[1] T. G. Liu, S. Wang, J. F. Jiang, K. Liu, and J. D. Yin, “Research progress of optical fiber sensing technology in aerospace,” Chinese Journal of Scientific Instrument, 2014, 35(8): 1681–1692.
[2] H. Y. Deng, Y. J. Rao, Z. L. Ran, X. Liao, and W. J. Liu, “Photonic crystal fiber based Fabry-Perot sensor fabricated by using 157nm laser micromachining,” Acta Optica Sinica, 2008, 28(2): 255–258.
[3] F. C. Favero, L. Araujo, G. Bouwmans, V. Finazzi, J. Villatoro, and V. Pruneri, “Spheroidal Fabry-Perot microcavities in optical fibers for high-sensitivity sensing,” Optics Express, 2012, 20(7): 7112–7118.
[4] S. Liu, Y. P. Wang, C. R. Liao, Z. Y. Li, and K. M. Yang, et al. “High-sensitivity strain sensors based on in-fiber reshaped air bubbles,” in Fifth Asia Pacific Optical Sensors Conference, Korea, May 20–22, 2015, pp. 96550A-1–96550A-4.
[5] Y. H. Li, M. W. Yang, C. R. Liao, D. N. Wang, J. Lu, and P. X. Lu, “Prestressed fiber Bragg grating with high temperature stability,” Journal of Lightwave Technology, 2011, 29(10): 1555–1559.
[6] W. Q. Niu, Y. Y. Ma, Y. Wu, Z. L. Yuan, Y. Gong, and Y. J. Rao, “Non-gel encapsulation process of a high temperature strain fiber Bragg grating sensor and its sensing properties,” Chinese Journal of Sensors and Actuators, 2013, 26(7): 927–931.
[7] X. R. Dong, Z. Xie, Y. X. Song, K. Yin, D. K. Chu, and J. A. Duan, “High temperature-sensitivity sensor based on long period fiber grating inscribed with femtosecond laser transversal-scanning method,” Chinese Optics Letters, 2017, 15(9): 51–55.
[8] H. Zhang, J. Z. Jiang, S. Liu, H. X. Chen, X. Q. Zheng, and Y. S. Qiu, “Overlap spectrum fiber Bragg grating sensor based on light power demodulation,” Sensors, 2018, 18(5): 1597-1–1597-11.
[9] D. Grobnic, S. J. Mihailov, C. W. Smelser, and H. M. Ding, “Sapphire fiber Bragg grating sensor made using femtosecond laser radiation for ultrahigh temperature applications,” IEEE Photonics Technology Letters, 2004, 16(11): 2505–2507.
[10] L. A. Ferreira, J. L. Santos, and F. Farahi, “Pseudoheterodyne demodulation technique for fiber Bragg grating sensors using two matched gratings,” IEEE Photonics Technology Letters, 1997, 9(4): 487–489.
[11] B. Q. Jiang, J. L. Zhao, C. Qin, and Z. Huang, and F. Fan. “An optimized strain demodulation method based on dynamic double matched fiber Bragg grating filtering,” Optics and Lasers in Engineering, 2011, 49(3): 415–418.
[12] Z. A. Jia, J. Liu, X. G. Qiao, T. Wei, H. Gao, and H. F. Feng, “A demodulation technology based on digital tunable F-P filter for fiber Bragg grating sensing signals,” Journal of Optoelectronics. Laser, 2011, 5(5): 649–651.
[13] Q. Y. Li, Y. L. Xiong, Y. Xia, M. Z. Wu, J. Y. Zou, and Z. Y. Ma, “The simulation of FBG demodulation system based on the tunable F-P filter,” in Proceedings of 2013 2nd International Conference on Measurement, Information and Control, China, Aug. 16–18, 2013, pp. 337–340.
[14] M. A. Davis and A. D. Kersey, “All-fibre Bragg grating strain-sensor demodulation technique using a wavelength division coupler,” Electronics Letters, 1994, 30(1): 75–77.
[15] Y. L. Yu, H. Y. Tam, and W. H. Chung, “A fiber Bragg grating sensor system with interferometric demodulation technique,” Acta Optica Sinca, 2001, 21(8): 987–989.
[16] D. D. Pang, Q. M. Sui, and M. S. Jiang, “New fiber Bragg grating high temperature sensing network based on diffraction demodulation,” Chinese Journal of Lasers, 2011, 38(11): 174–179.
[17] Z. W. Feng and L. Zhang, “Demodulation technique based on diffraction optical elements for fiber Bragg grating sensing system,” in Photonics Asia 2010, China, Oct. 17–20, 2010, pp: 78530I-1–78530I-9.
[18] I. V. Ciapurin, L. B. Glebov, and V. I. Smirnov, “Spectral combining of high-power fiber laser beams using Bragg grating in PTR glass,” in Lasers and Applications in Science and Engineering, United States, Jan. 25–29, 2004, pp. 116–124.