Settings for Spaceborne 3-D Scattering Tomography of Liquid-Phase Clouds by the CloudCT Mission

We introduce a comprehensive method for space-borne 3-D volumetric scattering-tomography of cloud microphysics, developed for the CloudCT mission. The retrieved microphysical properties are the liquid-water-content (LWC) and effective droplet radius within a cloud. We include a model for a perspecti...

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Bibliographic Details
Published in:IEEE transactions on geoscience and remote sensing 2022, Vol.60, p.1-16
Main Authors: Tzabari, Masada, Holodovsky, Vadim, Shubi, Omer, Eytan, Eshkol, Koren, Ilan, Schechner, Yoav Y.
Format: Article
Language:English
Subjects:
3-D scattering-tomography
Cloud computing
Clouds
Computed tomography
Cost function
Errors
initialization
Large eddy simulation
Liquid phases
Microphysics
Oceanic eddies
polarization
pySHDOM
Scattering
Spatial resolution
Three-dimensional displays
Tomography
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Summary:We introduce a comprehensive method for space-borne 3-D volumetric scattering-tomography of cloud microphysics, developed for the CloudCT mission. The retrieved microphysical properties are the liquid-water-content (LWC) and effective droplet radius within a cloud. We include a model for a perspective polarization imager and an assumption of 3-D variation of the effective radius. Elements of our work include computed tomography initialization by a parametric horizontally uniform microphysical model. This results in smaller errors than the prior art. The mean absolute errors of the retrieved LWC and effective radius are reduced from 62% and 28% to 40% and 9%, respectively. The parameters of this initialization are determined by a grid search of a cost function. Furthermore, we add viewpoints in the cloudbow region, to better sample the polarized scattering phase function. The suggested advances are evaluated by retrieval of a set of clouds generated by large-eddy simulations.
ISSN:0196-2892
1558-0644
DOI:10.1109/TGRS.2022.3198525