Litcius/Paper detail

Classification of tokamak plasma confinement states with convolutional recurrent neural networks

F. Matos, V. Menkovski, F. Felici, A. Pau, F. Jenko, the TCV Team, the EUROfusion MST1 Team

2020Nuclear Fusion25 citationsDOIOpen Access PDF

Abstract

During a tokamak discharge, the plasma can vary between different confinement regimes: low (L), high (H) and, in some cases, a temporary (intermediate state), called dithering (D). In addition, while the plasma is in H mode, edge localized modes (ELMs) can occur. The automatic detection of changes between these states, and of ELMs, is important for tokamak operation. Motivated by this, and by recent developments in deep learning, we developed and compared two methods for automatic detection of the occurrence of L-D-H transitions and ELMs, applied on data from the TCV tokamak. These methods consist in a convolutional neural network and a convolutional long short term memory neural network. We measured our results with regards to ELMs using ROC curves and Youden's score index, and regarding state detection using Cohen's Kappa index.

Topics & Concepts

TokamakConvolutional neural networkDitherPattern recognition (psychology)Artificial intelligencePlasmaComputer scienceRecurrent neural networkPhysicsEnhanced Data Rates for GSM EvolutionAlgorithmDeep learningArtificial neural networkMagnetic confinement fusionState (computer science)Plasma diagnosticsComputational physicsDetectorPlasma confinementKappaMagnetic confinement fusion researchAnomaly Detection Techniques and ApplicationsTime Series Analysis and Forecasting