Time-Biased Random Walks and Robustness of Expanders

Abstract

Random walks on expanders play a crucial role in Markov Chain Monte Carlo algorithms, derandomization, graph theory, and distributed computing. A desirable property is that they are rapidly mixing, which is equivalent to having a spectral gap γ (asymptotically) bounded away from 0. Our work has two main strands. First, we establish a dichotomy for the robustness of mixing times on edge-weighted d-regular graphs (i.e., reversible Markov chains) subject to a Lipschitz condition, which bounds the ratio of adjacent weights by β ≥ 1. If β 1 is sufficiently small, then γ 1 and the mixing time is logarithmic in n. On the other hand, if β ≥ 2d, there is an edge-weighting such that γ is polynomially small in 1/n. Second, we apply our robustness result to a time-dependent version of the so-called -biased random walk, as introduced in Azar et al. [Combinatorica 1996]. We show that, for any constant >0, a bias strategy can be chosen adaptively so that the -biased random walk covers any bounded-degree regular expander in (n) expected time, improving the previous-best bound of O(n n). We prove the first non-trivial lower bound on the cover time of the -biased random walk, showing that, on bounded-degree regular expanders, it is ω(n) whenever = o(1). We establish this by controlling how much the probability of arbitrary events can be ``boosted'' by using a time-dependent bias strategy.

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