t’ (as in all cases throughout this document unless otherwise specified) is: temporal region. (iff (hasContinuantPartAt a b t) (continuantPartOfAt b a t)) // axiom label in BFO2 CLIF: [006-001] [copied from inverse property 'part of continuant at some time'] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance level, relation. The BFO reading of the binary relation 'part of continuant at some time@en' is: exists t, exists_at(x,t) & exists_at(y,t) & 'part of continuant@en'(x,y,t) b has_continuant_part c at t = Def. c continuant_part_of b at t. (axiom label in BFO2 Reference: [006-001]) part of continuant at all times that whole exists This is a binary version of a ternary time-indexed, instance level, relation. Unlike the rest of the temporalized relations which temporally quantify over existence of the subject of the relation, this relation temporally quantifies over the existence of the object of the relation. The relation is provided tentatively, to assess whether the GO needs such a relation. It is inverse of 'has continuant part at all times' [copied from inverse property 'has continuant part at all times'] b has_continuant_part c at t = Def. c continuant_part_of b at t. (axiom label in BFO2 Reference: [006-001]) forall(t) exists_at(y,t) -> exists_at(x,t) and 'part of continuant'(x,y,t) [copied from inverse property 'has continuant part at all times'] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance-level, relation. The BFO reading of the binary relation 'has continuant part at all times@en' is: forall(t) exists_at(x,t) -> exists_at(y,t) and 'has continuant part@en(x,y,t)'. c-part-of-object_at has continuant part at all times that part exists [copied from inverse property 'part of continuant at all times'] BFO2 Reference: continuantThe range for ‘t’ (as in all cases throughout this document unless otherwise specified) is: temporal region. [copied from inverse property 'part of continuant at all times'] BFO2 Reference: continuant [copied from inverse property 'part of continuant at all times'] BFO 2 Reference: Immaterial entities are in some cases continuant parts of their material hosts. Thus the hold of a ship, for example, is a part of the ship; it may itself have parts, which may have names (used for example by ship stow planners, customs inspectors, and the like). Immaterial entities under both 1. and 2. can be of zero, one, two or three dimensions. We define:a(immaterial entity)[Definition: a is an immaterial entity = Def. a is an independent continuant that has no material entities as parts. (axiom label in BFO2 Reference: [028-001]) [copied from inverse property 'part of continuant at all times'] BFO 2 Reference: a (continuant or occurrent) part of itself. We appreciate that this is counterintuitive for some users, since it implies for example that President Obama is a part of himself. However it brings benefits in simplifying the logical formalism, and it captures an important feature of identity, namely that it is the limit case of mereological inclusion. [copied from inverse property 'part of continuant at all times'] b continuant_part_of c at t =Def. b is a part of c at t & t is a time & b and c are continuants. (axiom label in BFO2 Reference: [002-001]) [copied from inverse property 'part of continuant at all times'] Mary’s arm continuant_part_of Mary in the time of her life prior to her operation This is a binary version of a ternary time-indexed, instance level, relation. Unlike the rest of the temporalized relations which temporally quantify over existence of the subject of the relation, this relation temporally quantifies over the existence of the object of the relation. The relation is provided tentatively, to assess whether the GO needs such a relation. It is inverse of 'part of continuant at all times' c-has-part-object_at [copied from inverse property 'part of continuant at all times'] Alan Ruttenberg: This is a binary version of a ternary time-indexed, instance-level, relation. The BFO reading of the binary relation 'part of continuant at all times@en' is: forall(t) exists_at(x,t) -> exists_at(y,t) and 'part of continuant@en(x,y,t)'. [copied from inverse property 'part of continuant at all times'] the Northern hemisphere of the planet Earth is a part of the planet Earth at all times at which the planet Earth exists. forall(t) exists_at(y,t) -> exists_at(x,t) and 'has continuant part'(x,y,t) has_specified_input has_specified_input 8/17/09: specified inputs of one process are not necessarily specified inputs of a larger process that it is part of. This is in contrast to how 'has participant' works. PERSON: Bjoern Peters PERSON: Larry Hunter PERSON: Melanie Coutot has_specified_input A relation between a planned process and a continuant participating in that process that is not created during the process. The presence of the continuant during the process is explicitly specified in the plan specification which the process realizes the concretization of. PERSON: Alan Ruttenberg has_specified_input see is_input_of example_of_usage has_specified_output has_specified_output PERSON: Bjoern Peters PERSON: Larry Hunter PERSON: Melanie Courtot has_specified_output A relation between a planned process and a continuant participating in that process. The presence of the continuant at the end of the process is explicitly specified in the objective specification which the process realizes the concretization of. PERSON: Alan Ruttenberg has_specified_output is_specified_output_of PERSON:Bjoern Peters is_specified_output_of A relation between a planned process and a continuant participating in that process. The presence of the continuant at the end of the process is explicitly specified in the objective specification which the process realizes the concretization of. Alan Ruttenberg is_specified_output_of achieves_planned_objective A cell sorting process achieves the objective specification 'material separation objective' BP, AR, PPPB branch PPPB branch derived This relation obtains between a planned process and a objective specification when the criteria specified in the objective specification are met at the end of the planned process. achieves_planned_objective modified according to email thread from 1/23/09 in accordince with DT and PPPB branch inheres in A dependent inheres in its bearer at all times for which the dependent exists. a relation between a specifically dependent continuant (the dependent) and an independent continuant (the bearer), in which the dependent specifically depends on the bearer for its existence inheres in inheres_in this fragility inheres in this vase this red color inheres in this apple participates in a relation between a continuant and a process, in which the continuant is somehow involved in the process participates in participates_in this blood clot participates in this blood coagulation this input material (or this output material) participates in this process this investigator participates in this investigation has participant Has_participant is a primitive instance-level relation between a process, a continuant, and a time at which the continuant participates in some way in the process. The relation obtains, for example, when this particular process of oxygen exchange across this particular alveolar membrane has_participant this particular sample of hemoglobin at this particular time. a relation between a process and a continuant, in which the continuant is somehow involved in the process has participant http://www.obofoundry.org/ro/#OBO_REL:has_participant has_participant this blood coagulation has participant this blood clot this investigation has participant this investigator this process has participant this input material (or this output material) concretizes A journal article is an information artifact that inheres in some number of printed journals. For each copy of the printed journal there is some quality that carries the journal article, such as a pattern of ink. The quality (a specifically dependent continuant) concretizes the journal article (a generically dependent continuant), and both depend on that copy of the printed journal (an independent continuant). A relationship between a specifically dependent continuant and a generically dependent continuant, in which the generically dependent continuant depends on some independent continuant in virtue of the fact that the specifically dependent