机器人团队在危险环境中定向越野的双目标路径规划

Cory M. Simon, Jeffrey Richley, Lucas Overbey, Darleen Perez-Lavin
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引用次数: 0

摘要

移动[空中、地面或水上]机器人小组可应用于资源运送、巡逻、信息收集、农业、森林灭火、化学羽流源定位和绘图以及搜索和救援。机器人团队在穿越危险环境(如崎岖的地形或海洋、强风或能够攻击或捕获机器人的对手)时,应在考虑到瘫痪、破坏或捕获风险的情况下规划和协调它们的路径。具体来说,机器人应选择最安全的路径,协调它们的路径,以合作实现团队级目标,同时保证机器人故障的稳健性,并平衡访问地点带来的奖励与机器人损失的风险。在这里,我们考虑的是在危险环境中进行定向越野的移动机器人团队的双目标路径规划。危险环境被抽象为一个有向图,当机器人穿越该图中的弧时,其生存概率是已知的。图中的每个节点如果被机器人访问(例如,向节点运送物品或图像),都会给团队带来奖励。我们希望搜索帕累托最优机器人-团队路径计划,使两个[相互冲突的]团队目标最大化:预期的 (i) 团队奖励和 (ii) 任务中存活的机器人数量。然后,人类决策者可以根据奖励和机器人存活率这两个目标的价值,选择平衡的路径计划。在启发式方法的指导下,我们采用了蚁群优化方法来搜索帕累托最优的机器人团队路径计划集。作为案例研究,我们以艺术博物馆中的信息收集任务为例进行说明。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Bi-objective trail-planning for a robot team orienteering in a hazardous environment
Teams of mobile [aerial, ground, or aquatic] robots have applications in resource delivery, patrolling, information-gathering, agriculture, forest fire fighting, chemical plume source localization and mapping, and search-and-rescue. Robot teams traversing hazardous environments -- with e.g. rough terrain or seas, strong winds, or adversaries capable of attacking or capturing robots -- should plan and coordinate their trails in consideration of risks of disablement, destruction, or capture. Specifically, the robots should take the safest trails, coordinate their trails to cooperatively achieve the team-level objective with robustness to robot failures, and balance the reward from visiting locations against risks of robot losses. Herein, we consider bi-objective trail-planning for a mobile team of robots orienteering in a hazardous environment. The hazardous environment is abstracted as a directed graph whose arcs, when traversed by a robot, present known probabilities of survival. Each node of the graph offers a reward to the team if visited by a robot (which e.g. delivers a good to or images the node). We wish to search for the Pareto-optimal robot-team trail plans that maximize two [conflicting] team objectives: the expected (i) team reward and (ii) number of robots that survive the mission. A human decision-maker can then select trail plans that balance, according to their values, reward and robot survival. We implement ant colony optimization, guided by heuristics, to search for the Pareto-optimal set of robot team trail plans. As a case study, we illustrate with an information-gathering mission in an art museum.
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