Variable admittance time-delay control of an upper limb rehabilitation robot based on human stiffness estimation

•A variable admittance time-delay cooperative controller is developed for upper limb rehabilitation training.•An iterative optimization algorithm is proposed to estimate human arm stiffness and adjust interaction compliance.•The training trajectory is determined based on minimum jerk cost principle...

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Vydané v:Mechatronics (Oxford) Ročník 90; s. 102935
Hlavní autori: Wu, Qingcong, Chen, Ying
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Elsevier Ltd 01.04.2023
Predmet:
Human stiffness estimation
Interaction compliance
Time-delay control
Upper limb rehabilitation robot
Variable admittance
Upper limb rehabilitation robot
Variable admittance
Interaction compliance
Time-delay control
Human stiffness estimation
ISSN:0957-4158, 1873-4006
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Popis
Shrnutí:•A variable admittance time-delay cooperative controller is developed for upper limb rehabilitation training.•An iterative optimization algorithm is proposed to estimate human arm stiffness and adjust interaction compliance.•The training trajectory is determined based on minimum jerk cost principle to ensure smoothness and continuity.•The effectiveness is validated via trajectory tracking experiments with variable admittance regulation. This paper proposes a new variable admittance time-delay control strategy based on human stiffness estimation for improving the effectiveness of robot-assisted cooperative rehabilitation training. This control strategy is developed and implemented on a planar upper limb rehabilitation robot. Given the minimum-jerk-based desired trajectories of human hand position, in the developed control strategy, a time-delay approximator is utilized to estimate the external disturbances and modeling errors without exact knowledge of dynamics parameters, a sliding mode admittance controller is applied to obtained objective admittance characteristics, and an iterative optimization algorithm is used to estimate human arm stiffness and adjust human-robot interaction compliance. The closed-loop stability of the proposed control method is demonstrated via Lyapunov function theory. Experimental investigations involving ten subjects are conducted to validate the feasibility of the proposed control scheme. The experimental results show that the interaction compliance during cooperative rehabilitation training can be accurately adjusted based on selected admittance parameters and human arm stiffness, and it contributes to satisfying the specific training requirements of patients with different weakness levels and promoting the effectiveness of the robot-assisted training.
ISSN:0957-4158
1873-4006
DOI:10.1016/j.mechatronics.2022.102935