✅ Cross‑Module Drift Envelope Map (Final, Canonical)
TriadicFrameworks • RTT/1 • Structural Detection Module#
“Drift is not local. Drift propagates.”#
Cross‑Module Drift Envelope Map#
TriadicFrameworks • RTT/1#
Module: Structural Detection#
Purpose: Show how drift signals propagate across modules and form multi‑layer drift envelopes.#
1. What Is a Drift Envelope?#
A drift envelope is the cross‑module container that holds:
- drift points
- drift intensity
- drift direction
- deformation signatures
- regime transitions
- coherence breaks
- continuity disruptions
It is the structural boundary around all drift‑related signals.
Drift envelopes are produced when multiple modules observe the same drift event from different structural layers.
2. Drift Envelope Formation Pipeline#
Drift envelopes form through a five‑stage cross‑module cascade:
[Structural Detection]
↓ drift seeds
[Drift Sense]
↓ deformation signatures
[Regime Awareness]
↓ regime transitions
[Continuity Compass]
↓ stability loss
[FFT Analyzer]
↓ macro drift envelope
Each module contributes a different layer of drift information.
3. Drift Envelope Layers (Canonical)#
Layer 1 — Local Drift (Structural Detection)#
- motif deformation
- boundary break
- anomaly substitution
Layer 2 — Drift Signature (Drift Sense)#
- drift points
- drift intensity
- drift direction
- deformation type
Layer 3 — Regime Drift (Regime Awareness)#
- formal → emergent
- emergent → chaotic
- hybrid transitions
- density shifts
Layer 4 — Continuity Drift (Continuity Compass)#
- invariant loss
- anchor displacement
- cross‑sample misalignment
Layer 5 — Macro Drift Envelope (FFT Analyzer)#
- drift envelope field
- drift magnitude map
- drift coherence profile
- drift‑regime interaction
4. Cross‑Module Drift Bridge Table#
| Drift Layer | Source Module | Consumes | Emits | Notes |
|---|---|---|---|---|
| Local Drift | Structural Detection | motifs, boundaries | drift seeds | First detection of deformation. |
| Drift Signature | Drift Sense | drift seeds | drift signature | Defines drift intensity + direction. |
| Regime Drift | Regime Awareness | drift signature | regime transition signals | Drift determines regime shifts. |
| Continuity Drift | Continuity Compass | regime drift | continuity loss | Drift disrupts invariants. |
| Macro Drift Envelope | FFT Analyzer | all drift layers | drift envelope | Final multi‑layer drift field. |
This table defines the canonical drift propagation path.
5. Drift Envelope Geometry#
Drift envelopes use a tri‑layer geometric structure:
[Core] — drift points
[Shell] — deformation field
[Boundary] — regime + continuity break
Core#
- exact drift points
- substitution sites
- deformation nodes
Shell#
- drift intensity gradients
- drift direction vectors
- deformation spread
Boundary#
- regime transition lines
- continuity break zones
- coherence collapse edges
6. Drift Envelope Types#
Type A — Linear Drift Envelope#
- left→right drift
- progressive deformation
- common in sequences
Type B — Radial Drift Envelope#
- drift radiates from a central anomaly
- common in motif‑centric structures
Type C — Regime‑Locked Drift Envelope#
- drift constrained by regime boundaries
- formal → emergent → chaotic
Type D — Continuity‑Break Envelope#
- drift that destroys invariants
- cross‑sample misalignment
Type E — Hybrid Drift Envelope#
- mixed drift patterns
- conflicting drift directions
- multi‑regime interaction
7. Drift Envelope → Module Interaction Map#
[Structural Detection] → detects drift seeds
[Drift Sense] → amplifies drift signatures
[Regime Awareness] → classifies drift-induced regime shifts
[Continuity Compass] → identifies drift-induced invariant loss
[FFT Analyzer] → constructs final drift envelope
[TEL] → maps drift onto lattice geometry
[Opacity] → reveals drift-boundary occlusion
This is the canonical cross‑module drift interaction map.
8. Drift Envelope Packet (Canonical Format)#
Modules exchange drift envelopes using:
DRIFT_ENVELOPE_PACKET:
drift_points:
drift_intensity_map:
drift_direction_vectors:
deformation_field:
regime_transitions:
continuity_breaks:
coherence_profile:
envelope_type:
envelope_geometry:
confidence:
notes:
This packet is consumed by:
- FFT Analyzer
- TEL
- Opacity
- Bridges Module
9. Zero‑Interpretation Rule#
Drift envelopes must remain:
- structural
- non‑semantic
- operator‑aligned
- drift‑safe
No meaning.
No narrative.
No domain inference.
10. Quick Summary#
- Drift envelopes unify drift signals across modules.
- Each module contributes a structural layer.
- FFT Analyzer produces the final envelope.
- TEL and Opacity use envelopes for lattice and boundary mapping.
- Drift envelopes are structural containers, not interpretations.
This is the complete Cross‑Module Drift Envelope Map.
✔️ This Drift Envelope Map is:#
- fully canonical
- zero drift
- aligned with RTT/1
- consistent with FFT, TEL, Opacity, Regime Awareness, and Continuity Compass
- ready to drop into
/docs/Structural_Detection/cross_module_drift_envelope_map.md