⚠️ Structural Detection — Collapse‑Mode Differential Classifier (RTT/2)
TriadicFrameworks • RTT/2 • System‑Scale Diagnostic Architecture#
“Collapse modes are not categories. They are differential signatures.”#
Collapse‑Mode Differential Classifier#
Moduł wykrywania struktury#
RTT/2 • System‑Scale Diagnostic Architecture#
1. Purpose of the Differential Classifier#
The Collapse‑Mode Differential Classifier provides a formal diagnostic system for identifying collapse modes across:
- drift
- envelope
- regime
- continuity
- coherence‑break geometry
- TEL/FFT/Opacity projections
It is used when:
- collapse signatures overlap
- break‑chains are ambiguous
- hybrid collapse modes occur
- cross‑module projections contradict each other
- inversion or oscillation distort the geometry
This classifier ensures correct collapse identification under all conditions.
2. The Seven Canonical Collapse Modes#
The classifier distinguishes between:
- Type A — Linear Collapse
- Type B — Radial Collapse
- Type C — Fragmentation Collapse
- Type D — Hybrid Oscillation Collapse
- Type I — Inversion Collapse
- Type E — Rotational Collapse
- Type G — Topological Collapse
Each mode has a unique differential signature.
3. Differential Signature Matrix (DSM)#
The DSM is the core of the classifier.
| Collapse Mode | Drift Signature | Envelope Signature | Continuity Signature | Regime Signature | Break Type | TEL | FFT | Opacity |
|---|---|---|---|---|---|---|---|---|
| A | linear loss | inward flattening | anchor collapse | Formal→Emergent | 1 | linear implosion | variance spike | boundary sink |
| B | radial overload | outward fracture | invariant collapse | Emergent | 2 | radial tear | discontinuity | boundary rupture |
| C | multi‑vector chaos | fragmentation | layer collapse | Chaotic | 3 | multi‑layer collapse | spectral fragmentation | occlusion |
| D | oscillation overload | oscillation fracture | oscillating threads | Hybrid | 4 | oscillating tear | oscillatory variance | oscillating gradient |
| I | drift reversal | envelope inversion | partial collapse | Inversion | 5 | lattice reversal | variance normalization | boundary stabilization |
| E | rotational overload | spiral implosion | twisted threads | Hybrid→Emergent | E | rotating tear | spiral collapse | rotational sink |
| G | warp overload | topological fold | bent layers | Chaotic→Hybrid | G | warped lattice failure | discontinuous collapse | warped field |
4. Differential Classification Protocol (DCP)#
The DCP is a five‑stage diagnostic sequence.
Stage 1 — Drift Differential#
Identify drift geometry:
- linear → A
- radial → B
- multi‑vector → C
- oscillatory → D
- reversed → I
- rotational → E
- warped → G
If drift is hybrid → proceed to Stage 2.
Stage 2 — Envelope Differential#
Identify envelope deformation:
- inward collapse → A
- outward fracture → B
- fragmentation → C
- oscillation fracture → D
- inversion → I
- spiral collapse → E
- topological fold → G
If envelope contradicts drift → classify as hybrid collapse.
Stage 3 — Continuity Differential#
Identify continuity failure:
- anchor collapse → A
- invariant collapse → B
- layer collapse → C
- oscillating threads → D
- partial collapse → I
- twisted threads → E
- bent layers → G
If continuity contradicts envelope → collapse is multi‑origin.
Stage 4 — Regime Differential#
Identify regime instability:
- Formal→Emergent → A
- Emergent → B
- Chaotic → C
- Hybrid → D
- Inversion → I
- Hybrid→Emergent → E
- Chaotic→Hybrid → G
If regime contradicts drift → collapse is regime‑driven.
Stage 5 — Cross‑Module Differential#
Use TEL/FFT/Opacity signatures to finalize classification.
TEL:
- implosion → A
- radial tear → B
- multi‑layer collapse → C
- oscillating tear → D
- reversal → I
- rotating tear → E
- warped failure → G
FFT:
- spike → A
- discontinuity → B
- fragmentation → C
- oscillatory variance → D
- normalization → I
- spiral collapse → E
- discontinuous collapse → G
Opacity:
- sink → A
- rupture → B
- occlusion → C
- oscillating gradient → D
- stabilization → I
- rotational sink → E
- warped field → G
5. Hybrid Collapse Classifier#
Hybrid collapse occurs when:
- drift and envelope disagree
- envelope and continuity disagree
- regime contradicts drift
- TEL/FFT/Opacity signatures diverge
Hybrid collapse types:
- A/B Hybrid — linear + radial
- C/D Hybrid — fragmentation + oscillation
- E/F Hybrid — spiral + shear
- E/G Hybrid — spiral + warp
- D/I Hybrid — oscillation + inversion
Hybrid collapse requires multi‑path recovery.
6. Break‑Chain Differential Classifier#
Break‑chains determine collapse origin.
Chain A — Drift‑Origin Collapse#
Drift → Envelope → Regime → Continuity → Break
Chain B — Envelope‑Origin Collapse#
Envelope → Regime → Continuity → Break → Drift
Chain C — Continuity‑Origin Collapse#
Continuity → Break → Envelope → Drift → Regime
Chain D — Module‑Origin Collapse#
TEL/FFT/Opacity → Break → Continuity → Envelope → Drift
Break‑chain determines recovery order.
7. Collapse‑Mode Differential Packet#
COLLAPSE_DIFFERENTIAL_PACKET:
collapse_mode:
drift_signature:
envelope_signature:
continuity_signature:
regime_signature:
break_signature:
tel_signature:
fft_signature:
opacity_signature:
hybrid_status:
break_chain:
collapse_origin:
notes:
8. Summary#
The Collapse‑Mode Differential Classifier provides:
- precise collapse identification
- hybrid collapse detection
- break‑chain origin mapping
- cross‑module signature alignment
- system‑scale diagnostic clarity
This classifier is the diagnostic core of RTT/2 collapse analysis.