Transformer-based nowcasting of radar composites from satellite images
for severe weather
- URL: http://arxiv.org/abs/2310.19515v2
- Date: Wed, 6 Mar 2024 14:07:24 GMT
- Title: Transformer-based nowcasting of radar composites from satellite images
for severe weather
- Authors: \c{C}a\u{g}lar K\"u\c{c}\"uk and Apostolos Giannakos and Stefan
Schneider and Alexander Jann
- Abstract summary: We present a Transformer-based model for nowcasting ground-based radar image sequences using satellite data up to two hours lead time.
Trained on a dataset reflecting severe weather conditions, the model predicts radar fields occurring under different weather phenomena.
The model can support precipitation nowcasting across large domains without an explicit need for radar towers.
- Score: 45.0983299269404
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: Weather radar data are critical for nowcasting and an integral component of
numerical weather prediction models. While weather radar data provide valuable
information at high resolution, their ground-based nature limits their
availability, which impedes large-scale applications. In contrast,
meteorological satellites cover larger domains but with coarser resolution.
However, with the rapid advancements in data-driven methodologies and modern
sensors aboard geostationary satellites, new opportunities are emerging to
bridge the gap between ground- and space-based observations, ultimately leading
to more skillful weather prediction with high accuracy. Here, we present a
Transformer-based model for nowcasting ground-based radar image sequences using
satellite data up to two hours lead time. Trained on a dataset reflecting
severe weather conditions, the model predicts radar fields occurring under
different weather phenomena and shows robustness against rapidly
growing/decaying fields and complex field structures. Model interpretation
reveals that the infrared channel centered at 10.3 $\mu m$ (C13) contains
skillful information for all weather conditions, while lightning data have the
highest relative feature importance in severe weather conditions, particularly
in shorter lead times. The model can support precipitation nowcasting across
large domains without an explicit need for radar towers, enhance numerical
weather prediction and hydrological models, and provide radar proxy for
data-scarce regions. Moreover, the open-source framework facilitates progress
towards operational data-driven nowcasting.
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