[1] Meyer D, Larsen M. Nuclear magnetic resonance gyro for inertial navigation [J]. Gyroscopy and Navigation, 2014, 5(2): 75-82.

[2] by microtechnology: Are we there yet[J]. Micro-and Nanotechnology Sensors, System, and Applications, 2010, 8031(2): 5-9.

     Shkel A M. Precision navigation and timing enabled

[3] Shkel A M. The chip-scale combinatorial atomic navigator [J]. Gps World, 2013, 24(8): 8-10.

[4] Larsen M, Bulatowicz M. Nuclear magnetic resonance gyroscope: For DARPA's micro-technology for positioning, navigation and timing program [C]//International Symposium on Inertial Sensors and Systems. IEEE, 2012: 1-5.

[5] Wan Shuangai, Sun Xiaoguang, Zheng Xin, et al. Development prospect of magnetic resonance gyroscope [J]. Navigation and Timing, 2017, 4(1): 7-13. (in Chinese)

[6] Yi Xin, Wang Zhiguo, Xia Tao, et al. Research on temperature field in the vapor cell of nuclear magnetic resonance gyroscope [J]. Chinese Optics, 2016, 9(6): 671-677. (in Chinese)

[7] Happer W, Jau Y Y , Walker T. Optically Pumped Atoms [M]. Weinheim: Wiley-VCH Verlag GmbH & Co, 2010: 159-217.

[8] Ding Zhichao, Li Yingying, Wang Zhiguo, et al. Research on rubidium atomic magnetometer based on Faraday rotation detection [J]. Chinese Journal of Lasers, 2015, 42(4): 0408003. (in Chinese)

[9] Eklund E J. Microgyroscope based on spin-polarized nuclei [D]. Irvine: University of California, 2008.

[10] Terao A, Ban K, Ichihara S, et al. Highly responsive ac scalar atomic magnetometer with long relaxation time [J]. Physical Review A, 2013, 88(6): 063413.

[11] Tan Qiao, Xu Qifeng, Xie Nan. New method for retardance measurement of a quarter-wave plate[J]. Infrared and Laser Engineering, 2016, 45(7): 0717002. (in Chinese)

[12] Brooker G. Modern Classical Optics [M]. New York: Qxford University, 2003.

[13] Plumb R C. Analysis of elliptically polarized light [J]. Journal of the Optical Society of America, 1960, 50(9):892-894.