Title :
High-Order Mismatched Disturbance Compensation for Motion Control Systems Via a Continuous Dynamic Sliding-Mode Approach
Author :
Jun Yang ; Jinya Su ; Shihua Li ; Xinghuo Yu
Author_Institution :
Key Lab. of Meas. & Control of CSE, Southeast Univ., Nanjing, China
Abstract :
A new continuous dynamic sliding-mode control (CDSMC) method is proposed for high-order mismatched disturbance attenuation in motion control systems using a high-order sliding-mode differentiator. First, a new dynamic sliding surface is developed by incorporating the information of the estimates of disturbances and their high-order derivatives. A CDSMC law is then designed for a general motion control system with both high-order matched and mismatched disturbances, which can attenuate the effects of disturbances from the system output. The proposed control method is finally applied for the airgap control of a MAGnetic LEViation (MAGLEV) suspension vehicle. Simulation results show that the proposed method exhibits promising control performance in the presence of high-order matched and mismatched disturbances.
Keywords :
air gaps; compensation; magnetic levitation; motion control; suspensions (mechanical components); variable structure systems; vehicle dynamics; CDSMC law; MAGLEV; airgap control; continuous dynamic sliding-mode control method; disturbance estimation; general motion control systems; high-order derivatives; high-order matched disturbances; high-order mismatched disturbance compensation; high-order sliding-mode differentiator; magnetic leviation suspension vehicle; system output; Dynamics; Motion control; Sliding mode control; Suspensions; Uncertainty; Vehicle dynamics; Vehicles; Dynamic sliding-mode control (DSMC); MAGLEV suspension vehicle; high-order mismatched disturbances; motion control systems;
Journal_Title :
Industrial Informatics, IEEE Transactions on
DOI :
10.1109/TII.2013.2279232
