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Hauptverfasser: Qiang, Xianke, Liu, Hongda, Zhang, Xinran, Chang, Zheng, Liang, Ying-Chang
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2504.09114
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author Qiang, Xianke
Liu, Hongda
Zhang, Xinran
Chang, Zheng
Liang, Ying-Chang
author_facet Qiang, Xianke
Liu, Hongda
Zhang, Xinran
Chang, Zheng
Liang, Ying-Chang
contents Large Artificial Intelligence Models (LAMs) powered by massive datasets, extensive parameter scales, and extensive computational resources, leading to significant transformations across various industries. Yet, their practical deployment on resource-limited mobile edge devices is hindered by critical challenges such as data privacy, constrained resources, and high overhead costs. Addressing this gap, this paper proposes a novel framework, named Quantized Split Federated Fine-Tuning Large AI Model (SFLAM). By partitioning the training load between edge devices and servers using a split learning paradigm, SFLAM can facilitate the operation of large models on devices and significantly lowers the memory requirements on edge devices. Additionally, SFLAM incorporates quantization management, power control, and bandwidth allocation strategies to enhance training efficiency while concurrently reducing energy consumption and communication latency. A theoretical analysis exploring the latency-energy trade-off is presented, and the framework's efficacy is validated via comprehensive simulations. The findings indicate that SFLAM achieves superior performance in terms of learning efficiency and scalability compared to conventional methods, thereby providing a valuable approach for enabling advanced AI services in resource-constrained scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2504_09114
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Deploying Large AI Models on Resource-Limited Devices with Split Federated Learning
Qiang, Xianke
Liu, Hongda
Zhang, Xinran
Chang, Zheng
Liang, Ying-Chang
Machine Learning
Large Artificial Intelligence Models (LAMs) powered by massive datasets, extensive parameter scales, and extensive computational resources, leading to significant transformations across various industries. Yet, their practical deployment on resource-limited mobile edge devices is hindered by critical challenges such as data privacy, constrained resources, and high overhead costs. Addressing this gap, this paper proposes a novel framework, named Quantized Split Federated Fine-Tuning Large AI Model (SFLAM). By partitioning the training load between edge devices and servers using a split learning paradigm, SFLAM can facilitate the operation of large models on devices and significantly lowers the memory requirements on edge devices. Additionally, SFLAM incorporates quantization management, power control, and bandwidth allocation strategies to enhance training efficiency while concurrently reducing energy consumption and communication latency. A theoretical analysis exploring the latency-energy trade-off is presented, and the framework's efficacy is validated via comprehensive simulations. The findings indicate that SFLAM achieves superior performance in terms of learning efficiency and scalability compared to conventional methods, thereby providing a valuable approach for enabling advanced AI services in resource-constrained scenarios.
title Deploying Large AI Models on Resource-Limited Devices with Split Federated Learning
topic Machine Learning
url https://arxiv.org/abs/2504.09114