Near-Optimal Algorithms for Making the Gradient Small in Stochastic Minimax Optimization

Lesi Chen; Luo Luo

2024 JMLR JMLR 2024

Near-Optimal Algorithms for Making the Gradient Small in Stochastic Minimax Optimization

Abstract

We study the problem of finding a near-stationary point for smooth minimax optimization. The recently proposed extra anchored gradient (EAG) methods achieve the optimal convergence rate for the convex-concave minimax problem in the deterministic setting. However, the direct extension of EAG to stochastic optimization is not efficient. In this paper, we design a novel stochastic algorithm called Recursive Anchored IteratioN (RAIN). We show that the RAIN achieves near-optimal stochastic first-order oracle (SFO) complexity for stochastic minimax optimization in both convex-concave and strongly-convex-strongly-concave cases. In addition, we extend the idea of RAIN to solve structured nonconvex-nonconcave minimax problem and it also achieves near-optimal SFO complexity. [abs] [ pdf ][ bib ] © JMLR 2024. (edit, beta)

🌉 Interdisciplinary Bridge — Machine Learning and Mathematics & Optimization

🧭 Keyword Pioneer — stochastic minimax optimization

🐝 Cross-Pollinator — Artificial Intelligence, Deep Learning, Machine Learning, Mathematics & Optimization

Authors

Lesi Chen , Luo Luo

Topics

Machine Learning > Optimization & Theory > Optimization Mathematics & Optimization > Optimization > Stochastic Methods

Keywords

stochastic minimax optimization gradient oracle complexity convex-concave setting nonconvex-nonconcave setting first-order oracle

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