Optimal transportation and pressure at zero temperature

Abstract

Given two compact metric spaces X and Y, a Lipschitz continuous cost function c on X × Y and two probabilities μ ∈P(X),\,∈P(Y), we propose to study the Monge-Kantorovich problem and its duality from a zero temperature limit of a convex pressure function. We consider the entropy defined by H(π) = -DKL(π|μ× ), where DKL is the Kullback-Leibler divergence, and then the pressure defined by the variational principle \[P(β A) = π ∈ (μ,) [ β A\,dπ + H(π)],\]where β>0 and A=-c. We will show that it admits a dual formulation and when β +∞ we recover the solution for the usual Monge-Kantorovich problem and its Kantorovich duality. Such approach is similar to one which is well known in Thermodynamic Formalism and Ergodic Optimization, where β is interpreted as the inverse of the temperature (β = 1T) and β+∞ is interpreted as a zero temperature limit.