Geometric Bounds on the Fastest Mixing Markov Chain

Abstract

In the Fastest Mixing Markov Chain problem, we are given a graph G = (V, E) and desire the discrete-time Markov chain with smallest mixing time τ subject to having equilibrium distribution uniform on V and non-zero transition probabilities only across edges of the graph. It is well-known that the mixing time τRW of the lazy random walk on G is characterised by the edge conductance of G via Cheeger's inequality: -1 τRW -2 |V|. Analogously, we characterise the fastest mixing time τ via a Cheeger-type inequality but for a different geometric quantity, namely the vertex conductance of G: -1 τ -2 ( |V|)2. This characterisation forbids fast mixing for graphs with small vertex conductance. To bypass this fundamental barrier, we consider Markov chains on G with equilibrium distribution which need not be uniform, but rather only -close to uniform in total variation. We show that it is always possible to construct such a chain with mixing time τ -1 (diam G)2 |V|. Finally, we discuss analogous questions for continuous-time and time-inhomogeneous chains.