Statistical Guarantees for High-Dimensional Stochastic Gradient Descent
Abstract
Stochastic Gradient Descent (SGD) and its Ruppert-Polyak averaged variant (ASGD) lie at the heart of modern large-scale learning, yet their theoretical properties in high-dimensional settings are rarely understood. In this paper, we provide rigorous statistical guarantees for constant learning-rate SGD and ASGD in high-dimensional regimes. Our key innovation is to transfer powerful tools from high-dimensional time series to online learning. Specifically, by viewing SGD as a nonlinear autoregressive process and adapting existing coupling techniques, we prove the geometric-moment contraction of high-dimensional SGD for constant learning rates, thereby establishing asymptotic stationarity of the iterates. Building on this, we derive the -th moment convergence of SGD and ASGD for any in general -norms, and, in particular, the -norm that is frequently adopted in high-dimensional sparse or structured models. Furthermore, we provide sharp high-probability concentration analysis which entails the probabilistic bound of high-dimensional ASGD. Beyond closing a critical gap in SGD theory, our proposed framework offers a novel toolkit for analyzing a broad class of high-dimensional learning algorithms.
Keywords
Cite
@article{arxiv.2510.12013,
title = {Statistical Guarantees for High-Dimensional Stochastic Gradient Descent},
author = {Jiaqi Li and Zhipeng Lou and Johannes Schmidt-Hieber and Wei Biao Wu},
journal= {arXiv preprint arXiv:2510.12013},
year = {2025}
}
Comments
Accepted to NeurIPS 2025