[1] T F STOCKER, D QIN, G K PLATTNER. Climate change 2013: The physical science basis, 593(2013).
[2] K SASSEN, Z WANG. Classifying clouds around the globe with the CloudSat radar: 1-year of results. Geophysical Research Letters, 34(2008).
[3] S A K SCHÄFER, R J HOGAN, C KLINGER. Representing 3-D cloud radiation effects in two-stream schemes: 1. Longwave considerations and effective cloud edge length. Journal of Geophysical Research - Atmospheres, 121, 8567-8582(2016).
[4] R J HOGAN, J K P SHONK. Incorporating the effects of 3D radiative transfer in the presence of clouds into two-stream multilayer radiation schemes. Journal of the Atmospheric Sciences, 70, 708-724(2013).
[5] B V GORYACHEV, G Y GRIGORIEV, A A AVERKIEV. 108330F-1(2018).
[6] Chao ZHANG, Zhen WANG, Jun YANG. A numerical study of radiative heating rate in the three-dimensional cloudy atmosphere: Adjacent-cloud-induced radiative effect. Acta Meteorologica Sinica, 74, 598-612(2016).
[7] K F EVANS. The spherical harmonics discrete ordinate method for three-dimensional atmospheric radiative transfer. Journal of the Atmospheric Sciences, 55, 429-446(1998).
[8] A L JONES. Development of an accurate 3d monte carlo broadband atmospheric radiative transfer model, 24-28(2016).
[9] S MUKAI, T YOKOMAE, I SANO. Multiple scattering in a dense aerosol atmosphere. Atmospheric Measurement Techniques Discussions, 5, 881-907(2012).
[10] M GAO, X HUANG, P YANG. Angular distribution of diffuse reflectance from incoherent multiple scattering in turbid media. Applied Optics, 52, 5869-5879(2013).
[11] C BELLISARIO, C MALHERBE, C SCHWEITZER. Developement of an atmospheric infrared radiation model with high clouds for target detection(2016).
[12] Guang-de TONG, Zhan-shan WANG, Zheng-xiang SHEN. Laser multiple scattering simulation for fog with closed distance. Acta Photonica Sinica, 46, 0829001(2017).
[13] M SALIM, S TAN, L TSANG. Multiple scattering solution of radiative transfer equations of active and passive configuration for forests applications, 1-3(2019).
[14] W ZDUNKOWSKI, T TRAUTMANN, A BOTT. Radiation in the atmosphere — A course in theoretical meteorology, 32-34(2007).
[15] T VÁRNAI, R DAVIES. Effects of cloud heterogeneities on shortwave radiation: Comparison of cloud-top variability and internal heterogeneity. Journal of the Atmospheric Sciences, 56, 4206-4224(1999).
[16] Yan-an CAO, He-li WEI, Qing-shan XU. Simulation of atmospheric radiative properties at IR bands under water clouds based on MODIS data. Acta Photonica Sinica, 43, 0601001(2014).
[17] Shuang LUO, Qiu YIN. Comparison and analysis of scattering phase-function truncation approximations in radiative transfer calculation. Acta Optica Sinica, 37, 0229002(2017).
[18] T VÁRNAI, A MARSHAK. A method for analyzing how various parts of clouds influence each other's brightness. Journal of Geophysical Research Atmospheres, 108, 4706(2003).
[19] I KOREN, L OREOPOULOS, G FEINGOLD. How small is a small cloud?. Atmospheric Chemistry and Physics, 8, 3855-3864(2008).
[20] W M IRVINE. Multiple scattering by large particles. II. Optically thick layers. Astrophysical Journal, 152, 823-834(1968).
[21] C F BOHREN, E E CLOTHIAUX. Fundamentals of atmospheric radiation: An introduction with 400 problems, 258-268(2006).
[22] Xiao-lei NIU, R T PINKER. Revisiting satellite radiative flux computations at the top of the atmosphere. International Journal of Remote Sensing, 33, 1383-1399(2012).
[23] F JAKUB, B MAYER. A three-dimensional parallel radiative transfer model for atmospheric heating rates for use in cloud resolving models — The TenStream solver. Journal of Quantitative Spectroscopy and Radiative Transfer, 163, 63-71(2015).
[24] K N LIOU. An introduction to atmospheric radiation, 27-33(2002).
[25] L M HINKELMAN, B STEVENS, K F EVANS. A large-eddy simulation study of anisotropy in fair-weather cumulus cloud fields. Journal of the Atmospheric Sciences, 62, 2155-2171(2005).
[26] F EWALD. Retrieval of vertical profiles of cloud droplet effective radius using solar reflectance from cloud sides, 26-30(2016).
[27] A NIANG, F BADRAN, C MOULIN. Retrieval of aerosol type and optical thickness over the Mediterranean from SeaWiFS images using an automatic neural classification method. Remote Sensing of Environment, 100, 82-94(2006).
[28] Ying-jie WANG, J GRIMALDI, L LANDIER. 2020 edition), 843-848(2020).