An Approach for Non-Convex Uniformly Concave Structured Saddle Point Problem

TL;DR

This paper introduces a numerical method for non-convex uniformly-concave saddle point problems, combining adaptive gradient and high-order acceleration techniques, with proven complexity bounds for each component.

Contribution

It develops a novel approach that reduces saddle point problems to separate optimization tasks and provides complexity analysis for both outer and inner problems.

Findings

The method effectively handles non-convex and uniformly-concave structures.

Complexity bounds are established for the number of oracle calls.

The approach unifies high-order acceleration methods for saddle point problems.

Abstract

Recently, saddle point problems have received much attention due to their powerful modeling capability for a lot of problems from diverse domains. Applications of these problems occur in many applied areas, such as robust optimization, distributed optimization, game theory, and many applications in machine learning such as empirical risk minimization and generative adversarial networks training. Therefore, many researchers have actively worked on developing numerical methods for solving saddle point problems in many different settings. This paper is devoted to developing a numerical method for solving saddle point problems in the non-convex uniformly-concave setting. We study a general class of saddle point problems with composite structure and H\"older-continuous higher-order derivatives. To solve the problem under consideration, we propose an approach in which we reduce the problem to a combination of two auxiliary optimization problems separately for each group of variables, outer minimization problem w.r.t. primal variables, and inner maximization problem w.r.t the dual variables. For solving the outer minimization problem, we use the \textit{Adaptive Gradient Method}, which is applicable for non-convex problems and also works with an inexact oracle that is generated by approximately solving the inner problem. For solving the inner maximization problem, we use the \textit{Restarted Unified Acceleration Framework}, which is a framework that unifies the high-order acceleration methods for minimizing a convex function that has H\"older-continuous higher-order derivatives. Separate complexity bounds are provided for the number of calls to the first-order oracles for the outer minimization problem and higher-order oracles for the inner maximization problem. Moreover, the complexity of the whole proposed approach is then estimated.