A Laplace Principle for Hermitian Brownian Motion and Free Entropy I: the convex functional case

Abstract

This paper is part of a series aiming at proving that the and variants of Voiculescu's free entropy coincide. This is based on a Laplace principle (implying a large deviation principle) for hermitian brownian motion on [0,1]. In the current paper, we show that microstates free entropy (X1,...,Xm) and non-microstate free entropy *(X1,...,Xm) coincide for self-adjoint variables (X1,...,Xm) satisfying a Schwinger-Dyson equation for subquadratic, bounded below, strictly convex potentials with Lipschitz derivative sufficiently approximable by non-commutative polynomials. Our results are based on Dupuis-Ellis weak convergence approach to large deviations where one shows a Laplace principle in obtaining a stochastic control formulation for exponential functionals. In the non-commutative context, ultrapoduct analysis replaces weak-convergence of the stochastic control problems.