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Hauptverfasser: Ren, Pu, Erichson, N. Benjamin, Guo, Junyi, Subramanian, Shashank, San, Omer, Lukic, Zarija, Mahoney, Michael W.
Format: Preprint
Veröffentlicht: 2023
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2306.14070
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author Ren, Pu
Erichson, N. Benjamin
Guo, Junyi
Subramanian, Shashank
San, Omer
Lukic, Zarija
Mahoney, Michael W.
author_facet Ren, Pu
Erichson, N. Benjamin
Guo, Junyi
Subramanian, Shashank
San, Omer
Lukic, Zarija
Mahoney, Michael W.
contents Super-resolution (SR) techniques aim to enhance data resolution, enabling the retrieval of finer details, and improving the overall quality and fidelity of the data representation. There is growing interest in applying SR methods to complex spatiotemporal systems within the Scientific Machine Learning (SciML) community, with the hope of accelerating numerical simulations and/or improving forecasts in weather, climate, and related areas. However, the lack of standardized benchmark datasets for comparing and validating SR methods hinders progress and adoption in SciML. To address this, we introduce SuperBench, the first benchmark dataset featuring high-resolution datasets, including data from fluid flows, cosmology, and weather. Here, we focus on validating spatial SR performance from data-centric and physics-preserved perspectives, as well as assessing robustness to data degradation tasks. While deep learning-based SR methods (developed in the computer vision community) excel on certain tasks, despite relatively limited prior physics information, we identify limitations of these methods in accurately capturing intricate fine-scale features and preserving fundamental physical properties and constraints in scientific data. These shortcomings highlight the importance and subtlety of incorporating domain knowledge into ML models. We anticipate that SuperBench will help to advance SR methods for science.
format Preprint
id arxiv_https___arxiv_org_abs_2306_14070
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle SuperBench: A Super-Resolution Benchmark Dataset for Scientific Machine Learning
Ren, Pu
Erichson, N. Benjamin
Guo, Junyi
Subramanian, Shashank
San, Omer
Lukic, Zarija
Mahoney, Michael W.
Computer Vision and Pattern Recognition
Image and Video Processing
Computational Physics
Super-resolution (SR) techniques aim to enhance data resolution, enabling the retrieval of finer details, and improving the overall quality and fidelity of the data representation. There is growing interest in applying SR methods to complex spatiotemporal systems within the Scientific Machine Learning (SciML) community, with the hope of accelerating numerical simulations and/or improving forecasts in weather, climate, and related areas. However, the lack of standardized benchmark datasets for comparing and validating SR methods hinders progress and adoption in SciML. To address this, we introduce SuperBench, the first benchmark dataset featuring high-resolution datasets, including data from fluid flows, cosmology, and weather. Here, we focus on validating spatial SR performance from data-centric and physics-preserved perspectives, as well as assessing robustness to data degradation tasks. While deep learning-based SR methods (developed in the computer vision community) excel on certain tasks, despite relatively limited prior physics information, we identify limitations of these methods in accurately capturing intricate fine-scale features and preserving fundamental physical properties and constraints in scientific data. These shortcomings highlight the importance and subtlety of incorporating domain knowledge into ML models. We anticipate that SuperBench will help to advance SR methods for science.
title SuperBench: A Super-Resolution Benchmark Dataset for Scientific Machine Learning
topic Computer Vision and Pattern Recognition
Image and Video Processing
Computational Physics
url https://arxiv.org/abs/2306.14070