Subelliptic Random Walks on Riemannian Manifolds and Their Convergence to Equilibrium

Abstract

The aim of this work is to study the convergence to equilibrium of an (h,)-subelliptic random walk on a closed, connected Riemannian manifold (M,g) associated with a subelliptic second-order differential operator A on M. In such a random walk, h roughly represents the step size and the speed at which it is carried out. To construct the random walk and prove the convergence result, we employ a technique due to Fefferman and Phong, which reduces the problem to the study of a constant-coefficient operator A that is locally equivalent to our second-order subelliptic operator A, in the sense that the diffusion generated by A induces a local diffusion for A. By using the compactness of M this local diffusion can be lifted to a global diffusion, and the convergence result is then obtained via the spectral theory of the associated Markov operator.