[1] 汪柯红， 余洋， 王洋， 等. 空芯光纤的双机理温度传感特性比较［J］. 光子学报， 2022， 51（11）： 1106001.WANGK H， YUY， WANGY， et al. Comparative study on temperature sensing characteristics of dual mechanisms in hollow core fiber［J］. Acta Photonica Sinica， 2022， 51（11）： 1106001.（in Chinese）

[2] 蔡礼邹， 覃亚丽， 蔡小磊， 等. 基于游标原理的法布里-珀罗温度传感器的增敏方法［J］. 激光与光电子学进展， 2021， 58（11）： 1106004. doi: 10.3788/LOP202158.1106004CAIL Z， QINY L， CAIX L， et al. Sensitization method of Fabry-Perot temperature sensor based on vernier principle［J］. Laser & Optoelectronics Progress， 2021， 58（11）： 1106004.（in Chinese）. doi: 10.3788/LOP202158.1106004

[3] 郭海若， 刘琨， 江俊峰， 等. 基于可调谐激光器的光纤高低温力热复合多参量传感系统［J］. 中国激光， 2021， 48（19）： 1906003. doi: 10.3788/CJL202148.1906003GUOH R， LIUK， JIANGJ F， et al. Optical Fiber high and low temperature mechanical and thermal multi-parameter sensing system based on tunable laser［J］. Chinese Journal of Lasers， 2021， 48（19）： 1906003.（in Chinese）. doi: 10.3788/CJL202148.1906003

[4] 苏杭， 赵纯龙， 张钊溶， 等. 基于三种不同微腔状态的F-P干涉型高灵敏度温度传感器［J］. 光子学报， 2021， 50（9）： 0906007. doi: 10.3788/gzxb20215009.0906007SUH， ZHAOC L， ZHANGZ R， et al. High sensitivity fabry-Pérot interferometric temperature sensor based on three different microcavity states［J］. Acta Photonica Sinica， 2021， 50（9）： 0906007.（in Chinese）. doi: 10.3788/gzxb20215009.0906007

[5] 杨泓铭， 饶春芳， 吴锴， 等. 基于光纤布拉格光栅的压力蒸汽灭菌器气体质量监测［J］. 光学 精密工程， 2022， 30（3）： 264-273. doi: 10.37188/OPE.2021.0284YANGH M， RAOC F， WUK， et al. Gas quality monitoring for sterilizer based on fiber Bragg grating［J］. Opt. Precision Eng.， 2022， 30（3）： 264-273.（in Chinese）. doi: 10.37188/OPE.2021.0284

[6] 吴根柱， 林春婷， 卢俊城， 等. 七芯光子晶体光纤温度传感器［J］. 光学 精密工程， 2021， 29（5）： 951-957. doi: 10.37188/OPE.2020.0662WUG Z， LINC T， LUJ C， et al. Seven-core photonic crystal fiber temperature sensor［J］. Opt. Precision Eng.， 2021， 29（5）： 951-957. （in Chinese）. doi: 10.37188/OPE.2020.0662

[7] 薛兆康， 国旗， 刘善仁， 等. 油气井下光纤光栅温度压力传感器［J］. 中国光学， 2021， 14（5）： 1224-1230.XUEZ K， GUOQ， LIUS R， et al. Fiber Bragg grating temperature and pressure sensor for oil and gas well［J］. Chinese Journal of Optics， 2021， 14（5）： 1224-1230.（in Chinese）

[8] L Q XIE, B SUN, M M CHEN et al. Sensitivity enhanced temperature sensor with serial tapered two-mode fibers based on the Vernier effect. Optics Express, 28, 32447(2020).

[9] J ZHANG, H LIAO, P LU et al. Ultrasensitive temperature sensor with cascaded fiber optic Fabry-Perot interferometers based on vernier effect. IEEE Photonics Journal, 10, 1-11(2018).

