Coincidence anomaly detection for unsupervised locating of edge localized modes in the DIII-D tokamak dataset

Finn H. O’Shea; Semin Joung; David R. Smith; Daniel Ratner; Ryan Coffee

doi:10.1088/2632-2153/ad6be7

Coincidence anomaly detection for unsupervised locating of edge localized modes in the DIII-D tokamak dataset

Finn H. O’Shea, Semin Joung, David R. Smith, Daniel Ratner, Ryan Coffee

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Using supervised learning to train a machine learning model to predict an on-coming edge localized mode (ELM) requires a large number of labeled samples. Creating an appropriate data set from the very large database of discharges at a long-running tokamak, such as DIII-D, would be a very time-consuming process for a human. Considering this need and difficulty, we use coincidence anomaly detection, an unsupervised learning technique, to train an ELM-identifier to identify and label ELMs in the DIII-D discharge database. This ELM-identifier shows, simultaneously, a precision of 0.68 and a recall of 0.63 (AUC is 0.73) on identifying ELMs in example time series pulled from thousands of discharges spanning five years. In a test set of 50 discharges, the algorithm finds over 26 thousand ELM candidates, more than 5 times the existing catalog of ELMs labeled by humans.

Original language	English (US)
Article number	035050
Journal	Machine Learning: Science and Technology
Volume	5
Issue number	3
DOIs	https://doi.org/10.1088/2632-2153/ad6be7
State	Published - Sep 1 2024
Externally published	Yes

All Science Journal Classification (ASJC) codes

Software
Human-Computer Interaction
Artificial Intelligence

Keywords

fusion
machine learning
plasma
tokamak
unsupervised learning

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10.1088/2632-2153/ad6be7

Cite this

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title = "Coincidence anomaly detection for unsupervised locating of edge localized modes in the DIII-D tokamak dataset",

abstract = "Using supervised learning to train a machine learning model to predict an on-coming edge localized mode (ELM) requires a large number of labeled samples. Creating an appropriate data set from the very large database of discharges at a long-running tokamak, such as DIII-D, would be a very time-consuming process for a human. Considering this need and difficulty, we use coincidence anomaly detection, an unsupervised learning technique, to train an ELM-identifier to identify and label ELMs in the DIII-D discharge database. This ELM-identifier shows, simultaneously, a precision of 0.68 and a recall of 0.63 (AUC is 0.73) on identifying ELMs in example time series pulled from thousands of discharges spanning five years. In a test set of 50 discharges, the algorithm finds over 26 thousand ELM candidates, more than 5 times the existing catalog of ELMs labeled by humans.",

keywords = "fusion, machine learning, plasma, tokamak, unsupervised learning",

author = "O{\textquoteright}Shea, \{Finn H.\} and Semin Joung and Smith, \{David R.\} and Daniel Ratner and Ryan Coffee",

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doi = "10.1088/2632-2153/ad6be7",

language = "English (US)",

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T1 - Coincidence anomaly detection for unsupervised locating of edge localized modes in the DIII-D tokamak dataset

AU - O’Shea, Finn H.

AU - Joung, Semin

AU - Smith, David R.

AU - Ratner, Daniel

AU - Coffee, Ryan

PY - 2024/9/1

Y1 - 2024/9/1

N2 - Using supervised learning to train a machine learning model to predict an on-coming edge localized mode (ELM) requires a large number of labeled samples. Creating an appropriate data set from the very large database of discharges at a long-running tokamak, such as DIII-D, would be a very time-consuming process for a human. Considering this need and difficulty, we use coincidence anomaly detection, an unsupervised learning technique, to train an ELM-identifier to identify and label ELMs in the DIII-D discharge database. This ELM-identifier shows, simultaneously, a precision of 0.68 and a recall of 0.63 (AUC is 0.73) on identifying ELMs in example time series pulled from thousands of discharges spanning five years. In a test set of 50 discharges, the algorithm finds over 26 thousand ELM candidates, more than 5 times the existing catalog of ELMs labeled by humans.

AB - Using supervised learning to train a machine learning model to predict an on-coming edge localized mode (ELM) requires a large number of labeled samples. Creating an appropriate data set from the very large database of discharges at a long-running tokamak, such as DIII-D, would be a very time-consuming process for a human. Considering this need and difficulty, we use coincidence anomaly detection, an unsupervised learning technique, to train an ELM-identifier to identify and label ELMs in the DIII-D discharge database. This ELM-identifier shows, simultaneously, a precision of 0.68 and a recall of 0.63 (AUC is 0.73) on identifying ELMs in example time series pulled from thousands of discharges spanning five years. In a test set of 50 discharges, the algorithm finds over 26 thousand ELM candidates, more than 5 times the existing catalog of ELMs labeled by humans.

KW - fusion

KW - machine learning

KW - plasma

KW - tokamak

KW - unsupervised learning

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Coincidence anomaly detection for unsupervised locating of edge localized modes in the DIII-D tokamak dataset

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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