The weak Bernoulli property for matrix Gibbs states

Abstract

We study the ergodic properties of a class of measures on Z for which μA,t[x0·s xn-1]≈ e-nP \|Ax0·s Axn-1 \| t, where A=(A0, … , AM-1) is a collection of matrices. The measure μA,t is called a matrix Gibbs state. In particular we give a sufficient condition for a matrix Gibbs state to have the weak Bernoulli property. We employ a number of techniques to understand these measures including a novel approach based on Perron-Frobenius theory. We find that when t is an even integer the ergodic properties of μA ,t are readily deduced from finite dimensional Perron-Frobenius theory. We then consider an extension of this method to t>0 using operators on an infinite dimensional space. Finally we use a general result of Bradley to prove the main theorem.