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http://arks.princeton.edu/ark:/88435/dsp013b591c48v
Title: | Deep convolutional neural networks for multi-scale time-series classification and application to disruption prediction in fusion devices |
Contributors: | Churchill, R.M the DIII-D team U. S. Department of Energy |
Keywords: | fusion plasma physics machine learning deep learning convolutional neural networks ECEi |
Issue Date: | Oct-2019 |
Publisher: | Princeton Plasma Physics Laboratory, Princeton University |
Related Publication: | arxiv |
Abstract: | The multi-scale, mutli-physics nature of fusion plasmas makes predicting plasma events challenging. Recent advances in deep convolutional neural network architectures (CNN) utilizing dilated convolutions enable accurate predictions on sequences which have long-range, multi-scale characteristics, such as the time-series generated by diagnostic instruments observing fusion plasmas. Here we apply this neural network architecture to the popular problem of disruption prediction in fusion tokamaks, utilizing raw data from a single diagnostic, the Electron Cyclotron Emission imaging (ECEi) diagnostic from the DIII-D tokamak. ECEi measures a fundamental plasma quantity (electron temperature) with high temporal resolution over the entire plasma discharge, making it sensitive to a number of potential pre-disruptions markers with different temporal and spatial scales. Promising, initial disruption prediction results are obtained training a deep CNN with large receptive field ({$\sim$}30k), achieving an $F_1$-score of {$\sim$}91\% on individual time-slices using only the ECEi data. |
URI: | http://arks.princeton.edu/ark:/88435/dsp013b591c48v |
Appears in Collections: | Theory and Computation |
Files in This Item:
File | Description | Size | Format | |
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README.txt | 757 B | Text | View/Download | |
ARK_DATA.zip | 4.49 MB | Unknown | View/Download |
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