基于任意图检测的快速确定性采集:多机器人的力量

A. R. Molla, Kaushik Mondal, W. Moses
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引用次数: 0

摘要

多年来,已经进行了许多涉及移动计算实体的研究。从实际的微观(和更小的)机器人建模,到网络上的软件过程建模,许多重要的问题都在这一背景下进行了研究。在这个领域,聚集是一个基本问题。收集k个机器人的问题,最初是任意放置在n个节点图的节点上,要求这些机器人以局部方式(而不是全局方式)进行协调和通信,以便在图中移动,找到彼此,并尽快在单个节点上安顿下来。一个更难解决的问题是带检测的收集,一旦机器人收集,它们必须随后意识到收集已经发生,然后终止。在本文中,我们提出了一种确定性方法来解决任意连通图的带检测的收集问题,该方法比现有的任意图的仅收集(不要求检测)的确定性解决方案更快。与早期的收集工作相比,它利用了系统中存在更多机器人的事实,以更快的速度实现收集和检测,而不是之前那些只关注收集的论文。最先进的确定性收集解决方案[Ta-Shma和Zwick, TALG, 2014]需要$\tilde O\left({{n^5}\log \ell }\right)$轮,其中是机器人中最小的标签,$\tilde O$隐藏了一个多对数因子。我们根据存在的机器人数量设计了一种确定性算法,用于收集检测,并进行以下权衡:(i)当k≥⌊n/2⌋+ 1时,算法需要O(n3)轮,(ii)当k≥⌊n/3⌋+ 1时,算法需要O(n4 log n)轮,(iii)否则,算法需要$\tilde O\left({{n^5}}\right)$轮。这个算法不需要知道k,只需要知道n。
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Fast Deterministic Gathering with Detection on Arbitrary Graphs: The Power of Many Robots
Over the years, much research involving mobile computational entities has been performed. From modeling actual microscopic (and smaller) robots, to modeling software processes on a network, many important problems have been studied in this context. Gathering is one such fundamental problem in this area. The problem of gathering k robots, initially arbitrarily placed on the nodes of an n-node graph, asks that these robots coordinate and communicate in a local manner, as opposed to global, to move around the graph, find each other, and settle down on a single node as fast as possible. A more difficult problem to solve is gathering with detection, where once the robots gather, they must subsequently realize that gathering has occurred and then terminate.In this paper, we propose a deterministic approach to solve gathering with detection for any arbitrary connected graph that is faster than existing deterministic solutions for even just gathering (without the requirement of detection) for arbitrary graphs. In contrast to earlier work on gathering, it leverages the fact that there are more robots present in the system to achieve gathering with detection faster than those previous papers that focused on just gathering. The state of the art solution for deterministic gathering [Ta-Shma and Zwick, TALG, 2014] takes $\tilde O\left({{n^5}\log \ell }\right)$ rounds, where is the smallest label among robots and $\tilde O$ hides a polylog factor. We design a deterministic algorithm for gathering with detection with the following trade-offs depending on how many robots are present: (i) when k ≥ ⌊n/2⌋ + 1, the algorithm takes O(n3) rounds, (ii) when k ≥ ⌊n/3⌋ + 1, the algorithm takes O(n4 log n) rounds, and (iii) otherwise, the algorithm takes $\tilde O\left({{n^5}}\right)$ rounds. The algorithm is not required to know k, but only n.
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