Related papers: Federated Learning on the Road: Autonomous Controller Design for Connected and Autonomous Vehicles

Federated Learning on the Road: Autonomous Controller Design for Connected and Autonomous Vehicles

URL: http://arxiv.org/abs/2102.03401v1
Date: Fri, 5 Feb 2021 19:57:47 GMT
Title: Federated Learning on the Road: Autonomous Controller Design for Connected and Autonomous Vehicles
Authors: Tengchan Zeng, Omid Semiari, Mingzhe Chen, Walid Saad, and Mehdi Bennis
Abstract summary: A new federated learning (FL) framework is proposed for designing the autonomous controller of connected and autonomous vehicles (CAVs) A novel dynamic federated proximal (DFP) algorithm is proposed that accounts for the mobility of CAVs, the wireless fading channels, and the unbalanced and nonindependent and identically distributed data across CAVs. A rigorous convergence analysis is performed for the proposed algorithm to identify how fast the CAVs converge to using the optimal controller.
Score: 109.71532364079711
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: A new federated learning (FL) framework enabled by large-scale wireless connectivity is proposed for designing the autonomous controller of connected and autonomous vehicles (CAVs). In this framework, the learning models used by the controllers are collaboratively trained among a group of CAVs. To capture the varying CAV participation in the FL training process and the diverse local data quality among CAVs, a novel dynamic federated proximal (DFP) algorithm is proposed that accounts for the mobility of CAVs, the wireless fading channels, as well as the unbalanced and nonindependent and identically distributed data across CAVs. A rigorous convergence analysis is performed for the proposed algorithm to identify how fast the CAVs converge to using the optimal autonomous controller. In particular, the impacts of varying CAV participation in the FL process and diverse CAV data quality on the convergence of the proposed DFP algorithm are explicitly analyzed. Leveraging this analysis, an incentive mechanism based on contract theory is designed to improve the FL convergence speed. Simulation results using real vehicular data traces show that the proposed DFP-based controller can accurately track the target CAV speed over time and under different traffic scenarios. Moreover, the results show that the proposed DFP algorithm has a much faster convergence compared to popular FL algorithms such as federated averaging (FedAvg) and federated proximal (FedProx). The results also validate the feasibility of the contract-theoretic incentive mechanism and show that the proposed mechanism can improve the convergence speed of the DFP algorithm by 40% compared to the baselines.

Related papers

Deep Learning Methods for Adjusting Global MFD Speed Estimations to Local Link Configurations [4.2185937778110825]
This study introduces a Local Correction Factor (LCF) that integrates MFD-derived network mean speed with network configurations to accurately estimate the individual speed of a link. We use a novel deep learning framework to capture both spatial configurations and temporal dynamics of the network. Our model enhances the precision of link-level traffic speed estimations while preserving the computational benefits of aggregate models.
arXiv Detail & Related papers (2024-05-23T07:37:33Z)
Over-the-Air Federated Learning and Optimization [52.5188988624998]
We focus on Federated learning (FL) via edge-the-air computation (AirComp) We describe the convergence of AirComp-based FedAvg (AirFedAvg) algorithms under both convex and non- convex settings. For different types of local updates that can be transmitted by edge devices (i.e., model, gradient, model difference), we reveal that transmitting in AirFedAvg may cause an aggregation error. In addition, we consider more practical signal processing schemes to improve the communication efficiency and extend the convergence analysis to different forms of model aggregation error caused by these signal processing schemes.
arXiv Detail & Related papers (2023-10-16T05:49:28Z)
Accelerating Wireless Federated Learning via Nesterov's Momentum and Distributed Principle Component Analysis [59.127630388320036]
A wireless federated learning system is investigated by allowing a server and workers to exchange uncoded information via wireless channels. Since the workers frequently upload local to the server via bandwidth-limited channels, the uplink transmission from the workers to the server becomes a communication bottleneck. A one-shot distributed principle component analysis (PCA) is leveraged to reduce the dimension of the dimension of the communication bottleneck.
arXiv Detail & Related papers (2023-03-31T08:41:42Z)
Predictive GAN-powered Multi-Objective Optimization for Hybrid Federated Split Learning [56.125720497163684]
We propose a hybrid federated split learning framework in wireless networks. We design a parallel computing scheme for model splitting without label sharing, and theoretically analyze the influence of the delayed gradient caused by the scheme on the convergence speed.
arXiv Detail & Related papers (2022-09-02T10:29:56Z)
Federated Deep Learning Meets Autonomous Vehicle Perception: Design and Verification [168.67190934250868]
Federated learning empowered connected autonomous vehicle (FLCAV) has been proposed. FLCAV preserves privacy while reducing communication and annotation costs. It is challenging to determine the network resources and road sensor poses for multi-stage training.
arXiv Detail & Related papers (2022-06-03T23:55:45Z)
Communication-Efficient Stochastic Zeroth-Order Optimization for Federated Learning [28.65635956111857]
Federated learning (FL) enables edge devices to collaboratively train a global model without sharing their private data. To enhance the training efficiency of FL, various algorithms have been proposed, ranging from first-order computation to first-order methods.
arXiv Detail & Related papers (2022-01-24T08:56:06Z)
Semi-asynchronous Hierarchical Federated Learning for Cooperative Intelligent Transportation Systems [10.257042901204528]
Cooperative Intelligent Transport System (C-ITS) is a promising network to provide safety, efficiency, sustainability, and comfortable services for automated vehicles and road infrastructures. The components of C-ITS usually generate large amounts of data, which makes it difficult to explore data science. We propose a novel Semi-a synchronous Federated Learning (SHFL) framework for C-ITS that enables elastic edge to cloud model aggregation from data sensing.
arXiv Detail & Related papers (2021-10-18T07:44:34Z)
Fast Convergence Algorithm for Analog Federated Learning [30.399830943617772]
We propose an AirComp-based FedSplit algorithm for efficient analog federated learning over wireless channels. We prove that the proposed algorithm linearly converges to the optimal solutions under the assumption that the objective function is strongly convex and smooth. Our algorithm is theoretically and experimentally verified to be much more robust to the ill-conditioned problems with faster convergence compared with other benchmark FL algorithms.
arXiv Detail & Related papers (2020-10-30T10:59:49Z)
Federated Learning in the Sky: Joint Power Allocation and Scheduling with UAV Swarms [98.78553146823829]
Unmanned aerial vehicle (UAV) swarms must exploit machine learning (ML) in order to execute various tasks. In this paper, a novel framework is proposed to implement distributed learning (FL) algorithms within a UAV swarm.
arXiv Detail & Related papers (2020-02-19T14:04:01Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.