An accurate inversion method of aerosol extinction coefficient about ground-based lidar without needing calibration

Liu Hou-Tong; Mao Min-Juan

doi:10.7498/aps.68.20181825

Abstract

How to accurately calibrate the lidar data about haze in the presence of some cloud layers over the haze has always been a subject to be solved for data inversion of Mie scattering lidar. It is difficult for laser to penetrate the haze and clouds simultaneously, so the backscattering signal of lidar cannot be calibrated by using a clear air layer when the haze is under the low clouds. For the portable Mie scattering lidar with a detecting range of less than 6 km, it is also difficult to calibrate the lidar signals by using a clear air layer. An iterative algorithm for aerosol extinction coefficient is proposed based on the characteristics of the Fernald forward integral equation in this paper. By specific settings for the inversion process, the difference between the inversion value and the expected one of aerosol extinction coefficient is reduced after each iteration. After several iterations, the difference between the inversion value and the expected one of aerosol extinction coefficient is small enough to be negligible.The disadvantage of the iterative algorithm for aerosol extinction coefficient is that the inversion results are affected by the overlap factor of lidar. The errors of lidar overlap factor measured experimentally at different times are slightly different. However, the influence about the overlap factor of lidar measured experimentally at different times on the inversion results is slightly different when the iterative algorithm for aerosol extinction coefficient is used to calculate aerosol extinction coefficient.The results of preliminary calculation show that the iterative algorithm of aerosol extinction coefficient can accurately reproduce aerosol extinction coefficient profile without needing calibration of the lidar data. For the haze detection signal that cannot be calibrated by a clear air layer, the vertical distribution of the haze extinction coefficient can be accurately retrieved by the iterative algorithm for aerosol extinction coefficients. The vertical distribution of aerosol extinction coefficients can also be accurately retrieved by using the iterative algorithm of aerosol extinction coefficients for the Mie backscattering lidar data with the measuring height less than 6 km. Through comparative analysis and research, it is found that for the same lidar data, the aerosol extinction coefficient obtained by the iterative algorithm for aerosol extinction coefficient is closer to the actual value than that by the slope method.

Keywords:

Authors and contacts

Liu Hou-Tong¹,
Mao Min-Juan²

1.
College of Mathematics, Physics and Engineering, Anhui University of Technology, Maanshan 243002, China
2.
Zhejiang Meteorology Science Institute, Hangzhou 310017, China

Corresponding author: Liu Hou-Tong, houtong6@ahut.edu.cn ; Mao Min-Juan, mayammj@mail.ustc.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 41075027, 41475134).

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References

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图 1 雾霾的激光雷达距离校正回波信号

Figure 1. The range corrected lidar signal about fog and haze.

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图 2 大气透过率初始值与第一次迭代值之间的关系

Figure 2. The relationship between the initial values and the first iterative values of atmospheric transmittance.

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图 3 利用气溶胶消光系数迭代算法反演得到的气溶胶消光系数廓线

Figure 3. The aerosol extinction coefficient profiles retrieved by the iterative algorithm of aerosol extinction coefficient.

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图 4 米散射激光雷达距离校正信号

Figure 4. The range corrected lidar signal of the Mie scattering lidar.

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图 5 利用气溶胶消光系数迭代算法与其他定标方法获得的气溶胶消光系数比较

Figure 5. Comparison of aerosol extinction coefficients obtained by the iterative algorithm of aerosol extinction coefficient and other calibration methods.

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图 6 激光雷达几何重叠校正因子的相对误差

Figure 6. The relative errors of lidar overlap function.

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图 7 不同的激光雷达几何重叠因子误差所对应的激光雷达距离校正信号

Figure 7. The range corrected lidar signals corresponding to different errors of lidar geometric overlap function.

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图 8 几何重叠因子误差对气溶胶消光系数反演值的影响

Figure 8. The influence of lidar overlap function error on the retrievals of aerosol extinction coefficients.

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map

[1]	孙国栋, 秦来安, 张巳龙, 何枫, 谭逢富, 靖旭, 侯再红 2018 67 054205 Google Scholar Sun G D, Qin L A, Zhang S L, He F, Tan F F, Jing X, Hou Z H 2018 Acta Phys. Sin. 67 054205 Google Scholar
[2]	迟如利, 吴德成, 刘博, 周军 2009 光谱学与光谱分析 29 001468 Chi R L, Wu D C, Liu B, Zhou J 2009 Spectrosc. Spect. Anal. 29 001468
[3]	Lefrere J, Pelon J, Cahen C, Hauchecorne A, Flamant P 1981 Appl. Opt. 20 A70 Google Scholar
[4]	Ansmann A, Wandinger U, Riebesell M, Weitkamp C, Michaelis W 1992 Appl. Opt. 31 7113 Google Scholar
[5]	陈莎莎, 徐青山, 徐赤东, 余东升, 陈小威 2017 光学学报 37 9 Chen S S, Xu Q S, Xu C D, Yu D S, Chen X W 2017 Acta Opt. Sin. 37 9
[6]	Huang X Y, Yang X W, Geng F H, Zhang H, He Q S, Bu L B 2010 J. Opt. Soc. Korea 14 185 Google Scholar
[7]	Hee W S, Khor W Y, Lim H S, Jafri M Z M 2015 AIP Conference Proceedings Kuala Lumpur, November 18–19, 2014 040015
[8]	Liang M, Peng G, Yang Y, Zheng K 2017 Opt. Express 25 A628 Google Scholar
[9]	Klett J D 1981 Appl. Opt. 20 211 Google Scholar
[10]	Russell P B, Swissler T J, Mccormick M P 1979 Appl. Opt. 8 3873
[11]	Chiang C W, Das S K, Nee J B 2008 J. Quant. Spectrosc. Radiat. Transfer 109 1187 Google Scholar
[12]	NOAA U, Force U A 1976 US Standard Atmosphere
[13]	Liu H T, Wang Z Z, Zhao J X, Ma J J 2018 Curr. Opt. Photon. 2 119
[14]	Salem E 2007 J. Mod. Opt. 42 1439
[15]	刘厚通, 陈良富, 苏林 2011 60 064204 Google Scholar Liu H T, Chen L F, Su L 2011 Acta Phys. Sin. 60 064204 Google Scholar
[16]	Fernald F G 1984 Appl. Opt. 23 652 Google Scholar
[17]	Xian J H, Han Y L, Huang S Y, Sun D S, Zheng J, Han F, Zhou A R, Yang S C, Xu W J, Song Q C, Wei L F, Tan Q Z, Li X Z 2018 Opt. Express 26 34853 Google Scholar
[18]	Wong M S, Qin K, Lian H, Campbell J R, Lee K H, Sheng S J 2017 Atmos. Environ. 154 189 Google Scholar
[19]	Wang J, Zhang T, Liu W, Liu J, Wan X 2018 OSA Technical Digest (Optical Society of America, 2018) Singapore November 5–8, 2018 ET3A.1.
[20]	狄慧鸽, 华灯鑫, 王玉峰, 闫庆 2013 62 094215 Di H G, Hua D X, Wang Y F, Yan Q 2013 Acta Phys. Sin. 62 094215

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