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Laser & Optoelectronics Progress, Volume. 60, Issue 11, 1106007(2023)

Research on Distributed Fiber Temperature/Strain/Shape Sensing Based on OFDR

Cailing Fu1,2, Zhenwei Peng1,2, Pengfei Li1,2, Yanjie Meng1,2, Huajian Zhong1,2, Chao Du1,2, and Yiping Wang1,2,3、*
Author Affiliations
  • 1Shenzhen Key Laboratory of Photonic Devices and Sensing Systems for Internet of Things, Guangdong and Hong Kong Joint Research Centre for Optical Fiber Sensors, State Key Laboratory of Radio Frequency Heterogeneous Integration, Shenzhen University, Shenzhen 518060, Guangdong, China
  • 2Shenzhen Key Laboratory of Ultrafast Laser Micro/Nano Manufacturing, Key Laboratory of Optoelectronic Devices and Systems of Ministry of Education/Guangdong Province, College of Physics and Optoelectronic Engineering, Shenzhen University, Shenzhen 518060, Guangdong, China
  • 3Guangdong Laboratory of Artificial Intelligence and Digital Economy (Shenzhen), Shenzhen 518107, Guangdong, China
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    References (48)
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    Figures & Tables(11)
    Schematic diagram of frequency modulated continuous wave interferometer. (a) Michelson interferometer structure; (b) laser linear sweep light

    Fig. 1. Schematic diagram of frequency modulated continuous wave interferometer. (a) Michelson interferometer structure; (b) laser linear sweep light

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    Rayleigh scattering of standard single-mode fibers is enhanced by UV laser exposure[17]. (a) Schematic diagram of exposure area of UV laser exposure method; (b) Gain spectrum of Rayleigh scattering enhanced single mode fiber with optimal exposure parameters

    Fig. 2. Rayleigh scattering of standard single-mode fibers is enhanced by UV laser exposure[17]. (a) Schematic diagram of exposure area of UV laser exposure method; (b) Gain spectrum of Rayleigh scattering enhanced single mode fiber with optimal exposure parameters

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    Fabrication of weak scattering point array (WSPA) in SMF using femtosecond laser self-focusing technique[11]. (a) Schematic diagram of WSPA processing; (b) obtained Rayleigh scattering enhanced spectrum of WSPA

    Fig. 3. Fabrication of weak scattering point array (WSPA) in SMF using femtosecond laser self-focusing technique[11]. (a) Schematic diagram of WSPA processing; (b) obtained Rayleigh scattering enhanced spectrum of WSPA

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    Fabrication of weak scattering point array (WSPA) in each core of multicore fiber using femtosecond laser self-focusing technique[18]

    Fig. 4. Fabrication of weak scattering point array (WSPA) in each core of multicore fiber using femtosecond laser self-focusing technique[18]

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    Micro-cavity arrays fabricated by femtosecond laser micro-machining technology[19]

    Fig. 5. Micro-cavity arrays fabricated by femtosecond laser micro-machining technology[19]

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    Fabrication of weak fiber Bragg grating (WFBG) array in SMF using femtosecond laser technology[22]. (a) Distance domain spectra of 200 identical WFBG; (b) enlarged view of the 89th to 92nd grating

    Fig. 6. Fabrication of weak fiber Bragg grating (WFBG) array in SMF using femtosecond laser technology22. (a) Distance domain spectra of 200 identical WFBG; (b) enlarged view of the 89th to 92nd grating

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    Zero crossing resampling(ZCR) method and instantaneous optical frequency domain(IOFR) method eliminate nonlinear frequency sweep of light source[30]. (a) Schematic diagram of ZCR method; (b) schematic diagram of IOFR method; (c) obtained Rayleigh scattering spectra of optical fiber under test using uncompensated method, zero-crossing resampling method and instantaneous optical frequency resampling method

    Fig. 7. Zero crossing resampling(ZCR) method and instantaneous optical frequency domain(IOFR) method eliminate nonlinear frequency sweep of light source[30]. (a) Schematic diagram of ZCR method; (b) schematic diagram of IOFR method; (c) obtained Rayleigh scattering spectra of optical fiber under test using uncompensated method, zero-crossing resampling method and instantaneous optical frequency resampling method

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    Flow chart of the post-processing method based on combining distance compensation and image wavelet denoising[7]

    Fig. 8. Flow chart of the post-processing method based on combining distance compensation and image wavelet denoising[7]

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    Distributed high temperature sensing based on obtained weak micro-cavity array (WMCA)[19]. (a) Schematic of WMCA placed in the tube furnace; (b) measured optical frequency shift of WMCA with temperature change;(c)temperature variation in areas from 2.50 to 2.55 m

    Fig. 9. Distributed high temperature sensing based on obtained weak micro-cavity array (WMCA)[19]. (a) Schematic of WMCA placed in the tube furnace; (b) measured optical frequency shift of WMCA with temperature change;(c)temperature variation in areas from 2.50 to 2.55 m

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    Distributed strain sensing based on standard single-mode fiber and UV-exposed Rayleigh scattering enhanced fiber[17]. (a) Standard single-mode fiber strain sensing; (b)UV-exposed Rayleigh scattering enhanced fiber strain sensing

    Fig. 10. Distributed strain sensing based on standard single-mode fiber and UV-exposed Rayleigh scattering enhanced fiber[17]. (a) Standard single-mode fiber strain sensing; (b)UV-exposed Rayleigh scattering enhanced fiber strain sensing

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    Multi-core fiber 3D shape sensing technology based on vector projection[18]

    Fig. 11. Multi-core fiber 3D shape sensing technology based on vector projection[18]

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    Cailing Fu, Zhenwei Peng, Pengfei Li, Yanjie Meng, Huajian Zhong, Chao Du, Yiping Wang. Research on Distributed Fiber Temperature/Strain/Shape Sensing Based on OFDR[J]. Laser & Optoelectronics Progress, 2023, 60(11): 1106007

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    Paper Information

    Category: Fiber Optics and Optical Communications

    Received: Feb. 27, 2023

    Accepted: Apr. 7, 2023

    Published Online: Jun. 5, 2023

    The Author Email: Wang Yiping (ypwang@szu.edu.cn)

    DOI:10.3788/LOP230701

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology