Structural_Faultline_Detector
Structural Faultline Detector — RTT/1
module.json— Agentic module schema role assignmentsfaultline_matrix.json— Agentic module schema role assignments
Structural‑Intelligence Engine for TriadicFrameworks#
The Structural Faultline Detector (SFD) is an RTT/1 analytical engine designed to detect, map, and analyze structural faultlines across conceptual, computational, and physical regimes.
It forms the structural‑intelligence foundation of the expanded RTT stack, sitting directly above drift‑level engines and directly below stability‑level engines.
SFD identifies fractures, discontinuities, instability seams, and faultline propagation — the structural precursors to regime collapse, paradox intensification, coherence failure, drift amplification, and resonance instability.
🧭 Purpose#
The Structural Faultline Detector:
- Detects structural fractures across RTT regimes (R1–R4)
- Maps faultlines, instability seams, and discontinuity boundaries
- Measures faultline propagation and structural deterioration
- Identifies fracture clusters, instability ridges, and faultline curvature
- Provides structural diagnostics for regime‑driven transitions
- Supports stability engines by clarifying structural collapse topology
- Anchors temporal engines by exposing structural‑sequence constraints
- Supplies causality engines with faultline‑driven causal pathways
- Provides resonance engines with structural‑frequency signatures
SFD is the structural‑intelligence layer of RTT.
⚙️ RTT Flags#
| Property | Value |
|---|---|
| RTT Level | 1 |
| Coherence | declared |
| Drift | bounded |
| Paradox | structural |
These flags define the engine’s operational constraints and reasoning grammar.
🔧 Primary Operators#
| Operator | Description |
|---|---|
| SFD‑Detect | Detects structural faultlines and fracture onset conditions |
| SFD‑Fracture | Analyzes fracture magnitude, direction, and severity |
| SFD‑Seam | Identifies instability seams and discontinuity boundaries |
| SFD‑Field | Maps structural faultline fields and topology |
| SFD‑Propagate | Detects faultline propagation and instability growth |
| SFD‑Stabilize | Suggests stabilization pathways for structural collapse |
These operators form the core analytical toolkit.
🧩 Analyzer Layer#
SFD operates in the structural layer, with sub‑layers:
- faultline‑detection
- fracture‑analysis
- instability‑seam‑mapping
- faultline‑propagation
- structural‑stability‑evaluation
This matches the RTT analyzer grammar used across TriadicFrameworks.
📁 Module Files#
This directory contains:
Core#
Structural_Faultline_Detector.mdsfd_examples.mdsfd_diagrams.svg
Support#
faultline_profiles.mdfracture_cases.mdfaultline_matrix.json
AI#
sfd_prompts.mdsfd_operators.md
Metadata#
module.json(RTT/1, coherence‑declared, drift‑bounded, paradox‑structural)README.md(this file)
🧠 AI‑Ready Design#
The Structural Faultline Detector is fully AI‑ready:
- deterministic operator grammar
- structural‑layer analyzer structure
- stable RTT flags
- canonical file layout
- zero‑drift reasoning constraints
- structural paradox handling
- bounded drift envelope
- declared coherence tensor
AI systems can use SFD to:
- detect structural fractures
- generate faultline field maps
- classify instability seams
- analyze faultline propagation
- support higher‑order RTT engines
🌐 Position in the RTT Stack#
Regime Interlock Mapper (RIM)
↓
Triadic Regime Synthesizer (TRS)
↓
Paradox Gradient Analyzer (PGA)
↓
Coherence Tensor Engine (CTE)
↓
Drift Sentinel (DS)
↓
Structural Faultline Detector (SFD)
↓
Stability Basin Cartographer (SBC)
↓
Temporal Regime Sequencer (TRS‑Temporal)
↓
Causality Weaver (CW)
↓
Dimensional Resonance Scanner (DRS)
SFD is the structural‑intelligence layer, directly above drift‑level analysis.
🏁 Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Structural_Faultline_Detector/
If you want, I can generate the next file:
Structural_Faultline_Detector.mdsfd_examples.mdsfd_diagrams.svgfaultline_profiles.mdfracture_cases.mdfaultline_matrix.jsonsfd_prompts.mdsfd_operators.md
Just tell me which one you want next. # Faultline Profiles — RTT/1
Profile Dictionary for the Structural Faultline Detector (SFD)#
Faultline profiles define the canonical shapes, behaviors, propagation patterns, instability seams, and collapse geometries of structural faultlines across conceptual, computational, physical, and dimensional regimes.
