Saved in:
Bibliographic Details
Main Authors: Hu, Yukuan, Li, Mengyu, Liu, Xin, Meng, Cheng
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2306.16763
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917758064656384
author Hu, Yukuan
Li, Mengyu
Liu, Xin
Meng, Cheng
author_facet Hu, Yukuan
Li, Mengyu
Liu, Xin
Meng, Cheng
contents This paper focuses on multi-block optimization problems over transport polytopes, which underlie various applications including strongly correlated quantum physics and machine learning. Conventional block coordinate descent-type methods for the general multi-block problems store and operate on the matrix variables directly, resulting in formidable expenditure for large-scale settings. On the other hand, optimal transport problems, as a special case, have attracted extensive attention and numerical techniques that waive the use of the full matrices have recently emerged. However, it remains nontrivial to apply these techniques to the multi-block, possibly nonconvex problems with theoretical guarantees. In this work, we leverage the benefits of both sides and develop novel sampling-based block coordinate descent-type methods, which are equipped with either entropy regularization or Kullback-Leibler divergence. Each iteration of these methods solves subproblems restricted on the sampled degrees of freedom. Consequently, they involve only sparse matrices, which amounts to considerable complexity reductions. We explicitly characterize the sampling-induced errors and establish convergence and asymptotic properties for the methods equipped with the entropy regularization. Numerical experiments on typical strongly correlated electron systems corroborate their superior scalability over the methods utilizing full matrices. The advantage also enables the first visualization of approximate optimal transport maps between electron positions in three-dimensional contexts.
format Preprint
id arxiv_https___arxiv_org_abs_2306_16763
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Sampling-Based Methods for Multi-Block Optimization Problems over Transport Polytopes
Hu, Yukuan
Li, Mengyu
Liu, Xin
Meng, Cheng
Optimization and Control
Chemical Physics
Computational Physics
52-08, 65C05, 65F50, 81V05, 90C30
This paper focuses on multi-block optimization problems over transport polytopes, which underlie various applications including strongly correlated quantum physics and machine learning. Conventional block coordinate descent-type methods for the general multi-block problems store and operate on the matrix variables directly, resulting in formidable expenditure for large-scale settings. On the other hand, optimal transport problems, as a special case, have attracted extensive attention and numerical techniques that waive the use of the full matrices have recently emerged. However, it remains nontrivial to apply these techniques to the multi-block, possibly nonconvex problems with theoretical guarantees. In this work, we leverage the benefits of both sides and develop novel sampling-based block coordinate descent-type methods, which are equipped with either entropy regularization or Kullback-Leibler divergence. Each iteration of these methods solves subproblems restricted on the sampled degrees of freedom. Consequently, they involve only sparse matrices, which amounts to considerable complexity reductions. We explicitly characterize the sampling-induced errors and establish convergence and asymptotic properties for the methods equipped with the entropy regularization. Numerical experiments on typical strongly correlated electron systems corroborate their superior scalability over the methods utilizing full matrices. The advantage also enables the first visualization of approximate optimal transport maps between electron positions in three-dimensional contexts.
title Sampling-Based Methods for Multi-Block Optimization Problems over Transport Polytopes
topic Optimization and Control
Chemical Physics
Computational Physics
52-08, 65C05, 65F50, 81V05, 90C30
url https://arxiv.org/abs/2306.16763