Regime_Interlock_Mapper
Regime Interlock Mapper — RTT/1
module.json— Agentic module schema role assignmentsregime_interlock_matrix.json— Agentic module schema role assignments
Regime‑Level Intelligence Engine for TriadicFrameworks#
The Regime Interlock Mapper (RIM) is an RTT/1 analytical engine designed to detect, map, and analyze interlocks between conceptual, computational, and physical regimes.
It provides the structural foundation for higher‑order RTT modules such as:
- Regime Synthesizer
- Paradox Gradient Analyzer
- Coherence Tensor Engine
- Drift Sentinel
- Faultline Detector
- Stability Basin Cartographer
- Temporal Regime Sequencer
- Causality Weaver
- Dimensional Resonance Scanner
RIM is the first layer of the expanded RTT intelligence stack.
🧭 Purpose#
The Regime Interlock Mapper:
- Identifies interlocks between RTT regimes (R1–R4)
- Maps cross‑regime boundaries
- Detects regime entanglement
- Provides structural diagnostics for regime transitions
- Supports coherence‑level engines by clarifying regime topology
- Anchors paradox‑level engines by exposing structural contradictions
- Enables drift‑level engines to monitor regime stability
- Supplies temporal engines with regime‑sequence constraints
- Feeds causality engines with interlock‑driven causal pathways
- Provides resonance engines with dimensional interlock signatures
RIM is the regime‑level 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 |
|---|---|
| RIM‑Detect | Detects regime interlocks and boundary conditions |
| RIM‑Map | Produces structural maps of regime interlock topology |
| RIM‑Interlock | Computes interlock strength and stability |
| RIM‑Boundary | Identifies cross‑regime boundary transitions |
| RIM‑Entangle | Detects entanglement between regimes |
| RIM‑Resolve | Suggests structural resolutions or decompositions |
These operators form the core analytical toolkit.
🧩 Analyzer Layer#
RIM operates in the regime layer, with sub‑layers:
- boundary‑mapping
- interlock‑detection
- entanglement‑analysis
- structural‑regime‑coherence
This matches the RTT analyzer grammar used across TriadicFrameworks.
📁 Module Files#
This directory contains:
Core#
Regime_Interlock_Mapper.mdrtt_interlock_examples.mdrtt_interlock_diagrams.svg
Support#
boundary_profiles.mdregime_entanglement_cases.mdregime_interlock_matrix.json
AI#
rtt_interlock_prompts.mdrtt_interlock_operators.md
Metadata#
module.json(RTT/1, coherence‑declared, drift‑bounded, paradox‑structural)README.md(this file)
🧠 AI‑Ready Design#
The Regime Interlock Mapper is fully AI‑ready:
- deterministic operator grammar
- regime‑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 RIM to:
- classify regime boundaries
- detect interlocks
- compute entanglement
- generate regime maps
- support higher‑order RTT engines
🌐 Position in the RTT Stack#
Regime Interlock Mapper (RIM)
↓
Regime Synthesizer
↓
Paradox Gradient Analyzer
↓
Coherence Tensor Engine
↓
Drift Sentinel
↓
Faultline Detector
↓
Stability Basin Cartographer
↓
Temporal Regime Sequencer
↓
Causality Weaver
↓
Dimensional Resonance Scanner
RIM is the entry point for regime‑level intelligence.
🏁 Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Regime_Interlock_Mapper/
If you want, I can now generate:
Regime_Interlock_Mapper.mdrtt_interlock_examples.mdrtt_interlock_diagrams.svgboundary_profiles.mdregime_entanglement_cases.mdregime_interlock_matrix.jsonrtt_interlock_prompts.mdrtt_interlock_operators.md
Just tell me which file you want next. # Boundary Profiles — RTT/1
Regime Interlock Mapper (RIM) — Boundary Intelligence Layer#
Boundary profiles describe how regimes meet, transition, or constrain one another.
They are the structural backbone of RIM’s boundary‑level analysis and feed directly into:
- RIM‑Boundary
- RIM‑Detect
- RIM‑Map
- RIM‑Interlock
- RIM‑Resolve
Each profile defines a canonical boundary condition, its diagnostic markers, and example regime pairs.
