Abstract
A novel sliding mode controller (SMC) with nonlinear fractional order PID sliding surface based on a novel extended state observer for the speed operation of a surface-mounted permanent magnet synchronous motor (SPMSM) is proposed in this paper. First, a new smooth and derivable nonlinear function with improved continuity and derivative is designed to replace the traditional nonderivable nonlinear function of the nonlinear state error feedback control law. Then, a nonlinear fractional order PID sliding mode controller is proposed on the basis of the fractional order PID sliding surface with the combination of the novel nonlinear state error feedback control law to improve dynamic performance, static performance, and robustness of the system. Furthermore, a novel extended state observer is designed based on the new nonlinear function to achieve dynamic feedback compensation for external disturbances. Stability of the system is proved based on the Lyapunov stability theorem. The corresponding comparative simulation results demonstrate that the proposed composite control algorithm displays good stability, dynamic properties, and strong robustness against external disturbances.
Highlights
Permanent magnet synchronous motor (PMSM) gradually becomes one of the most competitive motion control products because of the inherent advantages of low rotor inertia, high efficiency, and high power density, which has been utilized in industrial applications [1,2,3]
Conclusions is paper presents a novel sliding mode controller (SMC) strategy composed of the SMC-nonlinear FOPID (NFOPID) and the novel second-order ESO (NSOESO) for the speed operation of the surface-mounted permanent magnet synchronous motor (SPMSM)
A novel nonlinear state error feedback control law (NLSEF) is designed on the basis of a new continuous and derivable nonlinear function; an SMC-NFOPID is designed on the basis of the fractional order PID (FOPID) sliding surface with the combination of the novel NLSEF
Summary
Permanent magnet synchronous motor (PMSM) gradually becomes one of the most competitive motion control products because of the inherent advantages of low rotor inertia, high efficiency, and high power density, which has been utilized in industrial applications [1,2,3]. In some researches [21, 22], an adaptive SMC was designed for the speed and current control of PMSMs. In another research [23], a new exponential reaching law of the SMC strategy was proposed to improve the performance of the control of PMSMs. Fractional order calculus has been widely used for the Mathematical Problems in Engineering improvement of the SMC. In order to improve that dynamic performance, static performance, and robustness of the SMC-FOPID and considering the advantages of the NLSEF, a novel nonlinear FOPID (NFOPID) sliding surface is developed in this study.
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