Sliding-Mode-Observer-Based Position Estimation for Sensorless Control of the Planar Switched Reluctance Motor

This paper proposes a position estimation method for a planar switched reluctance motor (PSRM). In the method, a second-order sliding mode observer (SMO) is used to achieve sensorless control of a PSRM for the first time. A sensorless closed-loop control strategy based on the SMO without a position...

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Bibliographic Details
Published inIEEE access Vol. 7; pp. 61034 - 61045
Main Authors Sun, Jundi, Cao, Guang-Zhong, Huang, Su-Dan, Peng, Yeping, He, Jiangbiao, Qian, Qing-Quan
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2019
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Error analysis
Flux
Force
Inductance
Mathematical analysis
Observers
Phase current
planar switched reluctance motor (PSRM)
Position estimation
Position sensing
Reluctance
Sensorless control
Sliding mode control
sliding mode observer (SMO)
Stability analysis
Stators
Switched reluctance motors
Thrust
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Summary:This paper proposes a position estimation method for a planar switched reluctance motor (PSRM). In the method, a second-order sliding mode observer (SMO) is used to achieve sensorless control of a PSRM for the first time. A sensorless closed-loop control strategy based on the SMO without a position sensor for the PSRM is constructed. The SMO mainly consists of a flux linkage estimation, an adaptive current estimation, an observing error calculation, and a position estimation section. An adaptive current observer is applied in the current estimation section to minimize the error between the measured and estimated currents and to increase the accuracy of the position estimation. The flux linkage is estimated by the voltage equation of the PSRM, and the estimated flux linkage is then used to estimate the phase current in the adaptive current observer. To calculate the observing error of the SMO using the measured and estimated phase currents, the observing error of the thrust force is introduced to replace the immeasurable state error of the position and speed of the mover. The sliding surface is designed based on the error of the thrust force, and stability analysis is given. Once the sliding surface is reached, the mover position is then estimated accurately. Finally, the effectiveness of the proposed method for the PSRM is verified experimentally.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2019.2913702