AdaGDA: Faster Adaptive Gradient Descent Ascent Methods for Minimax Optimization

TL;DR

This paper introduces faster adaptive GDA algorithms for nonconvex-strongly-concave minimax problems, improving convergence rates and efficiency over existing methods through adaptive matrices, momentum, and variance reduction techniques.

Contribution

It proposes novel adaptive GDA methods with improved gradient complexities and convergence guarantees for minimax optimization, including an accelerated variant with optimal complexity.

Findings

Achieves lower gradient complexity bounds for finding stationary points.

Demonstrates improved convergence rates over existing adaptive GDA methods.

Validates effectiveness through experiments on policy evaluation and fair classifier learning.

Abstract

In the paper, we propose a class of faster adaptive Gradient Descent Ascent (GDA) methods for solving the nonconvex-strongly-concave minimax problems by using the unified adaptive matrices, which include almost all existing coordinate-wise and global adaptive learning rates. In particular, we provide an effective convergence analysis framework for our adaptive GDA methods. Specifically, we propose a fast Adaptive Gradient Descent Ascent (AdaGDA) method based on the basic momentum technique, which reaches a lower gradient complexity of $\tilde{O}(\kappa^4\epsilon^{-4})$ for finding an $\epsilon$-stationary point without large batches, which improves the existing results of the adaptive GDA methods by a factor of $O(\sqrt{\kappa})$. Moreover, we propose an accelerated version of AdaGDA (VR-AdaGDA) method based on the momentum-based variance reduced technique, which achieves a lower gradient complexity of $\tilde{O}(\kappa^{4.5}\epsilon^{-3})$ for finding an $\epsilon$-stationary point without large batches, which improves the existing results of the adaptive GDA methods by a factor of $O(\epsilon^{-1})$. Moreover, we prove that our VR-AdaGDA method can reach the best known gradient complexity of $\tilde{O}(\kappa^{3}\epsilon^{-3})$ with the mini-batch size $O(\kappa^3)$. The experiments on policy evaluation and fair classifier learning tasks are conducted to verify the efficiency of our new algorithms.