Title :
An adjustable control for inertia momentum wheel with disturbance compensation
Author :
Zhang, Cong ; Liu, Gang ; Qin, Jie
Author_Institution :
Sci. & Technol. on Inertial Lab., Beihang Univ., Beijing, China
Abstract :
Inertia momentum wheel is widely used for satellite attitude-control that requires fine pointing accuracy and stability. But, the inner disturbance torque and noises produced by the inertia momentum wheel seriously deteriorate the output torque precision. Accordingly, this paper adopts the adjustable PID algorithm, regulated by RBF network with a simple disturbance compensator in the torque-mode control system of inertia momentum wheel. Based the dynamics and analysis of disturbance torque, the RBF-PID controller with disturbance compensator are designed. The performance comparisons of the proposed method with conventional PID are performed to show the advantages of the former over the latter on many aspects, such as response time, overshot, anti-disturbance ability, etc.
Keywords :
artificial satellites; attitude control; compensation; control system synthesis; neurocontrollers; noise; radial basis function networks; three-term control; torque control; RBF network; RBF-PID controller design; adjustable PID algorithm; adjustable control; anti-disturbance ability; disturbance compensation; disturbance compensator; disturbance torque analysis; disturbance torque dynamics; inertia momentum wheel; inner disturbance torque; noise; output torque precision; satellite attitude-control; torque-mode control system; Brushless DC motors; Prototypes; Satellites; Torque; Velocity control; Wheels; RBF-PID; disturbance compensator; inertia momentum wheel; inner disturbance torque; satellite attitude-control; torque-mode;
Conference_Titel :
Instrumentation and Control Technology (ISICT), 2012 8th IEEE International Symposium on
Conference_Location :
London
Print_ISBN :
978-1-4673-2615-5
DOI :
10.1109/ISICT.2012.6291630
