Performance analysis on 1.6 micron CW modulation laser absorption spectrometer for CO2 sensing

被引:1
作者
Imaki, Masaharu [1 ]
Kameyama, Shumpei [1 ]
Hirano, Yoshihito [1 ]
Ueno, Shinichi [1 ]
Kawakami, Shuji [2 ]
Sakaizawa, Daisuke [2 ]
Nakajima, Masakatsu [2 ]
机构
[1] Mitsubishi Electr Corp, 5-1-1 Ohuna, Kamakura, Kanagawa 2478507, Japan
[2] Japan Aerosp Explorat Agcy, Tsukuba, Ibaraki 3058505, Japan
来源
LIDAR REMOTE SENSING FOR ENVIRONMENTAL MONITORING XI | 2010年 / 7860卷
关键词
Laser; Laser Absorption Spectrometer; Laser Radar; CO2; sensing; CW modulation; 1.6; micron; Speckle; LIDAR MEASUREMENTS; OPTIMIZATION; SYSTEM;
D O I
10.1117/12.869432
中图分类号
TP7 [遥感技术];
学科分类号
081102 ; 0816 ; 081602 ; 083002 ; 1404 ;
摘要
For the application to the global CO2 monitoring from the space-borne active sensor have been studied. We have developed the Laser Absorption Sensor (LAS) system for ground-based CO2 monitoring using the wavelength of 1.6 micron. Furthermore, we have also reported about measurement result with short time fluctuation corresponding to the concentration of 4 ppm (rms) in 32 s intervals and 1 km path. In this paper, we discuss how to achieve this performance.
引用
收藏
页数:6
相关论文
共 14 条
[1]   Development of an OPO system at 1.57 μm for integrated path DIAL measurement of atmospheric carbon dioxide [J].
Amediek, A. ;
Fix, A. ;
Wirth, M. ;
Ehret, G. .
APPLIED PHYSICS B-LASERS AND OPTICS, 2008, 92 (02) :295-302
[2]   Complementary study of differential absorption lidar optimization in direct and heterodyne detections [J].
Bruneau, Didier ;
Gibert, Fabien ;
Flamant, Pierre H. ;
Pelon, Jacques .
APPLIED OPTICS, 2006, 45 (20) :4898-4908
[3]   Operating wavelengths optimization for a spaceborne lidar measuring atmospheric CO2 [J].
Caron, Jerome ;
Durand, Yannig .
APPLIED OPTICS, 2009, 48 (28) :5413-5422
[4]   Spectral diversity technique for heterodyne Doppler lidar that uses hard target returns [J].
Drobinski, P ;
Flamant, PH ;
Salamitou, P .
APPLIED OPTICS, 2000, 39 (03) :376-385
[5]   Space-borne remote sensing of CO2, CH4, and N2O by integrated path differential absorption lidar:: a sensitivity analysis [J].
Ehret, G. ;
Kiemle, C. ;
Wirth, M. ;
Amediek, A. ;
Fix, A. ;
Houweling, S. .
APPLIED PHYSICS B-LASERS AND OPTICS, 2008, 90 (3-4) :593-608
[6]   Retrieval of average CO2 fluxes by combining in situ CO2 measurements and backscatter lidar information [J].
Gibert, Fabien ;
Schmidt, Martina ;
Cuesta, Juan ;
Ciais, Philippe ;
Ramonet, Michel ;
Xueref, Irene ;
Larmanou, Eric ;
Flamant, Pierre Henri .
JOURNAL OF GEOPHYSICAL RESEARCH-ATMOSPHERES, 2007, 112 (D10)
[7]  
Kameyama S., U. S. Patent, Patent No. [7,361,922, 7361922]
[8]   Development of 1.6 μm continuous-wave modulation hard-target differential absorption lidar system for CO2 sensing [J].
Kameyama, Shumpei ;
Imaki, Masaharu ;
Hirano, Yoshihito ;
Ueno, Shinichi ;
Kawakami, Shuji ;
Sakaizawa, Daisuke ;
Nakajima, Masakatsu .
OPTICS LETTERS, 2009, 34 (10) :1513-1515
[9]   Coherent differential absorption lidar measurements of CO2 [J].
Koch, GJ ;
Barnes, BW ;
Petros, M ;
Beyon, JY ;
Amzajerdian, F ;
Yu, JR ;
Davis, RE ;
Ismail, S ;
Vay, S ;
Kavaya, MJ ;
Singh, UN .
APPLIED OPTICS, 2004, 43 (26) :5092-5099
[10]   Side-line tunable laser transmitter for differential absorption lidar measurements of CO2:: design and application to atmospheric measurements [J].
Koch, Grady J. ;
Beyon, Jeffrey Y. ;
Gibert, Fabien ;
Barnes, Bruce W. ;
Ismail, Syed ;
Petros, Mulugeta ;
Petzar, Paul J. ;
Yu, Jirong ;
Modlin, Edward A. ;
Davis, Kenneth J. ;
Singh, Upendra N. .
APPLIED OPTICS, 2008, 47 (07) :944-956
12