用于未知环境中动态任务分配的蜂群算法

Adithya Balachandran, Noble Harasha, Nancy Lynch
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摘要

机器人群是由许多机器人组成的分布式系统,在搜救、自然灾害应对和自我组装等领域有许多应用。其中一些应用可以抽象为环境中任务分配的一般问题,即机器人必须自行分配并完成任务。虽然已经提出了几种任务分配算法,但大多数算法都假定预先知道任务位置或任务集是静态的。在任务动态出现在未知位置的离散一般模型下,我们提出了三种新的任务分配算法。我们证明,当任务缓慢出现时,我们基于任务信息传播的分布式算法变体比列维随机行走算法更高效地完成任务,而列维随机行走算法是自然界中许多生物用来高效搜索环境的策略。我们还提出了一种分工算法,其中一些代理使用我们基于传播任务信息的算法,而剩下的代理则使用李维随机行走算法。最后,我们引入了一种混合算法,即每个代理在使用传播任务信息和遵循李维随机行走之间动态切换。我们的研究表明,我们的分工算法和混合算法比我们基于任务信息传播的算法和列维随机行走算法的性能都要好,尤其是在中低任务率的情况下。当任务出现速度较快时,我们观察到李维随机漫步策略的性能与上述两种方法不相上下,甚至更好。我们的工作展示了这些算法在各种任务率下的相对性能,也为我们根据环境参数优化算法提供了启示。
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Swarm Algorithms for Dynamic Task Allocation in Unknown Environments
Robot swarms, systems of many robots that operate in a distributed fashion, have many applications in areas such as search-and-rescue, natural disaster response, and self-assembly. Several of these applications can be abstracted to the general problem of task allocation in an environment, in which robots must assign themselves to and complete tasks. While several algorithms for task allocation have been proposed, most of them assume either prior knowledge of task locations or a static set of tasks. Operating under a discrete general model where tasks dynamically appear in unknown locations, we present three new swarm algorithms for task allocation. We demonstrate that when tasks appear slowly, our variant of a distributed algorithm based on propagating task information completes tasks more efficiently than a Levy random walk algorithm, which is a strategy used by many organisms in nature to efficiently search an environment. We also propose a division of labor algorithm where some agents are using our algorithm based on propagating task information while the remaining agents are using the Levy random walk algorithm. Finally, we introduce a hybrid algorithm where each agent dynamically switches between using propagated task information and following a Levy random walk. We show that our division of labor and hybrid algorithms can perform better than both our algorithm based on propagated task information and the Levy walk algorithm, especially at low and medium task rates. When tasks appear fast, we observe the Levy random walk strategy performs as well or better when compared to these novel approaches. Our work demonstrates the relative performance of these algorithms on a variety of task rates and also provide insight into optimizing our algorithms based on environment parameters.
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