Abstract
This paper concentrates on a robust resonant control strategy of a permanent magnet synchronous motor (PMSM) for electric drivers with model uncertainties and external disturbances to improve the control performance of the current loop. Firstly, to reduce the torque ripple of PMSM, the resonant controller with fractional order (FO) calculus is introduced. Then, a robust two degrees-of-freedom (Robust-TDOF) control strategy was designed based on the modified resonant controller. Finally, by combining the two control methods, this study proposes an enhanced Robust-TDOF regulation method, named as the robust two degrees-of-freedom resonant controller (Robust-TDOFR), to guarantee the robustness of model uncertainty and to further improve the performance with minimized periodic torque ripples. Meanwhile, a tuning method was constructed followed by stability and robust stability analysis. Furthermore, the proposed Robust-TDOFR control method was applied in the current loop of a PMSM to suppress the periodic current harmonics caused by non-ideal factors of inverter and current measurement errors. Finally, simulations and experiments were performed to validate our control strategy. The simulation and experimental results showed that the THDs (total harmonic distortion) of phase current decreased to a level of 0.69% and 5.79% in the two testing environments.
Highlights
Permanent magnet synchronous motors (PMSMs) have been widely employed in servo control systems, such as in electrical vehicles, numerical control machines, and robotic fields, owing to its advantages of high power density, low electric power loss, and small structural size [1,2,3,4]
To overcome the drawbacks of PMSMs, several useful control theories such as sliding mode control (SMC), model predictive control (MPC), and active disturbance rejection control (ADRC) have been developed, which are represented in references [6,7,8]
SiTmhuelcaotinotnroRledsiualgtsram of PMSM shown in Figure 7 was conducted in MATLAB-SIMULINK
Summary
Permanent magnet synchronous motors (PMSMs) have been widely employed in servo control systems, such as in electrical vehicles, numerical control machines, and robotic fields, owing to its advantages of high power density, low electric power loss, and small structural size [1,2,3,4]. Due to the non-linear factors of inverter, current measurement errors and periodic disturbances, i.e., harmonic components, will occur in PMSM operation [4] These periodic disturbances (conventionally occurring several times more often as the fundamental frequency) may be near or outside of the corner frequency of the Q filter (corresponding to the bandwidth), which decreases the control performance and results in torque ripple when classical a Robust-TDOF controller applied to PMSM. The magnitude of these high frequency components with periodic characteristics is pretty small, which would be insignificant.
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