February 2024 Spectral telescope: Convergence rate bounds for random-scan Gibbs samplers based on a hierarchical structure
Qian Qin, Guanyang Wang
Author Affiliations +
Ann. Appl. Probab. 34(1B): 1319-1349 (February 2024). DOI: 10.1214/23-AAP1992

Abstract

Random-scan Gibbs samplers possess a natural hierarchical structure. The structure connects Gibbs samplers targeting higher-dimensional distributions to those targeting lower-dimensional ones. This leads to a quasi-telescoping property of their spectral gaps. Based on this property, we derive three new bounds on the spectral gaps and convergence rates of Gibbs samplers on general domains. The three bounds relate a chain’s spectral gap to, respectively, the correlation structure of the target distribution, a class of random walk chains, and a collection of influence matrices. Notably, one of our results generalizes the technique of spectral independence, which has received considerable attention for its success on finite domains, to general state spaces. We illustrate our methods through a sampler targeting the uniform distribution on a corner of an n-cube.

Funding Statement

Qian Qin and Guanyang Wang gratefully acknowledge support by the National Science Foundation through grants DMS-2112887 and DMS-2210849.

Acknowledgments

The authors thank James P. Hobert for helpful comments. The authors also thank the Editor, the Associate Editor and two referees for their constructive suggestions.

Citation

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Qian Qin. Guanyang Wang. "Spectral telescope: Convergence rate bounds for random-scan Gibbs samplers based on a hierarchical structure." Ann. Appl. Probab. 34 (1B) 1319 - 1349, February 2024. https://doi.org/10.1214/23-AAP1992

Information

Received: 1 October 2022; Revised: 1 June 2023; Published: February 2024
First available in Project Euclid: 1 February 2024

MathSciNet: MR4700260
Digital Object Identifier: 10.1214/23-AAP1992

Subjects:
Primary: 60J05

Keywords: Glauber dynamics , influence matrix , mixing time , recursive algorithm , spectral gap , spectral independence

Rights: Copyright © 2024 Institute of Mathematical Statistics

Vol.34 • No. 1B • February 2024
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