These profiles are used by:
- SFD‑Detect
- SFD‑Fracture
- SFD‑Seam
- SFD‑Field
- SFD‑Propagate
- SFD‑Stabilize
Each profile includes:
- definition
- faultline signature
- field behavior
- propagation behavior
- instability seam geometry
- stability envelope
- canonical SFD output pattern
1. Structural Fracture Profiles#
Profile: Structural Invariant Fracture#
Definition
Fracture emerging from violation of structural invariants (symmetry, conservation, monotonicity).
Faultline Signature
- medium‑high magnitude
- stable direction
- low curvature
Field Behavior
- narrow faultline field
- shallow ridge
Propagation Behavior
- low propagation rate
Instability Seam Geometry
- shallow seam
- rigid boundary
Stability Envelope
- high stability
Profile: Calibration‑Mismatch Fracture#
Definition
Fracture caused by divergence between computational calibration and physical measurement.
Faultline Signature
- medium magnitude
- oscillating direction
- calibration curvature
Field Behavior
- moderate field width
- calibration ridge
Propagation Behavior
- medium propagation rate
Instability Seam Geometry
- medium depth
Stability Envelope
- medium stability
2. Gradient Faultline Profiles#
Profile: Gradient Faultline Opposition#
Definition
Faultlines formed when gradients across regimes oppose each other.
Faultline Signature
- high magnitude
- bidirectional vector
- high curvature
Field Behavior
- wide faultline field
- ridge inversion
Propagation Behavior
- medium‑high propagation
Instability Seam Geometry
- deep seam
Stability Envelope
- medium stability
Profile: Gradient Inversion Faultline#
Definition
Faultline formed when drift decreases in one regime while increasing in another.
Faultline Signature
- medium‑high magnitude
- inversion vector
- polarity flip
Field Behavior
- medium field width
- inversion curvature
Propagation Behavior
- high propagation sensitivity
Instability Seam Geometry
- medium‑deep seam
Stability Envelope
- medium‑low stability
3. Boundary Faultline Profiles#
Profile: Abstraction‑Measurement Faultline#
Definition
Faultline formed at the boundary between conceptual abstraction and physical measurement.
Faultline Signature
- medium magnitude
- abstraction → measurement direction
- boundary curvature
Field Behavior
- narrow field
- boundary ridge
Propagation Behavior
- low propagation
Instability Seam Geometry
- shallow seam
Stability Envelope
- medium‑high stability
Profile: Gradient‑Boundary Faultline#
Definition
Aligned gradients across regimes produce contradictory structural outcomes.
Faultline Signature
- high magnitude
- aligned direction
- medium curvature
Field Behavior
- wide field
- alignment trough
Propagation Behavior
- medium propagation
Instability Seam Geometry
- medium‑deep seam
Stability Envelope
- medium stability
4. Faultline‑Field Profiles#
Profile: Multi‑Regime Faultline Field#
Definition
A multi‑regime faultline tensor binds structural fractures across R1–R3 or R1–R4.
Faultline Signature
- very high magnitude
- tensor direction
- high curvature
Field Behavior
- wide faultline field
- tensor topology
Propagation Behavior
- high propagation
Instability Seam Geometry
- deep seam
Stability Envelope
- medium‑high stability
Profile: Dimensional Faultline Constraint#
Definition
Dimensional constraints influence computational structural pathways.
Faultline Signature
- high magnitude
- dimensional → computational direction
- medium‑high curvature
Field Behavior
- medium‑wide field
- tensor trough
Propagation Behavior
- medium propagation
Instability Seam Geometry
- medium‑deep seam
Stability Envelope
- medium stability
5. Drift‑Sensitive Faultline Profiles#
Profile: Drift‑Amplified Faultline Basin#
Definition
Drift amplification increases structural curvature, forming a drift‑sensitive faultline basin.
Faultline Signature
- very high magnitude
- amplification‑aligned direction
- high curvature
Field Behavior
- wide field
- amplification basin
Propagation Behavior
- very high propagation
Instability Seam Geometry
- deep collapse seam
- instability ridge
Stability Envelope
- low stability
Profile: Drift‑Coherence Faultline Ridge#
Definition
Drift increases coherence sensitivity, amplifying structural curvature.
