Comparison inequalities and fastest-mixing Markov chains

Abstract

We introduce a new partial order on the class of stochastically monotone Markov kernels having a given stationary distribution π on a given finite partially ordered state space X. When K L in this partial order we say that K and L satisfy a comparison inequality. We establish that if K1,…,Kt and L1,…,Lt are reversible and Ks Ls for s=1,…,t, then K1·s Kt L1·s Lt. In particular, in the time-homogeneous case we have Kt Lt for every t if K and L are reversible and K L, and using this we show that (for suitable common initial distributions) the Markov chain Y with kernel K mixes faster than the chain Z with kernel L, in the strong sense that at every time t the discrepancy - measured by total variation distance or separation or L2-distance - between the law of Yt and π is smaller than that between the law of Zt and π. Using comparison inequalities together with specialized arguments to remove the stochastic monotonicity restriction, we answer a question of Persi Diaconis by showing that, among all symmetric birth-and-death kernels on the path X=\0,…,n\, the one (we call it the uniform chain) that produces fastest convergence from initial state 0 to the uniform distribution has transition probability 1/2 in each direction along each edge of the path, with holding probability 1/2 at each endpoint.