Adaptive control of a robotic exoskeleton for neurorehabilitation

Tommaso Proietti, N. Jarrassé, A. Roby-Brami, G. Morel
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引用次数: 21

Abstract

Neurorehabilitation efficiency increases with therapy intensity and subject's involvement during physical exercises. Robotic exoskeletons could bring both features, if they could adapt the level of assistance to patient's motor capacities. To this aim, we developed an exoskeleton controller, based on adaptive techniques, that can actively modulate the stiffness of the robotic device in function of the subject's activity. We tested this control law on one healthy subject with an upper-limb exoskeleton. The experiment consisted in learning a trajectory imposed by the robot. The early results show the different features allowed by our controller with respect to controllers commonly used for neurorehabilitation with exoskeletons.
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神经康复机器人外骨骼的自适应控制
神经康复效率随治疗强度和受试者参与体育锻炼而增加。如果机器人外骨骼能够根据病人的运动能力调整辅助水平,它们就能实现这两种功能。为此,我们开发了一种基于自适应技术的外骨骼控制器,该控制器可以根据受试者的活动主动调节机器人设备的刚度。我们在一个有上肢外骨骼的健康受试者身上测试了这个控制律。实验包括学习机器人施加的轨迹。早期的结果显示了我们的控制器与通常用于外骨骼神经康复的控制器所允许的不同特征。
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