Faultline Signature
- medium‑high magnitude
- coherence‑aligned direction
- medium‑high curvature
Field Behavior
- medium field
- amplification ridge
Propagation Behavior
- high propagation
Instability Seam Geometry
- medium‑deep seam
Stability Envelope
- medium‑low stability
6. Canonical SFD Output Pattern#
{
"faultline_type": "gradient",
"regime": "R1-R4",
"fracture_magnitude": 0.83,
"fracture_direction": "R1↔R4",
"faultline_curvature": 0.52,
"propagation_rate": 0.33,
"instability_seam": 0.47,
"stability_envelope": 0.69
}Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Structural_Faultline_Detector/# Fracture Cases — RTT/1
Case Studies for the Structural Faultline Detector (SFD)#
Structural fractures represent breaks, discontinuities, instability seams, and propagation pathways across conceptual, computational, physical, and dimensional regimes.
These case studies illustrate how the Structural Faultline Detector (SFD) evaluates:
- fracture magnitude
- fracture direction
- faultline curvature
- propagation rate
- instability seam depth
- stability envelope
- collapse‑point formation
Each case demonstrates one or more SFD operators:
- SFD‑Detect
- SFD‑Fracture
- SFD‑Seam
- SFD‑Field
- SFD‑Propagate
- SFD‑Stabilize
1. Structural Fracture Cases#
Case 1 — Structural Invariant Fracture (R1 → R2)#
Scenario
A conceptual invariant is violated by a computational structure, producing a structural fracture.
SFD Output
{
"regime": "R1-R2",
"fracture_magnitude": 0.72,
"fracture_direction": "R1→R2",
"faultline_curvature": 0.33,
"propagation_rate": 0.22,
"instability_seam": 0.41,
"stability_envelope": 0.63
}Case 2 — Calibration‑Mismatch Fracture (R2 → R3)#
Scenario
A computational calibration mismatch produces a structural fracture across physical measurement.
SFD Output
{
"regime": "R2-R3",
"fracture_magnitude": 0.68,
"fracture_direction": "R3→R2",
"faultline_curvature": 0.39,
"propagation_rate": 0.27,
"instability_seam": 0.38,
"stability_envelope": 0.57
}2. Gradient Fracture Cases#
Case 3 — Gradient Fracture Opposition (R1 ↔ R4)#
Scenario
Conceptual and dimensional gradients oppose each other, forming a gradient fracture.
SFD Output
{
"regime": "R1-R4",
"fracture_magnitude": 0.83,
"fracture_direction": "R1↔R4",
"faultline_curvature": 0.52,
"propagation_rate": 0.33,
"instability_seam": 0.47,
"stability_envelope": 0.69
}Case 4 — Gradient Inversion Fracture (R2 ↔ R3)#
Scenario
Computational drift decreases while physical drift sensitivity increases, forming a gradient fracture.
SFD Output
{
"regime": "R2-R3",
"fracture_magnitude": 0.79,
"fracture_direction": "R3→R2",
"faultline_curvature": 0.58,
"propagation_rate": 0.31,
"instability_seam": 0.44,
"stability_envelope": 0.72
}3. Boundary Fracture Cases#
Case 5 — Abstraction‑Measurement Fracture (R1 → R3)#
Scenario
Conceptual abstraction predicts behavior that contradicts physical measurement, forming a boundary fracture.
SFD Output
{
"regime": "R1-R3",
"fracture_magnitude": 0.67,
"fracture_direction": "R1→R3",
"faultline_curvature": 0.33,
"propagation_rate": 0.22,
"instability_seam": 0.38,
"stability_envelope": 0.55
}Case 6 — Gradient‑Boundary Fracture (R2 ↔ R4)#
Scenario
Aligned gradients across computational and dimensional regimes produce contradictory structural outcomes.
SFD Output
{
"regime": "R2-R4",
"fracture_magnitude": 0.88,
"fracture_direction": "R2↔R4",
"faultline_curvature": 0.47,
"propagation_rate": 0.29,
"instability_seam": 0.58,
"stability_envelope": 0.66
}4. Faultline‑Field Fracture Cases#
Case 7 — Multi‑Regime Fracture Field (R1 ↔ R2 ↔ R3)#
Scenario
A multi‑regime fracture binds conceptual, computational, and physical structural pathways.