[10] H GAO, H HU, Y ZHAO et al. Highly-sensitive optical fiber temperature sensors based on PDMS/silica hybrid fiber structures. Sensors and Actuators A： Physical, 284, 22-27(2018).

[11] J W LI, M ZHANG, M G WAN et al. Ultrasensitive refractive index sensor based on enhanced Vernier effect through cascaded fiber core-offset pairs. Optics Express, 28, 4145-4155(2020).

[12] P M R ROBALINHO, A D GOMES, O FRAZÃO. High enhancement strain sensor based on vernier effect using 2-fiber loop mirrors. IEEE Photonics Technology Letters, 32, 1139-1142(2020).

[14] 郭云， 陈圣林， 王平， 等. 基于游标效应的温度不敏感光纤拉力传感器［J］. 光子学报， 2022， 51（12）： 1206003.GUOY， CHENS L， WANGP， et al. Temperature-insensitive optical fiber tension sensor based on vernier effect［J］. Acta Photonica Sinica， 2022， 51（12）： 1206003.（in Chinese）

[15] R PAN, W L YANG, L J LI et al. A high-sensitive fiber-optic fabry-perot sensor with parallel polymer-air cavities based on vernier effect for simultaneous measurement of pressure and temperature. IEEE Sensors Journal, 21, 21577-21585(2021).

[16] H SU, L GAO, Z ZHANG et al. Optical fiber temperature sensor with Vernier effect formed by Mach-Zehnder interferometer cascaded Sagnac interferometer based on Hollow-core photonic crystal fiber. Photonics and Nanostructures-Fundamentals and Applications, 52, 101085(2022).

[17] C P LANG, Y LIU, Y Y LIAO et al. Ultra-sensitive fiber-optic temperature sensor consisting of cascaded liquid-air cavities based on vernier effect. IEEE Sensors Journal, 20, 5286-5291(2020).

[18] W LUO, Z CAO, G ZHANG et al. A highly sensitive optical fiber temperature sensor based on the enhanced vernier effect. Optical Fiber Technology, 67, 102702(2021).

[19] X P ZHU, C JIANG, H L CHEN et al. Highly sensitive gas pressure sensor based on the enhanced Vernier effect through a cascaded Fabry-Perot and Mach-Zehnder interferometer. Optics Express, 30, 34956(2022).

[20] X G MU, J L GAO, Y Q YANG et al. Parallel polydimethylsiloxane-cavity fabry-perot interferometric temperature sensor based on enhanced vernier effect. IEEE Sensors Journal, 22, 1333-1337(2022).

[21] H GAO, Y X ZHANG, W G ZHANG et al. High sensitivity optical fiber temperature sensor based on PDMS-filled with extended measuring range. Optik, 248, 168181(2021).

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

[23] Y Q YANG, Y G WANG, Y X ZHAO et al. Sensitivity-enhanced temperature sensor by hybrid cascaded configuration of a Sagnac loop and a F-P cavity. Optics Express, 25, 33290(2017).

[24] W ZHANG, X WU, C ZUO et al. Highly sensitive temperature and strain sensor based on fiber Sagnac interferometer with Vernier effect. Optics Communications, 506, 127543(2022).

[25] 周豫， 周雪芳， 樊冰， 等. 基于Vernier效应的光纤温度传感特性研究［J］. 光电子·激光， 2020， 31（4）： 345-350.ZHOUY， ZHOUX F， FANB， et al. Research of fiber temperature sensing characteristics based on vernier effect［J］. Journal of Optoelectronics·Laser， 2020， 31（4）： 345-350.（in Chinese）

[26] M L DAI, Z M CHEN, Y F ZHAO et al. Fiber optic temperature sensor with online controllable sensitivity based on vernier effect. IEEE Sensors Journal, 21, 21555-21563(2021).

[27] R PAN, M LIU, Y BIAN et al. High-sensitive temperature sensor with parallel PDMS-filled FPIs based on dual Vernier effect. Optics Communications, 518, 128284(2022).