Recursive Thermodynamic Simulator: Symbolic Entropy Fields and Vesica-Coupled Phase Evolution

This release introduces a complete symbolic thermodynamic simulation framework based on recursive entropy propagation and fixed universal compression constants. The system models heat-like behavior without traditional temperature metrics, instead leveraging symbolic gradient feedback, memory field decay, and a Vesica Piscis resonance field at 0.244 Hz.

Components:

• et2_core.py: Main simulation engine for tensor ($T$), memory ($M$), and entropy ($S$) evolution.

• et2_constants.py: Symbolic constant sets derived from π, φ, ζ(3), γ, and e.

• et2_gui.py: Minimal interface for simulation control and output rendering.

• Program_User_Manual.pdf: Full user guide with setup, usage, and output explanations.

• recursive_thermodynamics.pdf: Foundational theory of symbolic entropy and recursive feedback.

• Symbolic Overcompression and Recursive Phase Detonation in Black Holes.pdf: Advanced speculation on energetic overdrive, compression collapse, and recursive singularity thermodynamics.

Outputs are printable frames showing field dynamics from any time window (e.g., steps 500–600), enabling users to explore structured thermal collapse and symbolic stabilization over time.

Constants are locked for symbolic integrity. This simulator is designed for advanced symbolic physics research and universal attractor exploration.