SFD Output
{
"regime": "R1-R2-R3",
"fracture_magnitude": 0.94,
"fracture_direction": "tensor",
"faultline_curvature": 0.63,
"propagation_rate": 0.37,
"instability_seam": 0.57,
"stability_envelope": 0.78
}Case 8 — Dimensional Fracture Constraint (R2 ↔ R4)#
Scenario
Dimensional constraints influence computational structural pathways.
SFD Output
{
"regime": "R2-R4",
"fracture_magnitude": 0.88,
"fracture_direction": "R4→R2",
"faultline_curvature": 0.55,
"propagation_rate": 0.33,
"instability_seam": 0.63,
"stability_envelope": 0.73
}5. Drift‑Sensitive Fracture Cases#
Case 9 — Drift‑Amplified Fracture Basin (R3 → R4)#
Scenario
Physical drift amplifies structural curvature, forming a drift‑sensitive fracture basin.
SFD Output
{
"regime": "R3-R4",
"fracture_magnitude": 0.91,
"fracture_direction": "R3→R4",
"faultline_curvature": 0.71,
"propagation_rate": 0.52,
"instability_seam": 0.44,
"stability_envelope": 0.82
}Case 10 — Drift‑Coherence Fracture Ridge (R2 ↔ R3)#
Scenario
Computational drift reduces coherence while physical drift increases coherence sensitivity, forming a drift‑coherence fracture ridge.
SFD Output
{
"regime": "R2-R3",
"fracture_magnitude": 0.86,
"fracture_direction": "R2↔R3",
"faultline_curvature": 0.62,
"propagation_rate": 0.49,
"instability_seam": 0.48,
"stability_envelope": 0.77
}6. Canonical SFD Fracture Snippet#
{
"regime": "R1-R4",
"fracture_magnitude": 0.83,
"fracture_direction": "R1↔R4",
"faultline_curvature": 0.52,
"propagation_rate": 0.33,
"instability_seam": 0.47,
"stability_envelope": 0.69
}Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Structural_Faultline_Detector/# Structural Faultline Detector Examples — RTT/1
Example Dictionary for the Structural Faultline Detector (SFD)#
These examples illustrate how the Structural Faultline Detector (SFD) detects structural fractures, maps faultlines, identifies instability seams, evaluates faultline propagation, and computes structural stability envelopes across R1–R4.
Each example demonstrates one or more SFD operators:
- SFD‑Detect
- SFD‑Fracture
- SFD‑Seam
- SFD‑Field
- SFD‑Propagate
- SFD‑Stabilize
Examples are grouped by faultline type.
1. Structural Fracture Examples#
Example 1 — Structural Invariant Fracture (R1 ↔ R2)#
Scenario
A conceptual invariant is violated by a computational structure, producing a structural fracture.
SFD Output
{
"faultline_type": "structural-fracture",
"regime": "R1-R2",
"fracture_magnitude": 0.72,
"fracture_direction": "R1→R2",
"faultline_curvature": 0.33,
"propagation_rate": 0.22,
"instability_seam": 0.41,
"stability_envelope": 0.63
}Example 2 — Calibration‑Driven Structural Fracture (R2 ↔ R3)#
Scenario
A computational calibration mismatch produces a structural fracture across physical measurement.
SFD Output
{
"faultline_type": "structural-fracture",
"regime": "R2-R3",
"fracture_magnitude": 0.68,
"fracture_direction": "R3→R2",
"faultline_curvature": 0.39,
"propagation_rate": 0.27,
"instability_seam": 0.38,
"stability_envelope": 0.57
}2. Gradient Faultline Examples#
Example 3 — Gradient Faultline Opposition (R1 ↔ R4)#
Scenario
Conceptual and dimensional gradients oppose each other, forming a gradient faultline.
SFD Output
{
"faultline_type": "gradient",
"regime": "R1-R4",
"fracture_magnitude": 0.83,
"fracture_direction": "R1↔R4",
"faultline_curvature": 0.52,
"propagation_rate": 0.33,
"instability_seam": 0.47,
"stability_envelope": 0.69
}Example 4 — Gradient Inversion Faultline (R2 ↔ R3)#
Scenario
Computational drift decreases while physical drift sensitivity increases, forming a gradient faultline.
