The Circuit Codex defines the flow, logic, and orchestration of electrical, computational, and symbolic systems as unified feedback mechanisms. It governs how inputs, processing states, and outputs form structured loopsβranging from physical wiring and integrated electronics to abstract reasoning circuits and conceptual flows.
Primary Components
- Closed-Loop Logic Design
Encodes feedback and signal continuity across logic gates, symbolic reasoning loops, semantic validations, and analog/digital transformations. - Signal Pathways & Flow Integrity
Models the uninterrupted flow of electrical, linguistic, or procedural currents with impedance handling, transient management, and recursion resilience. - Interrupt and Reset Protocols
Defines recovery, reset, and halting states across biological, digital, and philosophical systems (e.g., rest, death, or logic contradiction recovery). - Circuit Embedding Framework
Enables subcircuits (local logic) within supercircuits (global logic), allowing layered abstraction and modular nesting of symbolic or electronic architecture.
Interoperability
- Neural Circuits β Thought Loops
Maps brain signal transmission onto philosophical and linguistic recursions (cognition as looped inference). - Power Circuits β Energy Codex
Aligns thermodynamic conservation and transfer across electrical, radiative, and symbolic systems. - Symbolic Circuits β Syntax Codex
Structures the chaining of symbols, operations, and logic connectors in recursive grammar or code execution.
Meta-Principles
- Conservation of Flow
Information, energy, or symbolic value cannot vanishβit transforms or redistributes via junctions, splitters, or resistors. - Circuit Identity
A circuit is defined not just by its components, but by its pattern of return. Completion defines function. Open loops express potential or failure. - Interruptibility with Restoration
All codified circuits must define restoration logicβa philosophical necessity for resilience and intelligent agency.