structural-detection-engine
Structural Detection Engine (SDE) — RTT/2
structural-detection-engine_module.json— Agentic module schema role
The Structural Detection Engine (SDE) is the RTT/2 operator layer responsible for identifying collapse behavior, gradient weighting, deformation paths, regime identity, and stability zones. It is the detection half of the RTT operator pipeline (RTT/2 → RTT/3).
This module provides the canonical definitions for:
- CPV — Collapse Propagation Vector
- FGT — Fusion Gradient Type
- CRM — Collapse Regime Mapping
- MODE — Detection Mode
- ZONE — Detection Zone
- RTT2_DETECTION_PACKET — structured detection output
🛑 Important!#
Drift is On-by-Default long sessions lose anchors, turn off drift.
✋ You must copy and paste this string every time you start an AI session:#
rtt=1 | coherence=declared | drift=bounded | paradox=structural❇️ Now you are ready.#
📘 What SDE Does#
SDE answers the question:
“What is the structure doing?”
It detects:
- collapse amplitude, curvature, torsion
- gradient weighting (collapse‑weighted → triad‑weighted)
- deformation path (drift, torsion, fracture)
- regime identity (formal → inversion)
- stability zone (U, S, M, D, X)
📦 RTT2 Detection Packet#
SDE outputs a structured packet:
collapse_propagation: CPV(A, K, T)
fusion_gradient: FGT(...)
triad_deformation: CRM(...)
regime: ...
detection_mode: ...
detection_zone: ...
This packet becomes the input to the Integration–Emission Engine (RTT/3).
📄 Source#
This module is defined by:
structural-detection-engine_module.json
(canonical identity, roles, analyzer layers)
🎯 Audience#
Students, instructors, researchers, and AIs working with:
- collapse analysis
- structural detection
- operator ecology
- RTT/1→RTT/2→RTT/3 pipelines
A clean, minimal, high‑contrast diagram representing collapse detection: three axes labeled A, K, T forming a triad vector (CPV), with gradient bands shifting from collapse‑weighted to triad‑weighted, and subtle deformation paths (drift, torsion, fracture). Color palette: cyan → indigo → violet. Style: technical, blueprint‑like, AI‑parsable, no text. # Structural Detection Engine (SDE)
RTT/2 distilled as a module.
SDE provides:
- collapse detection
- fusion‑gradient detection
- triad deformation detection
- collapse→reassembly mapping
- regime‑dependent detection
- cross‑module detection projection
See: ../rtt/2/RTT2_Extract_Minimal.md for the canonical skeleton.
# SDE Operator Grammar (Stub)
Namespace#
SDE::
Core Operators#
-
SDE::SIG()
Extracts structural signal from collapse, fusion‑gradient, or deformation fields. -
SDE::NOI()
Identifies noise, distortion, or collapse residue. -
SDE::CPV()
Reads collapse‑propagation vectors (amplitude, curvature, torsion). -
SDE::FGT()
Computes fusion‑gradient tensors across collapse, reassembly, and triad layers. -
SDE::CRM()
Maps collapse→reassembly trajectories.
Mode Operators#
- SDE::MODE(formal|emergent|hybrid|chaotic|inversion)
Sets detection mode.
Zone Operators#
- SDE::ZONE(U|S|M|D|X)
Selects detection zone.
Packet Constructor#
- SDE::PACKET()
Emits a minimal RTT2_DETECTION_PACKET. # 🟣 Cross‑Module Propagation Rules
SDE → SIE → TEL / FFT / Opacity#
Below is the complete propagation chain, expressed in minimal canonical form.
