Diffusion Processes: entropy, Gibbs states and the continuous time Ruelle operator

Abstract

We consider a Riemmaniann compact manifold M, the associated Laplacian and the corresponding Brownian motion Xt, t≥ 0. Given a Lipschitz function V:M R we consider the operator 12+V, which acts on differentiable functions f: M R via the operator 12 f(x)+\,V(x)f(x) , for all x∈ M. Denote by PtV, t ≥ 0, the semigroup acting on functions f: M R given by PtV (f)(x)\,:=\, Ex [e∫0t V(Xr)\,dr f(Xt)].\, We will show that this semigroup is a continuous-time version of the discrete-time Ruelle operator. Consider the positive differentiable eigenfunction F: M R associated to the main eigenvalue λ for the semigroup PtV, t ≥ 0. From the function F, in a procedure similar to the one used in the case of discrete-time Thermodynamic Formalism, we can associate via a coboundary procedure a certain stationary Markov semigroup. The probability on the Skhorohod space obtained from this new stationary Markov semigroup can be seen as a stationary Gibbs state associated with the potential V. We define entropy, pressure, the continuous-time Ruelle operator and we present a variational principle of pressure for such a setting.