Dynamic Mobile Charger Scheduling in Heterogeneous Wireless Sensor Networks

2015 IEEE 12th International Conference on Mobile Ad Hoc and Sensor Systems Pub Date : 2015-10-19 DOI:10.1109/MASS.2015.99

Hua Huang, Shan Lin, Lin Chen, Jie Gao, A. Mamat, Jie Wu

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引用次数: 6

Abstract

Recent advances in energy transfer technology is boosting the development of renewable sensor networks. To sustain such a network, a mobile robot travels from node to node to recharge each sensor before its battery runs out. Consider each node's recharge as a real-time task, the robot needs to serve these tasks by their deadlines. This represents a class of challenging mobility scheduling problems, where the nodes' deadlines and spatial distribution are often at odds with each other. In this paper, we focus on the scenario where nodes have heterogeneous energy consumption rates, and our goal is to maximize the percentage of nodes alive. We formulate this scheduling problem and prove its NP-completeness. To solve this problem, we propose a spatial dependent task scheduling algorithm, which quantifies the impact of scheduling proximate tasks on the other tasks. With extensive simulations, we reveal the trade-offs of existing solutions under a wide range of network scenarios. Our evaluation results show that our algorithms out-perform classical TSP scheduler by up to 10% and 85% in terms of coverage ratio and average tardiness, respectively.

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异构无线传感器网络中的动态移动充电器调度

能源传输技术的最新进展推动了可再生传感器网络的发展。为了维持这样的网络，一个移动机器人从一个节点移动到另一个节点，在电池耗尽之前给每个传感器充电。将每个节点的充电视为实时任务，机器人需要在截止日期前完成这些任务。这代表了一类具有挑战性的移动性调度问题，其中节点的最后期限和空间分布通常彼此不一致。在本文中，我们关注节点具有异构能耗率的场景，我们的目标是最大化节点的存活百分比。我们提出了这个调度问题，并证明了它的np完备性。为了解决这一问题，我们提出了一种空间相关的任务调度算法，该算法量化了调度邻近任务对其他任务的影响。通过广泛的模拟，我们揭示了在广泛的网络场景下现有解决方案的权衡。我们的评估结果表明，我们的算法在覆盖率和平均延迟方面分别比传统的TSP调度程序高出10%和85%。

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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2015 IEEE 12th International Conference on Mobile Ad Hoc and Sensor Systems

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