Real-time-capable prediction of temperature and density profiles in a tokamak using RAPTOR and a first-principle-based transport model

The ASDEX Upgrade, MAST and TCV Teams; JET Contributors

doi:10.1088/1741-4326/aac8f0

Real-time-capable prediction of temperature and density profiles in a tokamak using RAPTOR and a first-principle-based transport model

The ASDEX Upgrade, MAST and TCV Teams
, JET Contributors

Laboratory for Plasma Physics

Commissariat à l'Énergie Atomique (CEA)
Ecole Polytechnique Federale de Lausanne
Max-Planck-Institut für Plasmaphysik
VTT Technical Research Centre of Finland
Consorzio Rfx
Institute of Plasma Physics, Academy of Sciences of the Czech Republic
Instituto Superior Técnico
University of Napoli 'Federico II'
University of Cagliari
Istituto di Fisica del Plasma Piero Caldirola
University of Napoli Parthenope
ENEA Centro Ricerche Frascati
National Technical University of Athens
Laboratorio Nacional de Fusión
University of Oxford
Culham Centre for Fusion Energy
EUROfusion PMU
University of Seville
Wigner Research Centre for Physics
University of Ghent
Université Libre de Bruxelles
Eindhoven University of Technology
University of Strathclyde
FORSCHUNGSZENTRUM JULICH GMBH
Institut Jean Lamour
Université Aix Marseille
University of Rome Tor Vergata
Uppsala University
University of Warwick
Institute of Plasma Physics and Laser Microfusion
FOM Institute DIFFER
Universitat Innsbruck
ITER
Faculty of Electrical Engineering, Mechanical Engineering and Naval Architecture, University of Split
Jozef Stefan Institute
University of York
Budapest University of Technology and Economics
KTH Royal Institute of Technology
Barcelona Supercomputer Centre
KARLSRUHER INSTITUT FUER TECHNOLOGIE
University of Milano-Bicocca
Ecole Polytechnique
Technische Universität Graz
Aristotle University of Thessaloniki
Technical University of Denmark
Aalto University
Vienna University of Technology
University of Helsinki
Foundation of Research and Technology
IPAG
Durham University
Politecnico di Torino
ICREA
University of Cassino
UNIVERSITY COLLEGE CORK, NATIONAL UNIVERSITY OF IRELAND, CORK
National Institute for Laser, Plasma and Radiation Physics
Chalmers University of Technology
Institute for Plasma Research
Queens University
National Institutes for Quantum and Radiological Science and Technology
Universidad Nacional de Educación a Distancia
Kurchatov Institute
Troitsk Insitute of Innovating and Thermonuclear Research (TRINITI)
The National Institute for Cryogenics and Isotopic Technology
Università degli Studi di Catania
Fusion for Energy
National Institute for Fusion Science
Massachusetts Institute of Technology
University of Latvia
Imperial College London
Oak Ridge National Laboratory
Maritime University of Szczecin
Institute of Nuclear Physics PAN
University of Trento
Lviv Polytechnic National University
The National Institute for Optoelectronics
Fourth State Research
University of Texas at Austin
STUDIECENTRUM VOOR KERNENERGIE / CENTRE D'ETUDE DE L'ENERGIE NUCLEAIRE
Narodowe Centrum Badań Jadrowych
Princeton Plasma Physics Laboratory
Institute of Plasma Physics Chinese Academy of Sciences
Center for Energy Research
EUROfusion
The 'Horia Hulubei' National Institute for Physics and Nuclear Engineering
European Commission
Universidad Politécnica de Madrid
Second University of Napoli
Warsaw University of Technology
University of Basilicata
Centro Brasileiro de Pesquisas Fisicas
Ioffe Physical-Technical Institute of the Russian Academy of Sciences
General Atomics
University of Toyama
University of Tuscia
KAIST
Seoul National University
University of Opole
Daegu University
National Fusion Research Institute (NFRI)
Dublin City University
Pelin Llc
Arizona State University
Universidad Complutense de Madrid
University of Basel
University Mlynska
Consorzio CREATE
NCSR 'Demokritos'
Purdue University
University of California
Universidade de São Paulo
Lithuanian Energy Institute
HRS Fusion
University of Electronic Science and Technology of China

