屈曲驱动弹性活动结构的新兴智能

Yuchen Xi, Trevor J. Jones, Richard Huang, Tom Marzin, P. -T. Brun
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引用次数: 0

摘要

鸟类、鱼类和细菌等自我推进的主动系统可以将它们的集体运动组织成无数的自主行为。这种现象在自然界中无处不在,而且跨越长度尺度,因此也适用于人工环境,例如,无脑自走式机器人通过施加外部压力或被限制在灵活的边界内,将其运动协调成空间-时间传送模式。在这里,我们展示了一种新颖而简单的机制,它利用非线性弹性驯服近乎扩散的运动粒子,形成能够定向运动和其他新兴智能行为的结构。Ourelasto-active 系统由两个用弹性梁连接的厘米级自走式微型机器人组成。这些微型机器人施加的力足以扣住横梁,使结构开始运动。我们首先对横梁和微型机器人之间相互作用的物理学原理进行了分析。然后,我们使用降序模型来预测我们的弹性活动结构与边界(如墙壁和收缩物)之间的相互作用,并演示了它们如何表现出迷宫导航等智能行为。这些发现与设计能够自主探索空间、适应环境并与周围环境互动的智能材料或软体机器人息息相关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Emergent intelligence of buckling-driven elasto-active structures
Active systems of self-propelled agents, e.g., birds, fish, and bacteria, can organize their collective motion into myriad autonomous behaviors. Ubiquitous in nature and across length scales, such phenomena are also amenable to artificial settings, e.g., where brainless self-propelled robots orchestrate their movements into spatio-temportal patterns via the application of external cues or when confined within flexible boundaries. Very much like their natural counterparts, these approaches typically require many units to initiate collective motion such that controlling the ensuing dynamics is challenging. Here, we demonstrate a novel yet simple mechanism that leverages nonlinear elasticity to tame near-diffusive motile particles in forming structures capable of directed motion and other emergent intelligent behaviors. Our elasto-active system comprises two centimeter-sized self-propelled microbots connected with elastic beams. These microbots exert forces that suffice to buckle the beam and set the structure in motion. We first rationalize the physics of the interaction between the beam and the microbots. Then we use reduced order models to predict the interactions of our elasto-active structure with boundaries, e.g., walls and constrictions, and demonstrate how they can exhibit intelligent behaviors such as maze navigation. The findings are relevant to designing intelligent materials or soft robots capable of autonomous space exploration, adaptation, and interaction with the surrounding environment.
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