计算机科学
可扩展性
机器人
机器人学
人工智能
智能材料
远程控制
软机器人
天线(收音机)
概念证明
平面的
仿生学
方向(向量空间)
人机交互
纳米传感器
遥感
接口(物质)
光刻
机电一体化
软质材料
计算机视觉
试验台
遥感应用
作者
Quan Gao,Min‐Soo Kim,Denis von Arx,Elric Zhang,X. Zhang,Hao Ye,Christian Vogt,Claas Ehmke,Dianne Corsino,Federica Catania,Niko Münzenrieder,Michele Magno,Giuseppe Cantarella,Bradley J. Nelson,Salvador Pané
标识
DOI:10.1038/s41467-025-65459-8
摘要
Remote communication in small-scale robotics offers a powerful way to enhance their capabilities, introducing options for state monitoring, multi-agent collaboration, and autonomous operation. Integrating common remote communication tools, such as antennas, into microrobots is challenging with conventional design and manufacturing techniques. We propose a concept that integrates shape-reconfigurable soft microrobots with flexible electronics, leveraging their elastic mechanical properties to enable remote communication. This approach, based on photolithography processes, is scalable and adaptable to various sensing applications. As a proof of concept, we present a microrobot, which integrates a thermoresponsive magnetic hydrogel, an anisotropic support structure, and a flexible dipole antenna into a cohesive three-layered design. The microrobot can morph from a helical shape at low-temperatures to a planar shape at high-temperatures. This shape transformation can be remotely detected by external radio communication receivers, enabling shape-state recognition and environmental temperature sensing. Furthermore, we show that the collective behavior of multiple microrobots enhances the recognition performance by amplifying the signal. The concept represents a significant advancement in co-engineering smart materials and flexible electronics, illustrating an approach of microrobotic embodied intelligence by integrating environmental monitoring, magnetic navigation, and remote signaling.
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