CVP Platform

The CVP stack: geometry primitives → execution → integrity

CVP is structured as a modular platform: physical primitives (curvature + refractance), propagation models (EM), overlay mechanics (spin), biological manifolds (brain), executable computation (CVE/QOP), and Integrity Overlays for deployment governance (Safe Bet + Health).

How the pieces fit

Geometry primitives: curvature, refractance, and boundary definitions
Propagation: EM behavior under geometry-defined constraints
Overlays: CVP Spin Overlay controls for coherence and transitions
Manifolds: represent biological/cognitive spaces as embedded manifolds
Execution: CVE/QOP for deterministic pipelines (simulation → encoding → runtime)
Integrity: Safe Bet + Health overlays for auditability and policy-driven controls

Architecture flow (recommended diagram placement)

Geometry Primitives → EM Propagation → Spin Overlay → Brain Manifold → CVE/QOP Execution → Integrity Overlay (Safe Bet / Health)

Validation path

Define: module primitives, parameters, and intended outcomes
Simulate: reference experiments and controlled benchmarks
Instrument: telemetry and evaluation harness for repeatability
Deploy: pilots with governance via Integrity Overlays

Explore Modules See the SDK

Modules

CVP modules designed for composition and testing

Each module is intended to be independently describable, simulatable, and composable into end-to-end architectures.

Module 1 — CVP Core: Toroidal Refractance Interfacing

Defines the interface boundary as a geometry-driven refractance domain using toroidal recirculation dynamics to preserve continuity at coupling boundaries (e.g., molecular ↔ terahertz signaling).

Stable coupling primitives for multi-domain interfaces
Continuity across boundary conditions via recirculation structure
Designed for composability into next-generation network stacks

Module 2 — EM Propagation

Models electromagnetic propagation and coupling as geometry-governed outcomes—enabling deterministic design targets and controllable operating envelopes for advanced communications and sensing architectures.

Propagation constraints expressed as geometric boundary conditions
Coupling and interaction models aligned to controlled envelopes
Applicable to sensing-native and distributed network contexts

Module 3 — CVP Spin Overlay

Formalizes overlay mechanics that stabilize, regulate, or amplify desired state trajectories—focused on coherence management, transitions, and overlay control layers sitting above propagation/interfacing primitives.

Coherence and stability constraints
Controlled transitions and regulated state trajectories
Overlay layer compatibility with execution pipelines

Module 4 — Brain Manifold

Represents cognitive/biological activity as an embedded manifold where signals, states, and transitions can be encoded geometrically. Designed to support sensing, inference, and control with reduced data movement.

Manifold-based representations for biological/cognitive domains
Geometry-driven state encoding and transition description
Edge-relevant framing for reduced transmission requirements

CVE / QOP SDK Research Materials

Energy

Tidal Curvature Energy

Applying CVP principles to curvature oscillations and recirculation regimes with the goal of new energy extraction and storage architectures. Public materials remain high-level; deeper technical artifacts can be shared in controlled collaboration settings.

Concept

Tidal Curvature Energy frames capture and optimization as a geometry and oscillation problem. The objective is to characterize controllable curvature-domain dynamics and translate them into actionable engineering parameters and validation pathways.

What makes this different

Emphasis on curvature-domain oscillation regimes and recirculation structures
Focus on controllable envelopes and measurable parameters
Validation pathway designed for repeatability and instrumentation

Development roadmap

Modeling & simulation: parameter sweeps, operating envelopes, sensitivity analyses
Prototype definition: instrumentation + measurement plan, test architecture
Validation: performance characterization and repeatable experiments
Pilots: partner-aligned pilot planning and deployment pathways

Discuss Energy Collaboration Related Materials

SDK

CVE / QOP SDK for curvature-native pipelines

The SDK is intended to provide a practical toolchain for building curvature-native workflows—simulation, state encoding, deterministic execution, evaluation, and deployment targets—integrated with Integrity Overlays for real-world governance.

