Phenomenological Model of the Temperature Dependence of Hysteresis Based on the Preisach Model

Dafri, Mourad; Ladjimi, Abdelaziz; Mendaci, Sofiane; Babouri, Abdesselam

doi:10.1007/s10948-021-05849-3

Cited by 7 publications

(5 citation statements)

References 14 publications

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“…where k J is the linear stiffness of the Jenkins element, δ( • ) is the Dirac delta function, H( • ) is the Heaviside function, f y,min and f y,max are the minimum and maximum values of the output function, respectively. Note that there are other ways to approximate the distribution density of elementary hysterons [69][70][71][72].…”

Section: Definition Of the Preisach Operatormentioning

confidence: 99%

The Preisach model of hysteresis: fundamentals and applications

Semenov,

Borzunov,

Meleshenko

et al. 2024

Phys. Scr.

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The Preisach model is a well-known model of hysteresis in the modern nonlinear science. This paper provides an overview of works that are focusing on the study of dynamical systems from various areas (physics, economics, biology), where the Preisach model plays a key role in the formalization of hysteresis dependencies. Here we describe the input-output relations of the classical Preisach operator, its basic properties, methods of constructing the output using the demagnetization function formalism, a generalization of the classical Preisach operator for the case of vector input-output relations. Various generalizations of the model are described here in relation to systems containing ferromagnetic and ferroelectric materials. The main attention we pay to experimental works, where the Preisach model has been used for analytic description of the experimentally observed results. Also, we describe a wide range of the technical applications of the Preisach model in such fields as energy storage devices, systems under piezoelectric effect, models of systems with long-term memory. The properties of the Preisach operator in terms of reaction to stochastic external impacts are described and a generalization of the model for the case of the stochastic threshold numbers of its elementary components is given.

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Section: Definition Of the Preisach Operatormentioning

confidence: 99%

The Preisach model of hysteresis: fundamentals and applications

Semenov,

Borzunov,

Meleshenko

et al. 2024

Phys. Scr.

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“…Dmitriy et al [22] have studied the magnetic impedance and stress impedance effects of Amorphous CoFeSiB at different temperatures and have shown that high temperatures have a significant impact on magnetic impedance and stress impedance. Dafri et al [23] tested ferrites under different thermal conditions and observed their magnetic properties, including coercivity, remanence, and saturation flux density. According to the results, these properties have been shown to be negatively correlated with temperature.…”

Section: Introductionmentioning

confidence: 99%

“…The saturation flux density of the three materials decreased with increasing temperature, while the coercivity of nanocrystalline (1k107B) first decreased and then increased with increasing temperature. In [23], the coercivity and saturation flux density of NiFe 2 O 4 ferrite material were analyzed at 27 • C to 150 • C, both of which decreased with increasing temperature. The relationship between the relative permeability, coercivity, and saturation flux density of magnetic materials and temperature is similar to that of this study, proving the correctness of the discussion.…”

mentioning

confidence: 99%

Measurement and Analysis of Magnetic Properties of Permalloy for Magnetic Shielding Devices under Different Temperature Environments

Sun

Ren

et al. 2023

Materials

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The relative permeability, coercivity, and remanence of permalloy are closely related to the performance of magnetic shielding devices. In this paper, the relationship between the magnetic properties of permalloy and the working temperature of magnetic shielding devices is measured. Firstly, the measurement method of permalloy properties based on the simulated impact method is analyzed. What is more, a magnetic property test system consisting of a soft magnetic material tester and a high–low temperature chamber for permalloy ring samples at different temperatures was established to measure DC and AC (0.01 Hz to 1 kHz) magnetic properties at different temperatures (−60 °C to 140 °C). Finally, the results show that compared with room temperature (25 °C), the initial permeability (μi) decreases by 69.64% at −60 °C and increases by 38.23% at 140 °C, and the coercivity (hc) decreases by 34.81% at −60 °C and increases by 8.93% at 140 °C, which are the key parameters in the magnetic shielding device. It can be concluded that the relative permeability and remanence of permalloy are positively correlated with temperature, while the saturation magnetic flux density and coercivity are negatively correlated with temperature. This paper is of great significance to the magnetic analysis and design of magnetic shielding devices.

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“…Cao et al [16] measured the high-frequency magnetic properties of nanocrystalline alloy at different temperatures and proved that the alloy exhibits good operating thermal stability at high frequencies. Dafri et al [17] measured the magnetic properties of ferrites at different temperatures, proving that the coercivity, remanence and saturation magnetic induction strength all decrease with the increase in temperature. Panakhov et al [18] proved that the temperature dependence of the differential thermoelectric potential of permalloy can be used to make thermocouples.…”

Section: Introductionmentioning

confidence: 99%

Measurement and analysis of an optimized Jiles–Atherton model considering the influence of temperature applied in magnetic shielding devices

Sun

Ren

Zhou

2023

J. Phys. D: Appl. Phys.

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The magnetic shielding devices works at different temperatures due to the influence of gas chamber and environmental temperature in the application of ultra-highly sensitive spin exchange relaxation free (SERF) magnetometer. To accurately evaluate the residual magnetic field of magnetic shielding device at different temperatures, it is necessary to build the magnetization model considering temperature. However, the modelling of permalloy’s magnetization properties and the measurement of residual magnetic field in magnetic shielding devices at different temperatures haven’t been considered. In this paper, the optimized Jiles-Atherton model of permalloy considering temperature is constructed in which parameters are extracted by particle swarm optimization algorithm. To further verify the effectiveness of the model in the magnetic shielding device, it is applied to the residual magnetic field simulation of magnetic shielding devices and verified by measurement. The optimized Jiles-Atherton model considering temperature improves the calculation accuracy of magnetic shielding devices, which is of great significance for the application of ultra-highly sensitive SERF magnetometers.

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Phenomenological Model of the Temperature Dependence of Hysteresis Based on the Preisach Model

Cited by 7 publications

References 14 publications

The Preisach model of hysteresis: fundamentals and applications

The Preisach model of hysteresis: fundamentals and applications

Measurement and Analysis of Magnetic Properties of Permalloy for Magnetic Shielding Devices under Different Temperature Environments

Measurement and analysis of an optimized Jiles–Atherton model considering the influence of temperature applied in magnetic shielding devices

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