应急救援场景无线网状网络中的路由器和网关节点布置

Mariusz Wzorek, Cyrille Berger, Patrick Doherty
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引用次数: 0

摘要

本文的重点是无人机在救援行动初期快速部署临时通信基础设施所需的基本功能。主要想法是使用异构无人机团队部署包括路由器在内的通信套件,并用于生成特设无线网状网络(WMN)。研究考虑了几个基本问题,并提出了解决这些问题的算法。首先考虑的是路由器节点放置问题(RNP)以及考虑到实际现场使用中出现的额外约束条件的该问题的一般化。RNP 问题试图确定如何在 WMN 中以最佳方式放置路由器。为解决这一问题,提出了一种新算法,即 RRT-WMN 算法。该算法部分基于运动规划中使用的快速探索随机树(RRT)算法。RRT-WMN 算法与现有技术(如协方差矩阵适应进化策略(CMA-ES)和粒子群优化(PSO))之间的经验比较评估表明,当广义 RNP 问题扩展到现实场景时,RRT-WMN 算法在耗时和区域覆盖方面都有更好的表现。网关节点安置问题(GNP)试图确定如何在 WMN 骨干网络中安置最少数量的网关节点,同时满足一系列服务质量(QoS)约束。第一种方法将 RRT-WMN 算法与已有的图聚类算法相结合。第二种方法是 WMNbyAreaDecomposition,它提出了一种新颖的 "分而治之 "算法,将目标部署区域递归划分为一组互不相交的区域,从而创建了许多更简单的 RNP 问题,然后并发解决这些问题。这两种算法都在不同规模和复杂度的真实世界 GIS 模型上进行了评估。结果表明,WMNbyAreaDecomposition 在满足所有 QoS 要求的同时,路由器节点数量减少了 73% 到 92%,性能优于现有算法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Router and gateway node placement in wireless mesh networks for emergency rescue scenarios

The focus of this paper is on base functionalities required for UAV-based rapid deployment of an ad hoc communication infrastructure in the initial phases of rescue operations. The main idea is to use heterogeneous teams of UAVs to deploy communication kits that include routers, and are used in the generation of ad hoc Wireless Mesh Networks (WMN). Several fundamental problems are considered and algorithms are proposed to solve these problems. The Router Node Placement problem (RNP) and a generalization of it that takes into account additional constraints arising in actual field usage is considered first. The RNP problem tries to determine how to optimally place routers in a WMN. A new algorithm, the RRT-WMN algorithm, is proposed to solve this problem. It is based in part on a novel use of the Rapidly Exploring Random Trees (RRT) algorithm used in motion planning. A comparative empirical evaluation between the RRT-WMN algorithm and existing techniques such as the Covariance Matrix Adaptation Evolution Strategy (CMA-ES) and Particle Swarm Optimization (PSO), shows that the RRT-WMN algorithm has far better performance both in amount of time taken and regional coverage as the generalized RNP problem scales to realistic scenarios. The Gateway Node Placement Problem (GNP) tries to determine how to locate a minimal number of gateway nodes in a WMN backbone network while satisfying a number of Quality of Service (QoS) constraints.Two alternatives are proposed for solving the combined RNP-GNP problem. The first approach combines the RRT-WMN algorithm with a preexisting graph clustering algorithm. The second approach, WMNbyAreaDecomposition, proposes a novel divide-and-conquer algorithm that recursively partitions a target deployment area into a set of disjoint regions, thus creating a number of simpler RNP problems that are then solved concurrently. Both algorithms are evaluated on real-world GIS models of different size and complexity. WMNbyAreaDecomposition is shown to outperform existing algorithms using 73% to 92% fewer router nodes while at the same time satisfying all QoS requirements.

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