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Autori principali: Ye, Haoxiang, Ling, Qing
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2407.08632
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author Ye, Haoxiang
Ling, Qing
author_facet Ye, Haoxiang
Ling, Qing
contents Recently, decentralized learning has emerged as a popular peer-to-peer signal and information processing paradigm that enables model training across geographically distributed agents in a scalable manner, without the presence of any central server. When some of the agents are malicious (also termed as Byzantine), resilient decentralized learning algorithms are able to limit the impact of these Byzantine agents without knowing their number and identities, and have guaranteed optimization errors. However, analysis of the generalization errors, which are critical to implementations of the trained models, is still lacking. In this paper, we provide the first analysis of the generalization errors for a class of popular Byzantine-resilient decentralized stochastic gradient descent (DSGD) algorithms. Our theoretical results reveal that the generalization errors cannot be entirely eliminated because of the presence of the Byzantine agents, even if the number of training samples are infinitely large. Numerical experiments are conducted to confirm our theoretical results.
format Preprint
id arxiv_https___arxiv_org_abs_2407_08632
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Generalization Error Matters in Decentralized Learning Under Byzantine Attacks
Ye, Haoxiang
Ling, Qing
Machine Learning
Recently, decentralized learning has emerged as a popular peer-to-peer signal and information processing paradigm that enables model training across geographically distributed agents in a scalable manner, without the presence of any central server. When some of the agents are malicious (also termed as Byzantine), resilient decentralized learning algorithms are able to limit the impact of these Byzantine agents without knowing their number and identities, and have guaranteed optimization errors. However, analysis of the generalization errors, which are critical to implementations of the trained models, is still lacking. In this paper, we provide the first analysis of the generalization errors for a class of popular Byzantine-resilient decentralized stochastic gradient descent (DSGD) algorithms. Our theoretical results reveal that the generalization errors cannot be entirely eliminated because of the presence of the Byzantine agents, even if the number of training samples are infinitely large. Numerical experiments are conducted to confirm our theoretical results.
title Generalization Error Matters in Decentralized Learning Under Byzantine Attacks
topic Machine Learning
url https://arxiv.org/abs/2407.08632