Abstract

Federated learning is a newly emerged distributed machine learning paradigm, where the clients are allowed to individually train local deep neural network (DNN) models with local data and then jointly aggregate a global DNN model at the central server. Vehicular edge computing (VEC) aims at exploiting the computation and communication resources at the edge of vehicular networks. Federated learning in VEC is promising to meet the ever-increasing demands of artificial intelligence (AI) applications in intelligent connected vehicles (ICV). Considering image classification as a typical AI application in VEC, the diversity of image quality and computation capability in vehicular clients potentially affects the accuracy and efficiency of federated learning. Accordingly, we propose a selective model aggregation approach, where “fine” local DNN models are selected and sent to the central server by evaluating the local image quality and computation capability. Regarding the implementation of model selection, the central server is not aware of the image quality and computation capability in the vehicular clients, whose privacy is protected under such a federated learning framework. To overcome this information asymmetry, we employ two-dimension contract theory as a distributed framework to facilitate the interactions between the central server and vehicular clients. The formulated problem is then transformed into a tractable problem through successively relaxing and simplifying the constraints, and eventually solved by a greedy algorithm. Using two datasets, i.e., MNIST and BelgiumTSC, our selective model aggregation approach is demonstrated to outperform the original federated averaging (FedAvg) approach in terms of accuracy and efficiency. Meanwhile, our approach also achieves higher utility at the central server compared with the baseline approaches.

Highlights

  • Federated learning has been proposed by Google as a distributed machine learning paradigm to push the computation of artificial intelligence (AI) applications into more and more end devices while protecting the privacy of end users [1]

  • The above steps are repeated in multiple rounds until the training accuracy of the global deep neural network (DNN) model meets the requirement of the central server

  • For federated learning with image classification, a selective model aggregation approach is proposed to reduce the influence from the diversity of image quality and computation capability in vehicular clients

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Summary

INTRODUCTION

Federated learning has been proposed by Google as a distributed machine learning paradigm to push the computation of artificial intelligence (AI) applications into more and more end devices while protecting the privacy of end users [1]. The vehicular clients are selected by the central server to participate in federated learning in a supervised fashion and generate global and local DNN model updates. By evaluating local image quality as well as computation capability, the ‘‘fine’’ local DNN models on the ‘‘fine’’ clients are selected and sent to the central server for aggregation. Since federated learning prevents from sending local data, the central server is not aware of the image quality and computation capability of vehicular clients, which is called information asymmetry. For federated learning with image classification, a selective model aggregation approach is proposed to reduce the influence from the diversity of image quality and computation capability in vehicular clients.

RELATED WORK
SYSTEM MODEL
IMAGE QUALITY
CONTRACT FORMULATION AND SOLUTION
PROBLEM RELAXATION AND TRANSFORMATION
SOLUTION TO OPTIMAL CONTRACTS
Method
Findings
CONCLUSION

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