[1] Meng Li, Pan Zhengqing, Geng Jianxin et al.. A short-cavity phosphate glass fiber laser and its output characteristics [J]. Chinese J. Lasers, 2010, 37(2): 362～366

[2] Yuan Libo. Overview and forecast of fiber optic white light interferometry [J]. Acta Optica Sinica, 2011, 31(9): 0900137

[3] Hong Lingfei, Zhang Chunxi, Feng Lishuang et al.. Frequency tracking and locking methods in resonator micro-optic gyro [J]. Chinese J. Lasers, 2011, 38(9): 0905003

[4] Lü Yuelan, Xing Yongwei. Investigation on Rayleigh scattering waveform in phase optical time domain reflectometer [J]. Acta Optica Sinica, 2011, 31(8): 0819001

[5] Jiang Yajun, Zhao Jianlin, Tang Daqing et al.. Measurement of the bending loss of single-mode fiber by use of fiber loop cavity ring-down technique [J]. Acta Optica Sinica, 2010, 30(4): 971～975

[6] Yuan Rong. Fiber Commication [M]. Beijing: Publishing House of Electronics Industry, 2010. 57～58

[7] F. Berghmans, E. Brichard, A. F. Fernandez et al.. An introduction to radiation effects on optical components and fiber optic sensors [C]. Optical Waveguide Sensing and Imaging, 2008, 127～165

[8] David L. Griscom. Self-trapped holes in glassy silica: basic science with relevance to photonics in space [C]. SPIE, 8164: 816405

[9] David L. Griscom. Trapped-electron centers in pure and doped glassy silica: a review and synthesis [J]. J. Non-Cryst. Solids, 2011, 357(8-9): 1945～1962

[10] Elise Regnier, Ivo Flammer, Sylvain Girard et al.. Low-dose radiation induced attenuation at infra-red wavelengths for P-doped, Ge-doped and pure silica-core optical fibres [J]. IEEE Trans. Nuclear Science, 2007, 54(4): 1115～1119

[11] B. Brichard, P. Borgermans, F. Berghmans et al.. Dedicated optical fibres for dosimetry based on radiation-induced attenuation: experimental results [C]. SPIE, 1999, 3872: 36～42

[12] E. J. Friebele, C. G. Askins, M. E. Gingerich et al.. Optical fiber waveguides in radiation environments II [J]. Nuclear Instruments and Methods in Physics Research B, 1984, 1(2-3): 355～369

[13] R. H. West. Predicting the radiation induced loss in Ge doped optical fibres at different temperatures [C]. Radiation and Its Effects on Components and Systems, 1999, 483～490

[14] E. J. Friebele, M.E. Gingerich, D.L. Griscom. Survivability of optical fibers in space [C]. SPIE, 1992, 177～188

[15] Wang Xueqin, Zhang Chunxi, Jin Jing et al.. Radiation-induced attenuation effect in hydroxyl-rich pure-silica-core photonic crystal fiber [J]. Optik, 2011, 122(21): 19818～1921

[16] B. Brichard, A. F. Fernandez, H. Oomsa et al.. True dose rate enhancement effect in phosphorous doped fibre optic radiation sensors [C]. SPIE, 1990, 5502: 184～187

[17] Roger A. Greenwell, Charles E. Barnes, David M. Scott et al.. Optical fibers in the adverse space environment: the space station [C]. SPIE, 1990, 1314: 100～104

[18] J. McFadden, R. Greenwell, J. Hatch et al.. Measurements and results of gamma radiation induced attenuation at 980 nm of single mode fiber [C]. SPIE, 1996, 2811: 77～86

[19] Y. Morita, W. Kawakami. Dose rate effect on radiation induced attenuation of pure silica core optical fibers [J]. IEEE Trans. Nuclear Science, 1989, 36(1): 584～592

[20] M. N. Ott, P. Friedberg. Technology validation of optical fiber cables for space flight environments [C]. SPIE, 2001, 4216: 206～217

[21] M. C. Paul, D. Bohra, A. Dhar et al.. Radiation response behavior of high phosphorous doped step-index multimode optical fibers under low dose gamma irradiation [J]. J. Non-Cryst. Solids, 2009, 355(28-30): 1496～1507

[22] O. Deparis, J. Noel, M. Decréton. Radiation induced attenuation in SiO2/F-SiO2 fibres under low neutron flux [C]. Fourth European Conference on Radiation and Its Effects on Components and Systems,1997, 456～470

[23] M.C. Paul, R. Sen, S. K. Bhadra et al.. Radiation response behaviour of Al codoped germano-silicate SM fiber at high radiation dose [J]. Opt. Commun., 2009, 282(5): 872～878

[24] Duncan T. H. Liu, Alan R. Johnston. Theory of radiation-induced absorption in optical fibers [J]. Opt. Lett., 1994, 19(8): 548～550

[25] P. Borgermansa, B. Brichard, M. Decréton. Models for the radiation induced attenuation in pure silica optical fibres: spectral dependencies and absorption band kinetics [C]. SPIE, 2002, 4547: 53～61

[26] A. Presland, T. Wijnands, L. Jonge et al.. Gamma-ray induced optical absorption in Ge and P-doped fibres at the LHC [C]. Radiation and Its Effects on Components and Systems, 2005, PA1

[27] Wang Xueqin, Zhang Chunxi, Jin Jing. Radiation induced attenuation effect on special optical fibers applied in space [J]. Infrared and Laser Engineering, 2011, 40(11): 2516～2520

[28] David L. Griscom. Fractal kinetics of radiation-induced point-defect formation and decay in amorphous insulators: application to color centers in silica-based optical fibers [J]. Phys. Rev. B, 2001, 64(17): 174201

[29] O. Gilard, M. Caussanel, H. Duval. New model for assessing dose, dose rate, and temperature sensitivity of radiation-induced absorption in glasses [J]. J. Appl. Phys., 2010, 108(9): 093115

[30] Yin Zongmin, Li Xinwan, Yu Xiaojing. The fiber-optic filtering under γ-radiation [J]. J. Shanghai Jiaotong University, 1995, 29(6): 88～90