Locomoting Robots Composed of Immobile Robots

2018 Second IEEE International Conference on Robotic Computing (IRC) Pub Date : 2018-02-14 DOI:10.1109/IRC.2018.00047

Ross Warkentin, W. Savoie, D. Goldman

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引用次数: 3

Abstract

Robotic materials are multi-robot systems formulated to leverage the low-order computation and actuation of the constituents to manipulate the high-order behavior of the entire material. We study the behaviors of ensembles composed of smart active particles, smarticles. Smarticles are small, low cost robots equipped with basic actuation and sensing abilities that are individually incapable of rotating or displacing. We demonstrate that a "supersmarticle", composed of many smarticles constrained within a bounding membrane, can harness the internal collisions of the robotic material among the constituents and the membrane to achieve diffusive locomotion. The emergent diffusion can be directed by modulating the robotic material properties in response to a light source, analogous to biological phototaxis. The light source introduces asymmetries within the robotic material, resulting in modified populations of interaction modes and dynamics which ultimately result in supersmarticle biased locomotion. We present experimental methods and results for the robotic material which moves with a directed displacement in response to a light source.

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由不能移动的机器人组成的运动机器人

机器人材料是一种多机器人系统，旨在利用低阶计算和驱动成分来操纵整个材料的高阶行为。我们研究了由智能活性粒子组成的系综的行为。Smarticles是一种小型、低成本的机器人，具有基本的驱动和传感能力，单个不能旋转或移动。我们证明了一个“超粒子”，由约束在一个边界膜内的许多智能粒子组成，可以利用机器人材料在成分和膜之间的内部碰撞来实现扩散运动。可以通过调节机器人材料的特性来响应光源，类似于生物趋光性来指导紧急扩散。光源在机器人材料中引入不对称，导致交互模式和动力学的修改种群，最终导致超粒子偏置运动。我们提出了机器人材料响应光源的定向位移运动的实验方法和结果。

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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2018 Second IEEE International Conference on Robotic Computing (IRC)

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