Disruption prediction using a full convolutional neural network on EAST

Guo, Bihao; Shen, Biluo; Chen, Dalong; Rea, Cristina; Granetz, R.; Huang, Yue; Zeng, Long; Zhang, H; Qian, Jinping; Sun, Yuan; Xiao, Baihua

doi:10.1088/1361-6587/abcbab

Cited by 32 publications

(33 citation statements)

References 29 publications

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“…To ensure model accuracy, the database should contain sufficient sample data for all the different configurations. Further, one single shot on EAST contains several diagnosis signals (Guo, Chen & Shen 2021; Guo, Shen & Chen 2021). Of these, only 88 vertical displacement control signals are chosen, containing 14 poloidal field (PF) coil current signals, 35 magnetic flux (FL) loops, 38 magnetic probes and plasma current.…”

Section: Database Constructionmentioning

confidence: 99%

Research on plasma vertical displacement calculation based on neural network

et al. 2023

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Plasma vertical displacement control is essential for the stable operation of tokamak devices. The traditional plasma vertical displacement calculation method is not suitable for balancing speed and accuracy simultaneously, which is necessary for real-time feedback control. In this study, neural networks are used to rapidly detect vertical displacement recognition. Based on a fully connected neural network, the vertical displacement calculation model is trained and tested using magnetic data of approximately 2000 shots. To compare the effects of different inputs on vertical displacement calculation, different magnetic measurement diagnostic signals are used to train and test the model. Compared with a full magnetic measurement dataset, 39 magnetic measurement signals (38 magnetic probes and plasma current) show better accuracy with mean square error <0.0005. The model is tested using historical experimental data, and it demonstrates accurate vertical displacement calculation even in the case of a vertical displacement event. In general, neural network algorithm has great application potential in vertical displacement calculation.

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Section: Database Constructionmentioning

confidence: 99%

Research on plasma vertical displacement calculation based on neural network

et al. 2023

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“…Approaches relying on a mixture of time/frequency domains, including wavelet decompositions, have also been pursued [17][18][19] . With regard to classifier technologies, real-time compatible predictors have typically been based on artificial neural networks, support vector machines, fuzzy logic, generative topographic mapping and deep learning and have been studied on a broad range of tokamaks, including ADITYA (India) 20 , ASDEX Upgrade (Germany) 21 , DIII-D (United States) [22][23][24] , J-TEXT (China) 25 , NSTX (United States) 26 , ALCATOR C-MOD (United States) 27 , JT-60U (Japan) 28 , EAST (China) [29][30][31] , HL-2A (China) 32 and JET (United Kingdom) [33][34][35] .…”

Section: And Jet Contributors*mentioning

confidence: 99%

“…The classifiers employed in the studies on tokamaks mentioned above [20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35] were developed using real-time valid solutions, which guarantee response times within a specified time window. The predictors discussed in the remainder of this work have been tested offline with real-time compatible technologies and using only real-time available signals.…”

Section: And Jet Contributors*mentioning

confidence: 99%

Disruption prediction with artificial intelligence techniques in tokamak plasmas

Mailloux¹,

Abid

Abraham³

et al. 2022

Nat. Phys.

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“…[12] EAST has developed disruption predictors based on CNN and LSTM, separately. [13,14] Fusion recurrent neural network (FRNN) has also been developed and has been applied to JET and DIII-D. [15] Though data-driven methods do not necessarily need to manually extract features, it is important to combine proper characteristics of disruption precursors. All deep learning-based methods mentioned above are designed with comprehension of disruption precursors.…”

Section: Introductionmentioning

confidence: 99%

Disruption prediction based on fusion feature extractor on J-TEXT

et al. 2023

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Predicting disruptions across different tokamaks is necessary for next generation device. Future large-scale tokamaks can hardly tolerate disruptions at high performance discharge, which makes it difficult for current data-driven methods to obtain an acceptable result. A machine learning method capable of transferring a disruption prediction model trained on one tokamak to another is required to solve the problem. The key is a feature extractor which is able to extract common disruption precursor traces in tokamak diagnostic data, and can be easily transferred to other tokamaks. Based on the concerns above, this paper presents a deep feature extractor, namely the Fusion Feature Extractor (FFE), which is designed specifically for extracting disruption precursor features from common diagnostics on tokamaks. Furthermore, an FFE-based disruption predictor on J-TEXT is demonstrated. The feature extractor is aimed to extracting disruption-related precursors and is designed according to the precursors of disruption and their representations in common tokamak diagnostics. Strong inductive bias on tokamak diagnostics data is introduced. The paper presents the evolution of the neural network feature extractor and its comparison against general deep neural networks, as well as a physics-based feature extraction with a traditional machine learning method. Results demonstrate that the FFE may reach a similar effect with physics-guided manual feature extraction, and reach a better result compared with other deep learning methods.

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Disruption prediction using a full convolutional neural network on EAST

Cited by 32 publications

References 29 publications

Research on plasma vertical displacement calculation based on neural network

Research on plasma vertical displacement calculation based on neural network

Disruption prediction with artificial intelligence techniques in tokamak plasmas

Disruption prediction based on fusion feature extractor on J-TEXT

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