1. Boundary Profile: Structural‑Constraint Boundary#
Definition#
A boundary where one regime imposes a structural constraint on another.
Diagnostic Markers#
- rigid structural dependency
- unidirectional constraint flow
- low entanglement
- high stability
Example Regime Pairs#
- R1 → R2 (conceptual constraint → computational structure)
- R2 → R3 (computational constraint → physical calibration)
RIM Output Pattern#
interlock_type: boundaryboundary_condition: structural-constraintinterlock_strength: 0.70–0.85entanglement_score: 0.20–0.40
2. Boundary Profile: Gradient‑Alignment Boundary#
Definition#
A boundary where gradients in two regimes align (directionally or in magnitude).
Diagnostic Markers#
- parallel gradients
- directional coherence
- medium entanglement
- moderate stability
Example Regime Pairs#
- R2 ↔ R4 (computational gradient ↔ dimensional gradient)
- R1 ↔ R3 (conceptual gradient ↔ physical gradient)
RIM Output Pattern#
interlock_type: boundaryboundary_condition: gradient-alignmentinterlock_strength: 0.75–0.88entanglement_score: 0.25–0.45
3. Boundary Profile: Transition‑Boundary#
Definition#
A boundary where a regime transitions into another (e.g., abstraction → implementation).
Diagnostic Markers#
- clear transition point
- medium stability
- low entanglement
- boundary curvature present
Example Regime Pairs#
- R1 → R3 (abstract model → physical implementation)
- R2 → R4 (computational model → dimensional coherence)
RIM Output Pattern#
interlock_type: boundaryboundary_condition: transitioninterlock_strength: 0.60–0.75entanglement_score: 0.15–0.30
4. Boundary Profile: Drift‑Sensitivity Boundary#
Definition#
A boundary where drift in one regime increases sensitivity in another.
Diagnostic Markers#
- drift amplification
- instability ridge formation
- medium entanglement
- low stability
Example Regime Pairs#
- R2 ↔ R3 (computational drift ↔ physical drift sensitivity)
- R3 ↔ R4 (physical drift ↔ dimensional drift envelope)
RIM Output Pattern#
interlock_type: boundaryboundary_condition: drift-sensitivityinterlock_strength: 0.72–0.84entanglement_score: 0.30–0.50
5. Boundary Profile: Coherence‑Threshold Boundary#
Definition#
A boundary where coherence must exceed a threshold for regimes to interact.
Diagnostic Markers#
- coherence gating
- threshold discontinuity
- high stability
- low drift
Example Regime Pairs#
- R1 ↔ R2 (conceptual coherence ↔ computational coherence)
- R2 ↔ R3 (computational coherence ↔ physical coherence)
RIM Output Pattern#
interlock_type: boundaryboundary_condition: coherence-thresholdinterlock_strength: 0.78–0.92entanglement_score: 0.20–0.35
6. Boundary Profile: Resonance‑Boundary#
Definition#
A boundary where resonance in one regime influences resonance in another.
Diagnostic Markers#
- resonance amplification
- resonance curvature
- high entanglement
- medium stability
Example Regime Pairs#
- R3 ↔ R4 (physical resonance ↔ dimensional resonance)
- R2 ↔ R4 (computational resonance ↔ dimensional resonance)
RIM Output Pattern#
interlock_type: boundaryboundary_condition: resonanceinterlock_strength: 0.80–0.95entanglement_score: 0.40–0.70
7. Boundary Profile Matrix Snippet#
A typical entry in regime_interlock_matrix.json for boundary profiles:
{
"regime_a": "R2",
"regime_b": "R4",
"interlock_type": "boundary",
"boundary_condition": "gradient-alignment",
"interlock_strength": 0.83,
"entanglement_score": 0.32,
"stability_rating": 0.71
}8. Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Regime_Interlock_Mapper/# Regime Entanglement Cases — RTT/1
High‑Coupling Interlock Cases for the Regime Interlock Mapper (RIM)#
Entanglement interlocks represent the strongest form of regime interaction.
