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Main Authors: Saccardi, Carlo, Pierzyna, Maximilian, Borde, Haitz Sáez de Ocáriz, Monaco, Simone, Meo, Cristian, Liò, Pietro, Saathof, Rudolf, Joseph, Geethu, Dauwels, Justin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.13722
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author Saccardi, Carlo
Pierzyna, Maximilian
Borde, Haitz Sáez de Ocáriz
Monaco, Simone
Meo, Cristian
Liò, Pietro
Saathof, Rudolf
Joseph, Geethu
Dauwels, Justin
author_facet Saccardi, Carlo
Pierzyna, Maximilian
Borde, Haitz Sáez de Ocáriz
Monaco, Simone
Meo, Cristian
Liò, Pietro
Saathof, Rudolf
Joseph, Geethu
Dauwels, Justin
contents Kilometer-scale weather data is crucial for real-world applications but remains computationally intensive to produce using traditional weather simulations. An emerging solution is to use deep learning models, which offer a faster alternative for climate downscaling. However, their reliability is still in question, as they are often evaluated using standard machine learning metrics rather than insights from atmospheric and weather physics. This paper benchmarks recent state-of-the-art deep learning models and introduces physics-inspired diagnostics to evaluate their performance and reliability, with a particular focus on geographic generalization and physical consistency. Our experiments show that, despite the seemingly strong performance of models such as CorrDiff, when trained on a limited set of European geographies (e.g., central Europe), they struggle to generalize to other regions such as Iberia, Morocco in the south, or Scandinavia in the north. They also fail to accurately capture second-order variables such as divergence and vorticity derived from predicted velocity fields. These deficiencies appear even in in-distribution geographies, indicating challenges in producing physically consistent predictions. We propose a simple initial solution: introducing a power spectral density loss function that empirically improves geographic generalization by encouraging the reconstruction of small-scale physical structures. The code for reproducing the experimental results can be found at https://github.com/CarloSaccardi/PSD-Downscaling
format Preprint
id arxiv_https___arxiv_org_abs_2510_13722
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Assessing the Geographic Generalization and Physical Consistency of Generative Models for Climate Downscaling
Saccardi, Carlo
Pierzyna, Maximilian
Borde, Haitz Sáez de Ocáriz
Monaco, Simone
Meo, Cristian
Liò, Pietro
Saathof, Rudolf
Joseph, Geethu
Dauwels, Justin
Machine Learning
Kilometer-scale weather data is crucial for real-world applications but remains computationally intensive to produce using traditional weather simulations. An emerging solution is to use deep learning models, which offer a faster alternative for climate downscaling. However, their reliability is still in question, as they are often evaluated using standard machine learning metrics rather than insights from atmospheric and weather physics. This paper benchmarks recent state-of-the-art deep learning models and introduces physics-inspired diagnostics to evaluate their performance and reliability, with a particular focus on geographic generalization and physical consistency. Our experiments show that, despite the seemingly strong performance of models such as CorrDiff, when trained on a limited set of European geographies (e.g., central Europe), they struggle to generalize to other regions such as Iberia, Morocco in the south, or Scandinavia in the north. They also fail to accurately capture second-order variables such as divergence and vorticity derived from predicted velocity fields. These deficiencies appear even in in-distribution geographies, indicating challenges in producing physically consistent predictions. We propose a simple initial solution: introducing a power spectral density loss function that empirically improves geographic generalization by encouraging the reconstruction of small-scale physical structures. The code for reproducing the experimental results can be found at https://github.com/CarloSaccardi/PSD-Downscaling
title Assessing the Geographic Generalization and Physical Consistency of Generative Models for Climate Downscaling
topic Machine Learning
url https://arxiv.org/abs/2510.13722