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/