Coordinated Motion Planning: Multi-Agent Path Finding in a Densely Packed, Bounded Domain

arXiv - CS - Data Structures and Algorithms Pub Date : 2024-09-10 DOI:arxiv-2409.06486

Sándor P. Fekete, Ramin Kosfeld, Peter Kramer, Jonas Neutzner, Christian Rieck, Christian Scheffer

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Abstract

We study Multi-Agent Path Finding for arrangements of labeled agents in the interior of a simply connected domain: Given a unique start and target position for each agent, the goal is to find a sequence of parallel, collision-free agent motions that minimizes the overall time (the makespan) until all agents have reached their respective targets. A natural case is that of a simply connected polygonal domain with axis-parallel boundaries and integer coordinates, i.e., a simple polyomino, which amounts to a simply connected union of lattice unit squares or cells. We focus on the particularly challenging setting of densely packed agents, i.e., one per cell, which strongly restricts the mobility of agents, and requires intricate coordination of motion. We provide a variety of novel results for this problem, including (1) a characterization of polyominoes in which a reconfiguration plan is guaranteed to exist; (2) a characterization of shape parameters that induce worst-case bounds on the makespan; (3) a suite of algorithms to achieve asymptotically worst-case optimal performance with respect to the achievable stretch for cases with severely limited maneuverability. This corresponds to bounding the ratio between obtained makespan and the lower bound provided by the max-min distance between the start and target position of any agent and our shape parameters. Our results extend findings by Demaine et al. (SIAM Journal on Computing, 2019) who investigated the problem for solid rectangular domains, and in the closely related field of Permutation Routing, as presented by Alpert et al. (Computational Geometry, 2022) for convex pieces of grid graphs.

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协调运动规划：在密集包装的有界域中进行多代理路径查找

我们研究的是在一个简单相连的域内部，针对有标记的代理排列进行多代理路径查找：给定每个代理的唯一起始和目标位置，目标是找到一个平行、无碰撞的代理运动序列，使所有代理到达各自目标之前的总时间（makespan）最小。一个自然的案例是具有轴平行边界和整数坐标的简单连接多边形域，即简单多面体，它相当于一个简单连接的晶格单位方阵或单元。我们重点研究了密集排列的代理（即每个单元一个代理）这一特别具有挑战性的设置，这极大地限制了代理的移动性，并需要复杂的运动协调。我们为这一问题提供了多种新成果，包括：(1) 保证存在重新配置计划的多面体的特征；(2) 形状参数的特征，这些参数会诱发最坏情况下的时间跨度约束；(3) 一套算法，可在机动性受到严重限制的情况下，在可实现的伸展范围内实现渐近最坏情况下的最优性能。这相当于限定了所获得的有效时间与任何代理的起始位置和目标位置与我们的形状参数之间的最大最小距离所提供的下限之间的比率。我们的结果扩展了 Demaine 等人（《SIAM 计算学报》，2019 年）的研究成果，他们针对实体矩形域研究了这一问题；我们的结果还扩展了与之密切相关的 "置换路由"（Permutation Routing）领域的研究成果，Alpert 等人（《计算几何》，2022 年）针对网格图的凸片研究了这一问题。

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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arXiv - CS - Data Structures and Algorithms

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