Speaker
Mr
Andrea Murari
(Italy)
Description
Disruptions are unavoidable in current Tokamaks and accurate and reliable predictions are a prerequisite to any mitigation strategy. Therefore the most recent efforts in data analysis and machine learning have concentrate on the one hand on improving the success rate of predictors and on the other hand on developing tools which can help in the understanding of disruption physics. The best performing predictor for JET is APODIS, which has been trained and tested, in a 24 dimensional space of features (all available in real time), using hundred of shots selected among more than 8400 discharges analysed using high performance computation tools. In the campaigns (C24, C25, C27a) with good quality signals and without the use of magnetic perturbation for ELM mitigation, not included in the training set, the success rate of the predictor is higher than 90% 35 ms before the disruption (for a rate of false alarms of a few percent). The following developments of this line of research will involve the optimisation of the learning rate.
The prediction of the type of disruption is in its turn a fundamental aspect to optimise mitigation strategies. The predictors of the complexity of APODIS can reach very good performance but their results are quite difficult to relate to physical theories of disruptions. Tools of higher interpretability are required to explore the operational space and investigate the physics (even at the price of reduced performance in terms of prediction accuracy). The adopted data driven approach consists of trying to determine whether the relevant information lies on an embedded, possibly non-linear, manifold within the higher-dimensional space. If this proved feasible, the data could be represented well in a low-dimensional subspace and more effectively analysed to extract information about the physics of the disruptions and their precursors. To this end, recently, dimensionality reduction and manifold learning methods have been successfully investigated, using various tools ranging from Data Tours to Principal Component Analysis and Self Organising Maps (SOM). In particular using SOM it has been possible to map seven non dimensional parameters in a way that the disruptive and non disruptive regions of the operational space are quite separate. This is quite promising for the understanding of disruptions and cross machine comparison.
Collaboration (if applicable, e.g., International Tokamak Physics Activities)
EFDA
Country or International Organization of Primary Author
JET
Primary author
Mr
Andrea Murari
(Italy)
Co-authors
Prof.
Alessandra Fanni
(Electrical and Electronic Engineering Dept. - University of Cagliari)
Mr
Alessandro Pau
(Electrical and Electronic Engineering Dept. - University of Cagliari, Italy)
Dr
Barbara Cannas
(Dept. - University of Cagliari)
Dr
Jan Mlynar
(Association EURATOM-IPP.CR, Faculty of Nuclear Sciences and Physical Engineering CTU Prague, CZ-115 19, Czech Republic)
Prof.
Jesus Manuel Ramirez
(Dpto. Informática y Automática, UNED. Madrid, Spain.)
Dr
Jesus Vega
(CIEMAT)
Mr
Michal Odstrcil
(Association EURATOM-IPP.CR, Faculty of Nuclear Sciences and Physical Engineering CTU Prague, CZ-115 19, Czech Republic)
Prof.
Sebastian Dormido-Canto
(Dpto. Informática y Automática, UNED.)
Dr
Sias Giuliana
(Electrical and Electronic Engineering Dept. - University of Cagliari, Italy)