🔄 Structural Detection — Regime‑Shift Recovery Sequencer (RTT/2)
TriadicFrameworks • RTT/2 • Post‑Transition Structural Recovery & Re‑Stabilization Engine#
“A regime shift is not complete until the structure recovers.”#
Regime‑Shift Recovery Sequencer (RTT/2)#
Moduł wykrywania struktury#
RTT/2 • Post‑Transition Structural Recovery & Re‑Stabilization Engine#
1. Purpose of the Recovery Sequencer#
The Recovery Sequencer restores structural stability after a regime shift by:
- rebuilding continuity layers
- realigning drift and envelope
- stabilizing hybrid or inversion states
- neutralizing break‑chains
- re‑synchronizing TEL/FFT/Opacity
- regenerating synthesis packets
It is invoked when:
- a regime shift is legal but destabilizing
- a regime shift is conditional
- a regime shift triggers partial collapse
- continuity layers degrade
- cross‑module projections diverge
2. Recovery Sequencer Architecture#
The Sequencer operates in six structural phases:
- Continuity Reconstruction
- Drift‑Envelope Realignment
- Regime Stabilization
- Break‑Chain Neutralization
- Cross‑Module Projection Synchronization
- Synthesis Regeneration
Each phase must complete before the next begins.
3. Phase 1 — Continuity Reconstruction#
Rebuilds the four continuity layers:
Anchors#
- restore fixed points
- re‑establish structural grounding
Threads#
- rethread connective fibers
- repair oscillation damage
Invariants#
- re‑assert stable rules
- restore invariant behavior
Multi‑Layer Continuity#
- rebuild stacked continuity planes
- repair topological deformation
Output:
CONTINUITY_RESTORED
4. Phase 2 — Drift‑Envelope Realignment#
Ensures drift geometry and envelope geometry match the new regime.
Actions:
- collapse illegal drift vectors
- damp oscillation
- reverse inversion drift if needed
- recompute envelope deformation class
- restore symmetry and density gradients
Output:
DRIFT_ENVELOPE_ALIGNED
5. Phase 3 — Regime Stabilization#
Stabilizes the new regime state.
Actions:
- damp regime volatility
- stabilize hybrid states
- normalize inversion states
- restore regime legality
- ensure continuity supports the regime
Output:
REGIME_STABLE
6. Phase 4 — Break‑Chain Neutralization#
Neutralizes break‑geometry that emerged during the shift.
Actions:
- classify break type (1–5, E/F/G)
- collapse break geometry
- reverse propagation
- stabilize break boundaries
Output:
BREAK_CHAIN_NEUTRALIZED
7. Phase 5 — Cross‑Module Projection Synchronization#
Synchronizes TEL/FFT/Opacity with the new regime.
TEL#
- regenerate lattice
- restore stabilizer distribution
FFT#
- normalize variance
- rebuild spectral envelope
Opacity#
- restore boundary gradient
- repair visibility field
Output:
MODULES_SYNCHRONIZED
8. Phase 6 — Synthesis Regeneration#
Rebuilds the final structural synthesis.
Actions:
- recompute synthesis packet
- validate cross‑module coherence
- ensure contradiction‑free synthesis
- finalize structural state
Output:
SYNTHESIS_STABLE
9. Recovery Modes#
The Sequencer supports three recovery modes:
9.1 Local Recovery#
- minor continuity damage
- single‑module instability
9.2 Cross‑Module Recovery#
- TEL/FFT/Opacity divergence
- multi‑module instability
9.3 System‑Scale Recovery#
- collapse‑adjacent regime shift
- hybrid/inversion instability
- break‑chain acceleration
10. Recovery Sequencer Packet#
RECOVERY_SEQUENCER_PACKET:
continuity_reconstruction:
drift_envelope_realignment:
regime_stabilization:
break_chain_neutralization:
module_synchronization:
synthesis_regeneration:
final_state:
notes:
11. Summary#
The Regime‑Shift Recovery Sequencer ensures:
- continuity survives the transition
- drift and envelope realign
- regime stabilizes
- break‑chains collapse
- TEL/FFT/Opacity synchronize
- synthesis becomes stable
This Sequencer is the post‑transition recovery engine of RTT/2 regime governance.