鳗形运动的运动规划

K. McIsaac, J. Ostrowski
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引用次数: 206

摘要

我们研究了仿生机器人系统的控制和运动规划问题。先前的工作表明,解决运动规划问题的一个成功方法是将其解耦为轨迹生成(前馈控制)和反馈调节两个子问题。本文研究了一类动态移动机器人动量产生的基本问题,重点研究了类鳗鱼游泳机器人。我们为在自然界中观察到的向前步态和在生物学文献中尚未广泛研究的控制律中使用的转向步态开发了理论依据。我们还探讨了理论预测的新步态的转身和侧身游泳。最后,我们介绍了仿生机器人系统运动规划的实验结果。我们在水下环境中使用基于图像的位置传感的模块化五连杆水下游泳机器人的开环和闭环控制与理论表现出良好的一致性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Motion planning for anguilliform locomotion
We investigate issues of control and motion planning for a biomimetic robotic system. Previous work has shown that a successful approach to solving the motion planning problem is to decouple it into the two subproblems of trajectory generation (feedforward controls) and feedback regulation. In this paper, we investigate basic issues of momentum generation for a class of dynamic mobile robots, focusing on eel-like swimming robots. We develop theoretical justification for a forward gait that has been observed in nature, and for a turning gait, used in our control laws, that has not been extensively studied in the biological literature. We also explore theoretical predictions for novel gaits for turning and sideways swimming. Finally, we present results from experiments in motion planning for a biomimetic robotic system. We show good agreement with theory for both open and closed-loop control of our modular, five-link, underwater swimming robot using image-based position sensing in an aquatic environment.
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