Physics-informed deep learning framework to model intense precipitation events at super resolution

B. Teufel; F. Carmo; L. Sushama; L. Sun; M. N. Khaliq; S. Bélair; A. Shamseldin; D. Nagesh Kumar; J. Vaze

doi:10.1186/s40562-023-00272-z

Geoscience Letters (Apr 2023)

Physics-informed deep learning framework to model intense precipitation events at super resolution

B. Teufel,
F. Carmo,
L. Sushama,
L. Sun,
M. N. Khaliq,
S. Bélair,
A. Shamseldin,
D. Nagesh Kumar,
J. Vaze

Affiliations

B. Teufel: Department of Civil Engineering, Trottier Institute for Sustainability in Engineering and Design, McGill University
F. Carmo: Department of Civil Engineering, Trottier Institute for Sustainability in Engineering and Design, McGill University
L. Sushama: Department of Civil Engineering, Trottier Institute for Sustainability in Engineering and Design, McGill University
L. Sun: Department of Civil Engineering, Trottier Institute for Sustainability in Engineering and Design, McGill University
M. N. Khaliq: Ocean, Coastal and River Engineering (OCRE) Research Centre, National Research Council Canada
S. Bélair: Meteorological Research Division, Science and Technology Branch, Environment and Climate Change Canada
A. Shamseldin: Department of Civil and Environmental Engineering, University of Auckland
D. Nagesh Kumar: Department of Civil Engineering, Indian Institute of Science
J. Vaze: CSIRO Land and Water

DOI: https://doi.org/10.1186/s40562-023-00272-z
Journal volume & issue: Vol. 10, no. 1
pp. 1 – 9

Abstract

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Abstract Physical modeling of precipitation at fine (sub-kilometer) spatial scales is computationally very expensive. This study develops a highly efficient framework for this task by coupling deep learning (DL) and physical modeling. This framework is developed and tested using regional climate simulations performed over a domain covering Montreal and adjoining regions, for the summers of 2015–2020, at 2.5 km and 250 m resolutions. The DL framework uses a recurrent approach and considers atmospheric physical processes, such as advection, to generate high-resolution information from low-resolution data, which enables it to recreate fine details and produce temporally consistent fields. The DL framework generates realistic high-resolution precipitation estimates, including intense short-duration precipitation events, which allows it to be applied in engineering problems, such as evaluating the climate resiliency of urban storm drainage systems. The results portray the value of the proposed DL framework, which can be extended to other resolutions, periods, and regions.

Published in Geoscience Letters

ISSN: 2196-4092 (Online)
Publisher: SpringerOpen
Country of publisher: Switzerland
LCC subjects: Science: Geology
Website: http://www.geoscienceletters.com/

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