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Main Authors: Wang, Haonan, Liu, Zeli, Hoshino, Kajimusugura, Zhang, Tuo, Walters, John Paul, Crago, Stephen
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.00308
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author Wang, Haonan
Liu, Zeli
Hoshino, Kajimusugura
Zhang, Tuo
Walters, John Paul
Crago, Stephen
author_facet Wang, Haonan
Liu, Zeli
Hoshino, Kajimusugura
Zhang, Tuo
Walters, John Paul
Crago, Stephen
contents Federated Learning (FL) enables distributed training on edge devices but faces significant challenges due to resource constraints in edge environments, impacting both communication and computational efficiency. Existing iterative pruning techniques improve communication efficiency but are limited by their centralized design, which struggles with FL's decentralized and data-imbalanced nature, resulting in suboptimal sparsity levels. To address these issues, we propose FedPaI, a novel efficient FL framework that leverages Pruning at Initialization (PaI) to achieve extreme sparsity. FedPaI identifies optimal sparse connections at an early stage, maximizing model capacity and significantly reducing communication and computation overhead by fixing sparsity patterns at the start of training. To adapt to diverse hardware and software environments, FedPaI supports both structured and unstructured pruning. Additionally, we introduce personalized client-side pruning mechanisms for improved learning capacity and sparsity-aware server-side aggregation for enhanced efficiency. Experimental results demonstrate that FedPaI consistently outperforms existing efficient FL that applies conventional iterative pruning with significant leading in efficiency and model accuracy. For the first time, our proposed FedPaI achieves an extreme sparsity level of up to 98% without compromising the model accuracy compared to unpruned baselines, even under challenging non-IID settings. By employing our FedPaI with joint optimization of model learning capacity and sparsity, FL applications can benefit from faster convergence and accelerate the training by 6.4 to 7.9 times.
format Preprint
id arxiv_https___arxiv_org_abs_2504_00308
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle FedPaI: Achieving Extreme Sparsity in Federated Learning via Pruning at Initialization
Wang, Haonan
Liu, Zeli
Hoshino, Kajimusugura
Zhang, Tuo
Walters, John Paul
Crago, Stephen
Machine Learning
Artificial Intelligence
Federated Learning (FL) enables distributed training on edge devices but faces significant challenges due to resource constraints in edge environments, impacting both communication and computational efficiency. Existing iterative pruning techniques improve communication efficiency but are limited by their centralized design, which struggles with FL's decentralized and data-imbalanced nature, resulting in suboptimal sparsity levels. To address these issues, we propose FedPaI, a novel efficient FL framework that leverages Pruning at Initialization (PaI) to achieve extreme sparsity. FedPaI identifies optimal sparse connections at an early stage, maximizing model capacity and significantly reducing communication and computation overhead by fixing sparsity patterns at the start of training. To adapt to diverse hardware and software environments, FedPaI supports both structured and unstructured pruning. Additionally, we introduce personalized client-side pruning mechanisms for improved learning capacity and sparsity-aware server-side aggregation for enhanced efficiency. Experimental results demonstrate that FedPaI consistently outperforms existing efficient FL that applies conventional iterative pruning with significant leading in efficiency and model accuracy. For the first time, our proposed FedPaI achieves an extreme sparsity level of up to 98% without compromising the model accuracy compared to unpruned baselines, even under challenging non-IID settings. By employing our FedPaI with joint optimization of model learning capacity and sparsity, FL applications can benefit from faster convergence and accelerate the training by 6.4 to 7.9 times.
title FedPaI: Achieving Extreme Sparsity in Federated Learning via Pruning at Initialization
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2504.00308