English

Proximal Gradient Descent-Ascent: Variable Convergence under K{\L} Geometry

Optimization and Control 2021-02-18 v2 Machine Learning

Abstract

The gradient descent-ascent (GDA) algorithm has been widely applied to solve minimax optimization problems. In order to achieve convergent policy parameters for minimax optimization, it is important that GDA generates convergent variable sequences rather than convergent sequences of function values or gradient norms. However, the variable convergence of GDA has been proved only under convexity geometries, and there lacks understanding for general nonconvex minimax optimization. This paper fills such a gap by studying the convergence of a more general proximal-GDA for regularized nonconvex-strongly-concave minimax optimization. Specifically, we show that proximal-GDA admits a novel Lyapunov function, which monotonically decreases in the minimax optimization process and drives the variable sequence to a critical point. By leveraging this Lyapunov function and the K{\L} geometry that parameterizes the local geometries of general nonconvex functions, we formally establish the variable convergence of proximal-GDA to a critical point xx^*, i.e., xtx,yty(x)x_t\to x^*, y_t\to y^*(x^*). Furthermore, over the full spectrum of the K{\L}-parameterized geometry, we show that proximal-GDA achieves different types of convergence rates ranging from sublinear convergence up to finite-step convergence, depending on the geometry associated with the K{\L} parameter. This is the first theoretical result on the variable convergence for nonconvex minimax optimization.

Keywords

Cite

@article{arxiv.2102.04653,
  title  = {Proximal Gradient Descent-Ascent: Variable Convergence under K{\L} Geometry},
  author = {Ziyi Chen and Yi Zhou and Tengyu Xu and Yingbin Liang},
  journal= {arXiv preprint arXiv:2102.04653},
  year   = {2021}
}

Comments

To appear in ICLR 2021

R2 v1 2026-06-23T22:58:10.684Z