Enlarging the region of stability using the torque-enhanced active SLIP model

H. Hamzacebi, Ö. Morgül
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引用次数: 7

Abstract

One of the most significant outcomes of bio-inspired robotics research studies is that simple spring-mass models can accurately represent legged locomotion with various sizes and morphologies and hence the legged robots. Specifically, the Spring-Loaded Inverted Pendulum (SLIP) model became a well-known tool among the biologists and robotics researchers due to its simplicity and explanatory nature. Nevertheless, SLIP model has non-integrable system dynamics, which prevents derivation of exact analytical solutions to its dynamics despite its simple nature. In this paper, we propose a torque-enhanced active SLIP (TA-SLIP) model to support partial feedback linearization on nonlinear dynamics of the SLIP model. A linear and rotary actuator is used in TA-SLIP model to inject or remove energy from the system both to support analytic solution of the system dynamics and to control the locomotion. We also investigate the stability of the TA-SLIP model and show that the proposed model increases the region of stability with respect to original SLIP model.
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利用力矩增强主动滑移模型扩大稳定区域
仿生机器人研究最重要的成果之一是简单的弹簧质量模型可以准确地表示各种尺寸和形态的腿运动,从而实现有腿机器人。具体来说,弹簧加载倒立摆(SLIP)模型由于其简单和解释性而成为生物学家和机器人研究人员中众所周知的工具。然而,SLIP模型具有不可积的系统动力学,这使得推导其动力学的精确解析解变得困难。在本文中,我们提出了一种扭矩增强的有源滑移模型(TA-SLIP),以支持滑移模型非线性动力学的部分反馈线性化。在TA-SLIP模型中使用线性和旋转驱动器从系统中注入或移除能量,以支持系统动力学的解析解并控制运动。我们还研究了TA-SLIP模型的稳定性,并表明该模型相对于原SLIP模型增加了稳定区域。
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