Fault-Tolerant Federated Reinforcement Learning with Theoretical Guarantee
Abstract
The growing literature of Federated Learning (FL) has recently inspired Federated Reinforcement Learning (FRL) to encourage multiple agents to federatively build a better decision-making policy without sharing raw trajectories. Despite its promising applications, existing works on FRL fail to I) provide theoretical analysis on its convergence, and II) account for random system failures and adversarial attacks. Towards this end, we propose the first FRL framework the convergence of which is guaranteed and tolerant to less than half of the participating agents being random system failures or adversarial attackers. We prove that the sample efficiency of the proposed framework is guaranteed to improve with the number of agents and is able to account for such potential failures or attacks. All theoretical results are empirically verified on various RL benchmark tasks.
Cite
Text
Fan et al. "Fault-Tolerant Federated Reinforcement Learning with Theoretical Guarantee." Neural Information Processing Systems, 2021.Markdown
[Fan et al. "Fault-Tolerant Federated Reinforcement Learning with Theoretical Guarantee." Neural Information Processing Systems, 2021.](https://mlanthology.org/neurips/2021/fan2021neurips-faulttolerant/)BibTeX
@inproceedings{fan2021neurips-faulttolerant,
title = {{Fault-Tolerant Federated Reinforcement Learning with Theoretical Guarantee}},
author = {Fan, Xiaofeng and Ma, Yining and Dai, Zhongxiang and Jing, Wei and Tan, Cheston and Low, Bryan Kian Hsiang},
booktitle = {Neural Information Processing Systems},
year = {2021},
url = {https://mlanthology.org/neurips/2021/fan2021neurips-faulttolerant/}
}