continuant also depends on that same independent continuant. Multiple specifically dependent continuants can concretize the same generically dependent continuant. An investigator reads a protocol and forms a plan to carry out an assay. The plan is a realizable entity (a specifically dependent continuant) that concretizes the protocol (a generically dependent continuant), and both depend on the investigator (an independent continuant). The plan is then realized by the assay (a process). role of A role inheres in its bearer at all times for which the role exists, however the role need not be realized at all the times that the role exists. a relation between a role and an independent continuant (the bearer), in which the role specifically depends on the bearer for its existence is role of role_of this investigator role is a role of this person has function A bearer can have many functions, and its functions can exist for different periods of time, but none of its functions can exist when the bearer does not exist. A function need not be realized at all the times that the function exists. a relation between an independent continuant (the bearer) and a function, in which the function specifically depends on the bearer for its existence has_function this enzyme has function this catalysis function (more colloquially: this enzyme has this catalysis function) has role A bearer can have many roles, and its roles can exist for different periods of time, but none of its roles can exist when the bearer does not exist. A role need not be realized at all the times that the role exists. a relation between an independent continuant (the bearer) and a role, in which the role specifically depends on the bearer for its existence has_role this person has role this investigator role (more colloquially: this person has this role of investigator) inheres in part of Because part_of is transitive, inheres in is a sub-relation of inheres in part of Chris Mungall q inheres in part of w if and only if there exists some p such that q inheres in p and p part of w. depends on Chris Mungall entity entity An entity is anything that exists or has existed or will exist. (axiom label in BFO2 Reference: [001-001]) entity Entity BFO 2 Reference: In all areas of empirical inquiry we encounter general terms of two sorts. First are general terms which refer to universals or types:animaltuberculosissurgical procedurediseaseSecond, are general terms used to refer to groups of entities which instantiate a given universal but do not correspond to the extension of any subuniversal of that universal because there is nothing intrinsic to the entities in question by virtue of which they – and only they – are counted as belonging to the given group. Examples are: animal purchased by the Emperortuberculosis diagnosed on a Wednesdaysurgical procedure performed on a patient from Stockholmperson identified as candidate for clinical trial #2056-555person who is signatory of Form 656-PPVpainting by Leonardo da VinciSuch terms, which represent what are called ‘specializations’ in [81 Entity doesn't have a closure axiom because the subclasses don't necessarily exhaust all possibilites. For example Werner Ceusters 'portions of reality' include 4 sorts, entities (as BFO construes them), universals, configurations, and relations. It is an open question as to whether entities as construed in BFO will at some point also include these other portions of reality. See, for example, 'How to track absolutely everything' at http://www.referent-tracking.com/_RTU/papers/CeustersICbookRevised.pdf Julius Caesar Verdi’s Requiem the Second World War your body mass index continuant continuant Continuant (forall (x) (if (Material Entity x) (exists (t) (and (TemporalRegion t) (existsAt x t))))) // axiom label in BFO2 CLIF: [011-002] (forall (x) (if (Continuant x) (Entity x))) // axiom label in BFO2 CLIF: [008-002] (forall (x y) (if (and (Continuant x) (exists (t) (continuantPartOfAt y x t))) (Continuant y))) // axiom label in BFO2 CLIF: [009-002] continuant (forall (x y) (if (and (Continuant x) (exists (t) (hasContinuantPartOfAt y x t))) (Continuant y))) // axiom label in BFO2 CLIF: [126-001] A continuant is an entity that persists, endures, or continues to exist through time while maintaining its identity. (axiom label in BFO2 Reference: [008-002]) An entity that exists in full at any time in which it exists at all, persists through time while maintaining its identity and has no temporal parts. An entity that exists in full at any time in which it exists at all, persists through time while maintaining its identity and has no temporal parts. BFO 2 Reference: Continuant entities are entities which can be sliced to yield parts only along the spatial dimension, yielding for example the parts of your table which we call its legs, its top, its nails. ‘My desk stretches from the window to the door. It has spatial parts, and can be sliced (in space) in two. With respect to time, however, a thing is a continuant.’ [60, p. 240 Continuant doesn't have a closure axiom because the subclasses don't necessarily exhaust all possibilites. For example, in an expansion involving bringing in some of Ceuster's other portions of reality, questions are raised as to whether universals are continuants if b is a continuant and if, for some t, c has_continuant_part b at t, then c is a continuant. (axiom label in BFO2 Reference: [126-001]) if b is a continuant and if, for some t, cis continuant_part of b at t, then c is a continuant. (axiom label in BFO2 Reference: [009-002]) if b is a material entity, then there is some temporal interval (referred to below as a one-dimensional temporal region) during which b exists. (axiom label in BFO2 Reference: [011-002]) occurrent Occurrent (forall (x) (iff (Occurrent x) (and (Entity x) (exists (y) (temporalPartOf y x))))) // axiom label in BFO2 CLIF: [079-001] occurrent (forall (x) (if (Occurrent x) (exists (r) (and (SpatioTemporalRegion r) (occupiesSpatioTemporalRegion x r))))) // axiom label in BFO2 CLIF: [108-001] An entity that has temporal parts and that happens, unfolds or develops through time. An occurrent is an entity that unfolds itself in time or it is the instantaneous boundary of such an entity (for example a beginning or an ending) or it is a temporal or spatiotemporal region which such an entity occupies_temporal_region or occupies_spatiotemporal_region. (axiom label in BFO2 Reference: [077-002]) BFO 2 Reference: every occurrent that is not a temporal or spatiotemporal region is s-dependent on some independent continuant that is not a spatial region BFO 2 Reference: s-dependence obtains between every process and its participants in the sense that, as a matter of necessity, this process could not have existed unless these or those participants existed also. A process may have a succession of participants at different phases of its unfolding. Thus there may be different players on the field at different times during the course of a football game; but the process which is the entire game s-depends_on all of these players nonetheless. Some temporal parts of this process will s-depend_on on only some of the players. Every occurrent occupies_spatiotemporal_region some spatiotemporal region. (axiom label in BFO2 Reference: [108-001]) Occurrent doesn't have a closure axiom because the subclasses don't necessarily exhaust all possibilites. An example would be the sum of a process and the process boundary of another process. Simons uses different terminology for relations of occurrents to regions: Denote the spatio-temporal location of a given occurrent e by 'spn[e]' and call this region its span. We may say an occurrent is at its span, in any larger region, and covers any smaller region. Now suppose we have fixed a frame of reference so that we can speak not merely of spatio-temporal but also of spatial regions (places) and temporal regions (times). The spread of an occurrent, (relative to a frame of reference) is the space it exactly occupies, and its spell is likewise the time it exactly occupies. We write 'spr[e]' and `spl[e]' respectively for the spread and spell of e, omitting mention of the frame. b is an occurrent entity iff b is an entity that has temporal parts. (axiom label in BFO2 Reference: [079-001]) independent continuant (forall (x t) (if (and (IndependentContinuant x) (existsAt x t)) (exists (y) (and (Entity