动力髋部外骨骼可以降低使用者在行走过程中髋部和踝关节的肌肉活动度。

Powered hip exoskeletons can reduce the user's hip and ankle muscle activations during walking.

出版信息

IEEE Trans Neural Syst Rehabil Eng. 2013 Nov;21(6):938-48. doi: 10.1109/TNSRE.2013.2248749. Epub 2013 Mar 20.

DOI:10.1109/TNSRE.2013.2248749

Abstract

In this paper, we study the human locomotor adaptation to the action of a powered exoskeleton providing assistive torque at the user's hip during walking. To this end, we propose a controller that provides the user's hip with a fraction of the nominal torque profile, adapted to the specific gait features of the user from Winter's reference data . The assistive controller has been implemented on the ALEX II exoskeleton and tested on ten healthy subjects. Experimental results show that when assisted by the exoskeleton, users can reduce the muscle effort compared to free walking. Despite providing assistance only to the hip joint, both hip and ankle muscles significantly reduced their activation, indicating a clear tradeoff between hip and ankle strategy to propel walking.

摘要

在本文中，我们研究了人类在行走时对动力外骨骼的作用的运动适应，该外骨骼在用户的臀部提供辅助扭矩。为此，我们提出了一种控制器，该控制器为用户的臀部提供了名义扭矩曲线的一部分，该曲线根据用户的特定步态特征从 Winter 的参考数据进行了适配。辅助控制器已在 ALEX II 外骨骼上实现，并在十个健康受试者上进行了测试。实验结果表明，当用户在外部辅助下行走时，与自由行走相比，他们可以减少肌肉的用力。尽管仅对髋关节提供辅助，但髋关节和踝关节的肌肉都明显降低了它们的激活程度，这表明在推动行走时，髋关节和踝关节的策略之间存在明显的权衡。

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动力髋部外骨骼可以降低使用者在行走过程中髋部和踝关节的肌肉活动度。

Powered hip exoskeletons can reduce the user's hip and ankle muscle activations during walking.

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