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

63 Citations (Scopus)

Résumé

The RAPTOR code is a control-oriented core plasma profile simulator with various applications in control design and verification, discharge optimization and real-time plasma simulation. To date, RAPTOR was capable of simulating the evolution of poloidal flux and electron temperature using empirical transport models, and required the user to input assumptions on the other profiles and plasma parameters. We present an extension of the code to simulate the temperature evolution of both ions and electrons, as well as the particle density transport. A proof-of-principle neural-network emulation of the quasilinear gyrokinetic QuaLiKiz transport model is coupled to RAPTOR for the calculation of first-principle-based heat and particle turbulent transport. These extended capabilities are demonstrated in a simulation of a JET discharge. The multi-channel simulation requires ∼0.2 s to simulate 1 second of a JET plasma, corresponding to ∼20 energy confinement times, while predicting experimental profiles within the limits of the transport model. The transport model requires no external inputs except for the boundary condition at the top of the H-mode pedestal. This marks the first time that simultaneous, accurate predictions of T _e, T _i and n _e have been obtained using a first-principle-based transport code that can run in faster-than-real-time for present-day tokamaks.

langue originale	Anglais
Numéro d'article	096006
journal	Nuclear Fusion
Volume	58
Numéro de publication	9
Les DOIs	https://doi.org/10.1088/1741-4326/aac8f0
état	Publié - 3 juil. 2018

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10.1088/1741-4326/aac8f0

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@article{f82243fc8e584753996af032900f2aba,

title = "Real-time-capable prediction of temperature and density profiles in a tokamak using RAPTOR and a first-principle-based transport model",

abstract = "The RAPTOR code is a control-oriented core plasma profile simulator with various applications in control design and verification, discharge optimization and real-time plasma simulation. To date, RAPTOR was capable of simulating the evolution of poloidal flux and electron temperature using empirical transport models, and required the user to input assumptions on the other profiles and plasma parameters. We present an extension of the code to simulate the temperature evolution of both ions and electrons, as well as the particle density transport. A proof-of-principle neural-network emulation of the quasilinear gyrokinetic QuaLiKiz transport model is coupled to RAPTOR for the calculation of first-principle-based heat and particle turbulent transport. These extended capabilities are demonstrated in a simulation of a JET discharge. The multi-channel simulation requires ∼0.2 s to simulate 1 second of a JET plasma, corresponding to ∼20 energy confinement times, while predicting experimental profiles within the limits of the transport model. The transport model requires no external inputs except for the boundary condition at the top of the H-mode pedestal. This marks the first time that simultaneous, accurate predictions of T e, T i and n e have been obtained using a first-principle-based transport code that can run in faster-than-real-time for present-day tokamaks.",

keywords = "integrated tokamak simulation, machine learning, real-time control, tokamak profiles, tokamak transport",

author = "J. Redondo and H. Meyer and Th Eich and M. Beurskens and S. Coda and A. Hakola and P. Martin and J. Adamek and M. Agostini and D. Aguiam and J. Ahn and L. Aho-Mantila and R. Akers and R. Albanese and R. Aledda and E. Alessi and S. Allan and D. Alves and R. Ambrosino and L. Amicucci and H. Anand and G. Anastassiou and Y. Andr{\`e}be and C. Angioni and G. Apruzzese and M. Ariola and H. Arnichand and W. Arter and A. Baciero and M. Barnes and L. Barrera and R. Behn and A. Bencze and J. Bernardo and A. Krivska and A. Lyssoivan and I. Stepanov and G. Verdoolaege and T. Wauters and K. Cromb{\'e} and P. Dumortier and F. Durodi{\'e} and S. Jachmich and Y. Kazakov and E. Lerche and A. Messiaen and S. Moradi and J. Ongena and R. Ragona and \{van Eester\}, D. and \{The ASDEX Upgrade, MAST and TCV Teams\} and \{JET Contributors\}",

note = "Publisher Copyright: {\textcopyright} EURATOM 2018.",

year = "2018",

month = jul,

day = "3",

doi = "10.1088/1741-4326/aac8f0",

language = "English",

volume = "58",

journal = "Nuclear Fusion",

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T1 - Real-time-capable prediction of temperature and density profiles in a tokamak using RAPTOR and a first-principle-based transport model

AU - Redondo, J.

AU - Meyer, H.

