English

ROOT-SGD: Sharp Nonasymptotics and Near-Optimal Asymptotics in a Single Algorithm

Optimization and Control 2024-09-19 v4 Machine Learning Machine Learning

Abstract

We study the problem of solving strongly convex and smooth unconstrained optimization problems using stochastic first-order algorithms. We devise a novel algorithm, referred to as Recursive One-Over-T SGD (ROOT-SGD), based on an easily implementable, recursive averaging of past stochastic gradients. We prove that it simultaneously achieves state-of-the-art performance in both a finite-sample, nonasymptotic sense and an asymptotic sense. On the non-asymptotic side, we prove risk bounds on the last iterate of ROOT-SGD with leading-order terms that match the optimal statistical risk with a unity pre-factor, along with a higher-order term that scales at the sharp rate of O(n3/2)O(n^{-3/2}) under the Lipschitz condition on the Hessian matrix. On the asymptotic side, we show that when a mild, one-point Hessian continuity condition is imposed, the rescaled last iterate of (multi-epoch) ROOT-SGD converges asymptotically to a Gaussian limit with the Cram\'er-Rao optimal asymptotic covariance, for a broad range of step-size choices.

Keywords

Cite

@article{arxiv.2008.12690,
  title  = {ROOT-SGD: Sharp Nonasymptotics and Near-Optimal Asymptotics in a Single Algorithm},
  author = {Chris Junchi Li and Wenlong Mou and Martin J. Wainwright and Michael I. Jordan},
  journal= {arXiv preprint arXiv:2008.12690},
  year   = {2024}
}

Comments

some corrections

R2 v1 2026-06-23T18:10:03.679Z