A Homogeneous Second-Order Descent Ascent Algorithm for Nonconvex-Strongly Concave Minimax Problems

Abstract

This paper introduces a novel Homogeneous Second-order Descent Ascent (HSDA) algorithm for nonconvex-strongly concave minimax optimization problems. At each iteration, HSDA uniquely computes a search direction by solving a homogenized eigenvalue subproblem built from the gradient and Hessian of the objective function. This formulation guarantees a descent direction with sufficient negative curvature even in near-positive-semidefinite Hessian regimes--a key feature that enhances escape from saddle points. We prove that HSDA finds an O(,)-second-order stationary point within O(-3/2) iterations, matching the optimal -order iteration complexity among second-order methods for this problem class. To address large-scale applications, we further design an inexact variant (IHSDA) that preserves the single-loop structure while solving the subproblem approximately via a Lanczos procedure. With high probability, IHSDA achieves the same O(-3/2) iteration complexity and attains an O(, )-second-order stationary point, with the total Hessian-vector product cost bounded by O(-7/4). Experiments on synthetic minimax problems and adversarial training tasks confirm the practical effectiveness and robustness of the proposed algorithms.