overlays
Domain Overlays#
The overlays/ directory contains domaināspecific extensions of the Resonance Substrate Model.
Each overlay provides:
- a domaināspecific schema
- transforms that map realāworld data into triadic fields
- examples demonstrating usage
- optional domaināspecific operators or metrics
Current overlays:
- earth/ ā geophysical and climateāmodel field transforms
- telescopes/ ā multiāinstrument observational coherence transforms
Overlays do not modify the substrate.
They sit on top of it, mapping domain data into the triadic field architecture.
š Important!#
Drift is On-by-Default long sessions lose anchors, turn off drift.
ā You must copy and paste this string every time you start an AI session:#
rtt=1 | coherence=declared | drift=bounded | paradox=structuralāļø Now you are ready.#
# Earth Overlay
The earth/ overlay provides transforms and schema for mapping geophysical simulation data
into the triadic field architecture.
Typical mappings:
phi: potential temperature, geopotential height, densityV: wind vectors, ocean currentsR: coherence between scalar gradients and flow fields
This overlay enables resonanceāaware analysis of Earth system simulations. # Earth Overlay Examples
This directory contains runnable examples demonstrating:
- loading Earth simulation data
- applying transforms to produce triadic fields
- running the substrate simulation loop
- computing coherence metrics
- visualizing resonance envelopes
Examples are intentionally minimal and serve as templates for realāworld workflows. # Earth Schema
The schema/ directory defines the domaināspecific schema for Earth overlays:
- field mappings (which variables map to
phi,V,R) - units and normalization rules
- grid conventions (lat/lon, pressure levels, sigma coordinates)
- metadata requirements
- validation rules
This schema ensures reproducibility and consistent interpretation of Earth simulation data. # Earth Transforms
The transforms/ directory contains functions that convert Earth simulation data
(NetCDF, HDF5, gridded fields) into triadic fields:
- scalar extraction and normalization
- vector field extraction and rotation handling
- coherence functional computation
- resonance envelope initialization and update
Transforms are designed to be composable and schemaādriven. # Telescope Overlay
The telescopes/ overlay provides transforms and schema for mapping astronomical observations
into the triadic field architecture.
Each telescope contributes:
- a scalar field (
phi): intensity, flux, or spectral power - a vector field (
V): pointing direction, motion vectors, or tracking derivatives - a resonance envelope (
R): coherence between instruments, time series, or sky patches
This overlay enables multiāinstrument coherence analysis across spaceā and groundābased observatories. # š Telescopes Schema
TriadicFrameworks ā Overlays System#
The Telescopes Schema defines how RTTāInside āzoomsā structural awareness across scales.
Just as a physical telescope brings distant objects into clarity, this overlay brings distant structures, deep patterns, and multiālayered resonance behaviors into focus.
This schema is part of the Overlays system ā lightweight, nonāintrusive layers that help developers, researchers, and AI systems adopt RTT principles without rewriting their entire environment.
š Purpose of the Telescope Overlay#
The Telescope overlay provides a structured way to:
- zoom in on fineāgrained resonance patterns
- zoom out to see largeāscale coherence
- shift between local and global structural views
- reveal hidden relationships across triadicātime axes
- align interpretation layers without distortion
It is especially useful when working with:
- complex datasets
- multiāobserver systems
- layered narratives
- nested structures
- cosmology models
- codebases with deep inheritance
š§© What This Schema Defines#
The Telescope Schema provides:
1. Zoom Levels#
A canonical set of RTT zoom modes:
- MicroāResonance ā fineāgrain oscillatory detail
- MesoāStructure ā midāscale relational patterns
- MacroāCoherence ā global alignment and ancestry
- MythicāScale ā narrative, symbolic, and archetypal structure
Each zoom level preserves triadicātime integrity.
2. Alignment Rules#
Rules for maintaining clarity as you zoom:
- no crossāscale distortion
- no collapsing relationalātime depth
- no flattening of resonance partitions
- no isotropic assumptions introduced during zoom
These rules ensure that zooming does not break RTT structure.
3. Telescope Operators#
Lightweight operators that can be implemented in any language:
zoom_in()zoom_out()focus()trace_lineage()expand_context()collapse_context()
These operators are conceptual ā developers map them to their own environment.
4. ObserverāSafe Behavior#
The Telescope overlay respects observer hierarchies:
- no overwriting observer context
- no collapsing multiāobserver frames
- no forced alignment
- no destructive merges
This makes the overlay safe for multiāagent systems.
