Title :
Sliding-Mode Control of an Electromagnetic Actuated Conveyance System Using Contactless Sensing
Author :
Chin, C.S. ; Wheeler, Caleb
Author_Institution :
Fac. of Sci., Agric. & Eng., Newcastle Univ., Newcastle upon Tyne, UK
Abstract :
A microcontroller-based conveyance system using a hybrid electromagnetic suspension (EMS) system and a linear synchronous motor (LSM) is proposed. Unique placements of the hybrid EMS and LSM integrated with an array of infrared sensors, embedded microcontroller, and electronics switching circuits are designed to maintain the air gaps and the propulsion. To improve the air-gap stability, a robust sliding-mode feedback controller is used. The entire control system is implemented, simulated, and verified by experimental measurements. As compared to different control schemes such as the H-infinity and the proportional-integral-derivative controller, it has shown to give reasonable performance under certain parametric uncertainties.
Keywords :
air gaps; electric propulsion; electromagnetic actuators; feedback; infrared detectors; linear synchronous motors; machine control; microcontrollers; robust control; variable structure systems; EMS; H-infinity controller; LSM; air-gap stability; electromagnetic actuated conveyance system; electronics switching circuits; embedded microcontroller; hybrid electromagnetic suspension system; infrared sensors; linear synchronous motor; parametric uncertainties; proportional-integral-derivative controller; propulsion; robust sliding-mode feedback controller; Coils; Electromagnetics; Electromagnets; Force; Magnetic flux; Magnetic levitation; Conveyance system; electromagnetic suspension (EMS) system; linear synchronous motor (LSM); sliding-mode control;
Journal_Title :
Industrial Electronics, IEEE Transactions on
DOI :
10.1109/TIE.2012.2227909
