Walking Stability of a Variable Length Inverted Pendulum Controlled with Virtual Constraints

Int. J. Humanoid Robotics Pub Date : 2019-12-01 DOI:10.1142/s0219843619500403

Qiuyue Luo, C. Chevallereau, Y. Aoustin

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引用次数: 5

Abstract

Bipedal walking is a complex phenomenon that is not fully understood. Simplified models make it easier to highlight the important features. Here, the variable length inverted pendulum (VLIP) model is used, which has the particularity of taking into account the vertical oscillations of the center of mass (CoM). When the desired walking gait is defined as virtual constraints, i.e., as functions of a phasing variable and not on time, for the evolution of the swing foot and the vertical oscillation of the CoM, the walk will asymptotically converge to the periodic motion under disturbance with proper choice of the virtual constraints, thus a self-stabilization is obtained. It is shown that the vertical CoM oscillation, positions of the swing foot and the choice of the switching condition play crucial roles in stability. Moreover, a PI controller of the CoM velocity along the sagittal axis is also proposed such that the walking speed of the robot can converge to another periodic motion with a different walking speed. In this way, a natural walking gait is illustrated as well as the possibility of velocity adaptation as observed in human walking.

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虚约束控制的变长倒立摆行走稳定性研究

双足行走是一种尚未完全了解的复杂现象。简化的模型可以更容易地突出重要的特性。本文采用变长倒立摆(VLIP)模型，该模型的特点是考虑了质心的垂直振荡。当将期望的步行步态定义为虚拟约束，即作为相位变量的函数而非时间函数时，对于摆动足的演化和CoM的垂直振荡，通过适当选择虚拟约束，步行将渐近收敛于扰动下的周期运动，从而实现自稳定。结果表明，垂直CoM振荡、摆脚位置和开关条件的选择对稳定性起着至关重要的作用。此外，还提出了一种沿矢状轴CoM速度的PI控制器，使机器人的行走速度收敛到具有不同行走速度的另一个周期运动中。通过这种方式，说明了自然行走步态以及在人类行走中观察到的速度适应的可能性。

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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Int. J. Humanoid Robotics

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