Practical Optimizing UAV Trajectory in Wireless Charging Networks: An Approximated Approach

IF 9.2 2区计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Transactions on Mobile Computing Pub Date : 2025-07-07 DOI:10.1109/TMC.2025.3586457

Yundi Wang;Xiaoyu Wang;He Huang;Haipeng Dai

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引用次数: 0

Abstract

Unmanned Aerial Vehicles (UAVs) can be easily deployed as auxiliary base stations due to their convenience and flexibility. However, limited battery capacity becomes a bottleneck. Promising wireless power transfer (WPT) technologies can provide a continuous power supply for UAVs. Many of the recent works treat the UAV battery capacity as a constraint, which hinders the assurance of continuous UAV operation. Furthermore, most studies employ intelligent path-planning algorithms that lack explicit performance guarantees. In this paper, we study the problem of Practical Optimizing UAV Trajectory in Wireless Charging Networks (POTWCN), which involves planning the trajectory of the wireless-powered UAV in the practical environment with obstacles by selecting candidate passing positions and determining the access order in the charging network. The goal is to maximize the benefit, i.e., balancing the total task completion time and the number of charging stations visited, so as to minimize path length and flight time, and ensure energy constraints with performance bound. To solve this problem, we first formalize the problem and prove its submodularity. Then, we propose the obstacle-aware weighted graph generation algorithm (OWGGA) to deal with the obstacles in the environment, which forms an obstacle-avoidance path using tangents and arcs between two hovering positions and the blocking obstacles. Next, we propose a dynamic charging station selection algorithm (ACSA), which maximizes the UAV’s energy utilization by limiting the number of charging stations that can be included. In the algorithm, we introduce the Christofides algorithm and use the path length calculated by OWGGA as the edge weights of the graph. Subsequently, considering the UAV’s energy constraints, we iteratively solve the UAV trajectory planning problem by adding the charging station with a maximized marginal benefit to the path. We prove that the proposed algorithm achieves an approximation ratio

$1 - 1/e$

as well as the path length is at most

$3\pi /4$

times the optimal solution. Simulation results show that our algorithm reduces the flight distance by 38.01% and the task completion time by 34.00% on average.

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无线充电网络中无人机轨迹的实用优化：一种近似方法

无人机（uav）由于其便利性和灵活性，可以很容易地作为辅助基站部署。然而，有限的电池容量成为瓶颈。有前途的无线电力传输（WPT）技术可以为无人机提供连续供电。近年来的许多研究都将无人机电池容量作为制约因素，阻碍了无人机持续运行的保证。此外，大多数研究采用缺乏明确性能保证的智能路径规划算法。本文研究了无线充电网络（POTWCN）中无人机飞行轨迹的实际优化问题，通过选择候选通过位置和确定充电网络中的接入顺序，规划无人机在具有障碍物的实际环境中的飞行轨迹。目标是实现效益最大化，即在任务总完成时间和充电站访问数量之间取得平衡，使路径长度和飞行时间最小，并在性能约束下保证能量约束。为了解决这个问题，我们首先将问题形式化并证明其子模块性。然后，我们提出了障碍物感知加权图生成算法（OWGGA）来处理环境中的障碍物，该算法利用悬停位置与阻塞障碍物之间的切线和弧线形成避障路径。接下来，我们提出了一种动态充电站选择算法（ACSA），该算法通过限制可包含的充电站数量来最大化无人机的能量利用率。在算法中，我们引入了Christofides算法，并使用OWGGA计算的路径长度作为图的边权。随后，考虑无人机的能量约束，通过在路径上添加边际效益最大化的充电站，迭代求解无人机的轨迹规划问题。我们证明了所提出的算法达到了近似比$1 - $1 /e$，并且路径长度不超过$3\pi /4$乘以最优解。仿真结果表明，该算法平均缩短了38.01%的飞行距离和34.00%的任务完成时间。

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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来源期刊

IEEE Transactions on Mobile Computing 工程技术-电信学

CiteScore

12.90

自引率

2.50%

发文量

403

审稿时长

6.6 months

期刊介绍： IEEE Transactions on Mobile Computing addresses key technical issues related to various aspects of mobile computing. This includes (a) architectures, (b) support services, (c) algorithm/protocol design and analysis, (d) mobile environments, (e) mobile communication systems, (f) applications, and (g) emerging technologies. Topics of interest span a wide range, covering aspects like mobile networks and hosts, mobility management, multimedia, operating system support, power management, online and mobile environments, security, scalability, reliability, and emerging technologies such as wearable computers, body area networks, and wireless sensor networks. The journal serves as a comprehensive platform for advancements in mobile computing research.