What the SDK will include

Reference pipelines: end-to-end examples (data → geometry → execution → outputs)
Curvature state encoding: manifold/state representations and transforms
Deterministic execution primitives: geometry-governed inference and control flows
Evaluation harness: accuracy, latency, energy, stability metrics
Deployment targets: edge devices, lab simulation, controlled environments

SDK outcomes

Repeatable experiments with consistent parameterization
Portable reference implementations for partners
Clear paths from research artifacts to pilots

Request the Developer Brief Integrity Overlays

Integrity Overlays

Safe Bet + Health integrity layers for auditability and control

Integrity Overlays are governance and controls layers designed to sit above physical and computational primitives. They provide policy-driven guardrails, audit trails, and enforcement-ready telemetry—without requiring a redesign of the underlying system.

Integrity Overlay — Safe Bet

The Safe Bet Integrity Overlay is designed for wagering environments where trust, safety, and compliance readiness must be engineered into operations. It emphasizes transparent controls, structured accountability, and intervention pathways.

Core objectives

Integrity-by-design controls and enforcement signals
Audit-ready logging and policy-driven decision boundaries
Risk monitoring, anomaly detection, structured escalation
Compatibility with operator workflows and regulator expectations

Integrity Overlay — Health

The Health Integrity Overlay targets integrity requirements in health-adjacent data and decision systems: provenance, governance, safety constraints, and auditability for high-stakes outcomes.

Core objectives

Provenance and traceability for inputs and outputs
Policy-controlled access, retention, and action constraints
Auditability, event-based review, and accountability structures
Safety-first operational controls for sensitive deployments

Integration points (CVP / CVE / QOP)

Telemetry + logging: audit trails and provenance
Policy engine: action gating and constraints
Monitoring & escalation: thresholding and interventions
Compliance packaging: reporting and attestations

Request the Integrity Brief SDK Integration

Research

Public materials, diagrams, and releases

This page hosts public-facing summaries and downloadable artifacts. Deeper technical packages can be provided through collaboration channels.

Downloads

CVP Overview (PDF): Download
Figures & Diagrams: Download
Energy brief (high-level): Download
SDK Developer Brief: Request
Integrity Brief (Safe Bet / Health): Request

Version notes

v1.0: Platform definition + module taxonomy
v1.1: Expanded Integrity Overlay integration + SDK pipeline structure

Request Full Technical Package Press Releases

Press

Press releases and media kit

Official announcements from 206 Innovation Inc. regarding Curvature Variable Physics (CVP), associated modules, and the Integrity Overlay stack (Safe Bet / Health).

FOR IMMEDIATE RELEASE

Bellevue, WA — December 29, 2025 — Timothy J. Dillon, Founder of 206 Innovation Inc., announced Curvature Variable Physics (CVP), a geometry-first platform spanning toroidal refractance interfacing, EM propagation, spin overlays, brain manifold representations, curvature-native computation (CVE/QOP), and Integrity Overlays for Safe Bet and Health.

CVP organizes critical boundaries—physical, informational, and operational—into modular primitives designed for composition, testing, and deployment. The platform is positioned to support next-generation network architectures, deterministic edge execution, integrity-first systems, and curvature-informed energy pathways.

“The next era will be defined by interfaces and integrity. CVP formalizes both: how systems couple across domains—and how they remain accountable when deployed in real-world environments.”

— Timothy J. Dillon, Founder, 206 Innovation Inc.

Media kit

Founder bio (short): Download
Logos & figures: Download
One-page overview: Download

Media / Collaboration Inquiries View Research

About

Timothy J. Dillon — Founder, 206 Innovation Inc.

Founder and inventor focused on geometry-first frameworks spanning interfacing, propagation, deterministic execution, integrity overlays, and next-generation architectures.

206 Innovation Inc.

206 Innovation Inc. advances frontier technologies across physics-driven frameworks, next-generation communications, and integrity-first deployment architectures.

Focus areas

Curvature Variable Physics (CVP) platform development
Tidal Curvature Energy concepts and validation pathways
CVE/QOP toolchains for deterministic execution
Integrity Overlays for Safe Bet and Health

Contact

Collaboration, media, and SDK inquiries

< For research collaboration, licensing discussions, Integrity Overlay brief requests, or SDK roadmap inquiries.