Opto-Electronic Engineering, Volume. 49, Issue 9, 220021(2022)
Recent progress in optical fiber sensing based on forward stimulated Brillouin scattering
Figures & Tables(21)
Fig. 1. Phase matching. (a) Backward stimulated Brillouin scattering; (b) Forward stimulated Brillouin scattering
Fig. 2. Dispersion relation of R0,m-induced F-SBS. The bule solid lines represented the dispersion curve of acoustic waves, and the red one represented which of light wave. The shade of blue lines means the intensity of F-SBS.
Fig. 3. Transverse displacement profiles. (a) Radial mode R0,5; (b) Torsional-radial mode TR2,5
Fig. 7. The experimental set-up of F-SBS measurement based on SI. The excitation and probe light are separated by their different wavelengths[39]
Fig. 8. F-SBS in multi-core fiber. (a), (b) Transverse displacement profiles of modes R0,7 and R0,8; (c), (d) F-SBS spectrums measured in the inner core and outer core. The excitation light propagates in the inner core[43]
Fig. 9. F-SBS in polarization maintaining fiber. (a) Experimental set-up; (b) Measured F-SBS spectrums. The red trace is measured when the excitation light propagating in the fast axis, and probe in the slow axis; The black trace is measured in the opposite situation[41]
Fig. 10. F-SBS demodulation by LPG. (a) Schematic diagram; (b) Experimental set-up[45]
Fig. 11. Distributed F-SBS sensor based on local light phase recovery. The excitation and probe pulses are not only separated by wavelength, but also by time[36]
Fig. 12. Distributed F-SBS sensor based on local light phase recovery. (a) Distributed light intensity of 0, +1 and +2-order sidebands; (b) Phase accumulation along the fiber; (c) Distributed phase shift demodulated by differentiation; (d)~(f) Distributed F-SBS spectrums measured when the fiber under test placed in air, ethanol, and water[36]
Fig. 13. Principle of OMTDR. The energy transferred between the dual-frequency components of the pulses, and their Rayleigh scattering lights are used to demodulation[47]
Fig. 14. Distributed sensing results of OMTDR. (a)~(c) are the distributed F-SBS spectrums measured when the fiber under test placed in air, ethanol, and water[47]
Fig. 17. Distributed results of OMTDA. (a) The energy transfer process along the fiber; (b) Distributed F-SBS gain spectrum[48]
Fig. 18. Results of acoustic impedance sensing. (a) The linewidth of spectrums along the fiber; (b) F-SBS spectrums measured in air and ethanol[48]
Fig. 19. Results of distributed diameter measurements[12]. (a) Diameter distribution before and after etching and its comparison with the SEM results (A-F); (b) Diameter variations along the FUT; (c) Representative images of the fiber cross section at A, B, C and E captured by SEM
Fig. 20. (a) Experimental setup for polarization separation assisted OMTDA; (b) Temporal trace and frequency components of activation and probing pulses[49]
Table 1. Acoustic impedance and F-SBS spectrum width of common substances
View tableView in ArticleTable 1. Acoustic impedance and F-SBS spectrum width of common substances
物质名称 声阻抗/(kg·m−2·s−1) F-SBS谱宽/MHz 数据来源 空气 439.6 0.45 [ 35 ]酒精 0.93×106 2.21 [ 35 ]水 1.483×106 3.57 [ 36 ]NaCl溶液(4%) 1.571×106 3.78 [ 11 ]NaCl溶液(8%) 1.664×106 4.00 [ 11 ]NaCl溶液(12%) 1.763×106 4.24 [ 11 ]聚酰亚胺(用作涂覆层) 3.60×106 8.7(2.83) [ 32 ]丙烯酸酯(用作涂覆层) 3.39×106 8.16(~8) [ 37 ]二氧化硅 13.19×106 \ [ 32 ]
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Tianfu Li, Dexin Ba, Dengwang Zhou, Yuli Ren, Chao Chen, Hongying Zhang, Yongkang Dong. Recent progress in optical fiber sensing based on forward stimulated Brillouin scattering[J]. Opto-Electronic Engineering, 2022, 49(9): 220021
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Category: Article
Received: Mar. 19, 2022
Accepted: --
Published Online: Oct. 13, 2022
The Author Email: Yongkang Dong (aldendong@163.com)
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