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Autori principali: Xue, Jingjing, Sun, Sheng, Liu, Min, Wang, Yuwei, Liu, Zhuotao, Wang, Jingyuan
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2412.07216
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author Xue, Jingjing
Sun, Sheng
Liu, Min
Wang, Yuwei
Liu, Zhuotao
Wang, Jingyuan
author_facet Xue, Jingjing
Sun, Sheng
Liu, Min
Wang, Yuwei
Liu, Zhuotao
Wang, Jingyuan
contents To effectively manage and utilize massive distributed data at the network edge, Federated Learning (FL) has emerged as a promising edge computing paradigm across data silos. However, FL still faces two challenges: system heterogeneity (i.e., the diversity of hardware resources across edge devices) and statistical heterogeneity (i.e., non-IID data). Although sparsification can extract diverse submodels for diverse clients, most sparse FL works either simply assign submodels with artificially-given rigid rules or prune partial parameters using heuristic strategies, resulting in inflexible sparsification and poor performance. In this work, we propose Learnable Personalized Sparsification for heterogeneous Federated learning (FedLPS), which achieves the learnable customization of heterogeneous sparse models with importance-associated patterns and adaptive ratios to simultaneously tackle system and statistical heterogeneity. Specifically, FedLPS learns the importance of model units on local data representation and further derives an importance-based sparse pattern with minimal heuristics to accurately extract personalized data features in non-IID settings. Furthermore, Prompt Upper Confidence Bound Variance (P-UCBV) is designed to adaptively determine sparse ratios by learning the superimposed effect of diverse device capabilities and non-IID data, aiming at resource self-adaptation with promising accuracy. Extensive experiments show that FedLPS outperforms status quo approaches in accuracy and training costs, which improves accuracy by 1.28%-59.34% while reducing running time by more than 68.80%.
format Preprint
id arxiv_https___arxiv_org_abs_2412_07216
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Learnable Sparse Customization in Heterogeneous Edge Computing
Xue, Jingjing
Sun, Sheng
Liu, Min
Wang, Yuwei
Liu, Zhuotao
Wang, Jingyuan
Distributed, Parallel, and Cluster Computing
Machine Learning
To effectively manage and utilize massive distributed data at the network edge, Federated Learning (FL) has emerged as a promising edge computing paradigm across data silos. However, FL still faces two challenges: system heterogeneity (i.e., the diversity of hardware resources across edge devices) and statistical heterogeneity (i.e., non-IID data). Although sparsification can extract diverse submodels for diverse clients, most sparse FL works either simply assign submodels with artificially-given rigid rules or prune partial parameters using heuristic strategies, resulting in inflexible sparsification and poor performance. In this work, we propose Learnable Personalized Sparsification for heterogeneous Federated learning (FedLPS), which achieves the learnable customization of heterogeneous sparse models with importance-associated patterns and adaptive ratios to simultaneously tackle system and statistical heterogeneity. Specifically, FedLPS learns the importance of model units on local data representation and further derives an importance-based sparse pattern with minimal heuristics to accurately extract personalized data features in non-IID settings. Furthermore, Prompt Upper Confidence Bound Variance (P-UCBV) is designed to adaptively determine sparse ratios by learning the superimposed effect of diverse device capabilities and non-IID data, aiming at resource self-adaptation with promising accuracy. Extensive experiments show that FedLPS outperforms status quo approaches in accuracy and training costs, which improves accuracy by 1.28%-59.34% while reducing running time by more than 68.80%.
title Learnable Sparse Customization in Heterogeneous Edge Computing
topic Distributed, Parallel, and Cluster Computing
Machine Learning
url https://arxiv.org/abs/2412.07216