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    Journals >Laser & Optoelectronics Progress >Volume 58 >Issue 17 >Page 1706007 > Article
    • Laser & Optoelectronics Progress
    • Vol. 58, Issue 17, 1706007 (2021)
    Optical Fiber Torsion Sensor Based on Pre-Twisted Polarization-Maintaining Fiber Sagnac Loop Mirror Structure
    Zhuo Song, Yichun Li, Jinpeng Wei, and Junhui Hu*
    Author Affiliations
  • College of Physical Science and Technology, Guangxi Normal University, Guilin , Guangxi 541004, China
    • show less
    DOI: 10.3788/LOP202158.1706007 Cite this Article Set citation alerts
    Zhuo Song, Yichun Li, Jinpeng Wei, Junhui Hu. Optical Fiber Torsion Sensor Based on Pre-Twisted Polarization-Maintaining Fiber Sagnac Loop Mirror Structure[J]. Laser & Optoelectronics Progress, 2021, 58(17): 1706007 Copy Citation Text show less
    Experimental setup. (a) Picture of real products; (b) schematic diagram
    Fig. 1. Experimental setup. (a) Picture of real products; (b) schematic diagram
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    Cross section and horizontal coordinate of optical fiber structure. (a) Cross section; (b) horizontal coordinate
    Fig. 2. Cross section and horizontal coordinate of optical fiber structure. (a) Cross section; (b) horizontal coordinate
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    Transmission spectrum and corresponding FFT figure of sensing structure with and without pre-twist. (a) Without pre-twist process; (b) with pre-twist process
    Fig. 3. Transmission spectrum and corresponding FFT figure of sensing structure with and without pre-twist. (a) Without pre-twist process; (b) with pre-twist process
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    Response diagram and fitting diagram of dip to the torsion without pre-twist process. (a) Spectra shift with the change of the torsion; (b) wavelength and power fitting diagram of the dip to torsion
    Fig. 4. Response diagram and fitting diagram of dip to the torsion without pre-twist process. (a) Spectra shift with the change of the torsion; (b) wavelength and power fitting diagram of the dip to torsion
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    Response diagram and fitting diagram of dip to the clockwise torsion with pre-twist process. (a) Spectra shift with the clockwise twisting in the range of 0°‒30°;(b)wavelength and power fitting diagram of the dip to torsion
    Fig. 5. Response diagram and fitting diagram of dip to the clockwise torsion with pre-twist process. (a) Spectra shift with the clockwise twisting in the range of 0°‒30°;(b)wavelength and power fitting diagram of the dip to torsion
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    Response diagram and fitting diagram of dip to the counter-clockwise torsion with pre-twist process. (a) Spectra shift with the counter-clockwise twisting in the range of 0°~-30°;(b)wavelength and power fitting diagram of the dip to torsion
    Fig. 6. Response diagram and fitting diagram of dip to the counter-clockwise torsion with pre-twist process. (a) Spectra shift with the counter-clockwise twisting in the range of 0°~-30°;(b)wavelength and power fitting diagram of the dip to torsion
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    Response diagram and fitting diagram of dip to the temperature with pre-twist process. (a) Spectra shift with the temperature change in the range of 25 ℃ to 65 ℃;(b)wavelength and intensity of the resonant dip change with the temperature change
    Fig. 7. Response diagram and fitting diagram of dip to the temperature with pre-twist process. (a) Spectra shift with the temperature change in the range of 25 ℃ to 65 ℃;(b)wavelength and intensity of the resonant dip change with the temperature change
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    Sensor structureSensitivityDirection discriminationReference
    LPG and TFBG1.074 dB·rad-1·mNO6
    FM-TFBG and FM-FBG0.16 dB/(°)YES7
    PM-PCF0.014 dB/(°)NO9
    Square-NCF1.28615 nm·rad-1·mNO10
    Taper-PMF2.392 nm·rad-1·mYES11
    PC with PMF0.29 dB/(°)NO12
    MMF-SCF-MMF0.118 nm·rad-1·mYES13
    MMF-SCF-MMF400 pm·rad-1·mYES14
    HB-PCF in Sagnac0.059 nm·rad-1·mYES15
    SLPCF in Sagnac0.9354 nm/(°)YES16
    HCF with Pb0.1 dB/(°)NO17
    MMF-PMF(pre-twist)-MMF

    455 pm·rad-1·m

    2.20 dB·rad-1·m

    		YESThis work
    Table 1. Performance comparison of the reported torsion sensors
    Abstract
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    References (18)
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    Zhuo Song, Yichun Li, Jinpeng Wei, Junhui Hu. Optical Fiber Torsion Sensor Based on Pre-Twisted Polarization-Maintaining Fiber Sagnac Loop Mirror Structure[J]. Laser & Optoelectronics Progress, 2021, 58(17): 1706007
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    Paper Information
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