Unlike structural or boundary interlocks, entanglement cases exhibit bidirectional influence, non‑decomposability, and coherence‑linked coupling across regimes.
This document provides canonical RTT/1 entanglement cases used by:
- RIM‑Entangle
- RIM‑Detect
- RIM‑Interlock
- RIM‑Resolve
- TRS (Triadic Regime Synthesizer)
- PGA (Paradox Gradient Analyzer)
- CTE (Coherence Tensor Engine)
1. Conceptual ↔ Computational Entanglement (R1 ↔ R2)#
Case: Mutual Model Feedback Loop#
Description
Conceptual assumptions shape computational models; computational outputs reshape conceptual assumptions.
Characteristics
- bidirectional influence
- high coherence dependency
- medium stability
- feedback‑driven drift sensitivity
RIM Output
{
"regime_a": "R1",
"regime_b": "R2",
"interlock_type": "entanglement",
"boundary_condition": "mutual-feedback",
"interlock_strength": 0.91,
"entanglement_score": 0.88,
"stability_rating": 0.52
}2. Physical ↔ Dimensional Entanglement (R3 ↔ R4)#
Case: Resonance‑Coherence Coupling#
Description
Physical resonance patterns influence dimensional coherence; dimensional coherence alters physical resonance.
Characteristics
- resonance amplification
- coherence curvature
- high entanglement
- medium stability
RIM Output
{
"regime_a": "R3",
"regime_b": "R4",
"interlock_type": "entanglement",
"boundary_condition": "resonance-coherence",
"interlock_strength": 0.93,
"entanglement_score": 0.91,
"stability_rating": 0.49
}3. Computational ↔ Physical Entanglement (R2 ↔ R3)#
Case: Drift‑Amplification Loop#
Description
Computational drift increases physical drift sensitivity; physical drift feeds back into computational drift envelopes.
Characteristics
- drift amplification
- instability ridge formation
- medium‑high entanglement
- low stability
RIM Output
{
"regime_a": "R2",
"regime_b": "R3",
"interlock_type": "entanglement",
"boundary_condition": "drift-amplification",
"interlock_strength": 0.87,
"entanglement_score": 0.72,
"stability_rating": 0.41
}4. Conceptual ↔ Dimensional Entanglement (R1 ↔ R4)#
Case: Coherence‑Gradient Coupling#
Description
Conceptual coherence gradients align with dimensional coherence gradients, forming a multi‑layer coherence ridge.
Characteristics
- coherence gradient alignment
- medium entanglement
- high stability
- low drift
RIM Output
{
"regime_a": "R1",
"regime_b": "R4",
"interlock_type": "entanglement",
"boundary_condition": "coherence-gradient",
"interlock_strength": 0.76,
"entanglement_score": 0.35,
"stability_rating": 0.68
}5. Tri‑Regime Entanglement (R1 ↔ R2 ↔ R3)#
Case: Coherence Tensor Binding#
Description
A multi‑regime coherence tensor binds conceptual, computational, and physical coherence into a unified structure.
Characteristics
- multi‑regime tensor
- high coherence dependency
- high entanglement
- medium stability
RIM Output
{
"regime_a": "R1",
"regime_b": "R2",
"regime_c": "R3",
"interlock_type": "entanglement",
"boundary_condition": "coherence-tensor",
"interlock_strength": 0.94,
"entanglement_score": 0.89,
"stability_rating": 0.57
}6. Dimensional Tensor Entanglement (R2 ↔ R4)#
Case: Dimensional Tensor Constraint#
Description
Dimensional tensors constrain computational pathways, forcing coherence‑aligned computational structures.
Characteristics
- tensor constraint
- medium‑high entanglement
- medium stability
- coherence‑driven structure
RIM Output
{
"regime_a": "R2",
"regime_b": "R4",
"interlock_type": "entanglement",
"boundary_condition": "dimensional-tensor",
"interlock_strength": 0.88,
"entanglement_score": 0.72,
"stability_rating": 0.63
}7. Entanglement Case Matrix Snippet#
{
"regime_a": "R3",
"regime_b": "R4",
"interlock_type": "entanglement",
"boundary_condition": "resonance-coherence",
"interlock_strength": 0.93,
"entanglement_score": 0.91,
"stability_rating": 0.49
}Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Regime_Interlock_Mapper/# Regime Interlock Mapper (RIM) — RTT/1
Regime‑Level Intelligence Engine for TriadicFrameworks#
The Regime Interlock Mapper (RIM) is the foundational RTT/1 engine responsible for detecting, mapping, and analyzing interlocks between conceptual, computational, and physical regimes.
