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Main Authors: Noh, Hyeongjun, Heo, Chweeho, Gao, Xiaotian, Na, Yong-Su
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.02672
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author Noh, Hyeongjun
Heo, Chweeho
Gao, Xiaotian
Na, Yong-Su
author_facet Noh, Hyeongjun
Heo, Chweeho
Gao, Xiaotian
Na, Yong-Su
contents Modelling the dynamics of complex physical systems is a fundamental challenge, particularly where nonlinear dynamics and multi-scale interactions render traditional simulations computationally prohibitive. Nuclear fusion plasma represents a complex system where accurately predicting the plasma state, encompassing both performance and stability, is a prerequisite for active control required for sustained energy production. However, existing approaches are limited in providing a comprehensive solution as they largely focus on predicting isolated indicators such as binary stability labels. To overcome this, we present Panoramic MagnetoHydroDynamics (PanoMHD), a self-supervised multimodal framework designed to model plasma dynamics. By utilising a causal Transformer operating on tokenised representations of multimodal physical signals, PanoMHD is able to model the dynamics of high-dimensional magnetic fluctuation signals, which serve as a direct signature of plasma stability. This shifts the prediction paradigm from isolated indicators to multimodal signals. We pioneer the direct prediction of magnetic fluctuation signals for the first time, and demonstrate that this comprehensive representation enables state-of-the-art performance on KSTAR nuclear fusion plant experimental data. Our model outperforms baselines in future plasma performance prediction ($R^2=0.987$ vs. $0.957$) and surpasses dedicated classifiers in the downstream classification of distinct plasma states (L/H mode) with 97.3\% vs. 94.5\% accuracy.
format Preprint
id arxiv_https___arxiv_org_abs_2603_02672
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle PanoMHD: Multimodal Modelling of Plasma Dynamics towards Tokamak Control
Noh, Hyeongjun
Heo, Chweeho
Gao, Xiaotian
Na, Yong-Su
Plasma Physics
Modelling the dynamics of complex physical systems is a fundamental challenge, particularly where nonlinear dynamics and multi-scale interactions render traditional simulations computationally prohibitive. Nuclear fusion plasma represents a complex system where accurately predicting the plasma state, encompassing both performance and stability, is a prerequisite for active control required for sustained energy production. However, existing approaches are limited in providing a comprehensive solution as they largely focus on predicting isolated indicators such as binary stability labels. To overcome this, we present Panoramic MagnetoHydroDynamics (PanoMHD), a self-supervised multimodal framework designed to model plasma dynamics. By utilising a causal Transformer operating on tokenised representations of multimodal physical signals, PanoMHD is able to model the dynamics of high-dimensional magnetic fluctuation signals, which serve as a direct signature of plasma stability. This shifts the prediction paradigm from isolated indicators to multimodal signals. We pioneer the direct prediction of magnetic fluctuation signals for the first time, and demonstrate that this comprehensive representation enables state-of-the-art performance on KSTAR nuclear fusion plant experimental data. Our model outperforms baselines in future plasma performance prediction ($R^2=0.987$ vs. $0.957$) and surpasses dedicated classifiers in the downstream classification of distinct plasma states (L/H mode) with 97.3\% vs. 94.5\% accuracy.
title PanoMHD: Multimodal Modelling of Plasma Dynamics towards Tokamak Control
topic Plasma Physics
url https://arxiv.org/abs/2603.02672