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Accelerating Federated Edge Learning via Topology Optimization

Information Theory 2022-04-04 v1 Machine Learning Networking and Internet Architecture Systems and Control Systems and Control math.IT

Abstract

Federated edge learning (FEEL) is envisioned as a promising paradigm to achieve privacy-preserving distributed learning. However, it consumes excessive learning time due to the existence of straggler devices. In this paper, a novel topology-optimized federated edge learning (TOFEL) scheme is proposed to tackle the heterogeneity issue in federated learning and to improve the communication-and-computation efficiency. Specifically, a problem of jointly optimizing the aggregation topology and computing speed is formulated to minimize the weighted summation of energy consumption and latency. To solve the mixed-integer nonlinear problem, we propose a novel solution method of penalty-based successive convex approximation, which converges to a stationary point of the primal problem under mild conditions. To facilitate real-time decision making, an imitation-learning based method is developed, where deep neural networks (DNNs) are trained offline to mimic the penalty-based method, and the trained imitation DNNs are deployed at the edge devices for online inference. Thereby, an efficient imitate-learning based approach is seamlessly integrated into the TOFEL framework. Simulation results demonstrate that the proposed TOFEL scheme accelerates the federated learning process, and achieves a higher energy efficiency. Moreover, we apply the scheme to 3D object detection with multi-vehicle point cloud datasets in the CARLA simulator. The results confirm the superior learning performance of the TOFEL scheme over conventional designs with the same resource and deadline constraints.

Keywords

Cite

@article{arxiv.2204.00489,
  title  = {Accelerating Federated Edge Learning via Topology Optimization},
  author = {Shanfeng Huang and Zezhong Zhang and Shuai Wang and Rui Wang and Kaibin Huang},
  journal= {arXiv preprint arXiv:2204.00489},
  year   = {2022}
}

Comments

15 pages, accepted by IEEE IoTJ for publication

R2 v1 2026-06-24T10:34:48.153Z