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Abstract

Due to the merit without requiring charging cable, wireless power transfer technology has drawn rising attention as a new method to replenish energy for Wireless Rechargeable Sensor Networks. In this article, we study the mobile charger scheduling problem for multi-node recharging with deadline constraints. Our target is to maximize the overall effective charging utility and minimize the traveling time for moving as well. Instead of charging only once over a scheduling cycle, we incorporate the multi-node charging strategy with deadline constraints, where charging spots and tour are jointly optimized. Specifically, we formulate the effective charging utility maximization problem as a monotone submodular function optimization subject to a partition matroid constraint, and we propose a simple but effective ½-approximation greedy algorithm. After that, we derive the result of global scheduling and present the grid-based skip-substitute operation to further save the traveling time, which can increase the charging utility. Finally, we conduct the evaluation for the performance of our scheduling scheme. The simulation and field experiment results show that our algorithm excels in terms of effective charging utility.