INSPIIRE - A Modular and Passive Exoskeleton to Investigate Human Walking and Balance.

Tristan Vouga, Romain Baud, Jemina Fasola, Mohamed Bouri
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Abstract

Powered exoskeletons for SCI patients are mainly limited by their inability to balance dynamically during walking. To investigate and understand the control strategies of human bipedal locomotion, we developed INSPIIRE, a passive exoskeleton. This device constrains the movements of able-bodied subjects to only hip and knee flexions and extensions, similar to most current active exoskeletons. In this paper, we detail the modular design and the mechanical implementation of the device. In preliminary experiments, we tested whether humans are able to handle dynamic walking without crutches, despite the limitation of lateral foot placement and locked ankles. Five healthy subjects showed the ability to stand and ambulate at an average speed of 1 m/s after 5 minutes of self-paced training. We found that while the hip abduction/adduction is constrained, the foot placement was made possible thanks to the pelvis yaw and residual flexibility of the exoskeleton segments in the lateral plan. This result points out that INSPIIRE is a reliable instrument to learn sagitally-constrained human locomotion, and the potential of investigating more dynamic walking, which is shown as possible in this implementation, even if only flexion/extension of the hip and knee are allowed.

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INSPIIRE-研究人类行走和平衡的模块化被动外骨骼。
SCI患者的动力外骨骼主要受到行走过程中无法动态平衡的限制。为了研究和理解人类两足运动的控制策略,我们开发了INSPIRE,一种被动外骨骼。该设备将身体健全的受试者的运动限制为仅髋关节和膝关节的弯曲和伸展,类似于目前大多数活动外骨骼。在本文中,我们详细介绍了该装置的模块化设计和机械实现。在初步实验中,我们测试了人类是否能够在没有拐杖的情况下进行动态行走,尽管脚的侧向位置和脚踝锁住是有限制的。五名健康受试者在5分钟的自定步训练后,表现出以1米/秒的平均速度站立和行走的能力。我们发现,虽然髋关节外展/内收受到限制,但由于骨盆偏转和外骨骼节段在横向平面图中的剩余灵活性,足部放置成为可能。这一结果指出,INSPIIRE是一种可靠的工具,可以学习受矢状约束的人类运动,以及研究更动态行走的潜力,即使只允许髋关节和膝关节屈曲/伸展,这在本实施中也是可能的。
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Individualized Three-Dimensional Gait Pattern Generator for Lower Limbs Rehabilitation Robots. Individualized Training of Back Muscles Using Iterative Learning Control of a Compliant Balance Board. Influence of Robotic Therapy on Severe Stroke Patients. INSPIIRE - A Modular and Passive Exoskeleton to Investigate Human Walking and Balance. Instrumented Upper Limb Functional Assessment Using a Robotic Exoskeleton: Normative References Intervals.
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