Title :
Decoupling Control of Magnetically Suspended Rotor System in Control Moment Gyros Based on an Inverse System Method
Author :
Fang, Jiancheng ; Ren, Yuan
Author_Institution :
Sch. of Instrum. Sci. & Optoelectron. Eng., Beihang Univ., Beijing, China
Abstract :
To radically eliminate the influence of gyroscopic effects on system stability and to improve the performances of high-precision, fast-response for the high-speed magnetically suspended rotor system in a control moment gyro, this paper proposes a control strategy that combines inverse system method and internal model control. The stability and robustness problems induced by current-mode linearization have been successfully solved by introducing phase-lead compensation and internal model controller. The effectiveness and superiority of the proposed strategy have been demonstrated by both simulation and experimental results.
Keywords :
actuators; attitude control; compensation; gyroscopes; robust control; rotors; actuator; attitude control; control moment gyros; current-mode linearization; decoupling control; gyroscopic effect; internal model controller; inverse system method; magnetically suspended rotor system; phase-lead compensation; robustness problem; system stability; Attitude control; Couplings; Magnetic levitation; Robust control; Rotors; Control moment gyro (CMG); decoupling control; exact linearization; internal model control (IMC); inverse system method; magnetic bearing; robust controller;
Journal_Title :
Mechatronics, IEEE/ASME Transactions on
DOI :
10.1109/TMECH.2011.2159618
