Abstract
Three machine learning techniques (multilayer perceptron, random forest and Gaussian process) provide fast surrogate models for lower hybrid current drive (LHCD) simulations. A single GENRAY/CQL3D simulation without radial diffusion of fast electrons requires several minutes of wall-clock time to complete, which is acceptable for many purposes, but too slow for integrated modelling and real-time control applications. The machine learning models use a database of more than 16 000 GENRAY/CQL3D simulations for training, validation and testing. Latin hypercube sampling methods ensure that the database covers the range of nine input parameters (
$n_{e0}$
,
$T_{e0}$
,
$I_p$
,
$B_t$
,
$R_0$
,
$n_{\|}$
,
$Z_{{\rm eff}}$
,
$V_{{\rm loop}}$
and
$P_{{\rm LHCD}}$
) with sufficient density in all regions of parameter space. The surrogate models reduce the inference time from minutes to
$\sim$
ms with high accuracy across the input parameter space.
Funder
U.S. Department of Energy
Publisher
Cambridge University Press (CUP)
Reference77 articles.
1. Deep Transfer Learning for Industrial Automation: A Review and Discussion of New Techniques for Data-Driven Machine Learning
2. An efficient transport solver for tokamak plasmas
3. Simple, general, realistic, robust, analytic tokamak equilibria. Part 1. Limiter and divertor tokamaks;Guazzotto;J. Plasma Phys,2021
4. Harvey, R.W. & McCoy, M. 1992 The CQL3D Fokker–Planck Code. In Proceedings of the IAEA Technical Committee Meeting on Simulation and Modeling of Thermonuclear Plasmas, pp. 489–526.
5. Scikit-learn: machine learning in Python;Pedregosa;J. Machine Learning Res,2011
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