A Homogenization Approach for Gradient-Dominated Stochastic Optimization
Abstract
Gradient dominance property is a condition weaker than strong convexity, yet sufficiently ensures global convergence even in non-convex optimization. This property finds wide applications in machine learning, reinforcement learning (RL), and operations management. In this paper, we propose the stochastic homogeneous second-order descent method (SHSODM) for stochastic functions enjoying gradient dominance property based on a recently proposed homogenization approach. Theoretically, we provide its sample complexity analysis, and further present an enhanced result by incorporating variance reduction techniques. Our findings show that SHSODM matches the best-known sample complexity achieved by other second-order methods for gradient-dominated stochastic optimization but without cubic regularization. Empirically, since the homogenization approach only relies on solving extremal eigenvector problem at each iteration instead of Newton-type system, our methods gain the advantage of cheaper computational cost and robustness in ill-conditioned problems. Numerical experiments on several RL tasks demonstrate the better performance of SHSODM compared to other off-the-shelf methods.
Cite
@article{arxiv.2308.10630,
title = {A Homogenization Approach for Gradient-Dominated Stochastic Optimization},
author = {Jiyuan Tan and Chenyu Xue and Chuwen Zhang and Qi Deng and Dongdong Ge and Yinyu Ye},
journal= {arXiv preprint arXiv:2308.10630},
year = {2024}
}
Comments
Accepted by UAI`24