Design of Braunbeck Coil for Nuclear Magnetic Resonance Gyro Magnetic Field Excitation

doi:10.1007/s12204-018-2000-3

Journal of Shanghai Jiao Tong University (Science) ›› 2018, Vol. 23 ›› Issue (6): 740-745.doi: 10.1007/s12204-018-2000-3

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Design of Braunbeck Coil for Nuclear Magnetic Resonance Gyro Magnetic Field Excitation

WANG Pei (王昢), LIU Hua (刘华), CHENG Xiang (程翔), ZHAO Wanliang (赵万良), LI Shaoliang (李绍良), CHENG Yuxiang (成宇翔)

(1. School of Electronic Information and Electrical Engineering, Shanghai Jiao Tong University, Shanghai 200240, China; 2. Department of Navigation and Inertial technology, Shanghai Institute of Spaceflight Control Technology, Shanghai 201109, China; 3. Department of Navigation and Inertial Technology, Shanghai Engineer Research Center of Inertia, Shanghai 201109, China; 4. Department of Navigation and Inertial technology, Shanghai Key Laboratory of Space Intelligent Control Technology, Shanghai 201109, China)
(1. School of Electronic Information and Electrical Engineering, Shanghai Jiao Tong University, Shanghai 200240, China; 2. Department of Navigation and Inertial technology, Shanghai Institute of Spaceflight Control Technology, Shanghai 201109, China; 3. Department of Navigation and Inertial Technology, Shanghai Engineer Research Center of Inertia, Shanghai 201109, China; 4. Department of Navigation and Inertial technology, Shanghai Key Laboratory of Space Intelligent Control Technology, Shanghai 201109, China)

Online:2018-12-01 Published:2018-12-07
Contact: WANG Pei (王昢) E-mail:dianluyuanli@sjtu.edu.cn

Abstract

Abstract: For generating a uniform and steady magnetic field, Helmholtz coil is extensively used in nuclear magnetic resonance gyro (NMRG). Unfortunately, the volume of Helmholtz coil makes it inconvenient to miniaturize NMRG. This study introduces Braunbeck coil that can be used in magnetic field excitation system. Braunbeck coil can produce homogeneous magnetic field within a limit space, and occupy a small volume. In addition, this study presents mathematical expressions that can be used to calculate the area of uniform magnetic field. Experimental test verifies the effectiveness of the proposed design, and the results accord closely with the actual simulation.

摘要： For generating a uniform and steady magnetic field, Helmholtz coil is extensively used in nuclear magnetic resonance gyro (NMRG). Unfortunately, the volume of Helmholtz coil makes it inconvenient to miniaturize NMRG. This study introduces Braunbeck coil that can be used in magnetic field excitation system. Braunbeck coil can produce homogeneous magnetic field within a limit space, and occupy a small volume. In addition, this study presents mathematical expressions that can be used to calculate the area of uniform magnetic field. Experimental test verifies the effectiveness of the proposed design, and the results accord closely with the actual simulation.

CLC Number:

TH 89

WANG Pei (王昢), LIU Hua (刘华), CHENG Xiang (程翔), ZHAO Wanliang (赵万良), LI Shaoliang (李绍良), CHENG Yuxiang (成宇翔). Design of Braunbeck Coil for Nuclear Magnetic Resonance Gyro Magnetic Field Excitation[J]. Journal of Shanghai Jiao Tong University (Science), 2018, 23(6): 740-745.

References 18

[1]	MEYER D, LARSEN M. Nuclear magnetic resonance gyro for inertial navigation [J]. Gyroscopy and Navigation,2014, 5(2): 75-82.
[2]	FANG J C, QIN J. Advances in atomic gyroscopes: A view from inertial navigation applications [J]. Sensors,2012, 12(5): 6331-6346.
[3]	FANG J C, QIN J, WAN S A, et al. Atomic spin gyroscope based on 129Xe-Cs comagnetometer [J]. Chinese Science Bulletin, 2013, 58(13): 1512-1515.
[4]	WAN S A, SUN X G, ZHENG X, et al. Prospective development of nuclear magnetic resonance gyroscope[J]. Navigation Positioning & Timing, 2017, 4(1): 7-13(in Chinese)
[5]	GROVER B C, KANEGSBERG E, MARK J G, et al.Nuclear magnetic resonance gyro: US patent 4157495[P]. 1979-6-5 [2017-08-15].
[6]	LARSEN M, BULATOWICZ M. Nuclear magnetic resonance gyroscope: For DARPA’s micro-technology for positioning, navigation and timing program[C]//Proceedings of 2012 IEEE International Frequency Control Symposium. Baltimore, USA: IEEE,2012: 1-5.
[7]	KORVER A, THRASHER D, BULATOWICZ M, et al. Synchronous spin-exchange optical pumping [J].Physical Review Letters, 2015, 115(25): 253001.
[8]	AJOY A, CAPPELLARO P. Stable three-axis nuclear spin gyroscope in diamond [J]. Physical Review A,2012, 86(6): 062104.
[9]	GUNDETI V M. Folded MEMS approach to NMRG[D].Irvine, USA: Department of Materials Science & Engineering, University of California, 2015.
[10]	BULATOWICZ M D, LARSEN M S. Self-calibrating nuclear magnetic resonance (NMR) gyroscope system:EP2952854 [P]. 2015-08-26 [2017-08-15].
[11]	YAN J Z, LI P, LIU Z Y. Analysis on the basic concept and the development tendency of atomic gyroscopes[J]. Piezoelectrics & Acoustooptics, 2014, 37(5): 810-817 (in Chinese).
[12]	WANG C E, QIN J. Design method of high uniform magnetic coil for nuclear magnetic resonance gyroscope[J]. Navigation Positioning & Timing, 2017,4(1): 89-93 (in Chinese).
[13]	MIRIJANIAN J J. Techniques to characterize vapor cell performance for a nuclear-magnetic-resonance gyroscope[D]. San Luis Obispo, USA: Faculty of California Polytechnic State University, 2012.
[14]	LIU Z Y, ZHANG Q, PAN M C, et al. Distortion magnetic field compensation of geomagnetic vector measurement system using a 3-D Helmholtz coil [J]. IEEE Geoscience and Remote Sensing Letters, 2017, 14(1):48-51.
[15]	RAUTELA R S, BHATT V, SHARMA P, et al. Mathematical approach for designing & development of Helmholtz coil for hyperpolarized Xenon gas used in MRI [C]//India International Conference on Power Electronics (IICPE). [s.l.]: IEEE, 2011: 1-5.
[16]	CAO Q L, HAN X T, ZHANG B, et al. Analysis and optimal design of magnetic navigation system using Helmholtz and Maxwell coils [C]//IEEE Transactions on Applied Superconductivity, 2012, 22(3): 4401504.
[17]	JIANG C, MI Y, YAO C G, et al. Analysis of Braunbeck coil for pulsed magnetic field generator [J].High Voltage Engineering, 2012, 38(5): 1150-1156 (in Chinese).
[18]	GOTTARDI G, MESIRCA P, AGOSTINI C, et al.A four coil exposure system (tetracoil) producing a highly uniform magnetic field [J]. Bioelectromagnetics,2003, 24: 125-133.

Design of Braunbeck Coil for Nuclear Magnetic Resonance Gyro Magnetic Field Excitation

Design of Braunbeck Coil for Nuclear Magnetic Resonance Gyro Magnetic Field Excitation

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