Title :
Large displacement control system beyond pull-in limitation in electro-static micro cantilever
Author :
Tanaka, Y. ; Hirai, Y. ; Kimura, N. ; Jin, T. ; Kabuto, M.
Author_Institution :
Dept. of Mech. Syst. Eng., Osaka Prefecture Univ., Japan
Abstract :
A displacement control system for an electrostatic drive cantilever beyond the pull-in limit is newly proposed using a feedback control. The electrostatic force is linearized around a target position for the purpose to obtain a linearized equation. Based on the equation of motion, the feedback control system is designed by the optimal regulator. The system performance is evaluated by a numerical simulation using a distributed parameter system for the electrostatic drive cantilever. The simulation results show divergent states by the 2nd. resonance mode of the cantilever. To overcome the unstable state, idealistic low-pass filter is added on the feedback loop to cut off higher resonance mode. The system shows stable operation for large displacement over the pull-in limitation.
Keywords :
control system synthesis; displacement control; distributed parameter systems; electrostatic actuators; feedback; linearisation techniques; low-pass filters; micromechanical devices; optimal control; stability; 2nd. resonance mode; DPS; control system design; distributed parameter system; electrostatic drive cantilever; electrostatic force linearization; electrostatic micro cantilever; feedback control; feedback loop; idealistic low-pass filter; large displacement control system; linearized equation; numerical simulation; optimal regulator; pull-in limitation; resonance modes; stable operation; unstable state; Displacement control; Drives; Electrostatics; Equations; Feedback control; Force control; Numerical simulation; Regulators; Resonance; System performance;
Conference_Titel :
Micromechatronics and Human Science, 2002. MHS 2002. Proceedings of 2002 International Symposium on
Print_ISBN :
0-7803-7611-0
DOI :
10.1109/MHS.2002.1058034
