|
|
|
|
|
|
Research on All-Fiber Dual-Channel Atmospheric Greenhouse Gases Laser Heterodyne Detection Technology |
WANG Jing-jing1, 2, TAN Tu1*, WANG Gui-shi1, ZHU Gong-dong1, XUE Zheng-yue1, 2, LI Jun1, 2, LIU Xiao-hai1, 2, GAO Xiao-ming1, 2 |
1. Anhui Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Hefei 230031, China
2. University of Science and Technology of China, Hefei 230026, China |
|
|
Abstract Laser heterodyne spectroscopy is a high-resolution remote sensing detection technology developed rapidly in recent years. Its device has the characteristics of small size, high spectral resolution, and is suitable for the detection of the concentration of atmospheric greenhouse gases. At present, it has been proved to be a practical and effective detection method in various observation experiments and has great application prospects and potentials in the field of earth atmosphere detection. Based on the existing laser heterodyne spectroscopy instruments, a new instrument structure is proposed in this paper. A fiber optic switch was used to modulate and split the direct sunlight, and realize the simultaneous detection of two-band laser heterodyne signals. It provides a new method for the next system integration of all-fiber laser heterodyne radiometer (LHR) and the construction of multi-band LHR. Based on the principle of laser heterodyne detection, this paper analyzes the advantages and key parameters of laser heterodyne spectrum detection technology. Combined with a self-developed high-precision solar tracker, a set of principle prototypes of a near-infrared dual-channel all-fiber LHR was built. The functions and parameters of the functional modules in LHR are elaborated in detail. The function principle and function of fiber optic switch are emphasized. The wavelength scanning mode and wavelength calibration method of the LHR are discussed. Based on this, the setting basis of related parameters and measurement method of the instrument function is discussed, and the instrument functions and the corresponding spectral resolution (0.004 4 cm-1) of the LHR described in this paper are given. Using the built LHR to conduct actual atmospheric surveys in the Hefei area (31.9°N,117.166°E), the laser heterodyne signals of CH4 and CO2 in the band of (6 056.2~6 058.1 cm-1) and (6 035.6~6 036.5 cm-1) were obtained simultaneously. The wavelength calibration and normalization of the absorption signals were performed to obtain the entire atmospheric transmittance spectrum of CH4 and CO2 molecules in the atmosphere. The signal-to-noise ratios of the measured spectral signals are 197 and 209, respectively and the spectral characteristics of molecular absorption signals are analyzed. The measurement practice in this paper shows that the fiber optical switch can be used to optimize the structure of laser heterodyne spectroscopy system, achieve the simultaneous measurement of multi-channel and multi-band LHR, and expand the application of LHR in the field of atmospheric detection.
|
Received: 2019-12-14
Accepted: 2020-04-11
|
|
Corresponding Authors:
TAN Tu
E-mail: tantu@aiofm.ac.cn
|
|
[1] Deutscher N M, Griffith D W T, Bryant G W, et al. Atmospheric Measurement Techniques, 2010, 3(4): 947.
[2] Clarke G B, Wilson E L, Miller J H, et al. Measurement Science and Technology, 2014, 25(5): 055204.
[3] Palmer P I, Wilson E L, Villanueva G L, et al. Atmospheric Measurement Techniques, 2019, 12(4): 2579.
[4] Weidmann D, Tsai T R, Macleod N A, et al. Optics Letters, 2011, 36 (12): 1951.
[5] Tsai T R, Rose R A, Weidmann D, et al. Applied Optics, 2012, 51(36): 8779.
[6] Wilson E L, McLinden M L, Miller J H, et al. Applied Physic B, 2013, 114(3): 385.
[7] Wilson E L, DiGregorio A J, Villanueva G, et al. Applied Physics B, 2019, 125(11): 211.
[8] Rodin A, Klimchuk A, Nadezhdinskiy A, et al. Optics Express, 2014, 22(11): 13825.
[9] Wang J, Wang G, Tan T, et al. Optics Express, 2019, 27(7): 9610.
[10] Guo X Q, Zheng F, Li C L, et al. Optics and Lasers in Engineering, 2019, 115(1): 243.
[11] Li C L, Shao L G, Meng H Y, et al. Optics Express, 2018, 26(22): 29330.
[12] Parvitte B, Zéninari V, Thiébeaux C, et al. Spectrochimica Acta Part A-Molecular and Biomolecular Spectroscopy, 2004, 60(5): 1193.
[13] Thuillier G, Hersé M, Labs D, et al. Solar Physics, 2003, 214(1): 1.
