A novel multi‐strategy self‐optimizing SAPSO algorithm for PMSM parameter identification

Dingdou Wen; Chuandong Shi; Yang Zhang; Kaixian Liao; Jianhua Liu; Bing Luo; Tingting Wang

doi:10.1049/pel2.12385

IET Power Electronics (Feb 2023)

A novel multi‐strategy self‐optimizing SAPSO algorithm for PMSM parameter identification

Dingdou Wen,
Chuandong Shi,
Yang Zhang,
Kaixian Liao,
Jianhua Liu,
Bing Luo,
Tingting Wang

Affiliations

Dingdou Wen: College of Electrical and Information Engineering Hunan University of Technology Zhuzhou Hunan Province People's Republic of China
Chuandong Shi: College of Electrical and Information Engineering Hunan University of Technology Zhuzhou Hunan Province People's Republic of China
Yang Zhang: College of Electrical and Information Engineering Hunan University of Technology Zhuzhou Hunan Province People's Republic of China
Kaixian Liao: College of Electrical and Information Engineering Hunan University of Technology Zhuzhou Hunan Province People's Republic of China
Jianhua Liu: College of Electrical and Information Engineering Hunan University of Technology Zhuzhou Hunan Province People's Republic of China
Bing Luo: CSG Electric Power Research Institute Co. Ltd Guangzhou Guangdong Province People's Republic of China
Tingting Wang: CSG Electric Power Research Institute Co. Ltd Guangzhou Guangdong Province People's Republic of China

DOI: https://doi.org/10.1049/pel2.12385
Journal volume & issue: Vol. 16, no. 2
pp. 305 – 319

Abstract

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Abstract To address the unsatisfactory performance of particle swarm optimization (PSO), a novel multi‐strategy self‐optimizing simulated annealing particle swarm optimization (SOSAPSO) method for permanent magnet synchronous motor (PMSM) parameter identification is proposed. The full‐rank mathematical model and the fitness function are developed. In SOSAPSO, the velocity term of the PSO is simplified and dynamic opposition‐based learning (DOBL) is introduced in the inertia weight update process to avoid population monotonicity. Moreover, A Cauchy–Gaussian hybrid variation strategy based on similarity and density is devised to achieve self‐learning in deep regions. Meanwhile, the simulated annealing (SA) with a memory and tempering mechanism is introduced into SOSAPSO, and the greedy optimization algorithm (GOA) is used to enhance local fine‐exploitation capabilities when SOSAPSO evolution is stalled. The test results indicate the proposed method can effectively avoid local convergence problems and has better robustness and convergence speed.

Published in IET Power Electronics

ISSN: 1755-4535 (Print); 1755-4543 (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering: Electronics
Website: https://ietresearch.onlinelibrary.wiley.com/journal/17554543

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