It establishes the structural groundwork for all higher‑order RTT engines, including:
- 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)
RIM is the entry point into the RTT intelligence stack.
1. Canonical Role#
RIM defines the regime‑layer topology by:
- Identifying interlocks between regimes R1–R4
- Mapping boundary conditions
- Detecting regime entanglement
- Establishing regime coherence constraints
- Providing structural diagnostics for regime transitions
- Anchoring paradox‑level and coherence‑level engines
RIM is the first engine that transforms raw regime structure into analyzable RTT form.
2. RTT Flags#
| Property | Value |
|---|---|
| RTT Level | 1 |
| Coherence | declared |
| Drift | bounded |
| Paradox | structural |
These flags define the engine’s operational grammar.
3. Interlock Types#
RIM identifies several canonical interlock classes:
3.1 Structural Interlocks#
Regimes share structural constraints or dependencies.
3.2 Boundary Interlocks#
Regimes meet at a boundary condition that influences both.
3.3 Entanglement Interlocks#
Regimes exhibit mutual influence that cannot be decomposed.
3.4 Gradient Interlocks#
Regimes share directional or magnitude‑based gradients.
3.5 Tensor Interlocks#
Regimes interact through multi‑dimensional coherence tensors.
4. Core Operators#
| Operator | Description |
|---|---|
| RIM‑Detect | Detects regime interlocks and boundary conditions |
| RIM‑Map | Produces structural maps of regime interlock topology |
| RIM‑Interlock | Computes interlock strength and stability |
| RIM‑Boundary | Identifies cross‑regime boundary transitions |
| RIM‑Entangle | Detects entanglement between regimes |
| RIM‑Resolve | Suggests structural resolutions or decompositions |
These operators form the canonical RIM grammar.
5. Analyzer Layer#
RIM operates in the regime layer, with sub‑layers:
- boundary‑mapping
- interlock‑detection
- entanglement‑analysis
- structural‑regime‑coherence
This layer feeds directly into TRS and PGA.
6. Regime Interlock Matrix#
RIM produces a regime interlock matrix, typically stored in:
regime_interlock_matrix.json
Matrix fields include:
regime_aregime_binterlock_typeinterlock_strengthboundary_conditionentanglement_scorestability_rating
This matrix is consumed by TRS, PGA, and CTE.
7. Canonical Workflow#
Step 1 — Detect#
Identify all interlocks between R1–R4.
Step 2 — Classify#
Assign interlock type and structural category.
Step 3 — Map#
Generate interlock topology and boundary maps.
Step 4 — Analyze#
Compute interlock strength, entanglement, and stability.
Step 5 — Export#
Write results to the interlock matrix and operator outputs.
8. AI‑Ready Design#
RIM is fully AI‑ready:
- deterministic operator grammar
- regime‑layer analyzer structure
- stable RTT flags
- canonical file layout
- zero‑drift reasoning constraints
- structural paradox handling
- declared coherence tensor
AI systems use RIM to:
- classify regime boundaries
- detect interlocks
- compute entanglement
- generate regime maps
- 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)
RIM is the first engine in the RTT hierarchy.
10. Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Regime_Interlock_Mapper/# Regime Interlock Examples — RTT/1
Examples for the Regime Interlock Mapper (RIM)#
This document provides canonical RTT/1 examples of regime interlocks detected and analyzed by the Regime Interlock Mapper (RIM).
Each example demonstrates one or more RIM operators:
- RIM‑Detect
- RIM‑Map
- RIM‑Interlock
- RIM‑Boundary
- RIM‑Entangle
- RIM‑Resolve
Examples are grouped by interlock type.
