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Main Authors: Cao, Jinghao, Li, Qin, Du, Mengnan, Wang, Haimin, Shen, Bo
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.05351
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author Cao, Jinghao
Li, Qin
Du, Mengnan
Wang, Haimin
Shen, Bo
author_facet Cao, Jinghao
Li, Qin
Du, Mengnan
Wang, Haimin
Shen, Bo
contents We propose Physics-informed Attention-enhanced Fourier Neural Operator (PIANO) to solve the Nonlinear Force-Free Field (NLFFF) problem in solar physics. Unlike conventional approaches that rely on iterative numerical methods, our proposed PIANO directly learns the 3D magnetic field structure from 2D boundary conditions. Specifically, PIANO integrates Efficient Channel Attention (ECA) mechanisms with Dilated Convolutions (DC), which enhances the model's ability to capture multimodal input by prioritizing critical channels relevant to the magnetic field's variations. Furthermore, we apply physics-informed loss by enforcing the force-free and divergence-free conditions in the training process so that our prediction is consistent with underlying physics with high accuracy. Experimental results on the ISEE NLFFF dataset show that our PIANO not only outperforms state-of-the-art neural operators in terms of accuracy but also shows strong consistency with the physical characteristics of NLFFF data across magnetic fields reconstructed from various solar active regions. The GitHub of this project is available https://github.com/Autumnstar-cjh/PIANO
format Preprint
id arxiv_https___arxiv_org_abs_2510_05351
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Physics-informed Attention-enhanced Fourier Neural Operator for Solar Magnetic Field Extrapolations
Cao, Jinghao
Li, Qin
Du, Mengnan
Wang, Haimin
Shen, Bo
Machine Learning
Artificial Intelligence
We propose Physics-informed Attention-enhanced Fourier Neural Operator (PIANO) to solve the Nonlinear Force-Free Field (NLFFF) problem in solar physics. Unlike conventional approaches that rely on iterative numerical methods, our proposed PIANO directly learns the 3D magnetic field structure from 2D boundary conditions. Specifically, PIANO integrates Efficient Channel Attention (ECA) mechanisms with Dilated Convolutions (DC), which enhances the model's ability to capture multimodal input by prioritizing critical channels relevant to the magnetic field's variations. Furthermore, we apply physics-informed loss by enforcing the force-free and divergence-free conditions in the training process so that our prediction is consistent with underlying physics with high accuracy. Experimental results on the ISEE NLFFF dataset show that our PIANO not only outperforms state-of-the-art neural operators in terms of accuracy but also shows strong consistency with the physical characteristics of NLFFF data across magnetic fields reconstructed from various solar active regions. The GitHub of this project is available https://github.com/Autumnstar-cjh/PIANO
title Physics-informed Attention-enhanced Fourier Neural Operator for Solar Magnetic Field Extrapolations
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2510.05351