y) (specificallyDependsOnAt y x t))))) // axiom label in BFO2 CLIF: [018-002] (forall (x t) (if (IndependentContinuant x) (exists (r) (and (SpatialRegion r) (locatedInAt x r t))))) // axiom label in BFO2 CLIF: [134-001] (iff (IndependentContinuant a) (and (Continuant a) (not (exists (b t) (specificallyDependsOnAt a b t))))) // axiom label in BFO2 CLIF: [017-002] A continuant that is a bearer of quality and realizable entity entities, in which other entities inhere and which itself cannot inhere in anything. For any independent continuant b and any time t there is some spatial region r such that b is located_in r at t. (axiom label in BFO2 Reference: [134-001]) For every independent continuant b and time t during the region of time spanned by its life, there are entities which s-depends_on b during t. (axiom label in BFO2 Reference: [018-002]) ic IndependentContinuant a chair a heart a leg a molecule a spatial region an atom an orchestra. an organism b is an independent continuant = Def. b is a continuant which is such that there is no c and no t such that b s-depends_on c at t. (axiom label in BFO2 Reference: [017-002]) the bottom right portion of a human torso the interior of your mouth spatial region true true (forall (x y t) (if (and (SpatialRegion x) (continuantPartOfAt y x t)) (SpatialRegion y))) // axiom label in BFO2 CLIF: [036-001] SpatialRegion (forall (x) (if (SpatialRegion x) (Continuant x))) // axiom label in BFO2 CLIF: [035-001] s-region A spatial region is a continuant entity that is a continuant_part_of spaceR as defined relative to some frame R. (axiom label in BFO2 Reference: [035-001]) All continuant parts of spatial regions are spatial regions. (axiom label in BFO2 Reference: [036-001]) BFO 2 Reference: Spatial regions do not participate in processes. Spatial region doesn't have a closure axiom because the subclasses don't exhaust all possibilites. An example would be the union of a spatial point and a spatial line that doesn't overlap the point, or two spatial lines that intersect at a single point. In both cases the resultant spatial region is neither 0-dimensional, 1-dimensional, 2-dimensional, or 3-dimensional. temporal region true true (forall (x) (if (TemporalRegion x) (Occurrent x))) // axiom label in BFO2 CLIF: [100-001] t-region (forall (x y) (if (and (TemporalRegion x) (occurrentPartOf y x)) (TemporalRegion y))) // axiom label in BFO2 CLIF: [101-001] TemporalRegion (forall (r) (if (TemporalRegion r) (occupiesTemporalRegion r r))) // axiom label in BFO2 CLIF: [119-002] A temporal region is an occurrent entity that is part of time as defined relative to some reference frame. (axiom label in BFO2 Reference: [100-001]) All parts of temporal regions are temporal regions. (axiom label in BFO2 Reference: [101-001]) Every temporal region t is such that t occupies_temporal_region t. (axiom label in BFO2 Reference: [119-002]) Temporal region doesn't have a closure axiom because the subclasses don't exhaust all possibilites. An example would be the mereological sum of a temporal instant and a temporal interval that doesn't overlap the instant. In this case the resultant temporal region is neither 0-dimensional nor 1-dimensional spatiotemporal region true true (forall (r) (if (SpatioTemporalRegion r) (occupiesSpatioTemporalRegion r r))) // axiom label in BFO2 CLIF: [107-002] (forall (x) (if (SpatioTemporalRegion x) (Occurrent x))) // axiom label in BFO2 CLIF: [095-001] (forall (x) (if (SpatioTemporalRegion x) (exists (y) (and (TemporalRegion y) (temporallyProjectsOnto x y))))) // axiom label in BFO2 CLIF: [098-001] (forall (x y) (if (and (SpatioTemporalRegion x) (occurrentPartOf y x)) (SpatioTemporalRegion y))) // axiom label in BFO2 CLIF: [096-001] (forall (x t) (if (SpatioTemporalRegion x) (exists (y) (and (SpatialRegion y) (spatiallyProjectsOntoAt x y t))))) // axiom label in BFO2 CLIF: [099-001] All parts of spatiotemporal regions are spatiotemporal regions. (axiom label in BFO2 Reference: [096-001]) Each spatiotemporal region at any time t projects_onto some spatial region at t. (axiom label in BFO2 Reference: [099-001]) Each spatiotemporal region projects_onto some temporal region. (axiom label in BFO2 Reference: [098-001]) Every spatiotemporal region occupies_spatiotemporal_region itself. Every spatiotemporal region s is such that s occupies_spatiotemporal_region s. (axiom label in BFO2 Reference: [107-002]) SpatiotemporalRegion st-region A spatiotemporal region is an occurrent entity that is part of spacetime. (axiom label in BFO2 Reference: [095-001]) the spatiotemporal region occupied by a human life the spatiotemporal region occupied by a process of cellular meiosis. the spatiotemporal region occupied by the development of a cancer tumor process process Process (iff (Process a) (and (Occurrent a) (exists (b) (properTemporalPartOf b a)) (exists (c t) (and (MaterialEntity c) (specificallyDependsOnAt a c t))))) // axiom label in BFO2 CLIF: [083-003] An occurrent that has temporal proper parts and for some time t, p s-depends_on some material entity at t. BFO 2 Reference: The realm of occurrents is less pervasively marked by the presence of natural units than is the case in the realm of independent continuants. Thus there is here no counterpart of ‘object’. In BFO 1.0 ‘process’ served as such a counterpart. In BFO 2.0 ‘process’ is, rather, the occurrent counterpart of ‘material entity’. Those natural – as contrasted with engineered, which here means: deliberately executed – units which do exist in the realm of occurrents are typically either parasitic on the existence of natural units on the continuant side, or they are fiat in nature. Thus we can count lives; we can count football games; we can count chemical reactions performed in experiments or in chemical manufacturing. We cannot count the processes taking place, for instance, in an episode of insect mating behavior.Even where natural units are identifiable, for example cycles in a cyclical process such as the beating of a heart or an organism’s sleep/wake cycle, the processes in question form a sequence with no discontinuities (temporal gaps) of the sort that we find for instance where billiard balls or zebrafish or planets are separated by clear spatial gaps. Lives of organisms are process units, but they too unfold in a continuous series from other, prior processes such as fertilization, and they unfold in turn in continuous series of post-life processes such as post-mortem decay. Clear examples of boundaries of processes are almost always of the fiat sort (midnight, a time of death as declared in an operating theater or on a death certificate, the initiation of a state of war) a process of cell-division, \ a beating of the heart a process of meiosis a process of sleeping p is a process = Def. p is an occurrent that has temporal proper parts and for some time t, p s-depends_on some material entity at t. (axiom label in BFO2 Reference: [083-003]) the course of a disease the flight of a bird the life of an organism your process of aging. disposition disposition Disposition (forall (x t) (if (and (RealizableEntity x) (existsAt x t)) (exists (y) (and (MaterialEntity y) (specificallyDepends x y t))))) // axiom label in BFO2 CLIF: [063-002] (forall (x) (if (Disposition x) (and (RealizableEntity x) (exists (y) (and (MaterialEntity y) (bearerOfAt x y t)))))) // axiom label in BFO2 CLIF: [062-002] BFO 2 Reference: Dispositions exist along a strength continuum. Weaker forms of disposition are realized in only a fraction of triggering cases. These forms occur in a significant number of cases of a similar type [89 BFO 2 Reference: Dispositions exist along a strength continuum. Weaker forms of disposition are realized in only a fraction of triggering cases. These forms occur in a significant number of cases of a similar type. If b is a realizable entity then for all t at which b exists, b s-depends_on some material entity at t. (axiom label in BFO2 Reference: [063-002]) an atom of element X has the disposition to decay to an atom of element Y b is a disposition means: b is a realizable entity & b’s bearer is some material entity & b is such that if it ceases to exist, then its bearer is physically changed, & b’s realization occurs when and because this bearer is in some special physical circumstances, & this realization occurs in virtue of the bearer’s physical make-up. (axiom label in BFO2 