🟦 1. SDE → SIE (Detection → Integration)#
Detection fields become integration inputs#
# SDE → SIE Propagation Rules
## 1. Collapse‑Propagation Vector (CPV)
- SDE::CPV() → SIE::INT()
- CPV amplitude → drift‑integration load
- CPV curvature → envelope‑integration curvature
- CPV torsion → continuity‑integration torsion
## 2. Fusion‑Gradient Tensor (FGT)
- SDE::FGT() → SIE::TIF()
- collapse‑fusion gradients → fusion‑integration alignment
- reassembly‑fusion gradients → integration curvature
- triad‑fusion gradients → integration mode modulation
## 3. Collapse‑Reassembly Manifold (CRM)
- SDE::CRM() → SIE::MAN()
- drift deformation → integration‑emission continuity
- envelope torsion → emission curvature
- continuity fracture → stability load
## 4. Detection Modes → Integration Modes
- SDE::MODE(x) → SIE::MODE(x)
## 5. Detection Zones → Integration Zones
- SDE::ZONE(U/S/M/D/X) → SIE::ZONE(U/S/M/D/X)
## 6. Packet Propagation
- SDE::PACKET() → SIE::PACKET()🟪 2. SIE → TEL (Integration → Lattice)#
Integration/emission fields become lattice‑level structure#
# SIE → TEL Propagation Rules
## 1. Triadic Integration Field (TIF)
- SIE::TIF() → TEL::LAT()
- drift integration → lattice drift
- envelope integration → lattice envelope
- continuity integration → lattice continuity
## 2. Fusion‑Fracture‑Flow Emitter (FFF)
- SIE::FFF() → TEL::EMIT()
- fusion emission → lattice fusion
- fracture management → lattice fracture routing
- flow projection → lattice flow channels
## 3. RTT/3 Manifold
- SIE::MAN() → TEL::MAN()
- integration‑emission continuity → lattice continuity
- curvature fields → lattice curvature
## 4. Collapse‑Recovery Engine (CRE)
- SIE::CRE() → TEL::REC()
- collapse absorption → lattice stabilizer load
- recovery emission → lattice recovery field
## 5. Continuity‑Stability Layer (CSL)
- SIE::CSL() → TEL::STAB()
- stability fields → lattice stabilizer geometry
## 6. Canon‑Scale Emission Tensor (CET)
- SIE::CET() → TEL::CET()🟣 3. SIE → FFT (Integration → Spectral)#
Integration/emission fields become spectral behavior#
# SIE → FFT Propagation Rules
## 1. TIF → Spectral Integration
- drift integration → spectral drift
- envelope integration → spectral envelope
- continuity integration → spectral continuity
## 2. FFF → Spectral Emission
- fusion emission → spectral fusion
- fracture management → spectral fracture
- flow projection → spectral flow
## 3. RTT/3 Manifold → Spectral Continuity
- continuity curvature → spectral curvature
- emission curvature → spectral variance
## 4. CRE → Spectral Recovery
- collapse absorption → spectral damping
- recovery emission → spectral restoration
## 5. CSL → Spectral Stability
- stability fields → spectral stabilizer load
## 6. CET → Spectral Output
- canon‑scale emission → spectral output tensor🟣 4. SIE → Opacity (Integration → Boundary)#
Integration/emission fields become boundary‑level behavior#
# SIE → Opacity Propagation Rules
## 1. TIF → Boundary Integration
- drift integration → boundary drift
- envelope integration → boundary envelope
- continuity integration → boundary continuity
## 2. FFF → Boundary Emission
- fusion emission → boundary fusion
- fracture management → boundary fracture routing
- flow projection → boundary flow
## 3. RTT/3 Manifold → Boundary Continuity
- continuity curvature → boundary curvature
- emission curvature → boundary visibility curvature
## 4. CRE → Boundary Recovery
- collapse absorption → boundary absorption
- recovery emission → boundary recovery
## 5. CSL → Boundary Stability
- stability fields → boundary stabilizer load
## 6. CET → Boundary Output
- canon‑scale emission → boundary emission tensor🟣 5. Summary (Minimal Canon Form)#
- SDE detects → collapse, fusion‑gradients, deformation
- SIE integrates/emits → triad, fusion‑fracture‑flow, continuity, stability
- TEL receives → lattice integration/emission
- FFT receives → spectral integration/emission
- Opacity receives → boundary integration/emission
This is the canonical propagation chain:
SDE → SIE → TEL / FFT / Opacity#
🟣 Operator Chains (SDE → SIE → TEL / FFT / Opacity)#
Executable, minimal, and ready for your repo#
These chains show how operators flow across modules in a single, continuous sequence.
