[1] [1] 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.

[2] [2] LIU L H, ZHANG X J, LI K W, et al. Ultrasensitive detection of endocrine disruptors via superfine plasmonic spectral combs [J]. Light Sci Appl, 2021, 10(1): 181.

[3] [3] 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.

[4] [4] CHAO K L, DHAKAL S, QIN J W, et al. A 1064 nm dispersive Raman spectral imaging system for food safety and quality evaluation [J]. Applied Sciences, 2018, 8(3): 431.

[5] [5] AGARWAL A, VENKATAKRISHNA K, TAN B, et al. Cellular DNA based cancer diagnosis using self-internalized plasmonic sensors [J]. Sensors and Actuators B: Chemical, 2020, 321:128496.

[6] [6] SU Y D, PREGER Y, BURROUGHS H, et al. Fiber optic sensing technologies for battery management systems and energy storage applications [J]. Sensors, 2021, 21(4): 1397.

[7] [7] SOMMER L W, RAGHAVAN A, KIESEL P, et al. Embedded fiber optic sensing for accurate state estimation in advanced battery management systems [J]. MRS Proc, 2014, 1681: mrss14-1681-q01-03.

[8] [8] YU Y F, VERGORI E, MADDAR F, et al. Real-time monitoring of internal structural deformation and thermal events in lithium-ion cell via embedded distributed optical fiber [J]. Journal of Power Sources, 2022, 521:230957.

[9] [9] RAGHAVAN A, KIESEL P, SOMMER L W, et al. Embedded fiber-optic sensing for accurate internal monitoring of cell state in advanced battery management systems part 1: Cell embedding method and performance [J]. Journal of Power Sources, 2017, 341: 466-473.

[10] [10] GANGULI A, SAHA B, RAGHAVAN A, et al. Embedded fiber-optic sensing for accurate internal monitoring of cell state in advanced battery management systems part 2: Internal cell signals and utility for state estimation [J]. Journal of Power Sources, 2017, 341: 474-482.

[11] [11] RAGHAVAN A, SOMMER L W, KIESEL P, et al. Embedded fiber optic chemical sensing for internal cell side-reaction monitoring in advanced battery management systems [J]. MRS Proc, 2014, 1681: mrss14-1681-q01-07.

[14] [14] SONG X, HOU L, WEI X, et al. High sensitivity fiber gas pressure sensor with two separated Fabry-Prot interferometers based on the vernier effect [J]. Photonics, 2022, 9: 31.

[15] [15] ZHAO Y J, LIU J X, LI H, et al. An ultra-sensitive gas pressure sensor based on tapered fiber coated with PDMS film working at TAP [J]. Optics & Laser Technology,2022, 151: 107998.

[16] [16] ZHOU X L, YU Q X, PENG W. Fiber-optic Fabry-Prot pressure sensor for down-hole application [J]. Optics and Lasers in Engineering, 2019, 121:289-299.

[17] [17] CUI Q S, THAKUR P, RABLAU C, et al. Miniature optical fiber pressure sensor with exfoliated graphene diaphragm [J]. IEEE Sensors, 2019, 19(14):5621-5631.

[18] [18] LIU S, WANG Y P, LIAO C R, et al. Nano silica diaphragm in-fiber cavity for gas pressure measurement [J]. Sci Rep, 2017, 7(1):787.

[19] [19] LIU Q P, WANG D Y, WANG C F, et al. Research on highly sensitive Fabry-Prot cavity sensing technology in frozen soil [J]. Optoelectron Lett, 2023, 19(4): 205-209.

[20] [20] XU B, LIU Y M, WANG D N, et al. Fiber Fabry-Prot interferometer for measurement of gas pressure and temperature [J]. Lightwave Technol, 2016, 34(21):4920-4925.

[21] [21] MA J, JU J, JIN L, et al. A compact fiber-tip micro-cavity sensor for high-pressure measurement [J]. IEEE Photon Technol Lett, 2011, 23(21): 1561-1563.

[22] [22] SCHWART J, ARAKAKI K, KIESEL P, et al. Embedded fiber optic sensors for in situ and in-operando monitoring of advanced batteries [J]. MRS Proc, 2018, 1740: mrsf14-1740-z01-08.