Reference: [062-002]) certain people have a predisposition to colon cancer children are innately disposed to categorize objects in certain ways. the cell wall is disposed to filter chemicals in endocitosis and exocitosis the cell wall is disposed to filter chemicals in endocytosis and exocytosis realizable entity (forall (x t) (if (RealizableEntity x) (exists (y) (and (IndependentContinuant y) (not (SpatialRegion y)) (bearerOfAt y x t))))) // axiom label in BFO2 CLIF: [060-002] (forall (x) (if (RealizableEntity x) (and (SpecificallyDependentContinuant x) (exists (y) (and (IndependentContinuant y) (not (SpatialRegion y)) (inheresIn x y)))))) // axiom label in BFO2 CLIF: [058-002] RealizableEntity All realizable dependent continuants have independent continuants that are not spatial regions as their bearers. (axiom label in BFO2 Reference: [060-002]) To say that b is a realizable entity is to say that b is a specifically dependent continuant that inheres in some independent continuant which is not a spatial region and is of a type instances of which are realized in processes of a correlated type. (axiom label in BFO2 Reference: [058-002]) realizable A specifically dependent continuant that inheres in continuant entities and are not exhibited in full at every time in which it inheres in an entity or group of entities. The exhibition or actualization of a realizable entity is a particular manifestation, functioning or process that occurs under certain circumstances. the disposition of this piece of metal to conduct electricity. the disposition of your blood to coagulate the function of your reproductive organs the role of being a doctor the role of this boundary to delineate where Utah and Colorado meet quality (forall (x) (if (exists (t) (and (existsAt x t) (Quality x))) (forall (t_1) (if (existsAt x t_1) (Quality x))))) // axiom label in BFO2 CLIF: [105-001] Quality (forall (x) (if (Quality x) (SpecificallyDependentContinuant x))) // axiom label in BFO2 CLIF: [055-001] quality If an entity is a quality at any time that it exists, then it is a quality at every time that it exists. (axiom label in BFO2 Reference: [105-001]) a quality is a specifically dependent continuant that, in contrast to roles and dispositions, does not require any further process in order to be realized. (axiom label in BFO2 Reference: [055-001]) the ambient temperature of this portion of air the color of a tomato the length of the circumference of your waist the mass of this piece of gold. the shape of your nose the shape of your nostril specifically dependent continuant (iff (SpecificallyDependentContinuant a) (and (Continuant a) (forall (t) (if (existsAt a t) (exists (b) (and (IndependentContinuant b) (not (SpatialRegion b)) (specificallyDependsOnAt a b t))))))) // axiom label in BFO2 CLIF: [050-003] sdc (iff (RelationalSpecificallyDependentContinuant a) (and (SpecificallyDependentContinuant a) (forall (t) (exists (b c) (and (not (SpatialRegion b)) (not (SpatialRegion c)) (not (= b c)) (not (exists (d) (and (continuantPartOfAt d b t) (continuantPartOfAt d c t)))) (specificallyDependsOnAt a b t) (specificallyDependsOnAt a c t)))))) // axiom label in BFO2 CLIF: [131-004] SpecificallyDependentContinuant A continuant that inheres in or is borne by other entities. Every instance of A requires some specific instance of B which must always be the same. A continuant that inheres in or is borne by other entities. Every instance of A requires some specific instance of B which must always be the same. Reciprocal specifically dependent continuants: the function of this key to open this lock and the mutually dependent disposition of this lock: to be opened by this key Specifically dependent continuant doesn't have a closure axiom because the subclasses don't necessarily exhaust all possibilites. We're not sure what else will develop here, but for example there are questions such as what are promises, obligation, etc. b is a relational specifically dependent continuant = Def. b is a specifically dependent continuant and there are n &gt; 1 independent continuants c1, … cn which are not spatial regions are such that for all 1 i &lt; j n, ci and cj share no common parts, are such that for each 1 i n, b s-depends_on ci at every time t during the course of b’s existence (axiom label in BFO2 Reference: [131-004]) b is a specifically dependent continuant = Def. b is a continuant & there is some independent continuant c which is not a spatial region and which is such that b s-depends_on c at every time t during the course of b’s existence. (axiom label in BFO2 Reference: [050-003]) of one-sided specifically dependent continuants: the mass of this tomato of relational dependent continuants (multiple bearers): John’s love for Mary, the ownership relation between John and this statue, the relation of authority between John and his subordinates. the disposition of this fish to decay the function of this heart: to pump blood the mutual dependence of proton donors and acceptors in chemical reactions [79 the mutual dependence of the role predator and the role prey as played by two organisms in a given interaction the pink color of a medium rare piece of grilled filet mignon at its center the role of being a doctor the shape of this hole. the smell of this portion of mozzarella role role Role (forall (x) (if (Role x) (RealizableEntity x))) // axiom label in BFO2 CLIF: [061-001] A realizable entity the manifestation of which brings about some result or end that is not essential to a continuant in virtue of the kind of thing that it is but that can be served or participated in by that kind of continuant in some kinds of natural, social or institutional contexts. BFO 2 Reference: One major family of examples of non-rigid universals involves roles, and ontologies developed for corresponding administrative purposes may consist entirely of representatives of entities of this sort. Thus ‘professor’, defined as follows,b instance_of professor at t =Def. there is some c, c instance_of professor role & c inheres_in b at t.denotes a non-rigid universal and so also do ‘nurse’, ‘student’, ‘colonel’, ‘taxpayer’, and so forth. (These terms are all, in the jargon of philosophy, phase sortals.) By using role terms in definitions, we can create a BFO conformant treatment of such entities drawing on the fact that, while an instance of professor may be simultaneously an instance of trade union member, no instance of the type professor role is also (at any time) an instance of the type trade union member role (any more than any instance of the type color is at any time an instance of the type length).If an ontology of employment positions should be defined in terms of roles following the above pattern, this enables the ontology to do justice to the fact that individuals instantiate the corresponding universals – professor, sergeant, nurse – only during certain phases in their lives. John’s role of husband to Mary is dependent on Mary’s role of wife to John, and both are dependent on the object aggregate comprising John and Mary as member parts joined together through the relational quality of being married. b is a role means: b is a realizable entity & b exists because there is some single bearer that is in some special physical, social, or institutional set of circumstances in which this bearer does not have to be& b is not such that, if it ceases to exist, then the physical make-up of the bearer is thereby changed. (axiom label in BFO2 Reference: [061-001]) the priest role the role of a boundary to demarcate two neighboring administrative territories the role of a building in serving as a military target the role of a stone in marking a property boundary the role of subject in a clinical trial the student role generically dependent continuant gdc GenericallyDependentContinuant (iff (GenericallyDependentContinuant a) (and (Continuant a) (exists (b t) (genericallyDependsOnAt a b t)))) // axiom label in BFO2 CLIF: [074-001] A continuant that is dependent on one or other independent continuant bearers. For every instance of A requires some instance of (an independent continuant type) B but which instance of B serves can change from time to time. The entries in your database are patterns instantiated as quality instances in your hard drive. The database itself is an aggregate of such patterns. When you create the database you create a particular