A morphogenetic self-organization algorithm for swarm robotic systems using relative position information

2010 UK Workshop on Computational Intelligence (UKCI) Pub Date : 2010-09-01 DOI:10.1109/UKCI.2010.5625575

Yaochu Jin, Y. Meng, Hongliang Guo

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引用次数: 15

Abstract

Inspired by the major principles of gene regulation and cellular interactions in multi-cellular development, this paper proposes a distributed self-organizing algorithm for multi-robot shape formation. In this approach, multiple robots are able to self-organize themselves into complex shapes driven by the dynamics of a gene regulatory network model. Particularly, no predefined global coordinate system is needed by building up a relative coordinate system through local interactions and limited communications among the robots. The target shape is represented by the non-uniform rational B-spline (NURBS) and embedded into the gene regulation model, analogous to the morphogen gradients in morphogenesis. Since the self-organization algorithm does not need absolute position information, the target shape can be formed anywhere within the environment based on the current location of the robots. Simulation and experimental results demonstrate that the proposed algorithm is effective for complex shape construction and robust to environmental changes and system failures.

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基于相对位置信息的群体机器人系统形态发生自组织算法

基于多细胞发育过程中基因调控和细胞相互作用的主要原理，提出了一种多机器人形状形成的分布式自组织算法。在这种方法中，多个机器人能够在基因调控网络模型的动态驱动下自我组织成复杂的形状。特别是，通过机器人之间的局部交互和有限的通信建立相对坐标系，不需要预先定义全局坐标系。目标形状由非均匀有理b样条(NURBS)表示，嵌入到基因调控模型中，类似于形态发生中的形态发生梯度。由于自组织算法不需要绝对位置信息，因此可以根据机器人的当前位置在环境中的任何位置形成目标形状。仿真和实验结果表明，该算法对复杂形状的构造是有效的，对环境变化和系统故障具有鲁棒性。

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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2010 UK Workshop on Computational Intelligence (UKCI)

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