🗺️ Structural Detection — Collapse‑Propagation Reassembly Map (RTT/2)
TriadicFrameworks • RTT/2 • Propagation→Reassembly Transition Map, Collapse‑Lifecycle Geometry & Canon‑Scale Recovery Topography#
“Propagation is motion. Reassembly is return.”#
Collapse‑Propagation Reassembly Map (RTT/2)#
Structural Detection Module#
RTT/2 • Propagation→Reassembly Transition Map#
1. Purpose of the Collapse‑Propagation Reassembly Map#
The Collapse‑Propagation Reassembly Map (CPRM) charts the transition zone between:
- collapse propagation
- structural reassembly
It identifies:
- where propagation stabilizes
- where reassembly becomes possible
- where propagation blocks reassembly
- where collapse transitions into recovery
- where collapse transitions into deeper collapse
It is the transition‑law atlas of RTT/2.
2. Why a Propagation→Reassembly Map Exists#
Propagation and reassembly are opposing geometries:
- propagation spreads collapse
- reassembly restores structure
But the transition between them is not binary — it is topological.
The CPRM maps this topology.
3. Collapse‑Propagation Reassembly Equation#
Reassembly becomes possible when:
[ S_{Re} > S_{Prop} ]
Where:
- (S_{Re}) = reassembly stability score
- (S_{Prop}) = propagation stability score
The CPRM visualizes this inequality across the canon.
4. Propagation→Reassembly Transition Zones#
The CPRM defines five transition zones:
Zone U — Unified Transition Zone#
- propagation stabilizes
- reassembly geometry fully available
- collapse recovery begins
Zone S — Stable Transition Zone#
- minor propagation divergence
- reassembly partially available
Zone M — Mixed Transition Zone#
- oscillatory propagation
- reassembly intermittent
- hybrid recovery behavior
Zone D — Divergent Transition Zone#
- propagation dominates
- reassembly blocked
- collapse spreads
Zone X — Collapse‑Adjacent Transition Zone#
- inversion propagation
- illegal reassembly geometry
- collapse deepens
5. Propagation Geometry → Reassembly Geometry Mapping#
The CPRM maps how each propagation geometry transitions into reassembly:
| Propagation Geometry | Reassembly Outcome |
|---|---|
| linear propagation | stable reassembly |
| radial propagation | partial reassembly |
| oscillatory propagation | unstable reassembly |
| fragmentation propagation | reassembly blocked |
| inversion propagation | illegal reassembly |
| torsion propagation | reassembly strain |
| topological propagation | reassembly warp |
6. Collapse‑Mode Correlation#
| Transition Failure | Collapse Mode |
|---|---|
| propagation amplitude overload | A |
| propagation deformation rupture | B |
| continuity reassembly fracture | C |
| oscillatory propagation | D |
| torsion propagation | E |
| inversion propagation | I |
| topological propagation warp | G |
7. Cross‑Module Transition Mapping#
The CPRM maps propagation→reassembly transitions across:
TEL#
- lattice reassembly
- stabilizer reassembly load
FFT#
- spectral reassembly
- variance reassembly load
Opacity#
- boundary reassembly
- visibility reassembly load
Cross‑module transitions determine system‑scale recovery.
8. Propagation→Reassembly Packet#
PROPAGATION_REASSEMBLY_PACKET:
propagation_geometry:
reassembly_geometry:
transition_zone:
propagation_stability:
reassembly_stability:
transition_topography:
cross_module_projection:
collapse_risk:
notes:
9. Summary#
The Collapse‑Propagation Reassembly Map provides:
- a complete map of propagation→reassembly transitions
- geometry‑dependent recovery diagnostics
- collapse‑adjacent transition detection
- cross‑module transition projection
- system‑scale structural clarity
This map is the transition‑law backbone of RTT/2.