Stochastic Second-Order Methods Improve Best-Known Sample Complexity of SGD for Gradient-Dominated Function
Abstract
We study the performance of Stochastic Cubic Regularized Newton (SCRN) on a class of functions satisfying gradient dominance property with which holds in a wide range of applications in machine learning and signal processing. This condition ensures that any first-order stationary point is a global optimum. We prove that the total sample complexity of SCRN in achieving -global optimum is for and for . SCRN improves the best-known sample complexity of stochastic gradient descent. Even under a weak version of gradient dominance property, which is applicable to policy-based reinforcement learning (RL), SCRN achieves the same improvement over stochastic policy gradient methods. Additionally, we show that the average sample complexity of SCRN can be reduced to for using a variance reduction method with time-varying batch sizes. Experimental results in various RL settings showcase the remarkable performance of SCRN compared to first-order methods.
Cite
@article{arxiv.2205.12856,
title = {Stochastic Second-Order Methods Improve Best-Known Sample Complexity of SGD for Gradient-Dominated Function},
author = {Saeed Masiha and Saber Salehkaleybar and Niao He and Negar Kiyavash and Patrick Thiran},
journal= {arXiv preprint arXiv:2205.12856},
year = {2023}
}