[14] Hoffmann A, Macleod N A, Huebner M, et al. Atmospheric Measurement Techniques, 2016, 9(12): 5975. |
[1] |
SHEN Feng-jiao1, 3, TAN Tu2*, LU Jun1, ZHANG Sheng1, GAO Xiao-ming2, CHEN Wei-dong3. Research on Middle Infrared Laser Heterodyne Remote Sensing
Technology Based on EC-QCL[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(06): 1739-1745. |
[2] |
PAN Ke-yu1, 2, ZHU Ming-yao1, 2, WANG Yi-meng1, 2, XU Yang1, CHI Ming-bo1, 2*, WU Yi-hui1, 2*. Research on the Influence of Modulation Depth of Phase Sensitive
Detection on Stimulated Raman Signal Intensity and
Signal-to-Noise Ratio[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(04): 1068-1074. |
[3] |
LIU Ye-kun, HAO Xiao-jian*, YANG Yan-wei, HAO Wen-yuan, SUN Peng, PAN Bao-wu. Quantitative Analysis of Soil Heavy Metal Elements Based on Cavity
Confinement LIBS Combined With Machine Learning[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(08): 2387-2391. |
[4] |
WANG Yue1, 3, 4, CHEN Nan1, 2, 3, 4, WANG Bo-yu1, 5, LIU Tao1, 3, 4*, XIA Yang1, 2, 3, 4*. Fourier Transform Near-Infrared Spectral System Based on Laser-Driven Plasma Light Source[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(06): 1666-1673. |
[5] |
YANG Yu-qing1, CAI Jiang-hui1, 2*, YANG Hai-feng1*, ZHAO Xu-jun1, YIN Xiao-na1. LAMOST Unknown Spectral Analysis Based on Influence Space and Data Field[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(04): 1186-1191. |
[6] |
HU Li-hong1, ZHANG Jin-tong1, WANG Li-yun2, ZHOU Gang3, WANG Jiang-yong1*, XU Cong-kang1*. Optimization of Working Parameters of Glow Discharge Optical Emission Spectrometry of High Barrier Aluminum Plastic Film[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(03): 954-960. |
[7] |
CUI Fang-xiao1, ZHAO Yue2, MA Feng-xiang2, WU Jun1*, WANG An-jing1, LI Da-cheng1, LI Yang-yu1. Optimization of FTIR Passive Remote Sensing Signal-to-Noise Ratio and Its Application in SF6 Leak Detection in Transform Substation[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(05): 1436-1440. |
[8] |
SUN Ran, HAO Xiao-jian*, YANG Yan-wei, REN Long. Effect of Cavity Confinement Materials on Laser-Induced Breakdown Cu Plasma Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2020, 40(12): 3801-3805. |
[9] |
ZHENG Guo-liang, ZHU Hong-qiu*, LI Yong-gang. Spectral Signal Denoising Algorithm Based on Improved LMS[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2020, 40(02): 643-649. |
[10] |
LI Zhi-wei1, 2, SHI Hai-liang1, 2, LUO Hai-yan1, 2, XIONG Wei1, 2*. Study on the Relationship Between Apodization Function and Signal-to-Noise Ratio of Hyperspectral Spatial Interferogram[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2020, 40(01): 29-33. |
[11] |
XIAO Hu-ying1, YANG Fan1, XIANG Liu1, HU Xue-jiao2*. Jet Vacuum Enhanced Tunable Diode Laser Absorption Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2019, 39(10): 2993-2997. |
[12] |
YI Li-na1, XU Xiao1, ZHANG Gui-feng2,3*, MING Xing2, GUO Wen-ji2, LI Shao-cong1, SHA Ling-yu1. Light and Small UAV Hyperspectral Image Mosaicking[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2019, 39(06): 1885-1891. |
[13] |
ZHAO Zhe1, 2, 3, WANG Hui1, WANG Hui-quan1, 2, 3*, HE Xin-wei1, MIAO Jing-hong1, 2, WANG Jin-hai1, 2*. Influence of Spectral Characteristics on the Accuracy of Concentration Quantitatively Analysis by NIR[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2019, 39(04): 1070-1074. |
[14] |
WANG Zi-ru1, LIU Ming-hui2, LIU En-kai1, DONG Zuo-ren2, CAI Sheng-wen1, YIN Lei1, LIU Feng1. Method and Application for Raman Spectra SNR Evaluation Based on Extreme Points Statistics[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2019, 39(04): 1080-1085. |
[15] |
WANG Li, FU Yuan-xia, XU Li,GONG Hao, RONG Chang-chun. The Effect of Sample Temperature on Characteristic Parameters of the Nanosecond Laser-Induced Cu Plasma[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2019, 39(04): 1247-1251. |
|
|
|
|