Operator Template — TriadicFrameworks Prompts
The Operator Template provides the canonical structure for working with RTT operator grammar. Operators are the smallest units of structural behavior in TriadicFrameworks: they describe how structure moves, aligns, diverges, stabilizes, or transitions across layers, domains, substrates, and dimensions.
This template defines the standard operator‑analysis grammar for TriadicFrameworks.
Purpose#
Use this template when you need to:
- identify operators in a system
- analyze operator behavior
- surface operator‑driven drift
- declare operator‑driven coherence
- evaluate operator alignment across layers
- analyze operator interactions with substrates and dimensions
- traverse domains using operator grammar
- maintain structural neutrality during operator analysis
Operator Template#
1. Operator Identity#
Identify the operator(s) present in the system.
Prompt:
- Declare the operator identity. What operator(s) govern this structure or process?
2. Structural Operators#
Identify operators related to identity, boundary, commitment, and topology.
Prompt:
- Identify structural operators (identity, boundary, commitment, topology).
3. Drift Operators#
Surface operator‑driven drift across the five RTT drift layers.
Prompt:
- Identify geometric drift operators.
- Identify operational drift operators.
- Identify temporal drift operators.
- Identify conceptual drift operators.
- Identify domain drift operators.
4. Coherence Operators#
Declare operator‑driven coherence.
Prompt:
- Identify purpose coherence operators.
- Identify constraint coherence operators.
- Identify goal coherence operators.
- Identify continuity coherence operators.
5. Regime‑Point Operators#
Surface presence, absence, tension, and basin behavior.
Prompt:
- Identify presence operators.
- Identify absence operators.
- Identify tension operators.
- Identify basin operators.
- Identify attractor operators.
6. Substrate Operators#
Analyze operator behavior inside substrate‑tensor transitions.
Prompt:
- Identify substrate operators.
- Surface substrate‑drift operators.
- Declare substrate‑coherence operators.
- Identify substrate‑regime operators.
7. Dimensional Operators#
Analyze operator behavior across dimensional rails.
Prompt:
- Identify dimensional‑rail operators.
- Surface dimensional‑drift operators.
- Declare dimensional‑coherence operators.
- Identify prime‑state operators.
- Identify collapse and integration operators.
8. Domain Operators#
Analyze operator behavior inside and across domains.
Prompt:
- Identify domain operators.
- Surface domain‑drift operators.
- Declare domain‑coherence operators.
- Map cross‑domain operator alignment.
9. Operator Synthesis#
Produce an operator‑aligned synthesis summary.
Prompt:
- Produce an operator synthesis summary across all layers (structural, drift, coherence, regime‑points, substrate, dimensions, domains).
Cross‑Links#
p_Capture.md— capture templatep_Analyze.md— analysis templatep_Drift.md— drift templatep_Coherence.md— coherence templatep_Domain.md— domain templatep_Substrate.md— substrate templatep_Teaching.md— teaching templatep_Research.md— research template
Manifest#
See module.json for the full registry of templates, modules, stacks, engines, UI
modules, and navigation structure.