instance of the generically dependent continuant type database. Each entry in the database is an instance of the generically dependent continuant type IAO: information content entity. b is a generically dependent continuant = Def. b is a continuant that g-depends_on one or more other entities. (axiom label in BFO2 Reference: [074-001]) the pdf file on your laptop, the pdf file that is a copy thereof on my laptop the sequence of this protein molecule; the sequence that is a copy thereof in that protein molecule. function function (forall (x) (if (Function x) (Disposition x))) // axiom label in BFO2 CLIF: [064-001] A function is a disposition that exists in virtue of the bearer’s physical make-up and this physical make-up is something the bearer possesses because it came into being, either through evolution (in the case of natural biological entities) or through intentional design (in the case of artifacts), in order to realize processes of a certain sort. (axiom label in BFO2 Reference: [064-001]) BFO 2 Reference: In the past, we have distinguished two varieties of function, artifactual function and biological function. These are not asserted subtypes of BFO:function however, since the same function – for example: to pump, to transport – can exist both in artifacts and in biological entities. The asserted subtypes of function that would be needed in order to yield a separate monoheirarchy are not artifactual function, biological function, etc., but rather transporting function, pumping function, etc. Function the function of a hammer to drive in nails the function of a heart pacemaker to regulate the beating of a heart through electricity the function of amylase in saliva to break down starch into sugar process boundary (iff (ProcessBoundary a) (exists (p) (and (Process p) (temporalPartOf a p) (not (exists (b) (properTemporalPartOf b a)))))) // axiom label in BFO2 CLIF: [084-001] (forall (x) (if (ProcessBoundary x) (exists (y) (and (ZeroDimensionalTemporalRegion y) (occupiesTemporalRegion x y))))) // axiom label in BFO2 CLIF: [085-002] Every process boundary occupies_temporal_region a zero-dimensional temporal region. (axiom label in BFO2 Reference: [085-002]) ProcessBoundary p is a process boundary =Def. p is a temporal part of a process & p has no proper temporal parts. (axiom label in BFO2 Reference: [084-001]) p-boundary the boundary between the 2nd and 3rd year of your life. material entity (forall (x) (if (MaterialEntity x) (IndependentContinuant x))) // axiom label in BFO2 CLIF: [019-002] material MaterialEntity (forall (x) (if (and (Entity x) (exists (y t) (and (MaterialEntity y) (continuantPartOfAt x y t)))) (MaterialEntity x))) // axiom label in BFO2 CLIF: [021-002] (forall (x) (if (and (Entity x) (exists (y t) (and (MaterialEntity y) (continuantPartOfAt y x t)))) (MaterialEntity x))) // axiom label in BFO2 CLIF: [020-002] A material entity is an independent continuant that has some portion of matter as proper or improper continuant part. (axiom label in BFO2 Reference: [019-002]) An independent continuant that is spatially extended whose identity is independent of that of other entities and can be maintained through time. BFO 2 Reference: Material entities (continuants) can preserve their identity even while gaining and losing material parts. Continuants are contrasted with occurrents, which unfold themselves in successive temporal parts or phases [60 BFO 2 Reference: Object, Fiat Object Part and Object Aggregate are not intended to be exhaustive of Material Entity. Users are invited to propose new subcategories of Material Entity. BFO 2 Reference: ‘Matter’ is intended to encompass both mass and energy (we will address the ontological treatment of portions of energy in a later version of BFO). A portion of matter is anything that includes elementary particles among its proper or improper parts: quarks and leptons, including electrons, as the smallest particles thus far discovered; baryons (including protons and neutrons) at a higher level of granularity; atoms and molecules at still higher levels, forming the cells, organs, organisms and other material entities studied by biologists, the portions of rock studied by geologists, the fossils studied by paleontologists, and so on.Material entities are three-dimensional entities (entities extended in three spatial dimensions), as contrasted with the processes in which they participate, which are four-dimensional entities (entities extended also along the dimension of time).According to the FMA, material entities may have immaterial entities as parts – including the entities identified below as sites; for example the interior (or ‘lumen’) of your small intestine is a part of your body. BFO 2.0 embodies a decision to follow the FMA here. Every entity which has a material entity as continuant part is a material entity. (axiom label in BFO2 Reference: [020-002]) a flame a forest fire a human being a hurricane a photon a puff of smoke a sea wave a tornado an aggregate of human beings. an energy wave an epidemic every entity of which a material entity is continuant part is also a material entity. (axiom label in BFO2 Reference: [021-002]) the undetached arm of a human being immaterial entity BFO 2 Reference: Immaterial entities are divided into two subgroups:boundaries and sites, which bound, or are demarcated in relation, to material entities, and which can thus change location, shape and size and as their material hosts move or change shape or size (for example: your nasal passage; the hold of a ship; the boundary of Wales (which moves with the rotation of the Earth) [38, 7, 10 immaterial ImmaterialEntity zero-dimensional temporal region 0d-t-region (forall (x) (if (ZeroDimensionalTemporalRegion x) (TemporalRegion x))) // axiom label in BFO2 CLIF: [102-001] A zero-dimensional temporal region is a temporal region that is without extent. (axiom label in BFO2 Reference: [102-001]) ZeroDimensionalTemporalRegion a temporal region that is occupied by a process boundary right now temporal instant. the moment at which a child is born the moment at which a finger is detached in an industrial accident the moment of death. objective specification 2009-03-16: original definition when imported from OBI read: "objective is an non realizable information entity which can serve as that proper part of a plan towards which the realization of the plan is directed." 2014-03-31: In the example of usage ("In the protocol of a ChIP assay the objective specification says to identify protein and DNA interaction") there is a protocol which is the ChIP assay protocol. In addition to being concretized on paper, the protocol can be concretized as a realizable entity, such as a plan that inheres in a person. The objective specification is the part that says that some protein and DNA interactions are identified. This is a specification of a process endpoint: the boundary in the process before which they are not identified and after which they are. During the realization of the plan, the goal is to get to the point of having the interactions, and participants in the realization of the plan try to do that. Answers the question, why did you do this experiment? In the protocol of a ChIP assay the objective specification says to identify protein and DNA interaction. OBI Plan and Planned Process/Roles Branch OBI_0000217 PERSON: Alan Ruttenberg PERSON: Barry Smith PERSON: Bjoern Peters PERSON: Jennifer Fostel a directive information entity that describes an intended process endpoint. When part of a plan specification the concretization is realized in a planned process in which the bearer tries to effect the world so that the process endpoint is achieved. goal specification objective specification data item 2/2/2009 Alan and Bjoern discussing FACS run output data. This is a data item because it is about the cell population. Each element records an event and is typically further composed a set of measurment data items that record the fluorescent intensity stimulated by one of the lasers. 2014-03-31: See discussion at http://odontomachus.wordpress.com/2014/03/30/aboutness-objects-propositions/ 2009-03-16: data item deliberatly ambiguous: we merged data set and datum to be one entity, not knowing how to define singular versus plural. So data item is more general than datum. 