Dynamic Robot Chain Networks for Swarm Foraging

2022 International Conference on Robotics and Automation (ICRA) Pub Date : 2022-05-23 DOI:10.1109/icra46639.2022.9811625

Dohee Lee, Qi Lu, T. Au

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引用次数: 2

Abstract

The objective of foraging robot swarms is to search for and collect resources in an unknown arena as quickly as possible. To avoid the congestion near the central collection zone, we previously proposed an extension to the multiple-place foraging in which robot chains are deployed dynamically so that foraging robots can deliver to the robot chains instead of the central collection zone. However, a robot chain can only reach one location at a time, and congestion can occur at the end of the robot chain. This paper presents an extension to dynamic robot chains called dynamic robot chain networks, which extends robot chains with branches, each of which reaches different resource clusters. We formulate the problem of finding the smallest dynamic robot chain networks as the Euclidean Steiner tree problem and explain how Steiner trees can be utilized to optimize the efficiency of the foraging operations. We implemented our foraging robot swarms in a simulator called ARGoS. Our experiments showed that dynamic robot chain networks can avoid obstacles and collect more resources when compared with the original robot chain design.

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群体觅食的动态机器人链网络

觅食机器人群的目标是在未知的环境中以最快的速度搜索和收集资源。为了避免中心采集区附近的拥堵，我们提出了一种多地点觅食的扩展方案，通过动态部署机器人链，使觅食机器人能够将货物运送到机器人链上，而不是运送到中心采集区。然而，一个机器人链一次只能到达一个位置，拥塞可能发生在机器人链的末端。本文提出了动态机器人链的一种扩展，即动态机器人链网络，它将机器人链扩展为具有分支的网络，每个分支到达不同的资源集群。我们将寻找最小动态机器人链网络的问题表述为欧几里得斯坦纳树问题，并解释了如何利用斯坦纳树来优化觅食操作的效率。我们在一个叫做ARGoS的模拟器中实现了我们的觅食机器人群。实验表明，与原机器人链设计相比，动态机器人链网络可以避开障碍物，收集更多的资源。

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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2022 International Conference on Robotics and Automation (ICRA)

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