Research on the Mechanical Parameter Identification and Controller Performance of Permanent Magnet Motors Based on Sensorless Control

In order to improve the control performance of the position sensorless control system of permanent magnet synchronous motors and to reduce the influence of external uncertainties on the control system, such as inertia ingestion and load disturbance, this paper proposes a novel position sensorless co...

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Bibliographic Details
Published in:Actuators 2024-12, Vol.13 (12), p.525
Main Authors: Luan, Mingchen, Zhang, Yun, Ruan, Jiuhong, Guo, Yongwu, Wang, Long, Min, Huihui
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Analysis
Coefficient of friction
Control algorithms
Control stability
Control systems
Control systems design
Control theory
Controllers
Design
Friction
Inertia
Ingestion
interleaved parallel extended sliding mode observer
Magnets, Permanent
Mechanical properties
Moments of inertia
novel predefined time sliding mode controller
Parameter estimation
Parameter identification
Parameter robustness
Parameter uncertainty
permanent magnet synchronous motor
Permanent magnets
Position measurement
Position sensing
position sensorless control
Robust control
Simulation methods
Sliding mode control
Synchronous motors
Systems stability
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Summary:In order to improve the control performance of the position sensorless control system of permanent magnet synchronous motors and to reduce the influence of external uncertainties on the control system, such as inertia ingestion and load disturbance, this paper proposes a novel position sensorless control algorithm for permanent magnet synchronous motors based on an interleaved parallel extended sliding mode observer. Firstly, in order to identify the time-varying moment of inertia, load torque and viscous friction coefficient of the system, a novel interleaved parallel extended sliding mode observer based on a single-observer model is proposed, and a robust activator is designed to reduce the coupling between the parameters to be measured. Then, a new predefined-time sliding mode controller is designed for the face-mounted permanent magnet synchronous motor using sliding film control theory, which improves the response speed and control accuracy of the system. Then, the proposed novel interleaved parallel extended sliding mode observer and predefined-time sliding mode controller are used to design the permanent magnet synchronous motor control system, and the stability of the system is proved using the Lyapunov stability theorem. Finally, through simulation analysis and experimental tests, it is verified that the control strategy proposed in this paper can improve the identification accuracy of the motor parameters, reduce the time of identification, and improve the control accuracy and tracking speed.
ISSN:2076-0825
2076-0825
DOI:10.3390/act13120525