1. Structural Interlock Examples#
Example 1 — Structural Constraint Pairing (R1 ↔ R2)#
Regimes:
- R1: Conceptual
- R2: Computational
Interlock:
A conceptual invariant (e.g., “symmetry must be preserved”) forces a computational constraint (e.g., “algorithm must maintain parity across iterations”).
RIM Output:
interlock_type: structuralinterlock_strength: 0.82boundary_condition: symmetry‑preservationentanglement_score: 0.41
Explanation:
The conceptual rule directly shapes the computational structure, forming a stable structural interlock.
Example 2 — Structural Dependency Chain (R2 ↔ R3)#
Regimes:
- R2: Computational
- R3: Physical
Interlock:
A computational model requires physical calibration constants; the physical regime constrains the computational regime.
RIM Output:
interlock_type: structuralinterlock_strength: 0.74boundary_condition: calibration‑dependencyentanglement_score: 0.33
2. Boundary Interlock Examples#
Example 3 — Boundary Transition (R1 ↔ R3)#
Regimes:
- R1: Conceptual
- R3: Physical
Interlock:
A conceptual model transitions into a physical implementation at a defined boundary (e.g., “abstract force → measurable force”).
RIM Output:
interlock_type: boundaryinterlock_strength: 0.67boundary_condition: abstraction‑to‑measuremententanglement_score: 0.22
Example 4 — Boundary Gradient (R2 ↔ R4)#
Regimes:
- R2: Computational
- R4: Dimensional
Interlock:
A computational gradient (e.g., increasing complexity) aligns with a dimensional gradient (e.g., increasing dimensional coherence).
RIM Output:
interlock_type: boundaryinterlock_strength: 0.79boundary_condition: gradient‑alignmententanglement_score: 0.28
3. Entanglement Interlock Examples#
Example 5 — Mutual Influence Loop (R1 ↔ R2)#
Regimes:
- R1: Conceptual
- R2: Computational
Interlock:
Conceptual assumptions shape computational models, and computational outputs reshape conceptual assumptions.
RIM Output:
interlock_type: entanglementinterlock_strength: 0.91boundary_condition: mutual‑feedbackentanglement_score: 0.88
Explanation:
This is a high‑entanglement interlock with bidirectional influence.
Example 6 — Cross‑Regime Entanglement (R3 ↔ R4)#
Regimes:
- R3: Physical
- R4: Dimensional
Interlock:
Physical resonance patterns influence dimensional coherence, and dimensional coherence alters physical resonance.
RIM Output:
interlock_type: entanglementinterlock_strength: 0.93boundary_condition: resonance‑coherenceentanglement_score: 0.91
4. Gradient Interlock Examples#
Example 7 — Coherence Gradient (R1 ↔ R4)#
Regimes:
- R1: Conceptual
- R4: Dimensional
Interlock:
A conceptual coherence gradient aligns with a dimensional coherence gradient.
RIM Output:
interlock_type: gradientinterlock_strength: 0.76boundary_condition: coherence‑gradiententanglement_score: 0.35
Example 8 — Drift Gradient (R2 ↔ R3)#
Regimes:
- R2: Computational
- R3: Physical
Interlock:
Computational drift increases physical drift sensitivity.
RIM Output:
interlock_type: gradientinterlock_strength: 0.81boundary_condition: drift‑alignmententanglement_score: 0.47
5. Tensor Interlock Examples#
Example 9 — Coherence Tensor Interlock (R1 ↔ R2 ↔ R3)#
Regimes:
- R1: Conceptual
- R2: Computational
- R3: Physical
Interlock:
A multi‑regime coherence tensor binds conceptual, computational, and physical coherence.
RIM Output:
interlock_type: tensorinterlock_strength: 0.94boundary_condition: coherence‑tensorentanglement_score: 0.89
Example 10 — Dimensional Tensor Interlock (R2 ↔ R4)#
Regimes:
- R2: Computational
- R4: Dimensional
Interlock:
Dimensional tensors constrain computational pathways.