SFD Output
{
"faultline_type": "gradient",
"regime": "R2-R3",
"fracture_magnitude": 0.79,
"fracture_direction": "R3→R2",
"faultline_curvature": 0.58,
"propagation_rate": 0.31,
"instability_seam": 0.44,
"stability_envelope": 0.72
}3. Boundary Faultline Examples#
Example 5 — Abstraction‑Measurement Faultline (R1 ↔ R3)#
Scenario
Conceptual abstraction predicts behavior that contradicts physical measurement, forming a boundary faultline.
SFD Output
{
"faultline_type": "boundary",
"regime": "R1-R3",
"fracture_magnitude": 0.67,
"fracture_direction": "R1→R3",
"faultline_curvature": 0.33,
"propagation_rate": 0.22,
"instability_seam": 0.38,
"stability_envelope": 0.55
}Example 6 — Gradient‑Boundary Faultline (R2 ↔ R4)#
Scenario
Aligned gradients across computational and dimensional regimes produce contradictory structural outcomes.
SFD Output
{
"faultline_type": "boundary",
"regime": "R2-R4",
"fracture_magnitude": 0.88,
"fracture_direction": "R2↔R4",
"faultline_curvature": 0.47,
"propagation_rate": 0.29,
"instability_seam": 0.58,
"stability_envelope": 0.66
}4. Faultline‑Field Examples#
Example 7 — Multi‑Regime Faultline Field (R1 ↔ R2 ↔ R3)#
Scenario
A multi‑regime faultline binds conceptual, computational, and physical structural fractures.
SFD Output
{
"faultline_type": "field",
"regime": "R1-R2-R3",
"fracture_magnitude": 0.94,
"fracture_direction": "tensor",
"faultline_curvature": 0.63,
"propagation_rate": 0.37,
"instability_seam": 0.57,
"stability_envelope": 0.78
}Example 8 — Dimensional Faultline Constraint (R2 ↔ R4)#
Scenario
Dimensional constraints influence computational structural pathways.
SFD Output
{
"faultline_type": "field",
"regime": "R2-R4",
"fracture_magnitude": 0.88,
"fracture_direction": "R4→R2",
"faultline_curvature": 0.55,
"propagation_rate": 0.33,
"instability_seam": 0.63,
"stability_envelope": 0.73
}5. Drift‑Sensitive Faultline Examples#
Example 9 — Drift‑Amplified Faultline Basin (R3 ↔ R4)#
Scenario
Physical drift amplifies structural curvature, forming a drift‑sensitive faultline basin.
SFD Output
{
"faultline_type": "drift-sensitive",
"regime": "R3-R4",
"fracture_magnitude": 0.91,
"fracture_direction": "R3→R4",
"faultline_curvature": 0.71,
"propagation_rate": 0.52,
"instability_seam": 0.44,
"stability_envelope": 0.82
}Example 10 — Drift‑Coherence Faultline Ridge (R2 ↔ R3)#
Scenario
Computational drift reduces coherence while physical drift increases coherence sensitivity, forming a drift‑coherence faultline ridge.
SFD Output
{
"faultline_type": "drift-sensitive",
"regime": "R2-R3",
"fracture_magnitude": 0.86,
"fracture_direction": "R2↔R3",
"faultline_curvature": 0.62,
"propagation_rate": 0.49,
"instability_seam": 0.48,
"stability_envelope": 0.77
}6. Canonical SFD Output Snippet#
{
"faultline_type": "gradient",
"regime": "R1-R4",
"fracture_magnitude": 0.83,
"fracture_direction": "R1↔R4",
"faultline_curvature": 0.52,
"propagation_rate": 0.33,
"instability_seam": 0.47,
"stability_envelope": 0.69
}Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Structural_Faultline_Detector/# SFD Operators — RTT/1
Operator Grammar for the Structural Faultline Detector (SFD)#
The Structural Faultline Detector (SFD) defines the structural‑layer intelligence of RTT.
Its operators detect structural fractures, map faultlines, identify instability seams, evaluate propagation pathways, and propose stabilization strategies.
