Accelerating Constrained Sampling: A Large Deviations Approach
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Research Topics
Paper Information
-
Journal:
Journal of Machine Learning Research -
Added to Tracker:
Jul 06, 2026
Abstract
The problem of sampling a target probability distribution on a constrained domain arises in many applications including machine learning. For constrained sampling, various Langevin algorithms such as projected Langevin Monte Carlo (PLMC), based on the discretization of reflected Langevin dynamics (RLD) and more generally skew-reflected non-reversible Langevin Monte Carlo (SRNLMC), based on the discretization of skew-reflected non-reversible Langevin dynamics (SRNLD), have been proposed and studied in the literature. This work focuses on the long-time behavior of SRNLD, where a skew-symmetric matrix is added to RLD. Although acceleration for SRNLD has been studied, it is not clear how one should design the skew-symmetric matrix in the dynamics to achieve good performance in practice. We establish a large deviation principle (LDP) for the empirical measure of SRNLD when the skew-symmetric matrix is chosen such that its product with the outward unit normal vector field on the boundary is zero. By explicitly characterizing the rate functions, we show that this choice of the skew-symmetric matrix accelerates the convergence to the target distribution compared to RLD and reduces the asymptotic variance. Numerical experiments for SRNLMC based on the proposed skew-symmetric matrix show superior performance, which validate the theoretical findings from the large deviations theory.
Author Details
Lingjiong Zhu
AuthorYingli Wang
AuthorChangwei Tu
AuthorXiaoyu Wang
AuthorResearch Topics & Keywords
Machine Learning
Research AreaCitation Information
APA Format
Lingjiong Zhu
,
Yingli Wang
,
Changwei Tu
&
Xiaoyu Wang
.
Accelerating Constrained Sampling: A Large Deviations Approach.
Journal of Machine Learning Research
.
BibTeX Format
@article{paper1379,
title = { Accelerating Constrained Sampling: A Large Deviations Approach },
author = {
Lingjiong Zhu
and Yingli Wang
and Changwei Tu
and Xiaoyu Wang
},
journal = { Journal of Machine Learning Research },
url = { https://www.jmlr.org/papers/v27/25-1616.html }
}