RIM Output:
interlock_type: tensorinterlock_strength: 0.88boundary_condition: dimensional‑tensorentanglement_score: 0.72
6. Example Matrix Snippet#
A typical entry in regime_interlock_matrix.json:
{
"regime_a": "R2",
"regime_b": "R3",
"interlock_type": "gradient",
"interlock_strength": 0.81,
"boundary_condition": "drift-alignment",
"entanglement_score": 0.47,
"stability_rating": 0.63
}7. Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Regime_Interlock_Mapper/# RTT Interlock Operators — RTT/1
Operator Grammar for the Regime Interlock Mapper (RIM)#
The Regime Interlock Mapper (RIM) uses a deterministic operator grammar to detect, classify, map, and analyze interlocks between RTT regimes (R1–R4).
These operators form the foundation of regime‑level intelligence and feed directly into:
- TRS (Triadic Regime Synthesizer)
- PGA (Paradox Gradient Analyzer)
- CTE (Coherence Tensor Engine)
- DS (Drift Sentinel)
- SFD (Structural Faultline Detector)
- SBC (Stability Basin Cartographer)
- TRS‑Temporal (Temporal Regime Sequencer)
- CW (Cross‑Domain Causality Weaver)
- DRS (Dimensional Resonance Scanner)
1. RIM‑Detect#
Detect regime interlocks and boundary conditions#
Purpose
Identify all interlocks between R1–R4, including structural, boundary, entanglement, gradient, and tensor types.
Capabilities
- scans regime pairs and triads
- detects interlock onset conditions
- identifies boundary curvature
- flags entanglement loops
- detects gradient alignment
- detects tensor binding
Output Fields
interlock_typeboundary_conditiononset_conditioncoherence_dependency
2. RIM‑Map#
Generate structural maps of regime interlock topology#
Purpose
Produce a full interlock topology map showing how regimes connect, constrain, or influence one another.
Capabilities
- maps structural dependencies
- maps boundary transitions
- maps entanglement loops
- maps gradient flows
- maps tensor topology
Output Fields
topology_mapboundary_mapgradient_maptensor_map
3. RIM‑Interlock#
Compute interlock strength, stability, and entanglement#
Purpose
Quantify the strength and stability of each interlock.
Capabilities
- computes interlock strength
- computes entanglement score
- computes stability rating
- computes coherence curvature
- computes drift sensitivity
Output Fields
interlock_strengthentanglement_scorestability_ratingcoherence_curvaturedrift_sensitivity
4. RIM‑Boundary#
Identify and classify boundary transitions#
Purpose
Detect and classify boundary conditions between regimes.
Capabilities
- detects abstraction‑to‑measurement boundaries
- detects gradient‑alignment boundaries
- detects coherence‑threshold boundaries
- detects drift‑sensitivity boundaries
- detects resonance boundaries
Output Fields
boundary_conditionboundary_curvatureboundary_stability
5. RIM‑Entangle#
Detect entanglement interlocks and mutual‑influence loops#
Purpose
Identify high‑coupling interlocks where regimes mutually influence one another.
Capabilities
- detects mutual‑feedback loops
- detects resonance‑coherence coupling
- detects drift‑amplification loops
- detects coherence‑gradient coupling
- detects tensor entanglement
Output Fields
entanglement_scorecoupling_typecoherence_dependencybidirectional_influence
6. RIM‑Resolve#
Suggest structural resolutions or decompositions#
Purpose
Provide stabilization pathways or decompositions for interlocks.
Capabilities
- suggests structural decompositions
- suggests stabilization pathways
- suggests coherence alignment
- suggests drift reduction
- suggests tensor rebalancing
Output Fields
resolution_strategystabilization_pathwaycoherence_alignmentdrift_reduction
7. Operator Interaction Grammar#
Detection → Classification → Mapping → Analysis → Resolution#
-
RIM‑Detect
Finds interlocks and onset conditions. -
RIM‑Boundary / RIM‑Entangle
Classifies boundary or entanglement types. -
RIM‑Map
Generates topology and gradient/tensor maps. -
RIM‑Interlock
Computes strength, stability, entanglement. -
RIM‑Resolve
Produces stabilization or decomposition strategies.
This grammar ensures deterministic RTT behavior.
