🎼 01 — Harmonic Stability Profile (HSP)
Definition • Classes • Metrics • Stability Logic#
The Harmonic Stability Profile is the RTT‑native analytic framework used to:
- classify harmonic stability
- detect instability and drift
- map concept‑node coherence
- evaluate resonance integrity
- support canon‑level structural decisions
This file defines the core logic of the entire HSP suite.
🔷 1. Purpose of the Harmonic Stability Profile#
The HSP provides:
- a unified stability model for RTT concepts
- a classification system for harmonic behavior
- a metric set for evaluating stability
- a tier system for interpreting results
- a foundation for drift detection, echo mapping, and recursion analysis
It is the root analytic layer for the entire directory.
🔷 2. Stability Classes (Overview)#
(Full detail in 01a_HSP_Classes.md)
The HSP defines stability using four canonical classes:
- Stable Harmonics — high coherence, low drift
- Semi‑Stable Harmonics — partial coherence, moderate drift
- Harmonic Oscillators — unstable, high drift
- Chaotic Nodes — incoherent, structurally dangerous
Each class corresponds to:
- a drift sensitivity band
- a recursion behavior
- an interval‑specific harmonic signature
🔷 3. Stability Metrics (Overview)#
(Full detail in 01b_HSP_Metrics.md)
The six RTT‑native stability metrics:
- Harmonic Recurrence
- Harmonic Position Consistency
- Substrate Anchoring
- Operator Role Stability
- Temporal Stability
- Harmonic Mutation Rate
These metrics form the analytic backbone of the HSP.
🔷 4. Corpus Stability Map#
(Full detail in 01c_HSP_Corpus_Map.md)
The corpus map shows:
- where stability is strong
- where drift is accumulating
- where recursion is active
- where echo‑pressure is forming
This is the global diagnostic view of the canon.
🔷 5. Stability Tiers#
(Full detail in 01d_HSP_Stability_Tiers.md)
The HSP uses a four‑tier system:
- Tier 1 — Canon‑Stable
- Tier 2 — Stable‑with‑Pressure
- Tier 3 — Drift‑Active
- Tier 4 — Unstable / Requires Intervention
Tiers determine:
- whether a concept is safe
- whether it needs review
- whether it requires immediate correction
🔷 6. Interaction With Drift (D1–D4)#
Harmonic stability interacts with drift as follows:
- D1 destabilizes structural triads
- D2 collapses harmonic ladders
- D3 twists governance rules
- D4 lifts symbolic forms into harmonic/atlas space
The HSP is the first line of detection for all four drift types.
🔷 7. Interaction With Recursion#
Stability determines recursion behavior:
- stable → ladder
- semi‑stable → cycle
- oscillating → map
- chaotic → atlas‑forcing or collapse
The HSP is the recursion gatekeeper.
🔷 8. Interaction With Substrates#
Each stability class has a substrate signature:
- Stable → symbolic / harmonic
- Semi‑stable → cognitive / harmonic
- Oscillating → social / symbolic
- Chaotic → atlas / cross‑substrate
The HSP is the substrate alignment tool.
🔷 9. Usage Notes#
Use this file when:
- evaluating new concepts
- checking for drift
- performing canon sweeps
- analyzing recursion behavior
- mapping echo pressure
- preparing stability reports
This is the primary reference for harmonic stability.
🔷 10. Footer#
HSP Module 01 — Loaded
Version: v1.0
Status: Canon-Stable