The Role of Inertial Stabilization in Walking Patterns

2021 XXIII Robotics Mexican Congress (ComRob) Pub Date : 2021-10-27 DOI:10.1109/comrob53312.2021.9628428

J. Quintanilla, Moises Perez, Rodolfo Balderas, Alejandro González, A. Cárdenas, M. Maya, D. Piovesan

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引用次数: 1

Abstract

Impedance control has been often proposed as a stable control strategy for human walking. On the other hand, the continuous control of stiffness in human is energetically expensive. It has been shown that systems with unstable equilibrium points can be stabilized using inertial effects. A Kapitza’s pendulum shows that it is possible to stabilize an inverted pendulum by making its base oscillate vertically. This work provides a set of simulations that show how an impedance control strategy can be used for dynamic stabilization. The simulations presented are based on experimental data extracted from publicly available videos depicting the self-paced walking pattern of an unimpaired human and a that of a NAO humanoid robot. In both cases, the average lower limb stiffness can be maintained under the minimum level of stability if its modulation induces vertical oscillations on the trunk with frequencies compatible with human locomotion. The results reiterate the possibility of integrating the intermittent control of human balance under the umbrella of impedance control.

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惯性稳定在行走模式中的作用

阻抗控制通常被认为是人类行走的稳定控制策略。另一方面，对人体刚度的连续控制是能量昂贵的。结果表明，具有不稳定平衡点的系统可以用惯性效应来稳定。卡皮察摆表明，通过使倒立摆的基座垂直摆动来稳定倒立摆是可能的。这项工作提供了一组模拟，展示了阻抗控制策略如何用于动态稳定。所提出的模拟是基于从公开视频中提取的实验数据，这些视频描绘了一个未受损的人和一个NAO类人机器人的自定节奏行走模式。在这两种情况下，如果其调制引起躯干上的垂直振荡，且频率与人体运动相匹配，则平均下肢刚度可以保持在最低的稳定水平下。结果重申了在阻抗控制的保护伞下整合人体平衡的间歇性控制的可能性。

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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2021 XXIII Robotics Mexican Congress (ComRob)

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