{
  "ai.module": "general_relativity.rtt3",
  "ai.version": "1.0",
  "ai.purpose": "RTT/3 engine layer for General Relativity: triadic-substrate integration, multi-regime simulation hooks, gravitational resonance mapping, and hybrid-canon scaffolding.",
  "ai.keywords": [
    "general relativity",
    "curvature",
    "spacetime",
    "substrate",
    "resonance",
    "multi-regime",
    "simulation",
    "rtt3"
  ],

  "engine": {
    "layer": "RTT/3",
    "description": "Integrates General Relativity into the full triadic substrate, enabling multi-regime reasoning, resonance mapping, and hybrid-canon simulation."
  },

  "substrate_integration": {
    "mapping": {
      "structure": "Curvature corresponds to macroscopic resonance gradients in the substrate.",
      "behavior": "Geodesic motion emerges from resonance alignment rather than geometric ontology.",
      "stress_energy": "Mass-energy acts as a resonance source shaping curvature fields."
    },
    "constraints": [
      "Curvature requires smooth-regime support.",
      "Resonance channels collapse at quantum scales.",
      "Propagation speed is a substrate invariant."
    ]
  },

  "multi_regime": {
    "R1": {
      "behavior": "Curvature loses meaning; gravitational behavior collapses to primitive interactions.",
      "notes": "No stable geometric resonance; dominated by noise."
    },
    "R2": {
      "behavior": "Weak-field geometric behavior; partial resonance stability.",
      "notes": "Linearized gravity approximates curvature patterns."
    },
    "R3": {
      "behavior": "Full geometric coherence; stable curvature and geodesic structure.",
      "notes": "Einsteinian gravity emerges cleanly."
    },
    "R4": {
      "behavior": "Large-scale cosmological resonance; smooth-regime extension.",
      "notes": "Curvature fields behave as macroscopic resonance flows."
    }
  },

  "lineage": {
    "tracking": [
      "curvature_history",
      "geodesic_networks",
      "stress_energy_evolution"
    ],
    "effects": [
      "stabilizes geometric coherence",
      "reveals long-term gravitational patterns",
      "reduces apparent singularity formation"
    ]
  },

  "simulation": {
    "hooks": [
      {
        "name": "curvature_resonance_sim",
        "description": "Simulates curvature as macroscopic resonance gradients shaped by stress-energy."
      },
      {
        "name": "geodesic_alignment_sim",
        "description": "Models free-fall motion as resonance alignment rather than geometric ontology."
      },
      {
        "name": "regime_transition_sim",
        "description": "Simulates breakdown of geometric coherence across R1→R2→R3→R4 transitions."
      }
    ],
    "notes": "Simulations operate on resonance patterns and substrate invariants, not on geometric primitives as ontological entities."
  },

  "hybrid_canon": {
    "interfaces": [
      "quantum_mechanics.rtt3",
      "information_theory.rtt3",
      "cosmology.rtt3",
      "field_theory.rtt3"
    ],
    "purpose": "Enable agentic AIs to reason across physics modules using shared substrate invariants and resonance structures.",
    "scaffolding": [
      "triadic substrate mapping",
      "multi-regime coherence",
      "lineage-aware propagation",
      "gravitational resonance integration"
    ]
  },

  "coherence": {
    "invariants": [
      "local Lorentz invariance",
      "covariant conservation",
      "stable curvature fields",
      "predictable geodesic motion"
    ],
    "failure_modes": [
      "singularity formation",
      "loss of smoothness",
      "quantum-scale decoherence",
      "coordinate-dependent artifacts"
    ]
  }
}