Geodesics and dynamical information projections on the manifold of H\"older equilibrium probabilities

Abstract

We consider here the discrete time dynamics described by a transformation T:M M, where T is either the action of shift T=σ on the symbolic space M=\1,2,...,d\N, or, T describes the action of a d to 1 expanding transformation T:S1 S1 of class C1+α (\,for example x T(x) =d\, x (mod 1) \,), where M=S1 is the unit circle. It is known that the infinite-dimensional manifold N of equilibrium probabilities for H\"older potentials A:M R is an analytical manifold and carries a natural Riemannian metric associated with the asymptotic variance. We show here that under the assumption of the existence of a Fourier-like Hilbert basis for the kernel of the Ruelle operator there exists geodesics paths. When T=σ and M=\0,1\N such basis exists. In a different direction, we also consider the KL-divergence DKL(μ1,μ2) for a pair of equilibrium probabilities. If DKL(μ1,μ2)=0, then μ1=μ2. Although DKL is not a metric in N, it describes the proximity between μ1 and μ2. A natural problem is: for a fixed probability μ1∈ N consider the probability μ2 in a convex set of probabilities in N which minimizes DKL(μ1,μ2). This minimization problem is a dynamical version of the main issues considered in information projections. We consider this problem in N, a case where all probabilities are dynamically invariant, getting explicit equations for the solution sought. Triangle and Pythagorean inequalities will be investigated.