Title :
Active Disturbance Rejection Position Control for a Magnetic Rodless Pneumatic Cylinder
Author :
Ling Zhao ; Yafei Yang ; Yuanqing Xia ; Zhixin Liu
Author_Institution :
Hebei Province Key Lab. of Heavy Machinery Fluid Power Transm. & Control, Yanshan Univ., Qinhuangdao, China
Abstract :
This paper presents an active disturbance rejection position control scheme for a magnetic rodless cylinder in servo systems without pressure states. It is very hard to achieve precise position control of magnetic rodless cylinders due to nonlinearity from large friction force and hysteresis. In this paper, the overshoot, which has a negative influence on position control, is effectively reduced by using a tracking differentiator. Furthermore, the nonlinearity is estimated by a designed extended-state observer. In addition, the self-stable region theory is used to prove the convergence of the extended-state observer. Finally, both control precision and response speed are guaranteed via a nonlinear error feedback controller in the pneumatic system. Experimental results show that the steady-state error within 0.05 mm is achieved for a step signal.
Keywords :
active disturbance rejection control; control system synthesis; convergence; feedback; hysteresis; nonlinear control systems; observers; pneumatic systems; position control; shapes (structures); active disturbance rejection position control scheme; convergence; extended-state observer; friction force; hysteresis; magnetic rodless pneumatic cylinder; nonlinear error feedback controller; pneumatic system; self-stable region theory; servo system; steady-state error; tracking differentiator; Adaptive control; Friction; Observers; Pneumatic systems; Position control; Servomotors; Trajectory; Active disturbance rejection control; Magnetic rodless pneumatic cylinder; active disturbance rejection control; magnetic rodless pneumatic cylinder; positioning control; self-stable region;
Journal_Title :
Industrial Electronics, IEEE Transactions on
DOI :
10.1109/TIE.2015.2418319
