Fiber optic methane sensing system based on temperature-tunable distributed feedback laser

Shang Hui Xiao; Yi Jiang; Jun Tang

doi:10.18494/SAM.2018.1958

Fiber optic methane sensing system based on temperature-tunable distributed feedback laser

Shang Hui Xiao^*, Yi Jiang, Jun Tang

^*Corresponding author for this work

School of Optics and Photonics

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

A fiber optic methane sensing system based on the temperature-tunable distributed feedback (DFB) laser is experimentally demonstrated. Two laser diodes (LDs) with different wavelengths are used in the system. One LD operates in the wavelength scanning mode, and the other LD is used as the reference beam to eliminate the fluctuation of light intensity. By comparing the intensities of the two wavelengths during wavelength scanning, we can determine methane content. Experimental results show that a measurement resolution of 0.038% can be reached. The obtained measuring system has good properties of high precision, low cost, and high reliability.

Original language	English
Pages (from-to)	2039-2048
Number of pages	10
Journal	Sensors and Materials
Volume	30
Issue number	9
DOIs	https://doi.org/10.18494/SAM.2018.1958
Publication status	Published - 2018

Keywords

Absorption spectroscopy
Fiber optic sensors
Methane measurement
Wavelength scanning

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10.18494/SAM.2018.1958

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title = "Fiber optic methane sensing system based on temperature-tunable distributed feedback laser",

abstract = "A fiber optic methane sensing system based on the temperature-tunable distributed feedback (DFB) laser is experimentally demonstrated. Two laser diodes (LDs) with different wavelengths are used in the system. One LD operates in the wavelength scanning mode, and the other LD is used as the reference beam to eliminate the fluctuation of light intensity. By comparing the intensities of the two wavelengths during wavelength scanning, we can determine methane content. Experimental results show that a measurement resolution of 0.038% can be reached. The obtained measuring system has good properties of high precision, low cost, and high reliability.",

keywords = "Absorption spectroscopy, Fiber optic sensors, Methane measurement, Wavelength scanning",

author = "Xiao, {Shang Hui} and Yi Jiang and Jun Tang",

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AU - Xiao, Shang Hui

AU - Jiang, Yi

AU - Tang, Jun

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N2 - A fiber optic methane sensing system based on the temperature-tunable distributed feedback (DFB) laser is experimentally demonstrated. Two laser diodes (LDs) with different wavelengths are used in the system. One LD operates in the wavelength scanning mode, and the other LD is used as the reference beam to eliminate the fluctuation of light intensity. By comparing the intensities of the two wavelengths during wavelength scanning, we can determine methane content. Experimental results show that a measurement resolution of 0.038% can be reached. The obtained measuring system has good properties of high precision, low cost, and high reliability.

AB - A fiber optic methane sensing system based on the temperature-tunable distributed feedback (DFB) laser is experimentally demonstrated. Two laser diodes (LDs) with different wavelengths are used in the system. One LD operates in the wavelength scanning mode, and the other LD is used as the reference beam to eliminate the fluctuation of light intensity. By comparing the intensities of the two wavelengths during wavelength scanning, we can determine methane content. Experimental results show that a measurement resolution of 0.038% can be reached. The obtained measuring system has good properties of high precision, low cost, and high reliability.

KW - Absorption spectroscopy

KW - Fiber optic sensors

KW - Methane measurement

KW - Wavelength scanning

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Fiber optic methane sensing system based on temperature-tunable distributed feedback laser

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Keywords

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