Ergodic Transport Theory, periodic maximizing probabilities and the twist condition

Abstract

The present paper is a follow up of another one by A. O. Lopes, E. Oliveira and P. Thieullen which analyze ergodic transport problems. Our main focus will a more precise analysis of case where the maximizing probability is unique and is also a periodic orbit. Consider the shift T acting on the Bernoulli space =1, 2, 3,.., dN and A: R a Holder potential. Denote m(A)=max is an invariant probability for T ∫ A(x) \; d(x) and, μ∞,A, any probability which attains the maximum value. We assume this probability is unique (a generic property). We denote the bilateral shift. For a given potential Holder A: R, we say that a Holder continuous function W: R is a involution kernel for A, if there is a Holder function A*: R, such that, A*(w)= A -1(w,x)+ W -1(w,x) - W(w,x). We say that A* is a dual potential of A. It is true that m(A)=m(A*). We denote by V the calibrated subaction for A, and, V* the one for A*. We denote by I* the deviation function for the family of Gibbs states for β A, when β ∞. For each x we get one (more than one) wx such attains the supremum above. That is, solutions of V(x) = W(wx,x) - V* (wx)- I*(wx). A pair of the form (x,wx) is called an optimal pair. If is the shift acting on (x,w) ∈ 1, 2, 3,.., dZ, then, the image by -1 of an optimal pair is also an optimal pair. Theorem - Generically, in the set of Holder potentials A that satisfy (i) the twist condition, (ii) uniqueness of maximizing probability which is supported in a periodic orbit, the set of possible optimal wx, when x covers the all range of possible elements x in ∈ , is finite.