Analyzing High-Resolution Clouds and Convection using Multi-Channel VAEs
- URL: http://arxiv.org/abs/2112.01221v1
- Date: Wed, 1 Dec 2021 06:23:07 GMT
- Title: Analyzing High-Resolution Clouds and Convection using Multi-Channel VAEs
- Authors: Harshini Mangipudi, Griffin Mooers, Mike Pritchard, Tom Beucler,
Stephan Mandt
- Abstract summary: Atmospheric scientists run high-resolution, storm-resolving simulations to capture kilometer-scale weather details.
This paper takes a data-driven approach and jointly embeds spatial arrays of vertical wind velocities, temperatures, and water vapor information as three "channels" of a VAE architecture.
- Score: 15.695330558298705
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Understanding the details of small-scale convection and storm formation is
crucial to accurately represent the larger-scale planetary dynamics. Presently,
atmospheric scientists run high-resolution, storm-resolving simulations to
capture these kilometer-scale weather details. However, because they contain
abundant information, these simulations can be overwhelming to analyze using
conventional approaches. This paper takes a data-driven approach and jointly
embeds spatial arrays of vertical wind velocities, temperatures, and water
vapor information as three "channels" of a VAE architecture. Our "multi-channel
VAE" results in more interpretable and robust latent structures than earlier
work analyzing vertical velocities in isolation. Analyzing and clustering the
VAE's latent space identifies weather patterns and their geographical
manifestations in a fully unsupervised fashion. Our approach shows that VAEs
can play essential roles in analyzing high-dimensional simulation data and
extracting critical weather and climate characteristics.
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