Attitude Control of a Quadruped Trot While Turning

2006 IEEE/RSJ International Conference on Intelligent Robots and Systems Pub Date : 2006-10-01 DOI:10.1109/IROS.2006.282381

Luther R. Palmer, D. Orin

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引用次数: 13

Abstract

During a complete running stride, which involves significant periods of flight during which no legs are contacting the ground, a quadruped cannot employ static stability techniques. Instead, the corrective forces necessary to maintain dynamic stability must be applied during the short stance intervals inherent to high-speed running. Because of this complexity and the large coupled forces required to run, much of the research on the control of quadruped running has focused on planar systems which are not required to simultaneously control attitude in all three dimensions. The 3D trot controller presented here overcomes these and other complexities to control a trot up to 3.75 m/s, approximately 3 body lengths per second, and turning rates up to 20 deg/s. The biomimetic method of banking into a high-speed turn is also investigated here. Along with the details of the attitude control algorithm, a set of control principles for high-speed legged motion is presented. These principles, such as the need to counteract the disturbance of swing leg return and the usefulness of force redistribution during stance, are not dependent on a particular scale or actuation scheme and can be applied to a wider range of legged systems

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四足小跑转弯时的姿态控制

在一个完整的跑步步幅中，四足动物不能使用静态稳定技术，因为在这一过程中有很长一段时间是没有腿接触地面的。相反，保持动态稳定性所需的纠正力必须在高速跑步固有的短站立间隔期间应用。由于这种复杂性和运行所需的大耦合力，许多关于四足动物运行控制的研究都集中在平面系统上，这些系统不需要同时在所有三个维度上控制姿态。这里提出的3D小跑控制器克服了这些和其他的复杂性，以控制小跑高达3.75米/秒，大约3个身体长度每秒，并转向率高达20度/秒。本文还研究了高速转弯的仿生方法。在详细介绍姿态控制算法的基础上，提出了一套高速腿运动的控制原理。这些原则，例如需要抵消摆动腿返回的干扰和站立期间力重新分配的有用性，不依赖于特定的规模或驱动方案，可以应用于更广泛的腿部系统

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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2006 IEEE/RSJ International Conference on Intelligent Robots and Systems

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