The Volatility Governance Model (VGM) is a unified, multi-timescale frame-work for volatility estimation, regime classification, and risk-governed po-sition sizing in cryptocurrency markets. This edition replaces the Black-Scholes synthetic Greek engine with a realised-calibrated Heston stochas-tic volatility model, which treats variance as a mean-reverting stochasticprocess with its own dynamics, volatility-of-volatility, and spot-variancecorrelation. The Heston variance process is formulated as a Langevinequation with an Ornstein-Uhlenbeck thermodynamic potential, whose sta-tionary distribution is the Boltzmann-Gibbs measure over variance states.The framework synthesises six distinct theoretical traditions into a singlecoherent architecture: (1) classical time-series econometrics via SARIMAX,(2) non-parametric regime identification via K-Means clustering on an en-riched thermodynamic-stochastic feature space, (3) non-Gaussian innova-tion modelling via Gaussian Mixture Models, (4) thermodynamic volatilityanchoring via the Entropic Mean and variance drag, (5) stochastic volatil-ity surface construction via the Heston model calibrated to realised mo-ments, and (6) information-theoretic position governance via an Entropic-State-Aware Kelly Criterion grounded in the gamma-theta modulus. Theunifying primitive is heat time — a reparameterisation of the calendar timeaxis by the cumulative Shannon entropy production of the return distribu-tion, grounded in Boltzmann’s H-theorem. The framework introduces eightdistinct Boltzmann-level connections, including the fluctuation-dissipationtheorem for volatility-of-volatility, a Jarzynski equality for path-level Kellygrowth, and the identification of the Feller condition with the third law ofthermodynamics.
J. Adam Perry (Thu,) studied this question.