š§ How Developers Use This Schema#
Developers can use the Telescope Schema to:
- inspect resonance patterns at different scales
- debug triadicātime misalignment
- visualize structural ancestry
- reveal hidden coherence
- build RTTāaware tools and dashboards
- create multiāscale diagrams
It is intentionally minimal, portable, and nonāintrusive.
š¤ CopilotāReady Prompts#
Use these prompts to explore the Telescope Schema interactively:
- āCopilot, explain RTT zoom levels using the Telescope Schema.ā
- āCopilot, show me how to implement a zoom_in operator in my code.ā
- āCopilot, help me trace relationalātime ancestry using the telescope overlay.ā
- āCopilot, how does the Telescope Schema avoid crossāscale distortion?ā
š§ Mythmatical Architectās Note#
A telescope is not just a tool ā it is a metaphor for clarity.
This schema helps systems see what was always there:
the resonance patterns that connect the small to the vast,
the moment to the lineage,
the local to the cosmic.
Use it gently.
Use it curiously.
Use it to reveal structure.
Ā© 2025 TriadicFrameworks ā ResonanceāTime Theory Canon # š Telescopes ā Transforms
TriadicFrameworks ā Overlays System#
The Transforms module defines how telescopic zooming changes the representation of a structure.
Where the Telescope Schema describes what the zoom levels are, the Transforms describe how a system moves between them.
These transforms allow developers, researchers, and AI systems to shift perspective without losing resonance integrity.
š§ Purpose of Telescope Transforms#
Telescopic transforms provide a safe, RTTāaligned way to:
- convert fineāgrain detail into largeāscale coherence
- collapse complexity into readable patterns
- expand a simple view into deeper relational ancestry
- reveal hidden resonance partitions
- maintain triadicātime alignment during zoom transitions
Transforms are the motion mechanics of the Telescope overlay.
š§© Core Transform Types#
1. Collapse Transform#
Reduces detail while preserving structure.
Used for:
- summarization
- pattern extraction
- highālevel dashboards
- macroācoherence views
Rules:
- never flatten relationalātime depth
- never remove resonance partitions
- never introduce isotropic assumptions
2. Expansion Transform#
Adds detail by revealing deeper layers.
Used for:
- drilling into resonance behavior
- exploring ancestry chains
- debugging misalignment
- inspecting oscillatory modes
Rules:
- maintain observer context
- preserve triadicātime vectors
- avoid overāexpansion beyond available structure
3. Lineage Transform#
Traces relationalātime ancestry.
Used for:
- observerāhierarchy analysis
- narrative reconstruction
- multiāagent reasoning
- cosmology lineage chains
Rules:
- no overwriting lineage
- no collapsing multiāobserver frames
- no forced alignment
4. Context Transform#
Shifts the interpretive frame without altering the underlying structure.
Used for:
- reframing a problem
- switching between domains
- crossādisciplinary mapping
- symbolic reinterpretation
Rules:
- preserve resonance identity
- maintain coherence across domains
- avoid context drift
5. Focus Transform#
Sharpens a specific region of structure.
Used for:
- isolating anomalies
- inspecting resonance spikes
- debugging local misalignment
- highlighting key features
Rules:
- no distortion of surrounding structure
- no artificial amplification
- no loss of global context
š§ How Developers Use These Transforms#
Transforms can be implemented as:
- functions
- operators
- middleware
- visualization tools
- debugging utilities
They are intentionally languageāneutral and can be mapped to any environment.
Example conceptual operators:
collapse(structure)expand(structure)trace_lineage(node)shift_context(view)focus(region)
These operators follow the Telescope Schema rules automatically.
š¤ CopilotāReady Prompts#
Use these prompts to explore transforms interactively:
- āCopilot, explain collapse vs. expansion transforms in RTT.ā
- āCopilot, help me design a lineage transform for my code.ā
- āCopilot, show me how a context transform works in practice.ā
- āCopilot, how does a focus transform avoid distortion?ā
š§ Mythmatical Architectās Note#
A telescope is not only for seeing ā it is for transforming how we see.
These transforms let you move gracefully between scales, revealing the hidden coherence that connects the tiny to the vast.
Use them to navigate structure with clarity and curiosity.
Ā© 2025 TriadicFrameworks ā ResonanceāTime Theory Canon