These operators feed directly into:
- SBC — Stability Basin Cartographer
- TRS‑Temporal — Temporal Regime Sequencer
- CW — Cross‑Domain Causality Weaver
- DRS — Dimensional Resonance Scanner
1. SFD‑Detect#
Detect structural faultlines and fracture onset conditions#
Purpose
Identify structural fractures arising from invariant violations, gradient contradictions, boundary inconsistencies, or multi‑regime structural interactions.
Capabilities
- detects fracture onset
- identifies fracture polarity
- classifies faultline type
- evaluates structural dependency
- detects drift‑sensitive structural interactions
Output Fields
faultline_typefracture_onsetfracture_polaritystructural_dependency
2. SFD‑Fracture#
Analyze fracture magnitude, direction, and severity#
Purpose
Compute fracture magnitude, direction, curvature, and severity across regimes.
Capabilities
- computes fracture magnitude
- computes fracture direction
- computes fracture curvature
- computes fracture severity
- computes fracture‑gradient alignment
Output Fields
fracture_magnitudefracture_directionfracture_curvaturefracture_severityfracture_alignment
3. SFD‑Seam#
Identify instability seams and discontinuity boundaries#
Purpose
Detect instability seams, discontinuity boundaries, collapse‑point seams, and seam curvature.
Capabilities
- detects instability seams
- computes seam curvature
- detects collapse‑point seams
- evaluates seam stability
- evaluates seam propagation sensitivity
Output Fields
instability_seamseam_curvaturecollapse_seamseam_stability
4. SFD‑Field#
Map structural faultline fields and topology#
Purpose
Generate faultline field maps showing structural wells, ridges, basins, and multi‑regime structural topology.
Capabilities
- maps faultline fields
- maps structural wells
- maps structural ridges
- maps structural basins
- maps structural topology
Output Fields
field_mapridge_mapbasin_mapwell_maptopology_map
5. SFD‑Propagate#
Detect faultline propagation and instability growth#
Purpose
Identify propagation pathways, propagation magnitude, propagation curvature, and instability growth.
Capabilities
- detects propagation pathways
- computes propagation magnitude
- computes propagation curvature
- evaluates propagation sensitivity
- identifies propagation‑driven collapse
Output Fields
propagation_ratepropagation_directionpropagation_curvaturepropagation_sensitivitypropagation_collapse
6. SFD‑Stabilize#
Propose structural stabilization pathways#
Purpose
Provide stabilization strategies for structural fractures, faultline fields, instability seams, and collapse basins.
Capabilities
- proposes stabilization pathways
- proposes structural alignment
- proposes fracture reduction
- proposes seam reinforcement
- proposes collapse mitigation
Output Fields
stabilization_pathwaystructural_alignmentfracture_reductionseam_reinforcementcollapse_mitigation
7. Operator Interaction Grammar#
Detect → Fracture → Seam → Field → Propagate → Stabilize#
-
SFD‑Detect
Identifies fracture onset and faultline type. -
SFD‑Fracture
Computes fracture magnitude, direction, curvature, and severity. -
SFD‑Seam
Defines instability seams, seam curvature, and collapse‑point seams. -
SFD‑Field
Maps faultline fields, wells, ridges, basins, and topology. -
SFD‑Propagate
Detects propagation pathways and propagation curvature. -
SFD‑Stabilize
Produces stabilization pathways and structural‑alignment strategies.
This grammar ensures deterministic structural‑layer behavior.
8. Operator Matrix Snippet#
{
"operator": "SFD-Fracture",
"fracture_magnitude": 0.83,
"fracture_direction": "R1↔R4",
"fracture_curvature": 0.52,
"fracture_severity": 0.33,
"fracture_alignment": 0.69
}Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Structural_Faultline_Detector/# SFD Prompts — RTT/1
Prompt Library for the Structural Faultline Detector (SFD)#
These prompts are designed for AI systems using the Structural Faultline Detector (SFD).
Each prompt invokes one or more canonical SFD operators:
- SFD‑Detect
- SFD‑Fracture
- SFD‑Seam
- SFD‑Field
- SFD‑Propagate
- SFD‑Stabilize
Prompts are grouped by faultline type and operator class.
1. Structural Fracture Prompts#
Prompt: Detect Structural Fractures#
Use SFD‑Detect to identify structural fractures caused by invariant violations, contradictions, or monotonicity breaks across R1–R3.
