Acta Photonica Sinica, Volume. 51, Issue 10, 1006002(2022)

Progress in Research of Optical Fiber High Temperature and Strain Sensor(Invited)

Hangzhou YANG... Xin LIU, Pengyu NAN and Guoguo XIN* |Show fewer author(s)
Author Affiliations
  • School of Physics,Northwest University,Xi′an710069,China
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    Figures & Tables(15)
    Schematic diagram of the dual RFBG sensor structure[17]
    Schematic diagram of multi-mode FBG structure[18]
    Schematic diagram of cascaded RFBG sensor structure[23]
    Schematic diagram of the sensor structure of the FPI cascaded RFBG[39]
    Micrograph of the FPI sensor based on CDF[42]
    Schematic diagram of the sensor structure[43]
    Schematic diagram of the FPI cascaded with RFBG sensor structure[44]
    Schematic diagram of the FPI sensor structure based on PCF[45]
    Schematic diagram of the sensor structure based on double FPIs[46]
    Micrograph of the FPI sensor based on bubble cavity[47]
    Schematic diagram of the FPI sensor structure based on HACF[48]
    Schematic diagram of the FPI sensor structure[50]
    Schematic diagram of the sensor package base[60]
    • Table 1. Comparison of measurement parameters of FBG type high temperature and strain sensor 1113-151720-23

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      Table 1. Comparison of measurement parameters of FBG type high temperature and strain sensor 1113-151720-23

      YearSensor structure

      Temperature

      range

      Temperature

      sensitivity

      Strain

      range

      Strain

      sensitivity

      Temperature compensationRef.
      2009CCG24~900 ℃13.8 pm/℃0~1 000 με1.1 pm/μεNo11
      2010Long-period FBG25~700 ℃163 pm/℃0~15 000 με0.31 pm/μεNo13
      2014Etched RFBG24~800 ℃12.2 pm/℃0~1 000 με4.5 pm/μεNo14
      2015Cascaded RFBG25~900 ℃15.2 pm/℃0~1 000 με0.81 pm/μεNo15
      2017Double RFBG20~800 ℃16.3 pm/℃0~1 000 με1.57 pm/μεNo17
      2018Sapphire FBG26~1 600 ℃34.96 pm/℃0~1 300 με1.45 pm/μεNo20
      2019Dual FBG100~800 ℃12.5 pm/℃0~1 000 με3.25 pm/μεNo21
      2020Off-axis FBG23~300 ℃12 pm/℃0~522 με1.44 pm/μεNo22
      2022Two RFBG100~1 000 ℃15.7 pm/℃0~120 με5.46 pm/μεYes23
    • Table 2. Comparison of measurement parameters of optical fiber FPI type high temperature and strain sensor 333739-404244-46

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      View in Article

      Table 2. Comparison of measurement parameters of optical fiber FPI type high temperature and strain sensor 333739-404244-46

      YearSensor structure

      Temperature

      range

      Temperature

      sensitivity

      Strain

      range

      Strain

      sensitivity

      Temperature compensationRef.
      2009HCPCF FPI100~700 ℃163.55 pm/℃0~414 με5.94 nm/μεNo33
      2014EFPI-FBG25~500 ℃13.6 pm/℃0~10 000 με46 nm/μεYes37
      2016FPI-RFBG19~600 ℃13.97 pm/℃0~600 με1.23 pm/μεNo39
      2018FPI-FBG25~500 ℃15.2 pm/℃0~650 με0.81 pm/μεNo40
      2019CDF FPI20~1 200 ℃15.6 pm/℃0~2 000 με1.5 pm/μεNo42
      2020RFBG-FPI100~1 000 ℃18.01 pm/℃0~450 με2.17 pm/μεYes44
      2021PCF FPI28~1 100 ℃426.7 pm/℃0~9 436.66 με25.1 pm/μεNo45
      2022Double FPIs26~1 000 ℃15.14 pm/℃0~350 με127.32 pm/μεYes46
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    Hangzhou YANG, Xin LIU, Pengyu NAN, Guoguo XIN. Progress in Research of Optical Fiber High Temperature and Strain Sensor(Invited)[J]. Acta Photonica Sinica, 2022, 51(10): 1006002

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    Paper Information

    Category: Fiber Optics and Optical Communications

    Received: Jul. 18, 2022

    Accepted: Oct. 9, 2022

    Published Online: Nov. 30, 2022

    The Author Email: XIN Guoguo (xinguo@nwu.edu.cn)

    DOI:10.3788/gzxb20225110.1006002

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