Abstract

Federated Learning (FL) has recently attracted considerable attention in internet of things, due to its capability of enabling mobile clients to collaboratively learn a global prediction model without sharing their privacy-sensitive data to the server. Despite its great potential, a main challenge of FL is that the training data are usually non-Independent, Identically Distributed (non-IID) on the clients, which may bring the biases in the model training and cause possible accuracy degradation. To address this issue, this paper aims to propose a novel FL algorithm to alleviate the accuracy degradation caused by non-IID data at clients. Firstly, we observe that the clients with different degrees of non-IID data present heterogeneous weight divergence with the clients owning IID data. Inspired by this, we utilize weight divergence to recognize the non-IID degrees of clients. Then, we propose an efficient FL algorithm, named CSFedAvg, in which the clients with lower degree of non-IID data will be chosen to train the models with higher frequency. Finally, we conduct simulations using publicly-available datasets to train deep neural networks. Simulation results show that the proposed FL algorithm improves the training performance compared with existing FL protocol.

Highlights

  • With the rapid advancement of Internet of Things (IoT), a large volume of data has been generated at local devices [1]

  • The emerging of mobile edge computing (MEC) [3], [4] makes it possible to realize the local data storing and processing at the network edges, as the edge nodes such as mobile devices, home gateways, or small cells, are in general equipped with the storage and computation capabilities

  • Considering the above issues, this paper mainly aims to propose a novel Federated Learning (FL) algorithm, which can efficiently improve the accuracy based on non-independent and identically distribution (non-IID) data

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Summary

Introduction

With the rapid advancement of Internet of Things (IoT), a large volume of data has been generated at local devices [1]. The emerging of mobile edge computing (MEC) [3], [4] makes it possible to realize the local data storing and processing at the network edges, as the edge nodes such as mobile devices, home gateways, or small cells, are in general equipped with the storage and computation capabilities. In this context, multiple edge nodes can work together with the remote cloud to perform data processing, involving both local processing at the edge nodes and global coordination at the remote cloud.

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