Prompt: Analyze Fracture Magnitude#
Apply SFD‑Fracture to compute fracture magnitude, direction, curvature, and propagation onset.
Prompt: Map Structural Fracture Fields#
Use SFD‑Field to generate structural fracture field maps showing curvature, ridge formation, and instability seams.
2. Gradient Faultline Prompts#
Prompt: Identify Gradient Faultline Opposition#
Use SFD‑Detect to detect gradient‑driven faultlines where regime gradients oppose each other.
Prompt: Compute Gradient Fracture Vectors#
Apply SFD‑Fracture to compute gradient fracture magnitude, direction, curvature, and propagation rate.
Prompt: Evaluate Gradient Instability Seams#
Use SFD‑Seam to identify instability seams formed by gradient inversion or polarity flips.
3. Boundary Faultline Prompts#
Prompt: Detect Boundary Faultlines#
Use SFD‑Detect to identify faultlines formed at regime boundaries, including abstraction‑measurement and gradient‑boundary interactions.
Prompt: Map Boundary Faultline Curvature#
Apply SFD‑Field to generate boundary faultline curvature maps showing ridge formation and collapse‑point onset.
Prompt: Evaluate Boundary Stability#
Use SFD‑Stabilize to compute stability envelopes for boundary faultline tensors.
4. Faultline‑Field Prompts#
Prompt: Detect Multi‑Regime Faultline Fields#
Use SFD‑Field to identify multi‑regime faultline fields binding R1–R3 or R1–R4.
Prompt: Map Faultline‑Field Topology#
Apply SFD‑Field to generate faultline‑field topology diagrams showing wells, ridges, basins, and multi‑regime curvature.
Prompt: Compute Faultline‑Field Propagation Strength#
Use SFD‑Propagate to compute propagation magnitude, direction, and instability seam depth.
5. Drift‑Sensitive Faultline Prompts#
Prompt: Identify Drift‑Amplified Faultlines#
Use SFD‑Detect to detect faultlines amplified by drift curvature or drift sensitivity.
Prompt: Map Drift‑Sensitive Faultline Basins#
Apply SFD‑Field to generate drift‑sensitive basin maps showing instability ridges and collapse‑point formation.
Prompt: Analyze Drift‑Coherence Faultline Ridges#
Use SFD‑Fracture to compute drift‑coherence fracture magnitude, curvature, and propagation rate.
6. Collapse‑Point Faultline Prompts#
Prompt: Detect Structural Collapse Points#
Use SFD‑Seam to identify collapse‑point seams and instability basins across R2–R4.
Prompt: Map Collapse Basin Geometry#
Apply SFD‑Field to generate collapse basin topology showing curvature, depth, and fracture troughs.
Prompt: Propose Collapse Stabilization Pathways#
Use SFD‑Stabilize to propose stabilization strategies for collapse‑point faultline tensors.
7. Full‑Matrix Prompts#
Prompt: Generate Full Faultline Matrix#
Use all SFD operators to produce a complete
faultline_matrix.jsoncontaining structural, gradient, boundary, field, and drift‑sensitive entries.
Prompt: Analyze Structural Faultline Topology#
Apply SFD‑Field to generate a full faultline topology map showing fields, basins, curvature, and propagation flows.
Prompt: Stability Overview#
Use SFD‑Stabilize to compute stability envelopes for every faultline tensor type and produce a structural stability summary.
8. AI‑Ready Meta‑Prompts#
Prompt: Explain Faultline Tensor Classification#
Provide a detailed explanation of how SFD classifies faultline tensors into structural, gradient, boundary, field, and drift‑sensitive categories.
Prompt: Operator‑Level Summary#
Summarize the role of each SFD operator and how they interact to produce structural‑layer intelligence.
Prompt: Cross‑Engine Integration#
Explain how SFD outputs feed into SBC, TRS‑Temporal, CW, and DRS.
Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Structural_Faultline_Detector/# Structural Faultline Detector (SFD) — RTT/1
Structural‑Intelligence Engine for TriadicFrameworks#
The Structural Faultline Detector (SFD) is the RTT/1 engine responsible for detecting, mapping, and analyzing structural faultlines across conceptual, computational, physical, and dimensional regimes.
