Sage Journals: Discover world-class research

Abstract

The accurate calculation and prediction of dynamic hysteresis losses are of great significance for the design and optimization of energy consumption in high-frequency electromagnetic devices. This paper modifies the existing J-A dynamic hysteresis model based on the nonlinear relationship between dynamic coefficients and magnetic flux density. Aiming at the problems of low computational accuracy and susceptibility to local optima in traditional particle swarm optimization algorithms, a modified hybrid algorithm (GA-CAPSO-NLDIW) is proposed by introducing Tent chaotic mapping function, adaptive velocity factor and learning factor, T-distribution function, and genetic algorithm crossover and mutation factor. Theoretical and experimental verification shows that the hybrid algorithm has low dependence on initial values and has better convergence speed and computational accuracy than other single algorithms. And this modified model, and method can be used for frequency dependent hysteresis loop identification, covering multi-component magnetic material systems such as ferromagnetic materials and low saturation magnetic flux density soft magnetic materials. In addition, this method can also predict dynamic losses under other unknown magnetic densities by using hysteresis loops under known magnetic densities, with errors within a reasonable range. The modeling method and hybrid optimization strategy proposed in this study can provide theoretical basis for the design of motor and magnetic bearing structures, accurate evaluation of dynamic losses in electromagnetic equipment, and other fields.

Keywords

parameter identification dynamic Jiles-Atherton(J-A) model hybrid algorithm loss prediction

Get full access to this article

View all access options for this article.

References

Zhao

Wang

Effect of material permeability character on the field calculation of iron core circuit. J Magn Mater Devices 2005; 06: 24–26.

de Campos

de Castro

. Predicting recoil curves in Stoner-Wohlfarth anisotropic magnets. Acta Phys Pol A 2019; 136(5): 737–739.

Xue

Zhang

, et al. Modification and numerical method for the Jiles-Atherton hysteresis model. Commun Comput Phys 2017; 21(3): 763–781.

Zhao

Liu

Xiao

, et al. Hysteretic and loss modeling of silicon steel sheet under the DC biased magnetization based on the preisach model. Trans China Electrotech Soc 2020; 35(09): 1849–1857.

Zheng

Miao

, et al. Anti-function solution of uniaxial anisotropic Stoner–Wohlfarth model Chin Phys B 2022; 31(4): 040202–040223.

Liu

, et al. The non-uniform element discretization method for identifying distribution function of static inverse preisach model. Proc CSEE 2021; 41(15): 5340–5351.

Chen

Ben

, et al. Parameter identification of preisach model based on velocity-controlled particle swarm optimization method. AIP Adv 2021; 11(1): 015022–015022-4.

Shao

Zhang

, et al. Stroke maximizing and high efficient hysteresis hybrid modeling for a rhombic piezoelectric actuator. Mech Syst Signal Process 2016; 75: 631–647.

Lin

Zhang

Liu

ZX.

Parameter identification of J-A dynamic hysteresis model based on an modified constriction factor PSO algorithm. J Electr Eng 2024; 19(01): 187–195.

10.

Schneider

Gedney

Joyce

, et al. Measurement and exponential model of ferromagnetic hysteresis. Physica B Condens Matter 2019; 570: 259–265.

11.

Wen

Lan

, et al. A self-adaptive genetic algorithm to estimate JA model parameters considering minor loops. J Magn Magn Mater 2015; 374: 502–507.

12.

Wilson

Ross

Brown

AD.

Optimizing the Jiles-Atherton model of hysteresis by a genetic algorithm. IEEE Trans Magn 2001; 37(2): 989–993.

13.

Coelho

LDS

Guerra

Leite

. Multiobjective exponential particle swarm optimization approach applied to hysteresis parameters estimation. IEEE Trans Magn 2012; 48(2): 283–286.

14.

Marion

Scorretti

Siauve

, et al. Identification of Jiles–Atherton model parameters using particle swarm optimization. IEEE Trans Magn 2008; 44(6): 894–897.

15.

Toman

Stumberger

Dolinar

Parameter identification of the Jiles–Atherton hysteresis model using differential evolution. IEEE Trans Magn 2008; 44(6): 1098–1101.

16.

Zhang

Fletcher

JE.

Double-frequency method using differential evolution for identifying parameters in the dynamic Jiles–Atherton model of Mn–Zn ferrites. IEEE Trans Instrum Meas 2013; 62(2): 460–466.

17.

Sedira

Gabi

Kedous-Lebouc

, et al. ABC method for hysteresis model parameters identification. J Magn Magn Mater 2020; 505: 505.

18.

Zou

Parameter estimation of extended Jiles–Atherton hysteresis model based on ISFLA

IET Electric Power Appl 2020; 14(2): 212–219.

19.

Zhu

, et al. Parameter identification method for J-A hysteresis model based on the sparrow search and genetic algorithm. High Volt Eng 2022; 48(10): 4181–4188.

20.

Zhao

JA.

Parameter identification and verification of J-A dynamic hysteresis model based on hybrid algorithms of AFSA and PSO. Chin J Sci Instrum 2020; 41(01): 26–34.

21.

Wei

Yang

Chen

, et al. Prediction of magnetic losses in giant magnetostrictive materials under different sinusoidal excitation magnetic fields. IEEE Trans Magn 2022; 58(11): 1–9.

22.

Chen

Yang

Zheng

, et al. Prediction of magnetic energy loss of giant magnetostrictive materials under different prestresses, AC excitations and DC biases. J Magn Magn Mater 2024; 589: 589.

23.

Zhu

Core loss calculation based on finite-element method with Jiles–Atherton dynamic hysteresis model. IEEE Trans Magn 2018; 54(3): 1–5.

24.

Bai

Radial basis function neural network based on an improved exponential decreasing inertia weight-particle swarm optimization algorithm for AQI prediction. Abstr Appl Anal 2014; 2014: 1–9.

25.

Mao

Bao

Particle swarm optimization algorithm based on non-symmetric learning factor adjusting. Comput Eng 2010; 36(19): 182–184.

26.

Wang

E S

Yang

Wang

, et al. Parameter analysis and improvement of PSO satellite selection algorithm. J Beijing Univ Aeronaut Astronaut 2019; 45(11): 2133–2138.

27.

Zhang

, et al. MIWOA: a multi-strategy improved whale optimization algorithm with hybrid perturbation for engineering optimization. Expert Syst Appl 2026; 302: 130245.

28.

Hosoda

Fujii

. A new phenomenological model for frequency dependent hysteresis of bimorph piezoelectric actuator: multi model estimation approach via particle filter. In: 2020 IEEE international conference on systems, man, and cybernetics (SMC), Toronto, ON, Canada, 2020, pp. 2857-2863, doi: 10.1109/SMC42975.2020.9282901.

29.

Nowicki

Szewczyk

, et al. Modeling the hysteresis loop of ultra-high permeability amorphous alloy for space applications. Materials 2018; 11(11): 2079. https://doi.org/10.3390/ma11112079

Parameter identification and loss prediction of modified J-A dynamic hysteresis model based on chaotic genetic particle swarm optimization

Abstract

Keywords

Get full access to this article

References