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Autores principales: Witte, Maximilian, Meuer, Johannes, Plésiat, Étienne, Kadow, Christopher
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2512.20350
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author Witte, Maximilian
Meuer, Johannes
Plésiat, Étienne
Kadow, Christopher
author_facet Witte, Maximilian
Meuer, Johannes
Plésiat, Étienne
Kadow, Christopher
contents Accurate and physically consistent modeling of Earth system dynamics requires machine-learning architectures that operate directly on continuous geophysical fields and preserve their underlying geometric structure. Here we introduce Field-Space attention, a mechanism for Earth system Transformers that computes attention in the physical domain rather than in a learned latent space. By maintaining all intermediate representations as continuous fields on the sphere, the architecture enables interpretable internal states and facilitates the enforcement of scientific constraints. The model employs a fixed, non-learned multiscale decomposition and learns structure-preserving deformations of the input field, allowing coherent integration of coarse and fine-scale information while avoiding the optimization instabilities characteristic of standard single-scale Vision Transformers. Applied to global temperature super-resolution on a HEALPix grid, Field-Space Transformers converge more rapidly and stably than conventional Vision Transformers and U-Net baselines, while requiring substantially fewer parameters. The explicit preservation of field structure throughout the network allows physical and statistical priors to be embedded directly into the architecture, yielding improved fidelity and reliability in data-driven Earth system modeling. These results position Field-Space Attention as a compact, interpretable, and physically grounded building block for next-generation Earth system prediction and generative modeling frameworks.
format Preprint
id arxiv_https___arxiv_org_abs_2512_20350
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Field-Space Attention for Structure-Preserving Earth System Transformers
Witte, Maximilian
Meuer, Johannes
Plésiat, Étienne
Kadow, Christopher
Machine Learning
Computer Vision and Pattern Recognition
Mathematical Physics
Accurate and physically consistent modeling of Earth system dynamics requires machine-learning architectures that operate directly on continuous geophysical fields and preserve their underlying geometric structure. Here we introduce Field-Space attention, a mechanism for Earth system Transformers that computes attention in the physical domain rather than in a learned latent space. By maintaining all intermediate representations as continuous fields on the sphere, the architecture enables interpretable internal states and facilitates the enforcement of scientific constraints. The model employs a fixed, non-learned multiscale decomposition and learns structure-preserving deformations of the input field, allowing coherent integration of coarse and fine-scale information while avoiding the optimization instabilities characteristic of standard single-scale Vision Transformers. Applied to global temperature super-resolution on a HEALPix grid, Field-Space Transformers converge more rapidly and stably than conventional Vision Transformers and U-Net baselines, while requiring substantially fewer parameters. The explicit preservation of field structure throughout the network allows physical and statistical priors to be embedded directly into the architecture, yielding improved fidelity and reliability in data-driven Earth system modeling. These results position Field-Space Attention as a compact, interpretable, and physically grounded building block for next-generation Earth system prediction and generative modeling frameworks.
title Field-Space Attention for Structure-Preserving Earth System Transformers
topic Machine Learning
Computer Vision and Pattern Recognition
Mathematical Physics
url https://arxiv.org/abs/2512.20350