Remote Sensing of Cloud Properties Based on Visible-to-Infrared Channel Observation from Passive Remote Sensing Satellites

被引:0
|
作者
Shang H. [1 ]
Husi L. [1 ]
Li M. [1 ,2 ]
Tao J. [1 ]
Chen L. [1 ,2 ]
机构
[1] State Key Laboratory of Remote Sensing Science, Aerospace Information Research Institute, Chinese Academy of Sciences, Beijing
[2] University of Chinese Academy of Sciences, Beijing
来源
Guangxue Xuebao/Acta Optica Sinica | 2022年 / 42卷 / 06期
关键词
Cloud inversion algorithm; Cloud remote sensing; Macroscopic properties; Microscopic properties; Passive optical satellite; Remote sensing;
D O I
10.3788/AOS202242.0600003
中图分类号
学科分类号
摘要
Clouds are the main regulators of Earth's radiation budget, water cycle, and biochemical cycle. Since the launch of the first human meteorological satellite (TIROS) in 1960, passive satellite remote sensing has developed into one of the most efficient means to obtain cloud observation data. Passive satellites have the characteristics of large observation range and long time span,in which the remote sensing imagers using visible and infrared bands (0.4015 μm) have higher spatial and temporal resolution than hyperspectral and microwave imagers. First, summarizes the observation characteristics of passive satellite observation sensors based on visible and infrared bands for three types of sensors (multispectral imagers, multi-angle polarization imagers onboard polar-orbiting satellites and multispectral imagers onboard the new generation geostationary satellites) are summarized. Then, the principles and application methods for cloud parameters such as cloud detection, cloud phase, cloud top parameters, cloud optical and microphysical parameters are introduced. Finally, some thoughts are provided for the remote sensing study of cloud characteristics of passive satellite visible and infrared data through summary and prospect. © 2022, Chinese Lasers Press. All right reserved.
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  • [21] Qu Y W, Han Y, Wu Y H, Et al., Study of PBLH and its correlation with particulate matter from one-year observation over Nanjing, southeast China, Remote Sensing, 9, 7, (2017)
  • [22] Gong W, Li W L., Simulation of severe storm rainfall event in 1991 over Changjiang Huaihe River valley with a Chinese regional climate model, Quarterly Journal of Applied Meteorlolgy, 8, 3, pp. 70-79, (1997)
  • [23] Huang J P, Chen W, Wen Z P, Et al., Review of Chinese atmospheric science research over the past 70 years: climate and climate change, Scientia Sinica Terrae, 49, 10, pp. 1607-1640, (2019)
  • [24] Zhang H, Wang F, Zhao S Y, Et al., Earth's energy budget, climate feedbacks, and climate sensitivity, Climate Change Research, 17, 6, pp. 691-698, (2021)
  • [25] Masson-Delmotte V, Zhai P, Pirani A, Et al., Towards the sixth assessment report of the Intergovernmental Panel on Climate Change (IPCC), Proceedings of the 2016 AGU Fall Meeting, (2016)
  • [26] Liu Y Z, Wu C Q, Jia R, Et al., An overview of the influence of atmospheric circulation on the climate in arid and semi-arid region of Central and East Asia, Science China Earth Sciences, 61, 9, pp. 1183-1194, (2018)
  • [27] Yu H P, Huang J P, Li W J, Et al., Development of the analogue-dynamical method for error correction of numerical forecasts, Journal of Meteorological Research, 28, 5, pp. 934-947, (2014)
  • [28] Wang M H, Ghan S, Liu X H, Et al., Constraining cloud lifetime effects of aerosols using A-Train satellite observations, Geophysical Research Letters, 39, 15, (2012)
  • [29] Zhu L, Lu C S, Gao S N, Et al., Spectral width of cloud droplet spectra and its impact factors in marine stratocumulus, Chinese Journal of Atmospheric Sciences, 44, 3, pp. 575-590, (2020)
  • [30] Dongfang X., A brief analysis of high resolution satellite and its application in China, Satellite Application, 3, pp. 44-48, (2015)
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