Template-based hopping control of a bio-inspired segmented robotic leg

2016 6th IEEE International Conference on Biomedical Robotics and Biomechatronics (BioRob) Pub Date : 2016-06-26 DOI:10.1109/BIOROB.2016.7523595

Jonathan Oehlke, Maziar Ahmad Sharbafi, P. Beckerle, A. Seyfarth

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引用次数: 18

Abstract

In human hopping in place, the axial leg function is representable by a spring mass model. This description can be utilized to control robot hopping. In this paper, the SLIP (spring loaded inverted pendulum) model is employed as a template for the control of MARCO Hopper II, a robot with a two-segmented leg. Using VMC (virtual model control) a spring is emulated between the foot and hip joint. The required knee torque is generated by a cable-driven actuator to mimic the unilateral knee extensor. In ground contact, gravity acts as the antagonistic knee flexor. The paper describes an evolution of controllers operating on systems ranging from a simple SLIP to more complex simulation models and finally proposes a control strategy that yields stable hopping in the hardware setup. To compensate losses, energy management by tuning the virtual leg spring stiffness is utilized. The resulting hopping motion is similar to human motions with respect to the positions of foot and hip as well as the ground reaction force. A combination of the SLIP model with a control technique for segmented structures and the addition of a bio-inspired energy management method is the result of this work.

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仿生分段机器人腿的基于模板的跳跃控制

人体原地跳跃时，轴向腿的功能可以用弹簧质量模型来表示。这种描述可以用来控制机器人的跳跃。本文以弹簧加载倒立摆(SLIP)模型为模板，对两段腿机器人MARCO Hopper II进行控制。利用虚拟模型控制(VMC)对足部与髋关节之间的弹簧进行了仿真。所需的膝关节扭矩由电缆驱动的致动器产生，以模拟单侧膝关节伸肌。在与地面接触时，重力起到拮抗膝关节屈肌的作用。本文描述了控制器在从简单的SLIP到更复杂的仿真模型的系统上运行的演变，并最后提出了一种在硬件设置中产生稳定跳变的控制策略。为了补偿损失，通过调整虚拟腿弹簧刚度来进行能量管理。由此产生的跳跃运动类似于人类的运动，就脚和臀部的位置以及地面反作用力而言。这项工作的结果是将SLIP模型与分段结构的控制技术相结合，并增加了一种仿生能量管理方法。

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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2016 6th IEEE International Conference on Biomedical Robotics and Biomechatronics (BioRob)

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