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Main Authors: Long, Feifei, Zhao, Yian, Zhang, Yunjiao, Wan, Chenguang, Zhou, Yinan, Qiang, Ziwei, Yang, Kangning, Li, Jiuying, Shi, Tonghui, Guo, Bihao, Zhang, Yang, Zhao, Hailing, Ti, Ang, Liu, Adi, Zhou, Chu, Xie, Jinlin, Liu, Zixi, Zhuang, Ge, Team, EAST
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.13498
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author Long, Feifei
Zhao, Yian
Zhang, Yunjiao
Wan, Chenguang
Zhou, Yinan
Qiang, Ziwei
Yang, Kangning
Li, Jiuying
Shi, Tonghui
Guo, Bihao
Zhang, Yang
Zhao, Hailing
Ti, Ang
Liu, Adi
Zhou, Chu
Xie, Jinlin
Liu, Zixi
Zhuang, Ge
Team, EAST
author_facet Long, Feifei
Zhao, Yian
Zhang, Yunjiao
Wan, Chenguang
Zhou, Yinan
Qiang, Ziwei
Yang, Kangning
Li, Jiuying
Shi, Tonghui
Guo, Bihao
Zhang, Yang
Zhao, Hailing
Ti, Ang
Liu, Adi
Zhou, Chu
Xie, Jinlin
Liu, Zixi
Zhuang, Ge
Team, EAST
contents The tearing mode, a large-scale MHD instability in tokamak, typically disrupts the equilibrium magnetic surfaces, leads to the formation of magnetic islands, and reduces core electron temperature and density, thus resulting in significant energy losses and may even cause discharge termination. This process is unacceptable for ITER. Therefore, the accurate identification of a magnetic island in real time is crucial for the effective control of the tearing mode in ITER in the future. In this study, based on the characteristics induced by tearing modes, an attention-aware convolutional neural network (AM-CNN) is proposed to identify the presence of magnetic islands in tearing mode discharge utilizing the data from ECE diagnostics in the EAST tokamak. A total of 11 ECE channels covering the range of core is used in the tearing mode dataset, which includes 2.5*10^9 data collected from 68 shots from 2016 to 2021 years. We split the dataset into training, validation, and test sets (66.5%, 5.7%, and 27.8%), respectively. An attention mechanism is designed to couple with the convolutional neural networks to improve the capability of feature extraction of signals. During the model training process, we utilized adaptive learning rate adjustment and early stopping mechanisms to optimize performance of AM-CNN. The model results show that a classification accuracy of 91.96% is achieved in tearing mode identification. Compared to CNN without AM, the attention-aware convolutional neural networks demonstrate great performance across accuracy, recall metrics, and F1 score. By leveraging the deep learning model, which incorporates a physical understanding of the tearing process to identify tearing mode behaviors, the combination of physical mechanisms and deep learning is emphasized, significantly laying an important foundation for the future intelligent control of tearing mode dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2412_13498
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Attention-aware convolutional neural networks for identification of magnetic islands in the tearing mode on EAST tokamak
Long, Feifei
Zhao, Yian
Zhang, Yunjiao
Wan, Chenguang
Zhou, Yinan
Qiang, Ziwei
Yang, Kangning
Li, Jiuying
Shi, Tonghui
Guo, Bihao
Zhang, Yang
Zhao, Hailing
Ti, Ang
Liu, Adi
Zhou, Chu
Xie, Jinlin
Liu, Zixi
Zhuang, Ge
Team, EAST
Plasma Physics
The tearing mode, a large-scale MHD instability in tokamak, typically disrupts the equilibrium magnetic surfaces, leads to the formation of magnetic islands, and reduces core electron temperature and density, thus resulting in significant energy losses and may even cause discharge termination. This process is unacceptable for ITER. Therefore, the accurate identification of a magnetic island in real time is crucial for the effective control of the tearing mode in ITER in the future. In this study, based on the characteristics induced by tearing modes, an attention-aware convolutional neural network (AM-CNN) is proposed to identify the presence of magnetic islands in tearing mode discharge utilizing the data from ECE diagnostics in the EAST tokamak. A total of 11 ECE channels covering the range of core is used in the tearing mode dataset, which includes 2.5*10^9 data collected from 68 shots from 2016 to 2021 years. We split the dataset into training, validation, and test sets (66.5%, 5.7%, and 27.8%), respectively. An attention mechanism is designed to couple with the convolutional neural networks to improve the capability of feature extraction of signals. During the model training process, we utilized adaptive learning rate adjustment and early stopping mechanisms to optimize performance of AM-CNN. The model results show that a classification accuracy of 91.96% is achieved in tearing mode identification. Compared to CNN without AM, the attention-aware convolutional neural networks demonstrate great performance across accuracy, recall metrics, and F1 score. By leveraging the deep learning model, which incorporates a physical understanding of the tearing process to identify tearing mode behaviors, the combination of physical mechanisms and deep learning is emphasized, significantly laying an important foundation for the future intelligent control of tearing mode dynamics.
title Attention-aware convolutional neural networks for identification of magnetic islands in the tearing mode on EAST tokamak
topic Plasma Physics
url https://arxiv.org/abs/2412.13498