Nuclear Fusion (Jan 2024)

Tokamak edge localized mode onset prediction with deep neural network and pedestal turbulence

  • Semin Joung,
  • David R. Smith,
  • G. McKee,
  • Z. Yan,
  • K. Gill,
  • J. Zimmerman,
  • B. Geiger,
  • R. Coffee,
  • F.H. O’Shea,
  • A. Jalalvand,
  • E. Kolemen

DOI
https://doi.org/10.1088/1741-4326/ad43fb
Journal volume & issue
Vol. 64, no. 6
p. 066038

Abstract

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A neural network, BES-ELMnet, predicting a quasi-periodic disruptive eruption of the plasma energy and particles known as edge localized mode (ELM) onset is developed with observed pedestal turbulence from the beam emission spectroscopy system in DIII-D. BES-ELMnet has convolutional and fully-connected layers, taking two-dimensional plasma fluctuations with a temporal window of size 128 µ s and generating a scalar output which can be interpreted as a probability of the upcoming ELM onset. As approximately labeled inter-ELM broadband ( $15\,\textrm{kHz} \unicode{x2A7D} f\unicode{x2A7D} 150\,\textrm{kHz}$ ) fluctuations are given to the network, BES-ELMnet learns by itself ELM-related precursors arising before the onsets through supervised learning scheme. BES-ELMnet achieves the gradually increasing ELM onset probabilities between two consecutive ELMs during the inter-ELM phases and can forecast the first ELM onsets which occur after the high confinement mode transition. We further investigate the network generality in terms of the selected frequency band to ensure the use of BES-ELMnet for various operation regimes without changing the trained architecture. Therefore, our novel prediction method will enhance a proactive high confinement mode control of fusion-grade plasmas.

Keywords