FedPAW：利用个性化聚合权重进行联合学习，用于城市车辆速度预测

IF 5.3 2区计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Transactions on Cloud Computing Pub Date : 2024-09-02 DOI:10.1109/TCC.2024.3452696

Yuepeng He;Pengzhan Zhou;Yijun Zhai;Fang Qu;Zhida Qin;Mingyan Li;Songtao Guo

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引用次数: 0

摘要

车速预测对于智能交通系统至关重要，通过准确预测未来车辆状况来促进更可靠的自动驾驶。由于驾驶员驾驶风格和车辆类型的差异，对不同目标车辆的速度预测可能存在显著差异。现有方法在保护驾驶员数据隐私的同时，可能无法实现个性化的车速预测。我们提出了一种具有个性化聚合权重（FedPAW）的联邦学习框架来克服这些挑战。该方法通过测量局部模型和全局模型参数之间的加权均方误差来捕获特定于客户端的信息。服务器向客户端发送定制的聚合模型，而不是单一的全局模型，不会为客户端带来额外的计算和通信开销。为了评估FedPAW的有效性，我们使用自动驾驶模拟器CARLA收集了城市场景下的驾驶数据，采用基于lstm的Seq2Seq模型和多头注意机制来预测目标车辆的未来速度。结果表明，与11个代表性基准基线相比，我们提出的FedPAW在10秒的时间范围内的预测误差最低，测试MAE降低了0.8%。

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FedPAW: Federated Learning With Personalized Aggregation Weights for Urban Vehicle Speed Prediction

Vehicle speed prediction is crucial for intelligent transportation systems, promoting more reliable autonomous driving by accurately predicting future vehicle conditions. Due to variations in drivers’ driving styles and vehicle types, speed predictions for different target vehicles may significantly differ. Existing methods may not realize personalized vehicle speed prediction while protecting drivers’ data privacy. We propose a Federated learning framework with Personalized Aggregation Weights (FedPAW) to overcome these challenges. This method captures client-specific information by measuring the weighted mean squared error between the parameters of local models and global models. The server sends tailored aggregated models to clients instead of a single global model, without incurring additional computational and communication overhead for clients. To evaluate the effectiveness of FedPAW, we collected driving data in urban scenarios using the autonomous driving simulator CARLA, employing an LSTM-based Seq2Seq model with a multi-head attention mechanism to predict the future speed of target vehicles. The results demonstrate that our proposed FedPAW ranks lowest in prediction error within the time horizon of 10 seconds, with a 0.8% reduction in test MAE, compared to eleven representative benchmark baselines.

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来源期刊

IEEE Transactions on Cloud Computing Computer Science-Software

CiteScore

9.40

自引率

6.20%

发文量

167

期刊介绍： The IEEE Transactions on Cloud Computing (TCC) is dedicated to the multidisciplinary field of cloud computing. It is committed to the publication of articles that present innovative research ideas, application results, and case studies in cloud computing, focusing on key technical issues related to theory, algorithms, systems, applications, and performance.