Decentralized Nonconvex Optimization under Heavy-Tailed Noise: Normalization and Optimal Convergence
Abstract
Heavy-tailed noise in nonconvex stochastic optimization has garnered increasing research interest, as empirical studies, including those on training attention models, suggest it is a more realistic gradient noise condition. This paper studies first-order nonconvex stochastic optimization under heavy-tailed gradient noise in a decentralized setup, where each node can only communicate with its direct neighbors in a predefined graph. Specifically, we consider a class of heavy-tailed gradient noise that is zero-mean and has only -th moment for . We propose GT-NSGDm, Gradient Tracking based Normalized Stochastic Gradient Descent with momentum, that utilizes normalization, in conjunction with gradient tracking and momentum, to cope with heavy-tailed noise on distributed nodes. We show that, when the communication graph admits primitive and doubly stochastic weights, GT-NSGDm guarantees, for the \textit{first} time in the literature, that the expected gradient norm converges at an optimal non-asymptotic rate , which matches the lower bound in the centralized setup. When tail index is unknown, GT-NSGDm attains a non-asymptotic rate that is, for , topology independent and has a speedup factor in terms of the number of nodes . Finally, experiments on nonconvex linear regression with tokenized synthetic data and decentralized training of language models on a real-world corpus demonstrate that GT-NSGDm is more robust and efficient than baselines.
Cite
@article{arxiv.2505.03736,
title = {Decentralized Nonconvex Optimization under Heavy-Tailed Noise: Normalization and Optimal Convergence},
author = {Shuhua Yu and Dusan Jakovetic and Soummya Kar},
journal= {arXiv preprint arXiv:2505.03736},
year = {2026}
}
Comments
Accepted to ICLR 2026