Primal-Dual First-Order Methods for Affinely Constrained Multi-Block Saddle Point Problems
Abstract
We consider the convex-concave saddle point problem , where the decision variables and/or subject to a multi-block structure and affine coupling constraints, and possesses certain separable structure. Although the minimization counterpart of such problem has been widely studied under the topics of ADMM, this minimax problem is rarely investigated. In this paper, a convenient notion of -saddle point is proposed, under which the convergence rate of several proposed algorithms are analyzed. When only one of and has multiple blocks and affine constraint, several natural extensions of ADMM are proposed to solve the problem. Depending on the number of blocks and the level of smoothness, or convergence rates are derived for our algorithms. When both and have multiple blocks and affine constraints, a new algorithm called ExtraGradient Method of Multipliers (EGMM) is proposed. Under desirable smoothness condition, an rate of convergence can be guaranteed regardless of the number of blocks in and . In depth comparison between EGMM (fully primal-dual method) and ADMM (approximate dual method) is made over the multi-block optimization problems to illustrate the advantage of the EGMM.
Cite
@article{arxiv.2109.14212,
title = {Primal-Dual First-Order Methods for Affinely Constrained Multi-Block Saddle Point Problems},
author = {Junyu Zhang and Mengdi Wang and Mingyi Hong and Shuzhong Zhang},
journal= {arXiv preprint arXiv:2109.14212},
year = {2023}
}
Comments
25 pages