AU - Eich, Th

AU - Beurskens, M.

AU - Coda, S.

AU - Hakola, A.

AU - Martin, P.

AU - Adamek, J.

AU - Agostini, M.

AU - Aguiam, D.

AU - Ahn, J.

AU - Aho-Mantila, L.

AU - Akers, R.

AU - Albanese, R.

AU - Aledda, R.

AU - Alessi, E.

AU - Allan, S.

AU - Alves, D.

AU - Ambrosino, R.

AU - Amicucci, L.

AU - Anand, H.

AU - Anastassiou, G.

AU - Andrèbe, Y.

AU - Angioni, C.

AU - Apruzzese, G.

AU - Ariola, M.

AU - Arnichand, H.

AU - Arter, W.

AU - Baciero, A.

AU - Barnes, M.

AU - Barrera, L.

AU - Behn, R.

AU - Bencze, A.

AU - Bernardo, J.

AU - Krivska, A.

AU - Lyssoivan, A.

AU - Stepanov, I.

AU - Verdoolaege, G.

AU - Wauters, T.

AU - Crombé, K.

AU - Dumortier, P.

AU - Durodié, F.

AU - Jachmich, S.

AU - Kazakov, Y.

AU - Lerche, E.

AU - Messiaen, A.

AU - Moradi, S.

AU - Ongena, J.

AU - Ragona, R.

AU - van Eester, D.

AU - The ASDEX Upgrade, MAST and TCV Teams

AU - JET Contributors

PY - 2018/7/3

Y1 - 2018/7/3

N2 - The RAPTOR code is a control-oriented core plasma profile simulator with various applications in control design and verification, discharge optimization and real-time plasma simulation. To date, RAPTOR was capable of simulating the evolution of poloidal flux and electron temperature using empirical transport models, and required the user to input assumptions on the other profiles and plasma parameters. We present an extension of the code to simulate the temperature evolution of both ions and electrons, as well as the particle density transport. A proof-of-principle neural-network emulation of the quasilinear gyrokinetic QuaLiKiz transport model is coupled to RAPTOR for the calculation of first-principle-based heat and particle turbulent transport. These extended capabilities are demonstrated in a simulation of a JET discharge. The multi-channel simulation requires ∼0.2 s to simulate 1 second of a JET plasma, corresponding to ∼20 energy confinement times, while predicting experimental profiles within the limits of the transport model. The transport model requires no external inputs except for the boundary condition at the top of the H-mode pedestal. This marks the first time that simultaneous, accurate predictions of T e, T i and n e have been obtained using a first-principle-based transport code that can run in faster-than-real-time for present-day tokamaks.

AB - The RAPTOR code is a control-oriented core plasma profile simulator with various applications in control design and verification, discharge optimization and real-time plasma simulation. To date, RAPTOR was capable of simulating the evolution of poloidal flux and electron temperature using empirical transport models, and required the user to input assumptions on the other profiles and plasma parameters. We present an extension of the code to simulate the temperature evolution of both ions and electrons, as well as the particle density transport. A proof-of-principle neural-network emulation of the quasilinear gyrokinetic QuaLiKiz transport model is coupled to RAPTOR for the calculation of first-principle-based heat and particle turbulent transport. These extended capabilities are demonstrated in a simulation of a JET discharge. The multi-channel simulation requires ∼0.2 s to simulate 1 second of a JET plasma, corresponding to ∼20 energy confinement times, while predicting experimental profiles within the limits of the transport model. The transport model requires no external inputs except for the boundary condition at the top of the H-mode pedestal. This marks the first time that simultaneous, accurate predictions of T e, T i and n e have been obtained using a first-principle-based transport code that can run in faster-than-real-time for present-day tokamaks.

KW - integrated tokamak simulation

KW - machine learning

KW - real-time control

KW - tokamak profiles

KW - tokamak transport

UR - https://www.scopus.com/pages/publications/85051239087

U2 - 10.1088/1741-4326/aac8f0

DO - 10.1088/1741-4326/aac8f0

M3 - Article

AN - SCOPUS:85051239087

SN - 0029-5515

VL - 58

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 9

M1 - 096006

ER -

Real-time-capable prediction of temperature and density profiles in a tokamak using RAPTOR and a first-principle-based transport model

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