Title :
High-Precision Control for a Single-Gimbal Magnetically Suspended Control Moment Gyro Based on Inverse System Method
Author :
Fang, Jiancheng ; Ren, Yuan
Author_Institution :
Sch. of Instrum. Sci. & Opto Electron. Eng., Beihang Univ., Beijing, China
Abstract :
To effectively reject the influence of gyroscopic effects and gimbal movement on system stability and precision for a single-gimbal magnetically suspended control moment gyro (SGMSCMG), this paper proposes a new control strategy combining an inverse system method and internal model control. The SGMSCMG is modeled using both analytic relationships and experimental data, and its inversion is implemented in a current-mode approach. The common problems associated with the current-mode linearization are successfully handled via compensation filters and internal model controllers. The effectiveness and superiority of this proposed strategy have been demonstrated by both simulation and experimental results.
Keywords :
attitude control; compensation; filtering theory; gyroscopes; inverse problems; linearisation techniques; multivariable control systems; nonlinear control systems; stability; attitude control; compensation filters; current-mode linearization; gimbal movement; gyroscopic effect; high-precision control; internal model control; inverse system method; multivariable control; nonlinear control; single-gimbal magnetically suspended control moment gyro; system stability; Couplings; Gyroscopes; Magnetic forces; Magnetic levitation; Robustness; Rotors; Control moment gyro (CMG); decoupling control; gyroscopic effects; internal model controller (IMC); inverse system method; magnetic bearing;
Journal_Title :
Industrial Electronics, IEEE Transactions on
DOI :
10.1109/TIE.2010.2095394