2009-03-16: removed datum as alternative term as datum specifically refers to singular form, and is thus not an exact synonym. Data items include counts of things, analyte concentrations, and statistical summaries. JAR: datum -- well, this will be very tricky to define, but maybe some information-like stuff that might be put into a computer and that is meant, by someone, to denote and/or to be interpreted by some process... I would include lists, tables, sentences... I think I might defer to Barry, or to Brian Cantwell Smith JAR: A data item is an approximately justified approximately true approximate belief PERSON: Alan Ruttenberg PERSON: Chris Stoeckert PERSON: Jonathan Rees a data item is an information content entity that is intended to be a truthful statement about something (modulo, e.g., measurement precision or other systematic errors) and is constructed/acquired by a method which reliably tends to produce (approximately) truthful statements. data data item information content entity 2014-03-10: The use of "thing" is intended to be general enough to include universals and configurations (see https://groups.google.com/d/msg/information-ontology/GBxvYZCk1oc/-L6B5fSBBTQJ). A generically dependent continuant that is about some thing. Examples of information content entites include journal articles, data, graphical layouts, and graphs. OBI_0000142 PERSON: Chris Stoeckert information content entity information_content_entity 'is_encoded_in' some digital_entity in obi before split (040907). information_content_entity 'is_encoded_in' some physical_document in obi before split (040907). Previous. An information content entity is a non-realizable information entity that 'is encoded in' some digital or physical entity. scalar measurement datum 10 feet. 3 ml. 2009-03-16: we decided to keep datum singular in scalar measurement datum, as in this case we explicitly refer to the singular form PERSON: Alan Ruttenberg PERSON: Melanie Courtot Would write this as: has_part some 'measurement unit label' and has_part some numeral and has_part exactly 2, except for the fact that this won't let us take advantage of OWL reasoning over the numbers. Instead use has measurment value property to represent the same. Use has measurement unit label (subproperty of has_part) so we can easily say that there is only one of them. a scalar measurement datum is a measurement datum that is composed of two parts, numerals and a unit label. directive information entity 2009-03-16: provenance: a term realizable information entity was proposed for OBI (OBI_0000337) , edited by the PlanAndPlannedProcess branch. Original definition was "is the specification of a process that can be concretized and realized by an actor" with alternative term "instruction".It has been subsequently moved to IAO where the objective for which the original term was defined was satisfied with the definitionof this, different, term. 2013-05-30 Alan Ruttenberg: What differentiates a directive information entity from an information concretization is that it can have concretizations that are either qualities or realizable entities. The concretizations that are realizable entities are created when an individual chooses to take up the direction, i.e. has the intention to (try to) realize it. 8/6/2009 Alan Ruttenberg: Changed label from "information entity about a realizable" after discussions at ICBO An information content entity whose concretizations indicate to their bearer how to realize them in a process. PERSON: Alan Ruttenberg PERSON: Bjoern Peters Werner pushed back on calling it realizable information entity as it isn't realizable. However this name isn't right either. An example would be a recipe. The realizable entity would be a plan, but the information entity isn't about the plan, it, once concretized, *is* the plan. -Alan measurement datum 2/2/2009 is_specified_output of some assay? A measurement datum is an information content entity that is a recording of the output of a measurement such as produced by a device. Examples of measurement data are the recoding of the weight of a mouse as {40,mass,"grams"}, the recording of an observation of the behavior of the mouse {,process,"agitated"}, the recording of the expression level of a gene as measured through the process of microarray experiment {3.4,luminosity,}. OBI_0000305 group:OBI measurement datum person:Chris Stoeckert planned process 'Plan' includes a future direction sense. That can be problematic if plans are changed during their execution. There are however implicit contingencies for protocols that an agent has in his mind that can be considered part of the plan, even if the agent didn't have them in mind before. Therefore, a planned process can diverge from what the agent would have said the plan was before executing it, by adjusting to problems encountered during execution (e.g. choosing another reagent with equivalent properties, if the originally planned one has run out.) 6/11/9: Edited at workshop. Used to include: is initiated by an agent Bjoern Peters Injecting mice with a vaccine in order to test its efficacy We are only considering successfully completed planned processes. A plan may be modified, and details added during execution. For a given planned process, the associated realized plan specification is the one encompassing all changes made during execution. This means that all processes in which an agent acts towards achieving some objectives is a planned process. branch derived planned process A processual entity that realizes a plan which is the concretization of a plan specification. This class merges the previously separated objective driven process and planned process, as they the separation proved hard to maintain. (1/22/09, branch call) planned process processed material Examples include gel matrices, filter paper, parafilm and buffer solutions, mass spectrometer, tissue samples Is a material entity that is created or changed during material processing. PERSON: Alan Ruttenberg processed material material to be added role 9 March 09 from discussion with PA branch OBI Role Branch drug added to a buffer contained in a tube; substance injected into an animal; material to be added role material to be added role is a protocol participant role realized by a material which is added into a material bearing the target of material addition role in a material addition process target of material addition role From Branch discussion with BP, AR, MC -- there is a need for the recipient to interact with the administered material. for example, a tooth receiving a filling was not considered to be a target role. GROUP: Role Branch OBI peritoneum of an animal receiving an interperitoneal injection; solution in a tube receiving additional material; location of absorbed material following a dermal application. target of material addition role target of material addition role is a role realized by an entity into which a material is added in a material addition process host role 30 Mar09 submitted by vaccine community 30Mar09 virus reproducing inside a cell; bacteria causing a disease, host can be harmed or not. we want to avoid a cat sitting on my lap and an animal care technician; these are not examples or hosts; dental cares = on tooth, but part of outer layer of tooth, so covered by "within" in the definition GROUP: Role Branch In biology, a host is an organism that harbors a virus or parasite, or a mutual or commensal symbiont, typically providing nourishment and shelter. http://en.wikipedia.org/wiki/Host_(biology) 30 March 09 OBI host role host role is a role played by an organism and realized by providing nourishment, shelter or a means of reproduction to another organism within the organism playing the host role http://en.wikipedia.org/wiki/Host_(biology) organism 10/21/09: This is a placeholder term, that should ideally be imported from the NCBI taxonomy, but the high level hierarchy there does not suit our needs (includes plasmids and 'other organisms') 13-02-2009: OBI doesn't take position as to when an organism starts or ends being an organism - e.g. sperm, foetus. This issue is outside the scope of OBI. GROUP: OBI Biomaterial Branch A material entity that is an individual living system, such as animal, plant, bacteria or virus, that is capable of replicating or reproducing, growth and maintenance in the right environment. An organism may be unicellular or made up, like humans, of many billions of cells divided into specialized