Minimax Optimal Convergence of Gradient Descent in Logistic Regression via Large and Adaptive Stepsizes
Authors
Research Topics
Paper Information
-
Journal:
Journal of Machine Learning Research -
Added to Tracker:
Jul 06, 2026
Abstract
We study gradient descent (GD) for logistic regression on linearly separable data with stepsizes that adapt to the current risk, scaled by a constant hyperparameter \(\eta\). We show that after at most \(1/\gamma^2\) burn-in steps, GD achieves a risk upper bounded by \(\exp(-\Theta(\eta))\), where \(\gamma\) is the margin of the dataset. As \(\eta\) can be arbitrarily large, GD attains an arbitrarily small risk immediately after the burn-in steps, though the risk evolution may be non-monotonic. We further construct hard datasets with margin \(\gamma\), where any batch (or online) first-order method requires \(\Omega(1/\gamma^2)\) steps to find a linear separator. Thus, GD with large, adaptive stepsizes matches the worst-case $1/\gamma^2$ dependence when the sample size is unrestricted. Notably, the classical Perceptron, a first-order online method, also achieves a step complexity of \(1/\gamma^2\), matching GD even in constants. Finally, our GD analysis extends to a broad class of loss functions and certain two-layer networks.
Author Details
Peter L. Bartlett
AuthorRuiqi Zhang
AuthorJingfeng Wu
AuthorLicong Lin
AuthorResearch Topics & Keywords
Machine Learning
Research AreaCitation Information
APA Format
Peter L. Bartlett
,
Ruiqi Zhang
,
Jingfeng Wu
&
Licong Lin
.
Minimax Optimal Convergence of Gradient Descent in Logistic Regression via Large and Adaptive Stepsizes.
Journal of Machine Learning Research
.
BibTeX Format
@article{paper1373,
title = { Minimax Optimal Convergence of Gradient Descent in Logistic Regression via Large and Adaptive Stepsizes },
author = {
Peter L. Bartlett
and Ruiqi Zhang
and Jingfeng Wu
and Licong Lin
},
journal = { Journal of Machine Learning Research },
url = { https://www.jmlr.org/papers/v27/25-1941.html }
}