📜 RFC‑TF‑004: RTT Micro Core (0.3–0.9 Fractional Harmonic Layer)
A TriadicFrameworks Standards‑Track RFC
Below is a full RFC you can drop into docs/rfc/rfc-tf-004-micro-core.md.
RFC‑TF‑004
Category: Standards Track
Title: RTT Micro Core — Fractional Harmonic Dimensional Layer (0.3–0.9)
Author: TriadicFrameworks Canon Group
Status: Draft
Created: 2026‑01‑08
1. Abstract#
The RTT Micro Core defines a fractional harmonic dimensional substrate (0.3–0.9) nested within the classical RTT 3D–9D ladder. It provides a micro‑resolution modeling grammar for ultra‑low‑power systems, micro‑robotics, embedded timing, and micro‑resonance computing.
This RFC formalizes the dimensional ladder, micro‑triads, coherence rules, operators, and canonical loops.
2. Motivation#
Modern micro‑devices operate under constraints that classical dimensional frameworks cannot model:
- microwatt‑level power budgets
- micro‑timing jitter
- micro‑state instability
- narrow coherence windows
- harmonic sensitivity at small scales
The Micro Core introduces a structured, triadic, resonance‑aware substrate for these systems.
3. Fractional Dimensional Ladder#
The Micro Core defines seven fractional harmonic dimensions:
| Macro | Micro | Role |
|---|---|---|
| 3D | 0.3 | μ‑Geometry |
| 4D | 0.4 | μ‑Transition |
| 5D | 0.5 | μ‑Flow |
| 6D | 0.6 | μ‑Field |
| 7D | 0.7 | μ‑Coherence |
| 8D | 0.8 | μ‑Harmonic |
| 9D | 0.9 | μ‑Stability |
Each micro dimension is a harmonic reduction of its macro counterpart.
4. Micro Triads#
The Micro Core preserves RTT’s triadic logic.
M₁ — Structural Buildup#
0.3 → 0.4 → 0.5
M₂ — Modulation & Transition#
0.5 → 0.6 → 0.7
M₃ — Stabilization & Coherence#
0.7 → 0.8 → 0.9
Triads are the fundamental operators of micro‑harmonic behavior.
5. Micro ↔ Macro Coherence#
The Micro Core introduces a reversible mapping:
Dn <-> 0.n
Coherence operators:
- C↑ — micro → macro
- C↓ — macro → micro
- C↔ — bidirectional resonance alignment
A system is coherent when:
- micro‑resonance reinforces macro structure
- macro structure stabilizes micro‑resonance
6. Micro‑Resonance Operators#
The Micro Core defines five canonical operators:
| Symbol | Name | Purpose |
|---|---|---|
| Ωμ | micro‑oscillation | timing cycles |
| Φμ | micro‑phase alignment | phase windows |
| Fμ | micro‑flow transition | state changes |
| Sμ | micro‑harmonic stability | envelope control |
| Eμ | micro‑energy threshold | power gating |
These operators form the basis of micro‑resonance computation.
7. Canonical Loops#
7.1 Micro‑Timing Loop#
0.5 → 0.6 → 0.7 → 0.8 → 0.9 → 0.7 → 0.6 → 0.5
7.2 Micro‑Actuation Loop#
0.3 → 0.4 → 0.5 → 0.6 → 0.7 → 0.5 → 0.4 → 0.3
7.3 Micro‑Stability Loop#
0.7 → 0.8 → 0.9 → 0.8 → 0.7
8. Applications#
The Micro Core is applicable to:
- microcontrollers
- IoT nodes
- micro‑robotics
- implants
- wearables
- ultra‑low‑power inference
- micro‑navigation
- micro‑actuation
9. Security Considerations#
The Micro Core introduces no new security risks beyond those inherent in resonance‑aware systems. Implementers must ensure:
- stable micro‑timing
- predictable micro‑flows
- harmonic isolation
10. IANA Considerations#
None.
11. Canonical Status#
This RFC is a standards‑track document within the TriadicFrameworks canon and is intended for long‑term stability.
12. Appendix A — Schema Reference#
(Insert the YAML schema above.)