Application of Gauss-Newton method in magnetic dipole model

doi:10.1088/1674-1056/addcd1

中国物理B ›› 2025, Vol. 34 ›› Issue (10): 100701-100701.doi: 10.1088/1674-1056/addcd1

Application of Gauss-Newton method in magnetic dipole model

Junchen Gao(高骏琛)¹, Chaobo Liu(刘超波)², Jinjing Zhang(张津菁)¹, Yu Duan(段宇)¹, Hao-Ran Yang(杨浩冉)¹, and Daqiang Gao(高大强)^1,†

1 College of Physical Science and Technology, Key Laboratory of Magnetism and Magnetic Materials, Ministry of Education, Lanzhou University, Lanzhou 730000, China;
2 Beijing Institute of Spacecraft Environment Engineering, Beijing 100000, China

收稿日期:2025-03-24 修回日期:2025-05-19 接受日期:2025-05-26 发布日期:2025-09-25
通讯作者: Daqiang Gao E-mail:gaodqxz@sina.com
基金资助:
Project supported by the National Key Research and Development Program of China (Grant No. 2023YFC2206003).

Application of Gauss-Newton method in magnetic dipole model

Junchen Gao(高骏琛)¹, Chaobo Liu(刘超波)², Jinjing Zhang(张津菁)¹, Yu Duan(段宇)¹, Hao-Ran Yang(杨浩冉)¹, and Daqiang Gao(高大强)^1,†

1 College of Physical Science and Technology, Key Laboratory of Magnetism and Magnetic Materials, Ministry of Education, Lanzhou University, Lanzhou 730000, China;
2 Beijing Institute of Spacecraft Environment Engineering, Beijing 100000, China

Received:2025-03-24 Revised:2025-05-19 Accepted:2025-05-26 Published:2025-09-25
Contact: Daqiang Gao E-mail:gaodqxz@sina.com
Supported by:
Project supported by the National Key Research and Development Program of China (Grant No. 2023YFC2206003).

摘要/Abstract

摘要： With the increasing accuracy requirements of satellite magnetic detection missions, reducing low-frequency noise has become a key focus of satellite magnetic cleanliness technology. Traditional satellite magnetic simulation methods have matured in static magnetic dipole simulations, but there is still significant room for optimization in the simulation and computation of low-frequency magnetic dipole models. This study employs the Gauss-Newton method and Fourier transform techniques for modeling and simulating low-frequency magnetic dipoles. Compared to the traditional particle swarm optimization (PSO) algorithm, this method achieves significant improvements, with errors reaching the order of 10$^{-13}$% under noise-free conditions and maintaining an error level of less than 0.5% under 10% noise. Additionally, the use of Fourier transform and the Gauss-Newton method enables high-precision magnetic field frequency identification and rapid computation of the dipole position and magnetic moment, greatly enhancing the computational efficiency and accuracy of the model.

关键词: magnetic dipole model, Gauss-Newton method, Fourier transform, inversion accuracy

Abstract: With the increasing accuracy requirements of satellite magnetic detection missions, reducing low-frequency noise has become a key focus of satellite magnetic cleanliness technology. Traditional satellite magnetic simulation methods have matured in static magnetic dipole simulations, but there is still significant room for optimization in the simulation and computation of low-frequency magnetic dipole models. This study employs the Gauss-Newton method and Fourier transform techniques for modeling and simulating low-frequency magnetic dipoles. Compared to the traditional particle swarm optimization (PSO) algorithm, this method achieves significant improvements, with errors reaching the order of 10$^{-13}$% under noise-free conditions and maintaining an error level of less than 0.5% under 10% noise. Additionally, the use of Fourier transform and the Gauss-Newton method enables high-precision magnetic field frequency identification and rapid computation of the dipole position and magnetic moment, greatly enhancing the computational efficiency and accuracy of the model.

Key words: magnetic dipole model, Gauss-Newton method, Fourier transform, inversion accuracy

中图分类号: (Magnetometers for magnetic field measurements)

07.55.Ge

02.30.Zz (Inverse problems) 41.20.Gz (Magnetostatics; magnetic shielding, magnetic induction, boundary-value problems) 02.60.Pn (Numerical optimization)

Junchen Gao(高骏琛), Chaobo Liu(刘超波), Jinjing Zhang(张津菁), Yu Duan(段宇), Hao-Ran Yang(杨浩冉), and Daqiang Gao(高大强). Application of Gauss-Newton method in magnetic dipole model[J]. 中国物理B, 2025, 34(10): 100701-100701.

参考文献

[1] Langel R A and Hinze W J 1998 The Magnetic Field of the Earth’s Lithosphere: The Satellite Perspective (Cambridge: Cambridge University Press) pp. 1-393
[2] Friis-Christensen E and Lühr H, Hulot G 2006 Earth Planets Space 58 351
[3] Acuna M H 2002 Rev. Sci. Instrum. 73 3717
[4] Tauxe L 2010 Essentials of Paleomagnetism (Berkeley: University of California Press) pp. 1-489
[5] Constable C G and Parker R L 1988 J. Geophys. Res. Solid Earth 93 11569
[6] Love J J and Constable C G 2003 Geophys. J. Int. 152 515
[7] Blakely R J 1996 Potential Theory in Gravity and Magnetic Applica tions (Cambridge: Cambridge University Press) pp. 1-356
[8] Kennedy J and Eberhart R 1995 Proc. Int. Conf. Neural Networks, November 27-December 1, 1995, Perth, Australia, pp. 1942-1945
[9] Nabighian M N, Grauch V J S, Hansen R O, LaFehr T R, Li Y, Peirce J W and Ruder M E, et al. 2005 Geophysics 70 33
[10] Mehlem K 1978 Spacecraft Electromagnetic Compatibility 165 165
[11] Mehlem K 1978 IEEE Trans. Magn. 14 1064
[12] Pudney M A, Carr C M, Schwartz S J and Howarth S I 2013 Geosci. Instrum. Method. Data Syst. 2 249
[13] Shi Y amd Eberhart R C 1999 Proc. Congr. Evol. Comput., July 6-9, 1999, Washington DC, USA, pp. 1945-1950
[14] Carrubba E, Junge A, Marliani F and Monorchio A 2012 Proc. ESA Workshop on Aerospace EMC, May 21-23, 2012, Florence, Italy, pp. 1-6
[15] Mehlem K, Wiegand A and Weickert S 2012 Proc. ESA Workshop on Aerospace EMC, May 21-23, 2012, Florence, Italy, pp. 1-6
[16] Love J J and Rigler E J 2014 Geophys. J. Int. 199 407
[17] Ovchinnikov M Y, Penkov V I, Roldugin D S and Pichuzhkina A V 2018 Acta Astronaut. 144 171
[18] Srivastava R, Sah R, Das K 2021 arXiv: 2107.09257 [physics.geo-ph]
[19] Torbert R B, Dors I, Argall M R, Genestreti K J, Burch J L, Farrugia C J, Strangeway R J, et al. 2020 Geophys. Res. Lett. 47 e2019GL085542
[20] Dennis J E Jr, Schnabel R B 1996 Numerical Methods for Uncon strained Optimization and Nonlinear Equations (Philadelphia: SIAM) pp. 1-258
[21] Wright S J 2006 Numerical Optimization (New York: Springer) pp. 135-163

Application of Gauss-Newton method in magnetic dipole model

Application of Gauss-Newton method in magnetic dipole model

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