计算机科学
代表(政治)
机器人
控制器(灌溉)
背景(考古学)
过程(计算)
对象(语法)
人工智能
一般化
计算机视觉
拓扑(电路)
控制理论(社会学)
控制(管理)
工程类
数学
古生物学
农学
数学分析
电气工程
政治
政治学
法学
生物
操作系统
作者
Peng Zhou,Pai Zheng,Jiaming Qi,Chengxi Li,Hoi-Yin Lee,Anqing Duan,Liang Lu,Zhongxuan Li,Luyin Hu,David Navarro-Alarcón
标识
DOI:10.1016/j.rcim.2024.102727
摘要
Real-time reactive manipulation of deformable linear objects is a challenging task that requires robots to quickly and adaptively respond to changes in the object's deformed shape that result from external forces. In this paper, a novel approach is proposed for real-time reactive deformable linear object manipulation in the context of human–robot collaboration. The proposed approach combines a topological latent representation and a fixed-time sliding mode controller to enable seamless interaction between humans and robots. The introduced topological control model offers a framework for controlling the dynamic shape of deformable objects. By leveraging the topological representation, our approach captures the connectivity and structure of the objects' shapes within a latent space. This enables improved generalization and performance when handling complex deformable shapes. A fixed-time sliding mode controller ensures that the object is manipulated in real-time, while also ensuring that it remains accurate and stable during the manipulation process. To validate our proposed framework, we first conduct motor-robot experiments to simulate fixed human interaction processes, enabling straightforward comparisons with other approaches. We then follow up with human–robot experiments to demonstrate the effectiveness of our approach.
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