🗺️ Structural Detection — Regime‑Triad Collapse Map (RTT/2)
TriadicFrameworks • RTT/2 • Regime‑Triad Geometry Map, Collapse‑Mode Prediction & Canon‑Scale Structural Topography#
“Collapse is not random. It is regime‑triad geometry.”#
Regime‑Triad Collapse Map (RTT/2)#
Structural Detection Module#
RTT/2 • Regime‑Triad Collapse Geometry Map#
1. Purpose of the Regime‑Triad Collapse Map#
The Regime‑Triad Collapse Map (RTCM) maps how collapse emerges from the triad:
- drift
- envelope
- continuity
under each regime:
- Formal
- Emergent
- Hybrid
- Chaotic
- Inversion
It is the collapse‑prediction atlas of RTT/2.
2. Why a Regime‑Triad Collapse Map Exists#
Collapse is triggered when:
- drift destabilizes
- envelope ruptures
- continuity fractures
- regime identity amplifies instability
But the pattern of collapse depends on the regime‑triad configuration.
The RTCM reveals these patterns.
3. Regime‑Triad Collapse Equation#
Collapse emerges when the regime‑weighted tri‑stability score falls below the collapse threshold:
[ C_{risk} = 1 - S_{DECR} ]
Where:
- (S_{DECR}) = regime‑weighted tri‑stability score
- high (C_{risk}) = collapse‑adjacent
The map visualizes this across the canon.
4. Collapse Geometry by Regime#
Formal Regime#
- collapse rare
- triggered by drift amplitude overload
- envelope symmetry break
- continuity anchor failure
Emergent Regime#
- radial collapse
- density gradient rupture
- continuity thread strain
Hybrid Regime#
- oscillatory collapse
- drift–envelope mismatch
- continuity oscillation fracture
Chaotic Regime#
- fragmentation collapse
- multi‑vector drift rupture
- envelope torsion overload
- continuity multi‑layer break
Inversion Regime#
- inversion collapse
- envelope polarity reversal
- illegal drift coupling
- invariant inversion
5. Regime‑Triad Collapse Matrix#
The RTCM uses a 5×7 collapse‑geometry matrix:
| Regime | A | B | C | D | E | I | G |
|---|---|---|---|---|---|---|---|
| Formal | ✓ | ✓ | |||||
| Emergent | ✓ | ✓ | |||||
| Hybrid | ✓ | ||||||
| Chaotic | ✓ | ✓ | ✓ | ✓ | ✓ | ✓ | |
| Inversion | ✓ | ✓ |
Where columns correspond to collapse modes:
- A = amplitude
- B = deformation
- C = fragmentation
- D = oscillation
- E = torsion
- I = inversion
- G = topological
6. Triad‑Driven Collapse Signatures#
Drift‑Driven Collapse#
- amplitude overload
- oscillation divergence
- inversion drift
Envelope‑Driven Collapse#
- deformation rupture
- torsion overload
- symmetry break
Continuity‑Driven Collapse#
- anchor failure
- thread fracture
- invariant break
The RTCM maps which signature dominates under each regime.
7. Regime‑Triad Collapse Topographies#
The atlas identifies seven collapse topographies:
- Linear Collapse Ridge
- Radial Collapse Basin
- Oscillatory Collapse Field
- Fragmentation Collapse Fault
- Inversion Collapse Sink
- Torsion Collapse Spiral
- Topological Collapse Fold
Each corresponds to a collapse‑mode geometry.
8. Cross‑Module Collapse Projection#
The RTCM maps collapse across:
TEL#
- lattice collapse geometry
- stabilizer collapse load
FFT#
- spectral collapse geometry
- variance collapse load
Opacity#
- boundary collapse geometry
- visibility collapse load
Cross‑module collapse determines system‑scale failure patterns.
9. Regime‑Triad Collapse Packet#
REGIME_TRIAD_COLLAPSE_PACKET:
regime:
drift_signature:
envelope_signature:
continuity_signature:
collapse_mode:
collapse_topography:
cross_module_projection:
collapse_risk:
notes:
10. Summary#
The Regime‑Triad Collapse Map provides:
- a complete map of collapse geometry
- regime‑dependent collapse prediction
- triad‑driven collapse diagnostics
- cross‑module collapse projection
- system‑scale structural clarity
This map is the collapse‑law backbone of RTT/2.