Title :
Nonlinear Disturbance Observer-Based Control Design for a Robotic Exoskeleton Incorporating Fuzzy Approximation
Author :
Zhijun Li ; Chun-Yi Su ; Liangyong Wang ; Ziting Chen ; Tianyou Chai
Author_Institution :
Key Lab. of Autonomous Syst. & Network Control, South China Univ. of Technol., Guangzhou, China
Abstract :
To perform power augmentation tasks of a robotic exoskeleton, this paper utilizes fuzzy approximation and designed disturbance observers to compensate for the disturbance torques caused by unknown input saturation, fuzzy approximation errors, viscous friction, gravity, and payloads. The proposed adaptive fuzzy control with updated parameters´ mechanism and additional torque inputs by using the disturbance observers are exerted into the robotic exoskeleton via feedforward loops to counteract to the disturbances. Through such an approach, the system does not need any requirement of built-in torque sensing units. In order to validate the proposed framework, extensive experiments are conducted on the upper limb exoskeleton using the state feedback and output feedback control to illustrate the performance of the proposed approaches.
Keywords :
adaptive control; approximation theory; artificial limbs; compensation; control system synthesis; feedforward; fuzzy control; fuzzy set theory; nonlinear control systems; observers; patient rehabilitation; state feedback; torque control; adaptive fuzzy control; disturbance torque compensation; feedforward loop; fuzzy approximation; medical rehabilitation; nonlinear disturbance observer-based control design; output feedback; robotic exoskeleton; state feedback; upper limb exoskeleton; Approximation error; Exoskeletons; Fuzzy control; Observers; Robot sensing systems; Adaptive fuzzy control; Input saturation; adaptive fuzzy control; disturbance observer design; input saturation; robotic exoskeleton;
Journal_Title :
Industrial Electronics, IEEE Transactions on
DOI :
10.1109/TIE.2015.2447498
