For the impulsive ankle push-off (APO) observed in human walking two muscle-tendon-units (MTUs) spanning the ankle joint play an important role: Gastrocnemius (GAS) and Soleus (SOL). GAS and SOL load the Achilles tendon to store elastic energy during stance followed by a rapid energy release during APO. We use a neuromuscular simulation (NMS) and a bipedal robot to investigate the role of GAS and SOL on the APO. We optimize the simulation for a robust gait and then sequentially replace the MTUs of (1) GAS, (2) SOL and (3) GAS and SOL by linear springs. To validate the simulation, we implement NMS-3 on a bipedal robot. Simulation and robot walk steady for all trials showing an impulsive APO. Our results imply that the elastic MTU properties shape the impulsive APO. For prosthesis or robot design that is, no complex ankle actuation is needed to obtain an impulsive APO, if more mechanical intelligence is incorporated in the design.
翻译:对于在人类行走时观察到的脉冲脚踝推力(APO),在两根肌肉-支部(MTUs)横跨脚踝的两根肌肉-支部(MTUs)中观察到的脉冲脚踝推力(APO)起着重要作用:Gastrocnemius(GAS)和Soleus(SOL)。GAS和SOL(SOL)装载Achilles(Achilles)在姿势期间储存弹性能量,然后在APO期间迅速释放能量。我们使用神经肌肉模拟(NMS)和双臂机器人来调查GAS和SOL(SOL)在APO上的作用。我们优化模拟并随后以线性弹簧顺序取代(1)GAS(GAS)、(2)SOL和(3)GAS(GAS)和S和SOL(SOL)的MTUTUs。为了验证模拟结果,我们用双臂机器人执行NMS-3。如果机械智能能显示所有试验的模拟和机器人步步步势稳定。我们的结果表明,弹性微动动脉动动动动动动动动动动动动动动动动动动动动脉或机器人设计不需要复杂的脚踝动作设计,那么复杂。
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