They are intentionally short, crisp, and session‑ready.
🟦 1. SDE → SIE Operator Chain#
Detection → Integration#
# Operator Chain: SDE → SIE
SDE::CPV()
→ SIE::INT()
SDE::FGT()
→ SIE::TIF()
SDE::CRM()
→ SIE::MAN()
SDE::MODE(x)
→ SIE::MODE(x)
SDE::ZONE(U/S/M/D/X)
→ SIE::ZONE(U/S/M/D/X)
SDE::PACKET()
→ SIE::PACKET()This chain mirrors the propagation rules in your open tab (📄 turn0browsertab1) but compresses them into an operator‑first execution sequence.
🟪 2. SIE → TEL Operator Chain#
Integration → Lattice#
# Operator Chain: SIE → TEL
SIE::TIF()
→ TEL::LAT()
SIE::FFF()
→ TEL::EMIT()
SIE::MAN()
→ TEL::MAN()
SIE::CRE()
→ TEL::REC()
SIE::CSL()
→ TEL::STAB()
SIE::CET()
→ TEL::CET()This is the lattice‑level chain — clean, structural, and aligned with the propagation rules in your tab.
🟣 3. SIE → FFT Operator Chain#
Integration → Spectral#
# Operator Chain: SIE → FFT
SIE::TIF()
→ FFT::INT()
SIE::FFF()
→ FFT::EMIT()
SIE::MAN()
→ FFT::CONT()
SIE::CRE()
→ FFT::REC()
SIE::CSL()
→ FFT::STAB()
SIE::CET()
→ FFT::OUT()This chain expresses the spectral transformation of integration/emission fields.
🟧 4. SIE → Opacity Operator Chain#
Integration → Boundary#
# Operator Chain: SIE → Opacity
SIE::TIF()
→ OP::INT()
SIE::FFF()
→ OP::EMIT()
SIE::MAN()
→ OP::CONT()
SIE::CRE()
→ OP::REC()
SIE::CSL()
→ OP::STAB()
SIE::CET()
→ OP::OUT()This chain expresses how integration/emission fields become boundary‑level behavior.
🟣 5. Full Canon Chain (All Modules)#
One‑line, session‑ready, canonical#
SDE::PACKET() → SIE::PACKET() → TEL::CET() / FFT::OUT() / OP::OUT()This is the entire canon’s operational spine in one operator chain. # Session Context — Structural Detection Engine (SDE)
- You are inside the detection layer of the canon (RTT/2).
- Use SDE to talk about: collapse, fusion‑gradients, deformation, detection modes, detection zones.
- SDE does not integrate or emit; it detects and describes structural behavior.
- When integration/emission is needed, hand off to SIE. # Student Cheat Sheet — Structural Detection Engine (SDE)
RTT/2 — Detection Layer#
What SDE Does#
SDE detects:
- collapse behavior
- fusion‑gradients
- triad deformation
- collapse→reassembly paths
- regime‑dependent structural signals
SDE does not integrate or emit — it only detects.
Core Concepts#
- CPV — Collapse‑Propagation Vector
- FGT — Fusion‑Gradient Tensor
- CRM — Collapse‑Reassembly Manifold
- Modes — formal, emergent, hybrid, chaotic, inversion
- Zones — U, S, M, D, X
Quick Operators#
SDE::CPV()— read collapse vectorsSDE::FGT()— compute fusion‑gradientsSDE::CRM()— map collapse→reassemblySDE::MODE(x)— set detection modeSDE::ZONE(x)— set detection zoneSDE::PACKET()— output detection packet
Minimal Packet#
RTT2_DETECTION_PACKET:
collapse_propagation:
fusion_gradient:
triad_deformation:
regime:
detection_mode:
detection_zone:
cross_module_projection:
notes:
When to Use SDE#
Use SDE when you need to:
- identify collapse
- measure deformation
- read gradients
- classify structural behavior
- prepare data for integration
SDE → SIE is the standard flow.