基于强化学习的双备用电池EH-WSNs路由

Proceedings of the 2020 6th International Conference on Computing and Artificial Intelligence Pub Date : 2020-04-23 DOI:10.1145/3404555.3404569

T. Zhao, Luyao Wang, Kwan-Wu Chin

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引用次数: 1

摘要

本文研究了一种能量收集无线传感器网络(EH-WSN)，其中节点具有双备用电池系统。我们提出了一种基于无状态分布式强化学习的路由算法，命名为QLRA，其中每个节点根据其邻居的电池和数据信息学习转发其数据的最佳下一跳。我们研究了源数量和路径探索概率对QLRA性能的影响。数值结果表明，经过学习，QLRA能够在所有测试场景中实现最小的端到端延迟，比竞争路由算法的平均端到端延迟低18%左右。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Reinforcement Learning Based Routing in EH-WSNs with Dual Alternative Batteries

This paper considers an Energy Harvesting Wireless Sensor Network (EH-WSN) where nodes have a dual alternative battery system. We propose a stateless distributed reinforcement learning based routing algorithm, named QLRA, where each node learns the best next hop(s) to forward its data based on the battery and data information of its neighbors. We study how the number of sources and path exploration probability impacts the performance of QLRA. Numerical results show that after learning, QLRA is able to achieve minimal end-to-end delays in all tested scenarios, which is about 18% lower than the average end-to-end delay of a competing routing algorithm.

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Proceedings of the 2020 6th International Conference on Computing and Artificial Intelligence

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