DRS Prompts — RTT/1
Prompt Library for the Dimensional Resonance Scanner (DRS)#
These prompts are designed for AI systems using the Dimensional Resonance Scanner (DRS).
Each prompt invokes one or more canonical DRS operators:
- DRS‑Scan
- DRS‑Frequency
- DRS‑Field
- DRS‑Vector
- DRS‑Amplify
- DRS‑Stabilize
Prompts are grouped by resonance tensor type and operator class.
1. Resonance Signature Prompts#
Prompt: Detect Resonance Signatures#
Use DRS‑Scan to identify resonance onset, polarity, harmonic structure, and resonance‑vector alignment across R1–R4.
Prompt: Analyze Resonance Polarity#
Apply DRS‑Scan to compute resonance polarity, onset strength, and polarity stability.
Prompt: Evaluate Resonance Onset Conditions#
Use DRS‑Scan to detect resonance onset conditions and classify resonance signature tensors.
2. Resonance Frequency Prompts#
Prompt: Compute Resonance Frequency#
Use DRS‑Frequency to compute resonance frequency, harmonic magnitude, and resonance‑frequency curvature.
Prompt: Detect Harmonic Frequency Alignment#
Apply DRS‑Frequency to detect harmonic alignment, harmonic sensitivity, and drift‑sensitive frequency behavior.
Prompt: Evaluate Frequency Inversion#
Use DRS‑Frequency to identify polarity flips, inversion bands, and inversion curvature.
3. Resonance Field Prompts#
Prompt: Map Resonance Fields#
Use DRS‑Field to map resonance fields, resonance wells, resonance ridges, resonance basins, and resonance topology.
Prompt: Generate Resonance‑Field Topology#
Apply DRS‑Field to generate resonance‑field topology diagrams showing multi‑regime resonance curvature.
Prompt: Evaluate Resonance‑Field Strength#
Use DRS‑Field to compute resonance‑field magnitude, curvature, and envelope boundaries.
4. Resonance Vector Prompts#
Prompt: Compute Resonance Vector Magnitude#
Use DRS‑Vector to compute resonance vector magnitude, direction, curvature, and multi‑regime resonance flow.
Prompt: Detect Cross‑Domain Resonance Vectors#
Apply DRS‑Vector to detect resonance vectors formed across conceptual, computational, physical, and dimensional regimes.
Prompt: Evaluate Drift‑Sensitive Resonance Vectors#
Use DRS‑Vector to identify drift‑sensitive resonance vectors and drift‑aligned resonance curvature.
5. Resonance Amplification Prompts#
Prompt: Detect Resonance Amplification Zones#
Use DRS‑Amplify to identify amplification zones, resonance growth, and instability amplification.
Prompt: Map Amplification Geometry#
Apply DRS‑Amplify to compute amplification depth, amplification curvature, and amplification topology.
Prompt: Evaluate Amplification‑Driven Instability#
Use DRS‑Amplify to detect amplification‑driven instability and resonance collapse risk.
6. Stabilization Prompts#
Prompt: Propose Resonance Stabilization Pathways#
Use DRS‑Stabilize to propose stabilization strategies for resonance collapse, amplification escalation, and resonance‑field instability.
Prompt: Compute Resonance Alignment#
Apply DRS‑Stabilize to compute resonance alignment, vector reinforcement, and field stabilization.
Prompt: Evaluate Resonance‑Collapse Mitigation#
Use DRS‑Stabilize to propose mitigation strategies for resonance collapse and amplification amplification.
7. Full‑Matrix Prompts#
Prompt: Generate Full Resonance Field Matrix#
Use all DRS operators to produce a complete
resonance_field_matrix.jsoncontaining signature, frequency, field, amplification, and vector entries.
Prompt: Analyze Resonance Topology#
Apply DRS‑Field to generate a full resonance topology map showing fields, vectors, amplification zones, and resonance flow.
Prompt: Resonance Overview#
Use DRS‑Stabilize to compute stability envelopes for every resonance tensor type and produce a resonance summary.
8. AI‑Ready Meta‑Prompts#
Prompt: Explain Resonance Tensor Classification#
Provide a detailed explanation of how DRS classifies resonance tensors into signature, frequency, field, amplification, and vector categories.
Prompt: Operator‑Level Summary#
Summarize the role of each DRS operator and how they interact to produce resonance‑layer intelligence.
Prompt: Cross‑Engine Integration#
Explain how DRS outputs feed into CW (Causality Weaver), TRS‑Temporal, SBC, and other RTT engines.
Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑resonance
- Module Path:
/docs/rtt/Dimensional_Resonance_Scanner/