🧭 Structural Detection — Regime‑Continuity Stability Ledger (RTT/2)
TriadicFrameworks • RTT/2 • Regime–Continuity Coupling Ledger, Stability Diagnostics & Transition Integrity Map#
“Regimes shift. Continuity holds. The ledger remembers how.”#
Regime‑Continuity Stability Ledger (RTT/2)#
Structural Detection Module#
RTT/2 • Regime–Continuity Coupling & Stability Ledger#
1. Purpose of the Stability Ledger#
The Regime‑Continuity Stability Ledger (RCSL) records the structural relationship between:
- regime identity
- continuity layers
- continuity stress
- continuity stability
- regime‑dependent continuity behavior
It is the canonical ledger that tracks how continuity responds to regime dynamics.
2. Why Regime–Continuity Stability Matters#
Regimes define:
- drift geometry
- envelope geometry
- volatility
- collapse‑adjacent behavior
Continuity defines:
- structural memory
- stability
- invariants
- multi‑layer support
Their interaction determines:
- transition safety
- collapse‑risk
- structural integrity
3. Regime‑Continuity Interaction Model#
Each regime interacts with continuity differently:
Formal Regime#
- high continuity stability
- low stress
- strong anchor support
Emergent Regime#
- moderate continuity stress
- radial continuity deformation
- thread elasticity required
Hybrid Regime#
- oscillatory continuity stress
- mixed anchor/thread load
- invariant strain
Chaotic Regime#
- extreme continuity stress
- thread fracture risk
- invariant overload
Inversion Regime#
- negative continuity coupling
- anchor polarity reversal
- invariant inversion
These behaviors are logged in the ledger.
4. Continuity Layers Tracked#
The RCSL tracks four continuity layers:
- Anchors
- Threads
- Invariants
- Multi‑Layer Continuity
Each layer has a regime‑dependent stability profile.
5. Regime‑Continuity Stability Matrix#
The ledger uses a 5×4 stability matrix:
[ M_{RC} = \begin{bmatrix} S_{FA} & S_{FT} & S_{FI} & S_{FM} \ S_{EA} & S_{ET} & S_{EI} & S_{EM} \ S_{HA} & S_{HT} & S_{HI} & S_{HM} \ S_{CA} & S_{CT} & S_{CI} & S_{CM} \ S_{IA} & S_{IT} & S_{II} & S_{IM} \end{bmatrix} ]
Where:
- rows = regimes
- columns = continuity layers
- (S_{xy}) = stability coefficient
6. Stability Coefficient Interpretation#
High Stability (0.8–1.0)#
- continuity fully supports regime
- low collapse‑risk
Moderate Stability (0.5–0.79)#
- continuity under load
- harmonization required
Low Stability (0.2–0.49)#
- continuity strain
- collapse‑adjacent
Negative Stability (<0.2)#
- continuity inversion
- collapse‑triggering
7. Regime‑Continuity Failure Modes#
| Failure Type | Collapse Mode |
|---|---|
| anchor overload | Type A |
| thread fracture | Type C |
| invariant break | Type G |
| oscillation overload | Type D |
| inversion coupling | Type I |
These are logged automatically.
8. Cross‑Module Continuity Projection#
The ledger records continuity behavior across:
TEL#
- lattice continuity
- stabilizer continuity
FFT#
- spectral continuity
- variance continuity
Opacity#
- boundary continuity
- visibility continuity
Cross‑module continuity determines system‑scale stability.
9. Regime‑Continuity Stability Packet#
REGIME_CONTINUITY_PACKET:
regime:
continuity_anchor_stability:
continuity_thread_stability:
continuity_invariant_stability:
continuity_multilayer_stability:
stability_coefficients:
failure_modes:
cross_module_projection:
collapse_risk:
notes:
10. Summary#
The Regime‑Continuity Stability Ledger provides:
- a canonical record of regime–continuity behavior
- stability coefficients for all continuity layers
- regime‑dependent continuity diagnostics
- collapse‑adjacent failure detection
- cross‑module continuity projection
- system‑scale structural clarity
This ledger is the continuity‑law backbone of RTT/2.