Can a Frozen K/M/C–Pi Medium Model Produce Maxwell-Like and Relativistic-Like Readouts from Moving Localized Excitations?

This project provides a reproducible simulation audit of a frozen KMC Pi medium response model. The central question is whether a condensed matter like KMC Pi simulator can produce Maxwell like and relativistic like readouts from moving localized internal excitations, without explicitly solving Maxwell equations or imposing Lorentz transformations. The model evolves a three component internal field w2 w3 w4. The w2 channel is density like, the w3 channel is torsional or magnetic like, and the w4 channel is volumetric or scale like. The observable w1 is not used as a solver coordinate and appears only through a Pi readout. The simulated excitation is represented as a localized w234 gyro soliton proxy. Its internal w2 w3 phase circulation defines a gyro density and a phase current. From this current the code computes a magnetic like curl readout Bₗike. The electric like readout Eₗike is computed separately from the gyro density. The main Maxwell like test compares Bₗike divided by Eₗike with the measured velocity divided by an effective medium propagation scale. The same run also computes a Pi time projection readout. This readout decreases under increasing phase current and curl load, producing a relativistic like time projection reduction within the frozen simulator. The final audit run includes seven reviewer gates: 1. Bₗike divided by Eₗike is not directly encoded in the readout 2. Reversing the velocity reverses the signed curl 3. The static case suppresses the curl 4. Mesh convergence is checked 5. Green function and time FEM responses are compared 6. Removing the w3 K24 C24 proxy channel kills the Maxwell like route 7. Removing the Pi projection kills the time projection route while the Maxwell like route remains The final status of the main audit is AUDITSUPPORT. This project reports software route support only. It does not claim to prove the MMU framework, derive Maxwell theory, derive special relativity, replace QED, GR, or the Standard Model, or identify the simulated excitation with a physical electron. The repository contains the LaTeX article, references, the main Python audit program, output files, reviewer gate diagnostics, mesh and ablation summaries, plots, and supporting gyro route programs.