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Main Authors: deJong, Emily K., Gunawardena, Nipun, Smalley, Kevin, Beydoun, Hassan, Caldwell, Peter
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.08772
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author deJong, Emily K.
Gunawardena, Nipun
Smalley, Kevin
Beydoun, Hassan
Caldwell, Peter
author_facet deJong, Emily K.
Gunawardena, Nipun
Smalley, Kevin
Beydoun, Hassan
Caldwell, Peter
contents Atmospheric clouds exhibit complex three-dimensional structure and microphysical details that are poorly constrained by the predominantly two-dimensional satellite observations available at global scales. This mismatch complicates data-driven learning and evaluation of cloud processes in weather and climate models, contributing to ongoing uncertainty in atmospheric physics. We introduce CERBERUS, a probabilistic inference framework for generating vertical radar reflectivity profiles from geostationary satellite brightness temperatures, near-surface meteorological variables, and temporal context. CERBERUS employs a three-headed encoder-decoder architecture to predict a zero-inflated (ZI) vertically-resolved distribution of radar reflectivity. Trained and evaluated using ground-based Ka-band radar observations at the ARM Southern Great Plains site, CERBERUS recovers coherent structures across cloud regimes, generalizes to withheld test periods, and provides uncertainty estimates that reflect physical ambiguity, particularly in multilayer and dynamically complex clouds. These results demonstrate the value of distribution-based learning targets for bridging observational scales, introducing a path toward model-relevant synthetic observations of clouds.
format Preprint
id arxiv_https___arxiv_org_abs_2604_08772
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle CERBERUS: A Three-Headed Decoder for Vertical Cloud Profiles
deJong, Emily K.
Gunawardena, Nipun
Smalley, Kevin
Beydoun, Hassan
Caldwell, Peter
Atmospheric and Oceanic Physics
Machine Learning
Atmospheric clouds exhibit complex three-dimensional structure and microphysical details that are poorly constrained by the predominantly two-dimensional satellite observations available at global scales. This mismatch complicates data-driven learning and evaluation of cloud processes in weather and climate models, contributing to ongoing uncertainty in atmospheric physics. We introduce CERBERUS, a probabilistic inference framework for generating vertical radar reflectivity profiles from geostationary satellite brightness temperatures, near-surface meteorological variables, and temporal context. CERBERUS employs a three-headed encoder-decoder architecture to predict a zero-inflated (ZI) vertically-resolved distribution of radar reflectivity. Trained and evaluated using ground-based Ka-band radar observations at the ARM Southern Great Plains site, CERBERUS recovers coherent structures across cloud regimes, generalizes to withheld test periods, and provides uncertainty estimates that reflect physical ambiguity, particularly in multilayer and dynamically complex clouds. These results demonstrate the value of distribution-based learning targets for bridging observational scales, introducing a path toward model-relevant synthetic observations of clouds.
title CERBERUS: A Three-Headed Decoder for Vertical Cloud Profiles
topic Atmospheric and Oceanic Physics
Machine Learning
url https://arxiv.org/abs/2604.08772