Self-tuning dual-layer sliding mode control of electromagnetic suspension system

Abstract

The suspension system in electromagnetic suspension maglev trains is highly nonlinear and sensitive to uncertainties, noise, and disturbances, making it quite challenging to design the proper electromagnetic voltages to control the suspension gap. In this paper, a self-tuning dual-layer sliding mode control system (SD-SMC) is developed to control the electromagnetic suspension system where voltage saturation, sensor noise, and a wide range of parametric uncertainties/variations exist. SD-SMC consists of dual-layer sliding mode controllers, a delay-compensated low-pass filter, and a forgetting least-squares estimator. Compared with existing control systems, SD-SMC can achieve high performance under large model uncertainties and disturbances with relatively low control voltages, and meanwhile, the control chattering and overshooting issues can be well mitigated. Both numerical and experimental examples are investigated to validate the proposed control system.