PGA Prompts — RTT/1
Prompt Library for the Paradox Gradient Analyzer#
These prompts are designed for AI systems using the Paradox Gradient Analyzer (PGA).
Each prompt invokes one or more canonical PGA operators:
- PGA‑Detect
- PGA‑Gradient
- PGA‑Intensity
- PGA‑Source
- PGA‑Field
- PGA‑Resolve
Prompts are grouped by paradox type and operator class.
1. Structural Paradox Prompts#
Prompt: Detect Structural Paradox Sources#
Use PGA‑Detect to identify all structural paradox sources, including symmetry‑violation, calibration‑contradiction, and invariant‑break conditions.
Prompt: Map Structural Paradox Fields#
Apply PGA‑Field to generate a structural paradox field map showing curvature, basin geometry, and paradox ridges.
Prompt: Compute Structural Paradox Gradients#
Use PGA‑Gradient to compute gradient magnitude, direction, and coherence dependency for structural paradoxes.
2. Gradient Paradox Prompts#
Prompt: Identify Opposing Gradients#
Use PGA‑Detect to find all coherence‑gradient and drift‑gradient oppositions across R1–R4.
Prompt: Compute Gradient Vectors#
Apply PGA‑Gradient to compute paradox gradient vectors, including magnitude, direction, and inversion signatures.
Prompt: Analyze Gradient Intensity#
Use PGA‑Intensity to measure paradox intensity for all gradient‑aligned or gradient‑opposed paradoxes.
3. Boundary Paradox Prompts#
Prompt: Detect Boundary Paradox Conditions#
Use PGA‑Source to identify paradoxes arising at regime boundaries, including abstraction‑measurement and gradient‑boundary contradictions.
Prompt: Map Boundary Curvature#
Apply PGA‑Field to generate boundary curvature maps showing paradox onset and basin formation.
Prompt: Evaluate Boundary Stability#
Use PGA‑Intensity to compute stability ratings for all boundary paradoxes.
4. Tensor Paradox Prompts#
Prompt: Detect Tensor Paradox Violations#
Use PGA‑Detect to identify coherence‑tensor and dimensional‑tensor paradox sources across multi‑regime interactions.
Prompt: Map Tensor Paradox Fields#
Apply PGA‑Field to generate tensor paradox topology diagrams showing multi‑regime curvature and basin geometry.
Prompt: Compute Tensor Gradient Strength#
Use PGA‑Gradient to compute tensor gradient magnitude, direction, and coherence curvature.
5. Drift‑Induced Paradox Prompts#
Prompt: Identify Drift‑Amplification Paradoxes#
Use PGA‑Detect to find paradoxes where drift in one regime amplifies drift curvature in another.
Prompt: Map Drift‑Induced Paradox Basins#
Apply PGA‑Field to generate drift‑amplification basin maps showing instability ridges and drift wells.
Prompt: Analyze Drift‑Coherence Paradox Intensity#
Use PGA‑Intensity to compute intensity and stability ratings for drift‑coherence paradoxes.
6. Full‑Matrix Prompts#
Prompt: Generate Full Paradox Gradient Matrix#
Use all PGA operators to produce a complete
paradox_gradient_matrix.jsoncontaining structural, gradient, boundary, tensor, and drift‑induced paradox entries.
Prompt: Analyze Paradox Field Topology#
Apply PGA‑Field to generate a full paradox topology map showing paradox fields, basins, curvature, and gradient flows.
Prompt: Stability Overview#
Use PGA‑Intensity to compute stability ratings for every paradox type and produce a paradox stability summary.
7. AI‑Ready Meta‑Prompts#
Prompt: Explain Paradox Classification#
Provide a detailed explanation of how PGA classifies paradoxes into structural, gradient, boundary, tensor, and drift‑induced categories.
Prompt: Operator‑Level Summary#
Summarize the role of each PGA operator and how they interact to produce paradox‑layer intelligence.
Prompt: Cross‑Engine Integration#
Explain how PGA outputs feed into CTE, DS, SFD, SBC, TRS‑Temporal, CW, and DRS.
Status#
- Version: 1.0
- Status: canon‑stable
- Category: rtt‑structural
- Module Path:
/docs/rtt/Paradox_Gradient_Analyzer/