Comparative assessment of image super-resolution techniques for spatial downscaling of gridded rainfall data
Comparative assessment of image super-resolution techniques for spatial downscaling of gridded rainfall data
With an increasing focus on improving localized understanding of weather and climate phenomena and the computation cost involved in high-resolution modelling, spatial downscaling of data has proven to be a viable alternative method to obtain high-resolution climate data. Historically, several statistical and dynamical downscaling techniques have been employed to enhance coarse-resolution data to a finer grid scale. However, these conventional methods are either inefficient in capturing several finer scale details or are resource-heavy for recursive applications. Image Super-Resolution (SR) is a computer vision concept of using grid-based approaches to enhance the resolution of an image, analogous to spatial downscaling. In this study, we explore and compare the performance of different image super-resolution methods in downscaling the Indian Meteorological Department’s (IMD) gridded rainfall data from a low spatial resolution (1.0°) to a high resolution (0.25°). The SR methods considered include a fully connected autoencoder, four traditional convolutional neural networks, and two residual neural networks. The primary objective of this study was to make an initial assessment of the performance of such methods in downscaling gridded rainfall data over the Indian region. Furthermore, the resultant downscaled products have been compared using different objective metrics and analytical comparisons with ground truth data. One of the key findings of this study is that the residual learning-based neural networks demonstrated better performance in creating perceptually realistic rainfall maps (proven both quantitatively and qualitatively), closely followed by the traditional convolutional neural networks and the autoencoder.
Deep learning, Image super-resolution, Convolutional neural networks, Spatial downscaling, Gridded rainfall
Golla, Sreevathsa
dc183162-2ad5-4e22-91b5-9cc5240c56dc
Murukesh, Midhun
1802a34f-223d-4b89-9028-6bc30a2d2659
Kumar, Pankaj
f82a343d-bad1-4042-a036-8d146ab28273
11 March 2024
Golla, Sreevathsa
dc183162-2ad5-4e22-91b5-9cc5240c56dc
Murukesh, Midhun
1802a34f-223d-4b89-9028-6bc30a2d2659
Kumar, Pankaj
f82a343d-bad1-4042-a036-8d146ab28273
Golla, Sreevathsa, Murukesh, Midhun and Kumar, Pankaj
(2024)
Comparative assessment of image super-resolution techniques for spatial downscaling of gridded rainfall data.
SN Computer Science, 5, [312].
(doi:10.1007/s42979-024-02653-3).
Abstract
With an increasing focus on improving localized understanding of weather and climate phenomena and the computation cost involved in high-resolution modelling, spatial downscaling of data has proven to be a viable alternative method to obtain high-resolution climate data. Historically, several statistical and dynamical downscaling techniques have been employed to enhance coarse-resolution data to a finer grid scale. However, these conventional methods are either inefficient in capturing several finer scale details or are resource-heavy for recursive applications. Image Super-Resolution (SR) is a computer vision concept of using grid-based approaches to enhance the resolution of an image, analogous to spatial downscaling. In this study, we explore and compare the performance of different image super-resolution methods in downscaling the Indian Meteorological Department’s (IMD) gridded rainfall data from a low spatial resolution (1.0°) to a high resolution (0.25°). The SR methods considered include a fully connected autoencoder, four traditional convolutional neural networks, and two residual neural networks. The primary objective of this study was to make an initial assessment of the performance of such methods in downscaling gridded rainfall data over the Indian region. Furthermore, the resultant downscaled products have been compared using different objective metrics and analytical comparisons with ground truth data. One of the key findings of this study is that the residual learning-based neural networks demonstrated better performance in creating perceptually realistic rainfall maps (proven both quantitatively and qualitatively), closely followed by the traditional convolutional neural networks and the autoencoder.
This record has no associated files available for download.
More information
Accepted/In Press date: 24 January 2024
Published date: 11 March 2024
Keywords:
Deep learning, Image super-resolution, Convolutional neural networks, Spatial downscaling, Gridded rainfall
Identifiers
Local EPrints ID: 504330
URI: http://eprints.soton.ac.uk/id/eprint/504330
ISSN: 2662-995X
PURE UUID: f2d268fb-6ae9-4257-ad65-b7bbe051874d
Catalogue record
Date deposited: 04 Sep 2025 16:51
Last modified: 05 Sep 2025 02:08
Export record
Altmetrics
Contributors
Author:
Sreevathsa Golla
Author:
Midhun Murukesh
Author:
Pankaj Kumar
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics