Saved in:
Bibliographic Details
Main Authors: Ai, Xinkun, Zheng, Wei, Zhang, Ming, Ding, Yonghua, Chen, Dalong, Chen, Zhongyong, Shen, Chengshuo, Guo, Bihao, Wang, Nengchao, Yang, Zhoujun, Chen, Zhipeng, Pan, Yuan, Shen, Biao, Xiao, Binjia, team, J-TEXT
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2311.10368
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910509687635968
author Ai, Xinkun
Zheng, Wei
Zhang, Ming
Ding, Yonghua
Chen, Dalong
Chen, Zhongyong
Shen, Chengshuo
Guo, Bihao
Wang, Nengchao
Yang, Zhoujun
Chen, Zhipeng
Pan, Yuan
Shen, Biao
Xiao, Binjia
team, J-TEXT
author_facet Ai, Xinkun
Zheng, Wei
Zhang, Ming
Ding, Yonghua
Chen, Dalong
Chen, Zhongyong
Shen, Chengshuo
Guo, Bihao
Wang, Nengchao
Yang, Zhoujun
Chen, Zhipeng
Pan, Yuan
Shen, Biao
Xiao, Binjia
team, J-TEXT
contents In the initial stages of operation for future tokamak, facing limited data availability, deploying data-driven disruption predictors requires optimal performance with minimal use of new device data. This paper studies the issue of data utilization in data-driven disruption predictor during cross tokamak deployment. Current predictors primarily employ supervised learning methods and require a large number of disruption and non-disruption shots for training. However, the scarcity and high cost of obtaining disruption shots for future tokamaks result in imbalanced training datasets, reducing the performance of supervised learning predictors. To solve this problem, we propose the Enhanced Convolutional Autoencoder Anomaly Detection (E-CAAD) predictor. E-CAAD can be only trained by normal samples from non-disruption shots and can also be trained by disruption precursor samples when disruption shots occur. This model not only overcomes the sample imbalance in supervised learning predictors, but also overcomes the inefficient dataset utilization faced by traditional anomaly detection predictors that cannot use disruption precursor samples for training, making it more suitable for the unpredictable datasets of future tokamaks. Compared to traditional anomaly detection predictor, the E-CAAD predictor performs better in disruption prediction and is deployed faster on new devices. Additionally, we explore strategies to accelerate deployment of E-CAAD predictor on the new device by using data from existing devices. Two deployment strategies are presented: mixing data from existing devices and fine-tuning the predictor trained on existing devices. Our comparisons indicate that the data from existing device can accelerate the deployment of predictor on new device. Notably, the fine-tuning strategy yields the fastest deployment on new device among the designed strategies.
format Preprint
id arxiv_https___arxiv_org_abs_2311_10368
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Cross-Tokamak Deployment Study of Plasma Disruption Predictors Based on Convolutional Autoencoder
Ai, Xinkun
Zheng, Wei
Zhang, Ming
Ding, Yonghua
Chen, Dalong
Chen, Zhongyong
Shen, Chengshuo
Guo, Bihao
Wang, Nengchao
Yang, Zhoujun
Chen, Zhipeng
Pan, Yuan
Shen, Biao
Xiao, Binjia
team, J-TEXT
Plasma Physics
In the initial stages of operation for future tokamak, facing limited data availability, deploying data-driven disruption predictors requires optimal performance with minimal use of new device data. This paper studies the issue of data utilization in data-driven disruption predictor during cross tokamak deployment. Current predictors primarily employ supervised learning methods and require a large number of disruption and non-disruption shots for training. However, the scarcity and high cost of obtaining disruption shots for future tokamaks result in imbalanced training datasets, reducing the performance of supervised learning predictors. To solve this problem, we propose the Enhanced Convolutional Autoencoder Anomaly Detection (E-CAAD) predictor. E-CAAD can be only trained by normal samples from non-disruption shots and can also be trained by disruption precursor samples when disruption shots occur. This model not only overcomes the sample imbalance in supervised learning predictors, but also overcomes the inefficient dataset utilization faced by traditional anomaly detection predictors that cannot use disruption precursor samples for training, making it more suitable for the unpredictable datasets of future tokamaks. Compared to traditional anomaly detection predictor, the E-CAAD predictor performs better in disruption prediction and is deployed faster on new devices. Additionally, we explore strategies to accelerate deployment of E-CAAD predictor on the new device by using data from existing devices. Two deployment strategies are presented: mixing data from existing devices and fine-tuning the predictor trained on existing devices. Our comparisons indicate that the data from existing device can accelerate the deployment of predictor on new device. Notably, the fine-tuning strategy yields the fastest deployment on new device among the designed strategies.
title Cross-Tokamak Deployment Study of Plasma Disruption Predictors Based on Convolutional Autoencoder
topic Plasma Physics
url https://arxiv.org/abs/2311.10368