Non Asymptotic Mixing Time Analysis of Non-Reversible Markov Chains
Abstract
We introduce a unified operator-theoretic framework for analyzing mixing times of finite-state ergodic Markov chains that applies to both reversible and non-reversible dynamics. The central object in our analysis is the projected transition operator PU 1, where P is the transition kernel and U 1 is orthogonal projection onto mean-zero subspace in 2(π), where π is the stationary distribution. We show that explicitly computable matrix norms of (PU 1)k gives non-asymptotic mixing times/distance to stationarity, and bound autocorrelations at lag k. We establish, for the first time, submultiplicativity of pointwise chi-squared divergence in the general non-reversible case. We provide for all times 2(k) bounds based on the spectrum of PU 1, i.e., magnitude of its distinct non-zero eigenvalues, discrepancy between their algebraic and geometric multiplicities, condition number of a similarity transform, and constant coming from smallest atom of stationary distribution(all scientifically computable). Furthermore, for diagonalizable PU 1, we provide explict constants satisfying hypocoercivity phenomenon for discrete time Markov Chains. Our framework enables direct computation of convergence bounds for challenging non-reversible chains, including momentum-based samplers for V-shaped distributions. We provide the sharpest known bounds for non-reversible walk on triangle. Our results combined with simple regression reveals a fundamental insight into momentum samplers: although for uniform distributions, nn iterations suffice for 2 mixing, for V-shaped distributions they remain diffusive as n1.969n1.956 iterations are sufficient. The framework shows that for ergodic chains relaxation times τrel=\|Σk=0∞PkU 1\|2(π).
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