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Autori principali: Ding, Siqi, Zhang, Zitong, Shi, Guoyang, Li, Xingyu, Gu, Xiang, Xu, Yanan, Xie, Huasheng, Zhao, Hanyue, Shi, Yuejiang, Liu, Tianyuan
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.19114
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author Ding, Siqi
Zhang, Zitong
Shi, Guoyang
Li, Xingyu
Gu, Xiang
Xu, Yanan
Xie, Huasheng
Zhao, Hanyue
Shi, Yuejiang
Liu, Tianyuan
author_facet Ding, Siqi
Zhang, Zitong
Shi, Guoyang
Li, Xingyu
Gu, Xiang
Xu, Yanan
Xie, Huasheng
Zhao, Hanyue
Shi, Yuejiang
Liu, Tianyuan
contents As artificial intelligence emerges as a transformative enabler for fusion energy commercialization, fast and accurate solvers become increasingly critical. In magnetic confinement nuclear fusion, rapid and accurate solution of the Grad-Shafranov equation (GSE) is essential for real-time plasma control and analysis. Traditional numerical solvers achieve high precision but are computationally prohibitive, while data-driven surrogates infer quickly but fail to enforce physical laws and generalize poorly beyond training distributions. To address this challenge, we present a Physics-Informed Neural Operator (PINO) that directly learns the GSE solution operator, mapping shape parameters of last closed flux surface to equilibrium solutions for realistic nonlinear current profiles. Comprehensive benchmarking of five neural architectures identifies the novel Transformer-KAN (Kolmogorov-Arnold Network) Neural Operator (TKNO) as achieving highest accuracy (0.25% mean L2 relative error) under supervised training (only data-driven). However, all data-driven models exhibit large physics residuals, indicating poor physical consistency. Our unsupervised training can reduce the residuals by nearly four orders of magnitude through embedding physics-based loss terms without labeled data. Critically, semi-supervised learning--integrating sparse labeled data (100 interior points) with physics constraints--achieves optimal balance: 0.48% interpolation error and the most robust extrapolation performance (4.76% error, 8.9x degradation factor vs 39.8x for supervised models). Accelerated by TensorRT optimization, our models enable millisecond-level inference, establishing PINO as a promising pathway for next-generation fusion control systems.
format Preprint
id arxiv_https___arxiv_org_abs_2511_19114
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Physics-informed Neural Operator Learning for Nonlinear Grad-Shafranov Equation
Ding, Siqi
Zhang, Zitong
Shi, Guoyang
Li, Xingyu
Gu, Xiang
Xu, Yanan
Xie, Huasheng
Zhao, Hanyue
Shi, Yuejiang
Liu, Tianyuan
Plasma Physics
Artificial Intelligence
As artificial intelligence emerges as a transformative enabler for fusion energy commercialization, fast and accurate solvers become increasingly critical. In magnetic confinement nuclear fusion, rapid and accurate solution of the Grad-Shafranov equation (GSE) is essential for real-time plasma control and analysis. Traditional numerical solvers achieve high precision but are computationally prohibitive, while data-driven surrogates infer quickly but fail to enforce physical laws and generalize poorly beyond training distributions. To address this challenge, we present a Physics-Informed Neural Operator (PINO) that directly learns the GSE solution operator, mapping shape parameters of last closed flux surface to equilibrium solutions for realistic nonlinear current profiles. Comprehensive benchmarking of five neural architectures identifies the novel Transformer-KAN (Kolmogorov-Arnold Network) Neural Operator (TKNO) as achieving highest accuracy (0.25% mean L2 relative error) under supervised training (only data-driven). However, all data-driven models exhibit large physics residuals, indicating poor physical consistency. Our unsupervised training can reduce the residuals by nearly four orders of magnitude through embedding physics-based loss terms without labeled data. Critically, semi-supervised learning--integrating sparse labeled data (100 interior points) with physics constraints--achieves optimal balance: 0.48% interpolation error and the most robust extrapolation performance (4.76% error, 8.9x degradation factor vs 39.8x for supervised models). Accelerated by TensorRT optimization, our models enable millisecond-level inference, establishing PINO as a promising pathway for next-generation fusion control systems.
title Physics-informed Neural Operator Learning for Nonlinear Grad-Shafranov Equation
topic Plasma Physics
Artificial Intelligence
url https://arxiv.org/abs/2511.19114