English

Expanderizing Higher Order Random Walks

Data Structures and Algorithms 2024-06-04 v3

Abstract

We study a variant of the down-up and up-down walks over an nn-partite simplicial complex, which we call expanderized higher order random walks -- where the sequence of updated coordinates correspond to the sequence of vertices visited by a random walk over an auxiliary expander graph HH. When HH is the clique, this random walk reduces to the usual down-up walk and when HH is the directed cycle, this random walk reduces to the well-known systematic scan Glauber dynamics. We show that whenever the usual higher order random walks satisfy a log-Sobolev inequality or a Poincar\'e inequality, the expanderized walks satisfy the same inequalities with a loss of quality related to the two-sided expansion of the auxillary graph HH. Our construction can be thought as a higher order random walk generalization of the derandomized squaring algorithm of Rozenman and Vadhan. We show that when initiated with an expander graph our expanderized random walks have mixing time O(nlogn)O(n \log n) for sampling a uniformly random list colorings of a graph GG of maximum degree Δ=O(1)\Delta = O(1) where each vertex has at least (11/6ϵ)Δ(11/6 - \epsilon) \Delta and at most O(Δ)O(\Delta) colors and O(nlogn(1J)2)O\left( \frac{n \log n}{(1 - \| J\|)^2}\right) for sampling the Ising model with a PSD interaction matrix JRn×nJ \in R^{n \times n} satisfying J1\| J \| \le 1 and the external field hRnh \in R^n-- here the O()O(\bullet) notation hides a constant that depends linearly on the largest entry of hh. As expander graphs can be very sparse, this decreases the amount of randomness required to simulate the down-up walks by a logarithmic factor. We also prove some simple results which enable us to argue about log-Sobolev constants of higher order random walks and provide a simple and self-contained analysis of local-to-global Φ\Phi-entropy contraction in simplicial complexes -- giving simpler proofs for many pre-existing results.

Keywords

Cite

@article{arxiv.2405.08927,
  title  = {Expanderizing Higher Order Random Walks},
  author = {Vedat Levi Alev and Shravas Rao},
  journal= {arXiv preprint arXiv:2405.08927},
  year   = {2024}
}
R2 v1 2026-06-28T16:27:31.244Z