Saved in:
Bibliographic Details
Main Authors: Yu, Zhan, Shi, Zhongjie, Yuan, Deming
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.12901
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866908987567374336
author Yu, Zhan
Shi, Zhongjie
Yuan, Deming
author_facet Yu, Zhan
Shi, Zhongjie
Yuan, Deming
contents With the rapid development of distributed optimization (DO) theory, the distributed stochastic gradient methods (DSGMs) occupy an important position. Although the theory of different DSGMs has been widely established, the main-stream results of existing work are still derived under the condition of light-tailed stochastic gradient noises. Increasing examples from various fields, indicate that, the light-tailed noise model is overly idealized in many practical instances, failing to capture the complexity and variability of noises in real-world scenarios, such as the presence of outliers or extreme values from data science and statistical learning. To address this issue, we propose a new DO framework that incorporates stochastic gradients under sub-Weibull randomness. We study a distributed composite stochastic mirror descent scheme with sub-Weibull gradient noise (DCSMD-SW) for solving a convex distributed composite optimization (DCO) problem over the time-varying multi-agent network. By investigating sub-Weibull randomness in DCSMD for the first time, we show that the algorithm is applicable in some common heavier-tailed noise environments while also guaranteeing good convergence properties. We comprehensively study the convergence performance of DCSMD-SW. Satisfactory high-probability convergence rates are derived for DCSMD-SW without any smoothness requirement. The work also offers a unified analytical framework for several critical cases of both algorithms and noise environments.
format Preprint
id arxiv_https___arxiv_org_abs_2506_12901
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle High-Probability Convergence Theory for Distributed Composite Optimization with Sub-Weibull Noises
Yu, Zhan
Shi, Zhongjie
Yuan, Deming
Optimization and Control
With the rapid development of distributed optimization (DO) theory, the distributed stochastic gradient methods (DSGMs) occupy an important position. Although the theory of different DSGMs has been widely established, the main-stream results of existing work are still derived under the condition of light-tailed stochastic gradient noises. Increasing examples from various fields, indicate that, the light-tailed noise model is overly idealized in many practical instances, failing to capture the complexity and variability of noises in real-world scenarios, such as the presence of outliers or extreme values from data science and statistical learning. To address this issue, we propose a new DO framework that incorporates stochastic gradients under sub-Weibull randomness. We study a distributed composite stochastic mirror descent scheme with sub-Weibull gradient noise (DCSMD-SW) for solving a convex distributed composite optimization (DCO) problem over the time-varying multi-agent network. By investigating sub-Weibull randomness in DCSMD for the first time, we show that the algorithm is applicable in some common heavier-tailed noise environments while also guaranteeing good convergence properties. We comprehensively study the convergence performance of DCSMD-SW. Satisfactory high-probability convergence rates are derived for DCSMD-SW without any smoothness requirement. The work also offers a unified analytical framework for several critical cases of both algorithms and noise environments.
title High-Probability Convergence Theory for Distributed Composite Optimization with Sub-Weibull Noises
topic Optimization and Control
url https://arxiv.org/abs/2506.12901