tissues and organs. WEB: http://en.wikipedia.org/wiki/Organism animal fungus organism plant virus administering substance in vivo 2009-11-10. Tracker: https://sourceforge.net/tracker/?func=detail&aid=2893050&group_id=177891&atid=886178 A process by which a substance is intentionally given to an organism resulting in exposure of the organism to that substance. Balb/c mice received an intracameral or subconjunctival injection of trinitrophenylated spleen cells Person:Bjoern Peters Bjoern Peters Different routes and means of administration should go as children underneath this IEDB Update the definition based on the discussion. Details see the tracker: https://sourceforge.net/p/obi/obi-terms/738/ administering substance in vivo injecting mice with 10 ug morphine intranasally, a patient taking two pills of 1 mg aspirin orally needs roles such as perturber and perturbee (children of input role). Perturb is too strong. Host might be the name for one role. Others considered: Doner, Donated, Acceptor. genome WEB: http://en.wikipedia.org/wiki/Genome Book: Eugene Nester, Denise Anderson, C. Evans Roberts, Jr., Microbiology (Companion Site): A Human Perspective, 7th Edition. Mcgraw Hill, October 18, 2011. ISBN-13: 978-0073375311 A genome is a material entity that represents the entirety of an organism's hereditary information. The genome includes both the genes and the non-coding sequences of the DNA and RNA. Oliver He gene In addition to the coding regions (exons), a gene includes transcription-control regions and sometimes introns. Although the majority of genes encode proteins, some encode tRNAs, rRNAs, and other types of RNA. Oliver He WEB: http://www.ncbi.nlm.nih.gov/books/NBK21640/ A gene is a material entity that represents the entire DNA sequence required for synthesis of a functional protein or RNA molecule. gene disposition a disposition that a gene can be used as a blueprint for generating a new form of product such as protein. YH: According to NCBI Gene project, there are two gene types: unknown (0) , tRNA (1) , rRNA (2) , snRNA (3) , scRNA (4) , snoRNA (5) , protein-coding (6) , pseudo (7) , transposon (8) , miscRNA (9) , ncRNA (10) , other (255). Therefore, we have generated corresponding gene dispositions. Note that we don't use the term "gene type" here to differentiate the meanings of "type" and "disposition". Yongqun He WEB: http://www.ncbi.nlm.nih.gov/IEB/ToolBox/CPP_DOC/lxr/source/src/objects/entrezgene/entrezgene.asn frequency A physical quality which inheres in a bearer by virtue of the number of the bearer's repetitive actions in a particular time. frequency physical quality A quality of a single physical entity that exists through action of continuants at the physical level of organisation. physical quality quality of a single physical entity A physical object quality which inheres in a single-bearer. quality of a single physical entity physical object quality A quality which inheres in a continuant. physical object quality vaccine Many vaccines are developed to protect against infectious pathogens. Many vaccines are also being developed against some diseases such as cancer and autoimmune diseases. Vaccine is developed against a disease. Allergy. YH, BP, BS, MC, LC, XZ, RS A vaccine is a processed material with the function that when administered, it prevents or ameliorates a disorder in a target organism by inducing or modifying adaptive immune responses specific to the antigens in the vaccine. a role that inheres in a prepared material entity that is designed to induce protection or treament for a diease or infection in vivo. MeSH: D014612 vaccination YH, BP a process of administering substance in vivo that involves in adding a vaccine into a host (e.g., human) in vivo with the intent to invoke a protective or therapeutic adaptive immune response. vaccine administration vaccination frequency YH Vaccination frequency is a qualitative term that represents how many times vaccination has occurred. colony forming unit CFU YH WEB: http://en.wikipedia.org/wiki/Colony-forming_unit Colony-forming unit (CFU) is a titer measurement of viable bacterial or fungal numbers. Unlike in direct microscopic counts where all cells, dead and living, are counted, CFU measures viable cells. By convenience the results are given as CFU/mL (colony-forming units per milliliter) for water, and CFU/g (colony-forming units per gram) for soil or other porous material. vaccine function YH, MC, XZ, and AR PERSPN: Oliver He: There has been hot discussion about whether we use 'vaccine function' or 'vaccine role'. Vaccine role may not be the good term to use. Vaccine is designed to be 'vaccine', so it should be vaccine function. One special case is cowpox virus. The cowpox virus can be mixed with some liquid like water and used as a smallpox vaccine. In this case, people often say: the cowpox virus has a 'vaccine role'. However, the cowpox virus vaccine is a processed material of a mix of the virus with water. The virus is a virus, it is not a vaccine per se. Therefore, vaccine role may not be an accurate term. vaccine function is a function that inheres in a vaccine that induces protective immune response against a disease. It is realized in the immunization process in the host. preventive vaccine function preventive vaccine function is a vaccine function realized by the process of vaccination and leading to induction of an adaptive immune response to the antigens in a vaccine, which protects against a specific disorder. YH prophylactic vaccine function immunization WEB: http://en.wikipedia.org/wiki/Immunization immunization is a processual entity that primes or modifies an adaptivie immune response to some antigens. YH, XZ, BP active immunization WEB: http://en.wikipedia.org/wiki/Immunization Active immunization entails the introduction of a foreign molecule into the body, which causes the body itself to generate immunity against the target. This immunity comes from the T cells and the B cells with their antibodies. Active immunization can occur naturally when a person comes in contact with, for example, a microbe. If the person has not yet come into contact with the microbe and has no pre-made antibodies for defense (like in passive immunization), the person becomes immunized. The immune system will eventually create antibodies and other defenses against the microbe. The next time, the immune response against this microbe can be very efficient; this is the case in many of the childhood infections that a person only contracts once, but then is immune. Artificial active immunization is where the microbe, or parts of it, are injected into the person before they are able to take it in naturally. If whole microbes are used, they are pre-treated, Attenuated vaccine. (Wikipedia) Active immunization is an immunization process that entails the introduction of a foreign molecule into the body, which causes the body itself to generate adaptive immunity against the target. YH, XZ vaccine immunization YH, XZ WEB: http://en.wikipedia.org/wiki/Immunization artificial active immunization artificial active immunization is an active immunization that occurs when a person or animal is vaccinated with a specific vaccine. induction of adaptive immune response to antigen induction of adaptive immune response to antigen is an active immunization process that results in induction of adaptive immune response to some antigens, for example, in a vaccine. YH, XZ disorder prevention disorder prevention is a processual entity that prevents a disorder that is the physical basis of a disease. YH, XZ disorder treatment disorder treatment is a processual entity that leads to treat a disorder that is the physical basis of a disease. YH, XZ modification of adaptive immune response to antigen modification of adaptive immune response to antigen is an active immunization process that results in modification of an adaptive immune response to some antigens, for example, in a therapeutic vaccine. YH, XZ titer WEB:http://en.wikipedia.org/wiki/Titer A titer (or titre) is a measure of concentration. Titer testing employs serial dilution to obtain approximate quantitative information from an analytical procedure that inherently only evaluates as positive or negative. The titer corresponds to the highest dilution factor that still yields a positive reading; for example, positive readings in the first 8 serial twofold