Measurement of Brillouin gain spectrum with dual-frequency laser for optical fibre sensor

In this Letter, the authors present a first measurement of Brillouin gain spectrum with dual-frequency solid-state laser. This allows a coherent detection of the Brillouin backscattered spectrum in a frequency range below the hundreds of MHz by fine-tuning of the difference between the two cross-pol...

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Bibliographic Details
Published in:Electronics letters 2020-06, Vol.56 (13), p.672-674
Main Authors: Salhi, M, Kemlin, V, Faci, S, Baili, G, Khadour, A, Mostarshedi, S, Billabert, A.-L
Format: Article
Language:English
Subjects:
balanced detection technique
Brillouin backscattered spectrum
Brillouin frequency shift
Brillouin gain spectrum measurement
Brillouin spectra
Brillouin spectrum line‐width
coherent detection
cross‐polarised field
direct measurement
dual‐frequency solid‐state laser
Engineering Sciences
fibre optic sensors
high dynamic range measurements
low‐frequency benefits
measurement by laser beam
optical fibre sensor
Optics
photodetection
photodetectors
Photonic
Photonics
spectral line breadth
standard single‐mode fibre‐28
temperature coefficients
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Summary:In this Letter, the authors present a first measurement of Brillouin gain spectrum with dual-frequency solid-state laser. This allows a coherent detection of the Brillouin backscattered spectrum in a frequency range below the hundreds of MHz by fine-tuning of the difference between the two cross-polarised fields emitted by the laser. The photodetection at low-frequency benefits from the balanced detection technique where high dynamic range measurements are largely available. The narrow line-width of the cross-polarised field permits also the direct measurement of the Brillouin spectrum line-width. The system is demonstrated by measuring the Brillouin frequency shift with temperature when standard single-mode fibre-28 (SMF-28) and large effective area fibre (LEAF) are fully heated. This gives temperature coefficients close to theoretical expectations with values of 1.16 MHz/°C for SMF-28 and 1.15 MHz/°C for LEAF.
ISSN:0013-5194
1350-911X
1350-911X
DOI:10.1049/el.2019.4101