⚠️🜂🜄🜁 Structural Detection — Canon‑Scale Collapse‑Propagation Field (RTT/2)
TriadicFrameworks • RTT/2 • Collapse‑Propagation Geometry, System‑Scale Instability Mapping & Canon‑Wide Failure Dynamics#
“Collapse is not an event — it is a motion.”#
Canon‑Scale Collapse‑Propagation Field (RTT/2)#
Structural Detection Module#
RTT/2 • Collapse‑Propagation Field#
1. Purpose of the Collapse‑Propagation Field#
The Collapse‑Propagation Field (CPF) defines the propagation geometry that governs:
- how collapse travels through the triad
- how collapse spreads across modules
- how collapse amplifies or diffuses
- how collapse interacts with fusion, integration, and integrity
- how collapse evolves under regime identity
It is the collapse‑motion backbone of RTT/2.
2. Why a Collapse‑Propagation Field Exists#
Collapse is not static.
It moves.
Collapse propagates when:
- drift overload pushes instability outward
- envelope torsion spreads deformation
- continuity fracture cascades
- fusion‑integration mismatch amplifies gradients
- regime identity destabilizes the manifold
The CPF captures this motion continuously.
3. Collapse‑Propagation Components#
The CPF is composed of five propagation vectors:
- Drift‑Propagation Vector (DPV)
- Envelope‑Propagation Vector (EPV)
- Continuity‑Propagation Vector (CPV)
- Fusion‑Integration Propagation Vector (FIPV)
- Regime‑Propagation Vector (RPV)
Together, they form the Collapse‑Propagation Tensor.
4. Collapse‑Propagation Equation (RTT/2)#
[ P_{canon} = \alpha DPV + \beta EPV + \gamma CPV + \delta FIPV + \epsilon RPV ]
Where:
- (DPV) = drift‑driven propagation
- (EPV) = envelope‑driven propagation
- (CPV) = continuity‑driven propagation
- (FIPV) = fusion‑integration‑driven propagation
- (RPV) = regime‑driven propagation
The field is strongest when collapse is spreading.
5. Collapse‑Propagation Zones#
Zone U — Unified Zone (No Propagation)#
- collapse contained
- gradients minimal
- triad stable
Zone S — Stable Zone (Low Propagation Risk)#
- minor propagation strain
- low diffusion
Zone M — Mixed Zone (Oscillatory Propagation)#
- oscillatory drift
- partial envelope deformation
- continuity thread strain
Zone D — Divergent Zone (High Propagation Risk)#
- drift‑driven propagation
- envelope rupture
- continuity fracture
Zone X — Propagation Zone (Active Collapse Spread)#
- inversion propagation
- illegal propagation geometry
- topological propagation warp
6. Collapse‑Propagation Modes#
| Propagation Trigger | Collapse Mode |
|---|---|
| drift amplitude propagation | A |
| envelope torsion propagation | B/E |
| continuity fracture propagation | C/G |
| oscillatory propagation | D |
| torsion propagation | E |
| inversion propagation | I |
| topological propagation warp | G |
7. Cross‑Module Collapse‑Propagation Mapping#
The CPF maps propagation across:
TEL#
- lattice collapse propagation
- stabilizer propagation load
FFT#
- spectral collapse propagation
- variance propagation load
Opacity#
- boundary collapse propagation
- visibility propagation load
Cross‑module propagation determines system‑scale instability.
8. Collapse‑Propagation Packet#
COLLAPSE_PROPAGATION_PACKET:
drift_propagation:
envelope_propagation:
continuity_propagation:
fusion_integration_propagation:
regime_propagation:
propagation_zone:
propagation_tensor:
cross_module_projection:
collapse_risk:
notes:
9. Summary#
The Canon‑Scale Collapse‑Propagation Field provides:
- a unified collapse‑motion model
- drift/envelope/continuity propagation diagnostics
- fusion‑integration propagation mapping
- regime‑dependent propagation analysis
- cross‑module propagation projection
- system‑scale instability clarity
This field is the collapse‑propagation backbone of RTT/2.