dilutions translate into a titer of 1:256. YH therapeutic vaccine function YH The therapeutic vaccine function is a function realized by the process of vaccination and leading to induction of an adaptive immune response to the antigens in a vaccine, which ameliorates a specific disorder. immunization objective WEB: http://en.wikipedia.org/wiki/Immunization YH, XZ immunization objective is the specification of an objective to achieve immunization. vaccine preparation vaccine production YH, BP vaccine preparation is a manufacturing process to produce a vaccine. vaccine generation vaccination dose vaccination dose is a dose of vaccine that is used in a vaccination. Vaccination dose may be and may be not the same as the vaccine dose. YH dose dose is a measurement data that measures the quantity of something that may be eaten by or administered to an organism, or that an organism may be exposed to. Quantities of nutrients, drugs, vaccines and toxins are referred to as doses. WEB: http://en.wikipedia.org/wiki/Dose_%28biochemistry%29 YH, MC challenge dose challenge dose is a dose of a virulent pathogen used for a vaccine challenge process. YH reduction of colony forming unit reduction of colony-forming unit (CFU) is a titer measurement of viable bacterial or fungal numbers. It equals to a reduction of a CFU count from another CFU count. This term is often used as a measurement of a vaccine protection study. YH, ZX vaccine strain datum Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. a measurement datum that represents a vaccine strain. Different strains can be represented using distinct digital numbers. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf YH vaccine viability datum Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. YH a measurement datum that represents vaccine viability. 0 = live; 1 = irradiated; 2 = killed. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf vaccine adjuvant usage datum a measurement datum that indicates the usage of a vaccine adjuvant. Different digital numbers can be used to represent different adjuvants. Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. YH He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf vaccine protective antigen datum Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. YH a measurement datum that represents a specific protective antigen used in a vaccine. The antigen can be represented by a described digit. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf mutated gene in vaccine strain datum a measurement datum that represents a specific mutated gene from a vaccine strain. The mutated can be represented by a described digit. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. YH vaccination mouse strain datum Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. YH He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf a measurement datum that represents a specific mouse strain used for vaccination. Different strains can be represented using discretized digitals. For example, 0 = BALB/c; 1 = CD1; 2 = mixed/outbred; 3 = C57BL/6; 4 = OF1; 5 = 129/Sv; 6 = Swiss albino. biological sex datum Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. A measurement datum that represents the biological sex of an animal. The result can be represented using a discretized digit, for example, 0 = female; 1 = male; 2 = unknown. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf YH vaccination route datum He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf YH a measurement datum that represents a specific route (e.g., i.p.) used for vaccination. Different routes can be represented using discretized digitals. 0 = IP; 1 = PO; 2 = SC; 3 = IM; 4 = IN; 6 = IG; 7 = IV; 8 = ID. Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. vaccination dose (unit: CFU) a vaccination dose that is used with the unit of colony forming units (CFU). Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf YH animal age at vaccination in days YH A measurement datum that represents the animal age (unit: day) at the time of vaccination. Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf pathogen strain for challenge datum a measurement datum that represents a specific pathogen strain used for animal challenge study. Different pathogen strains can be represented using discretized digitals. YH He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. pathogen challenge datum He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf a measurement datum that represents a specific pathogen used for animal challenge study. Different pathogens can be represented using discretized digitals. YH Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. challenge dose (unit: CFU) a challenge dose that is represented with the unit of colony forming units (CFU). He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf YH Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. vaccination-challenge interval in days a measurement datum that represents a length of days as the interval between a vaccination and a challenge in a specific vaccine protection study. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. YH CFU per spleen A colony forming unit (CFU) from the sample of mouse spleen. YH Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf CFU reduction per spleen Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf YH a reduction of CFU that was measured with the unit of colony forming units (CFU) from the sample of mouse spleen. vaccine protection efficacy datum YH Todd TE, Tibi O, Lin Y, Sayers S, Bronner DN, Xiang Z, He Y. Meta-analysis of variables affecting mouse protection efficacy of whole organism Brucella vaccines and vaccine candidates. BMC Bioinformatics. 2013, 14(Suppl 6):S3. PMID: 23735014. PMCID: PMC3633026. He Y, Xiang Z, Todd T, Courtot M, Brinkman R, Zheng J, Stoeckert CJ, Malone J, Rocca-Serra P, Sansone S, Fostel J, Soldatova LN, Peters B, Rutternberg A. Ontology representation and ANOVA analysis of vaccine protection investigation. Proceeding of Bio-Ontologies 2010: Semantic Applications in Life Sciences, ISMB, July 9-10, 2010. Boston, MA, USA. Full length paper. URL: http://www.hegroup.org/docs/ANOVA_Vaccine_usecase_camera.pdf a measurement datum that represents a type of vaccine protection efficacy as an outcome of a vaccine protection study. The result can be represented as a digit, for example, 0 = no protection, and 1 = protection (determined by a p-value cutoff). vaccine host role YH, ZX a role of host that contains vaccine. It is a role that inheres in an organism that is the target of a vaccine administration (vaccination process). vaccine target specification The objective that intends to produce vaccine via the vaccine preparation process. YH Alexander D. Diehl An ontology in the domain of vaccine and vaccination Ryan R. Brinkman Rebecca Racz Thomas Todd Chris mungall Alan Ruttenburg Omar Tibi Barry Smith Jason Hu Bjoern Peters Edison Ong Samantha G. Sayers (SGS) en Richard H. Scheuermann Melanie Courtot Erica Marcos Ningxian Fan Lindsay Cowell April 1, 2018 Ningxian Fan OWL-DL Ronak Sutariya Shunzhou Deng The Vaccine Ontology (VO) is a biomedical ontology in the domain of vaccine and vaccination. VO aims to standardize vaccine annotation, integrate various vaccine data, and support computer-assisted reasoning. VO supports basic vaccine R&D and clincal vaccine usage. VO is initiated and primarily developed by Dr. Yongqun "Oliver" He at the University of Michigan Medical School. VO is being developed as a community-based ontology with support and collaborations from the vaccine and bio-ontology communities. Vaccine Ontology Vision Release; 1.0.799 Yongqun "Oliver" He (YH) Yu Lin (YL) Zuoshuang "Allen" Xiang 12-01-2016 Bin Zhao A biological ontology in the area of genes and genomes. OGG is a biological ontology in the area of genes and genomes. OGG uses the Basic Formal Ontology (BFO) as its upper level ontology. This OGG document contains the genes and genomes of a list of selected organisms, including human, two viruses (HIV and influenza virus), and bacteria (B. melitensis strain 16M, E. coli strain K-12 substrain MG1655, M. tuberculosis strain H37Rv, and P. aeruginosa strain PAO1). More OGG information for other organisms (e.g., mouse, zebrafish, fruit fly, yeast, etc.) may be found in other OGG subsets. OGG: Ontology of Genes and Genomes OWL-DL Vision Release: 1.0.59 Yongqun "Oliver" He (YH) Yue Liu