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Main Authors: Liu, Zijian, Zhou, Zhengyuan
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.07723
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author Liu, Zijian
Zhou, Zhengyuan
author_facet Liu, Zijian
Zhou, Zhengyuan
contents Shuffling gradient methods are widely used in modern machine learning tasks and include three popular implementations: Random Reshuffle (RR), Shuffle Once (SO), and Incremental Gradient (IG). Compared to the empirical success, the theoretical guarantee of shuffling gradient methods was not well-understood for a long time. Until recently, the convergence rates had just been established for the average iterate for convex functions and the last iterate for strongly convex problems (using squared distance as the metric). However, when using the function value gap as the convergence criterion, existing theories cannot interpret the good performance of the last iterate in different settings (e.g., constrained optimization). To bridge this gap between practice and theory, we prove the first last-iterate convergence rates for shuffling gradient methods with respect to the objective value even without strong convexity. Our new results either (nearly) match the existing last-iterate lower bounds or are as fast as the previous best upper bounds for the average iterate.
format Preprint
id arxiv_https___arxiv_org_abs_2403_07723
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle On the Last-Iterate Convergence of Shuffling Gradient Methods
Liu, Zijian
Zhou, Zhengyuan
Machine Learning
Optimization and Control
Shuffling gradient methods are widely used in modern machine learning tasks and include three popular implementations: Random Reshuffle (RR), Shuffle Once (SO), and Incremental Gradient (IG). Compared to the empirical success, the theoretical guarantee of shuffling gradient methods was not well-understood for a long time. Until recently, the convergence rates had just been established for the average iterate for convex functions and the last iterate for strongly convex problems (using squared distance as the metric). However, when using the function value gap as the convergence criterion, existing theories cannot interpret the good performance of the last iterate in different settings (e.g., constrained optimization). To bridge this gap between practice and theory, we prove the first last-iterate convergence rates for shuffling gradient methods with respect to the objective value even without strong convexity. Our new results either (nearly) match the existing last-iterate lower bounds or are as fast as the previous best upper bounds for the average iterate.
title On the Last-Iterate Convergence of Shuffling Gradient Methods
topic Machine Learning
Optimization and Control
url https://arxiv.org/abs/2403.07723