Design, construction and control of a fluidic robotic joint for compliant legged locomotion

2011 IEEE International Symposium on Industrial Electronics Pub Date : 2011-06-27 DOI:10.1109/ISIE.2011.5984276

L. Sentis, J. Gámez García, B. Fernández, M. Gonzales, N. Paine

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引用次数: 1

Abstract

In humanoid robotics, there is a long pursuit of making biped robots capable of walking in highly unstructured and roughly sensed environments. Within this goal, our objective is to develop a compliant bipedal humanoid robot that can move in these terrains as well as quickly adapt to unpredicted variations on the contact state. We present here the first part of our work, focusing on the design, construction and control of a robotic joint capable of realizing the control performance necessary for responding compliantly and accurately to contact transitions while delivering high forces needed to handle the uniqueness of rough terrains. In particular, we address our progress in the mechanical and embedded electronic design, actuator modeling, and compliant control strategies for a robotic joint based on fluidic pneumatic artificial muscles (PAMs). The proposed robot joint has been validated experimentally, exploring various aspects of its performance as well as its shortcomings, but overall demonstrating the potential benefits of using pneumatic muscles.

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柔性机器人关节的设计、构造与控制

在类人机器人技术中，人们一直在追求使双足机器人能够在高度非结构化和粗略感知的环境中行走。在这个目标中，我们的目标是开发一种兼容的双足类人机器人，它可以在这些地形中移动，并快速适应接触状态的不可预测的变化。我们在这里介绍了我们工作的第一部分，重点是机器人关节的设计、构造和控制，该关节能够实现对接触过渡做出顺从和准确响应所需的控制性能，同时提供处理粗糙地形独特性所需的高力。特别地，我们讨论了基于流体气动人工肌肉(pam)的机器人关节的机械和嵌入式电子设计，执行器建模和柔性控制策略方面的进展。所提出的机器人关节已经过实验验证，探索其性能的各个方面以及它的缺点，但总体上证明了使用气动肌肉的潜在好处。

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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2011 IEEE International Symposium on Industrial Electronics

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