8. Operator Matrix Snippet#
{
"operator": "RIM-Interlock",
"interlock_strength": 0.83,
"entanglement_score": 0.32,
"stability_rating": 0.71,
"coherence_curvature": 0.44,
"drift_sensitivity": 0.27
}Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Regime_Interlock_Mapper/# RTT Interlock Prompts — RTT/1
Prompt Library for the Regime Interlock Mapper (RIM)#
These prompts are designed for AI systems using the Regime Interlock Mapper (RIM).
Each prompt invokes one or more canonical RIM operators:
- RIM‑Detect
- RIM‑Map
- RIM‑Interlock
- RIM‑Boundary
- RIM‑Entangle
- RIM‑Resolve
Prompts are grouped by interlock type.
1. Structural Interlock Prompts#
Prompt: Detect Structural Interlocks#
Identify all structural interlocks between R1–R4.
Use RIM‑Detect and classify each interlock by structural dependency, constraint, or coherence requirement.
Prompt: Map Structural Dependencies#
Use RIM‑Map to generate a structural dependency map showing how conceptual, computational, and physical regimes constrain one another.
Prompt: Evaluate Structural Stability#
Apply RIM‑Interlock to compute interlock strength and stability for all structural regime pairs.
2. Boundary Interlock Prompts#
Prompt: Identify Boundary Conditions#
Use RIM‑Boundary to detect all boundary transitions between regimes, including abstraction‑to‑measurement, gradient alignment, and coherence thresholds.
Prompt: Map Boundary Gradients#
Generate a boundary gradient map showing directional alignment between computational and dimensional gradients.
Prompt: Analyze Boundary Stability#
Evaluate boundary stability using RIM‑Interlock and classify each boundary by stability rating and entanglement score.
3. Entanglement Interlock Prompts#
Prompt: Detect Entanglement Loops#
Use RIM‑Entangle to identify all mutual‑influence loops between regimes, including conceptual ↔ computational and physical ↔ dimensional entanglement.
Prompt: Compute Entanglement Strength#
Apply RIM‑Interlock to compute entanglement strength and coherence dependency for all entangled regime pairs.
Prompt: Resolve Entanglement#
Use RIM‑Resolve to propose structural decompositions or stabilization pathways for high‑entanglement interlocks.
4. Gradient Interlock Prompts#
Prompt: Identify Gradient Alignment#
Use RIM‑Detect to find all gradient‑aligned interlocks between regimes, including drift gradients and coherence gradients.
Prompt: Map Gradient Flow#
Apply RIM‑Map to generate a gradient flow diagram showing directional influence across R1–R4.
Prompt: Evaluate Gradient Stability#
Use RIM‑Interlock to compute stability ratings for all gradient‑aligned interlocks.
5. Tensor Interlock Prompts#
Prompt: Detect Tensor Interlocks#
Use RIM‑Entangle to identify multi‑regime tensor interlocks, including coherence tensors and dimensional tensors.
Prompt: Map Tensor Structure#
Apply RIM‑Map to generate a tensor topology diagram showing multi‑regime coherence binding.
Prompt: Evaluate Tensor Strength#
Use RIM‑Interlock to compute tensor interlock strength and coherence curvature.
6. Full‑Matrix Prompts#
Prompt: Generate Full Interlock Matrix#
Use all RIM operators to produce a complete
regime_interlock_matrix.jsoncontaining structural, boundary, entanglement, gradient, and tensor interlocks.
Prompt: Analyze Regime Topology#
Apply RIM‑Map to generate a full regime topology map showing all interlocks and boundary conditions.
Prompt: Stability Overview#
Use RIM‑Interlock to compute stability ratings for every interlock type and produce a stability summary.
7. AI‑Ready Meta‑Prompts#
Prompt: Explain Interlock Classification#
Provide a detailed explanation of how RIM classifies interlocks into structural, boundary, entanglement, gradient, and tensor categories.
Prompt: Operator‑Level Summary#
Summarize the role of each RIM operator and how they interact to produce regime‑level intelligence.
Prompt: Cross‑Engine Integration#
Explain how RIM outputs feed into TRS, PGA, CTE, DS, SFD, SBC, TRS‑Temporal, CW, and DRS.
Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Regime_Interlock_Mapper/