[1] [1] ARREGUI F J, MATAS I R, COOPER K L, et al. Simultaneous measurement of humidity and temperature by combining a reflective intensity-based optical fiber sensor and a fiber Bragg grating［J］. IEEE Sensors Journal, 2002,2(5):482-487.

[2] [2] PECORELLA C, CIRILLO A, SICILIANO B, et al. Robot-aided prostate cancer diagnosis with fiber optic sensing: A validation study on phantoms and ex-vivo tissues［J］. Uro, 2021,1(4):245-253.

[3] [3] SALVO P, CALISI N, MELAI B, et al. Temperature and pH sensors based on graphenic materials［J］. Biosensors and Bioelectronics, 2017,91:870-877.

[4] [4] OZBEY B, UNAL E, ERTUGRUL H, et al. Wireless displacement sensing enabled by metamaterial probes for remote structural health monitoring［J］. Sensors, 2014,14(1):1691-1704.

[5] [5] QIN J, CHAO K, KIM M S. Raman chemical imaging system for food safety and quality inspection［J］. Transactions of the ASABE, 2010,53(6):1873-1882.

[6] [6] NOVAIS S, NASCIMENTO M, GRANDE L, et al. Internal and external temperature monitoring of a Li-ion battery with fiber Bragg grating sensors［J］. Sensors, 2016,16(9):1394.

[7] [7] NASCIMENTO M, FERREIRA M S, PINTO J L. Real time thermal monitoring of lithium batteries with fiber sensors and thermocouples: A comparative study［J］. Measurement, 2017,111:260-263.

[8] [8] QIAN S, CHEN X, JIANG S, et al. Plasmonic fiber-optic sensing system for in situ monitoring the capacitance and temperature of supercapacitors［J］. Optics Express, 2022,30(15):27322-27332.

[9] [9] LIU Y, LIU Z, MEI W, et al. Operando monitoring Lithium-ion battery temperature via implanting femtosecond-laser-inscribed optical fiber sensors［J］. Measurement, 2022,203:111961.

[10] [10] YANG G, LEITO C, LI Y, et al. Real-time temperature measurement with fiber Bragg sensors in lithium batteries for safety usage［J］. Measurement, 2013,46(9):3166-3172.

[11] [11] OSUCH T, JUREK T, MARKOWSKI K, et al. Simultaneous measurement of liquid level and temperature using tilted fiber Bragg grating［J］. IEEE Sensors Journal, 2015,16(5):1205-1209.

[12] [12] DAS A K, LEE H, NODA K, et al. Potential of mechanically induced cascaded long-period grating structure for reflectometric pressure, strain, and temperature sensing［J］. IEEE Sensors Journal, 2020, 20(18):10539-10546.

[13] [13] LIU Y, QU S, LI Y. Single microchannel high-temperature fiber sensor by femtosecond laser-induced water breakdown［J］. Optics letters, 2013,38(3):335-337.

[14] [14] RONG Q, SUN H, QIAO X, et al. A miniature fiber-optic temperature sensor based on a Fabry-Prot interferometer［J］. Journal of Optics, 2012,14(4):045002.

[15] [15] LI M, LIU Y, GAO R, et al. Ultracompact fiber sensor tip based on liquid polymer-filled Fabry-Prot cavity with high temperature sensitivity［J］. Sensors and Actuators B: Chemical, 2016,233:496-501.

[16] [16] CHEN M, ZHAO Y, XIA F, et al. High sensitivity temperature sensor based on fiber air-microbubble Fabry-Prot interferometer with PDMS-filled hollow-core fiber［J］. Sensors and Actuators A: Physical, 2018, 275:60-66.

[17] [17] DENG M, TANG C P, ZHU T, et al. PCF-based Fabry-Prot interferometric sensor for strain measurement at high temperatures［J］. IEEE Photonics Technology Letters, 2011, 23(11):700-702.

[18] [18] RAN Z L, RAO Y J, LIU W J, et al. Laser-micromachined Fabry-Prot optical fiber tip sensor for high-resolution temperature-independent measurement of refractive index［J］. Optics Express, 2008, 16(3):2252-2263.

[19] [19] WEI T, HAN Y, LI Y, et al. Temperature-insensitive miniaturized fiber inline Fabry-Prot interferometer for highly sensitive refractive index measurement［J］. Optics Express, 2008,16(8):5764-5769.

[20] [20] LIANG J, LI X, LI J, et al. High-temperature-sensitive and spectrum-contrast-enhanced sensor using a bullet-shaped fiber cavity filled with PDMS［J］. Optics Express, 2022,30(8):12316-12325.