Full speed range position‑sensorless compound control scheme for PMSMs

At low speeds, a high frequency signal injection method for the position-sensorless control of permanent magnet synchronous motors (PMSMs) produces additional power loss and position estimation delay. Meanwhile, at high speeds, the sliding mode observer (SMO) method has a chattering problem. With a focus on these problems, a full speed range position-sensorless compound control approach is proposed in this paper. First, the phase relationship between the different coordinate systems of the I/F control, and the mechanism of the chattering phenomenon of a sliding mode observer are analyzed. Then the full speed range position-sensorless control approach based on a combination of I/F control and an extended sliding mode observer is constructed. Through feeding back the estimated back electromotive force to the calculation of the stator current observer and using the rotated influence immune phase-locked loop, the innovative extended-SMO effectively improves the chattering phenomenon. Furthermore, the smooth transition between the two control schemes is achieved by a current slope decrement switching controller. Finally, the effectiveness of the proposed full speed range position-sensorless compound control approach for PMSMs is validated on a surface PMSM experimental bench.

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Cite this article

[IEEE Style]

P. Liu, D. Liu, Y. Shen, A. Liu, X. Yang, J. Zhao, "Full speed range position‑sensorless compound control scheme for PMSMs," Journal of Power Electronics, vol. 22, no. 8, pp. 1302-1312, 2022. DOI: 10.1007/s43236-022-00441-x.

[ACM Style]

Pu Liu, Di Liu, Yongpeng Shen, Ankang Liu, Xiaoliang Yang, and Jun Zhao. 2022. Full speed range position‑sensorless compound control scheme for PMSMs. Journal of Power Electronics, 22, 8, (2022), 1302-1312. DOI: 10.1007/s43236-022-00441-x.