Identifying the atmospheric drivers of drought and heat using a smoothed
deep learning approach
- URL: http://arxiv.org/abs/2111.05303v1
- Date: Tue, 9 Nov 2021 18:16:39 GMT
- Title: Identifying the atmospheric drivers of drought and heat using a smoothed
deep learning approach
- Authors: Magdalena Mittermeier and Maximilian Weigert and David R\"ugamer
- Abstract summary: We propose a smoothed convolutional neural network for six types of anticyclonic circulations associated with drought and heat.
Our work can help to identify important drivers of hot and dry extremes in climate simulations.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Europe was hit by several, disastrous heat and drought events in recent
summers. Besides thermodynamic influences, such hot and dry extremes are driven
by certain atmospheric situations including anticyclonic conditions. Effects of
climate change on atmospheric circulations are complex and many open research
questions remain in this context, e.g., on future trends of anticyclonic
conditions. Based on the combination of a catalog of labeled circulation
patterns and spatial atmospheric variables, we propose a smoothed convolutional
neural network classifier for six types of anticyclonic circulations that are
associated with drought and heat. Our work can help to identify important
drivers of hot and dry extremes in climate simulations, which allows to unveil
the impact of climate change on these drivers. We address various challenges
inherent to circulation pattern classification that are also present in other
climate patterns, e.g., subjective labels and unambiguous transition periods.
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