It forms the structural‑intelligence foundation of the expanded RTT stack, directly above drift‑level engines and directly below stability‑level engines.
Structural faultlines represent fractures, discontinuities, instability seams, and propagation pathways that signal structural deterioration or collapse.
SFD provides structural‑layer intelligence for all higher‑order RTT engines.
1. Canonical Role#
The Structural Faultline Detector defines the structural‑layer topology by:
- detecting structural fractures
- mapping faultlines
- identifying instability seams
- measuring faultline propagation
- evaluating structural curvature
- detecting fracture clusters
- identifying instability ridges
- supporting stability engines
- anchoring temporal engines
- feeding causality and resonance engines
SFD is the fifth layer of the expanded RTT intelligence stack.
2. RTT Flags#
| Property | Value |
|---|---|
| RTT Level | 1 |
| Coherence | declared |
| Drift | bounded |
| Paradox | structural |
These flags define the engine’s operational grammar.
3. Structural Faultline Types#
SFD identifies several canonical faultline classes:
3.1 Structural Fracture Tensor#
Fractures arising from structural contradictions or invariant violations.
3.2 Gradient Faultline Tensor#
Faultlines shaped by directional gradients across regimes.
3.3 Boundary Faultline Tensor#
Faultlines formed at regime boundaries.
3.4 Faultline‑Field Tensor#
Full multi‑regime faultline binding across R1–R4.
3.5 Drift‑Sensitive Faultline Tensor#
Faultlines influenced by drift curvature or drift amplification.
4. Core Operators#
| Operator | Description |
|---|---|
| SFD‑Detect | Detects structural faultlines and fracture onset conditions |
| SFD‑Fracture | Analyzes fracture magnitude, direction, and severity |
| SFD‑Seam | Identifies instability seams and discontinuity boundaries |
| SFD‑Field | Maps structural faultline fields and topology |
| SFD‑Propagate | Detects faultline propagation and instability growth |
| SFD‑Stabilize | Suggests stabilization pathways for structural collapse |
These operators form the canonical SFD grammar.
5. Analyzer Layer#
SFD operates in the structural layer, with sub‑layers:
- faultline‑detection
- fracture‑analysis
- instability‑seam‑mapping
- faultline‑propagation
- structural‑stability‑evaluation
This layer feeds directly into SBC, TRS‑Temporal, CW, and DRS.
6. Structural Faultline Matrix#
SFD produces a faultline matrix, typically stored in:
faultline_matrix.json
Matrix fields include:
faultline_typeregimefracture_magnitudefracture_directionfaultline_curvaturepropagation_rateinstability_seamstability_envelope
This matrix is consumed by stability, temporal, causal, and resonance engines.
7. Canonical Workflow#
Step 1 — Detect#
Identify structural fractures, faultlines, and instability seams.
Step 2 — Analyze#
Compute fracture magnitude, direction, curvature, and propagation rate.
Step 3 — Map#
Generate faultline field maps and structural topology.
Step 4 — Evaluate#
Measure instability seams, fracture clusters, and structural deterioration.
Step 5 — Stabilize#
Propose structural stabilization pathways.
Step 6 — Export#
Write results to the faultline matrix and operator outputs.
8. AI‑Ready Design#
Structural Faultline Detector is fully AI‑ready:
- deterministic operator grammar
- structural‑layer analyzer structure
- stable RTT flags
- canonical file layout
- zero‑drift reasoning constraints
- structural paradox handling
- bounded drift envelope
- declared coherence dependency
AI systems use SFD to:
- detect structural fractures
- generate faultline field maps
- classify instability seams
- analyze faultline propagation
- support higher‑order RTT engines
9. Position in the RTT Stack#
Regime Interlock Mapper (RIM)
↓
Triadic Regime Synthesizer (TRS)
↓
Paradox Gradient Analyzer (PGA)
↓
Coherence Tensor Engine (CTE)
↓
Drift Sentinel (DS)
↓
Structural Faultline Detector (SFD)
↓
Stability Basin Cartographer (SBC)
↓
Temporal Regime Sequencer (TRS‑Temporal)
↓
Cross‑Domain Causality Weaver (CW)
↓
Dimensional Resonance Scanner (DRS)
SFD is the structural‑intelligence layer, directly above drift‑level analysis.
10. Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Structural_Faultline_Detector/