Impedance learning adaptive super-twisting control of a robotic exoskeleton for physical human-robot interaction

IF 1.5 Q3 AUTOMATION & CONTROL SYSTEMS IET Cybersystems and Robotics Pub Date : 2023-02-16 DOI:10.1049/csy2.12077

Brahim Brahmi, Mohammad Habibur Rahman, Maarouf Saad

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引用次数: 2

Abstract

This study addresses two issues about the interaction of the upper limb rehabilitation robot with individuals who have disabilities. The first step is to estimate the human's target position (also known as TPH). The second step is to develop a robust adaptive impedance control mechanism. A novel Non-singular Terminal Sliding Mode Control combined with an adaptive super-twisting controller is being developed to achieve this goal. This combination's purpose is to provide high reliability, continuous performance tracking of the system's trajectories. The proposed adaptive control strategy reduces matched dynamic uncertainty while also lowering chattering, which is the sliding mode's most glaring issue. The proposed TPH is coupled with adaptive impedance control with the use of a Radial Basis Function Neural Network, which allows a robotic exoskeleton to simply track the desired impedance model. To validate the approach in real-time, an exoskeleton robot was deployed in controlled experimental circumstances. A comparison study has been set up to show how the adaptive impedance approach proposed is better than other traditional controllers.

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用于物理人机交互的机器人外骨骼的阻抗学习自适应超扭曲控制

本研究解决了上肢康复机器人与残疾人互动的两个问题。第一步是估计人的目标位置(也称为TPH)。第二步是开发鲁棒自适应阻抗控制机制。为了实现这一目标，提出了一种结合自适应超扭转控制器的非奇异末端滑模控制方法。这种组合的目的是提供系统轨迹的高可靠性、连续性能跟踪。提出的自适应控制策略降低了匹配的动态不确定性，同时降低了滑模最突出的抖振问题。所提出的TPH与使用径向基函数神经网络的自适应阻抗控制相结合，使机器人外骨骼能够简单地跟踪所需的阻抗模型。为了实时验证该方法，将外骨骼机器人部署在受控的实验环境中。对比研究表明，所提出的自适应阻抗方法优于其他传统控制器。

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