Stability of a compass gait walking model with series elastic ankle actuation

Deniz Kerimoglu, Ö. Morgül, U. Saranlı
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引用次数: 4

Abstract

Passive dynamic walkers exhibit stable human-like walking on inclined planes. The simplest model of this behavior is the well known passive compass gait (PCG) model, which consists of a point mass at the hip and two stick legs. Due to their passive nature, these systems rely on a sloped ground to recover energy lost to ground collisions. A variety of methods have been proposed to eliminate this requirement by using different actuation methods. In this study, we propose a simple model to investigate how series elastic actuation at the ankle can be used to achieve stable walking on level ground. The structure we propose is designed to behave in a similar fashion to how humans utilize toe push-off prior to leg liftoff, and is intended to be used for controlling the ankle joint in a lower-body robotic orthosis. We present the derivation of the hybrid equations of motion for this model, resulting in a numerically computed return map for a single stride. We then numerically identify fixed points of this system and investigate their stability. We show that asymptotically stable walking on flat ground is possible with this model and identify the dependence of limit cycles and their stability on system parameters.
串联弹性踝关节驱动的罗盘步态步行模型的稳定性
被动动态步行者在斜面上表现出稳定的人形行走。这种行为最简单的模型是众所周知的被动罗盘步态(PCG)模型,它由臀部的一个点质量和两条棍腿组成。由于它们的被动性质,这些系统依赖于倾斜的地面来恢复在地面碰撞中损失的能量。已经提出了多种方法,通过使用不同的驱动方法来消除这一要求。在这项研究中,我们提出了一个简单的模型来研究如何在踝关节处使用一系列弹性驱动来实现在平地上的稳定行走。我们提出的结构被设计成类似于人类在腿部抬起之前利用脚趾蹬离的方式,并打算用于控制下半身机器人矫形器中的踝关节。我们提出了该模型的混合运动方程的推导,得到了一个单步的数值计算返回图。然后用数值方法确定系统的不动点并研究其稳定性。我们证明了用该模型在平地上渐近稳定行走是可能的,并确定了极限环及其稳定性对系统参数的依赖关系。
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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