Design and first applications of the ITER integrated modelling & analysis suite

被引：127

作者：

Imbeaux, F. ^{[1
]}

Pinches, S. D. ^{[2
]}

Lister, J. B. ^{[3
]}

Buravand, Y. ^{[1
]}

Casper, T. ^{[2
]}

Duval, B. ^{[3
]}

Guillerminet, B. ^{[1
]}

Hosokawa, M. ^{[2
]}

Houlberg, W. ^{[2
]}

Huynh, P. ^{[1
]}

Kim, S. H. ^{[2
]}

Manduchi, G. ^{[4
]}

Owsiak, M. ^{[5
]}

Palak, B. ^{[5
]}

Plociennik, M. ^{[5
]}

Rouault, G. ^{[6
]}

Sauter, O. ^{[3
]}

Strand, P. ^{[7
]}

机构：

[1] CEA, IRFM, F-13108 St Paul Les Durance, France

[2] ITER Org, F-13067 St Paul Les Durance, France

[3] Ecole Polytech Fed Lausanne, Ctr Rech Phys Plasmas, Assoc EURATOM Confederat Suisse, CH-1015 Lausanne, Switzerland

[4] Consorzio RFX, I-35127 Padua, Italy

[5] Poznan Supercomp & Networking Ctr, Poznan, Poland

[6] CORYS TESS, F-38024 Grenoble 1, France

[7] Chalmers Univ Technol, S-41296 Gothenburg, Sweden

来源：

NUCLEAR FUSION | 2015年 / 55卷 / 12期

关键词：

integrated modelling; modelling infrastructure; ITER; plasma control system; SIMULATION; TRANSPORT;

D O I：

10.1088/0029-5515/55/12/123006

中图分类号：

O35 [流体力学]; O53 [等离子体物理学];

学科分类号：

070204 ; 080103 ; 080704 ;

摘要：

The ITER Integrated Modelling & Analysis Suite (IMAS) will support both plasma operation and research activities on the ITER tokamak experiment. The IMAS will be accessible to all ITER members as a key tool for the scientific exploitation of ITER. The backbone of the IMAS infrastructure is a standardized, machine-generic data model that represents simulated and experimental data with identical structures. The other outcomes of the IMAS design and prototyping phase are a set of tools to access data and design integrated modelling workflows, as well as first plasma simulators workflows and components implemented with various degrees of modularity.

引用

页数：13

共 17 条

[1] The CRONOS suite of codes for integrated tokamak modelling [J].

Artaud, J. F. ;

Basiuk, V. ;

Imbeaux, F. ;

Schneider, M. ;

Garcia, J. ;

Giruzzi, G. ;

Huynh, P. ;

Aniel, T. ;

Albajar, F. ;

Ane, J. M. ;

Becoulet, A. ;

Bourdelle, C. ;

Casati, A. ;

Colas, L. ;

Decker, J. ;

Dumont, R. ;

Eriksson, L. G. ;

Garbet, X. ;

Guirlet, R. ;

Hertout, P. ;

Hoang, G. T. ;

Houlberg, W. ;

Huysmans, G. ;

Joffrin, E. ;

Kim, S. H. ;

Koechl, F. ;

Lister, J. ;

Litaudon, X. ;

Maget, P. ;

Masset, R. ;

Pegourie, B. ;

Peysson, Y. ;

Thomas, P. ;

Tsitroneand, E. ;

Turco, F. .

NUCLEAR FUSION, 2010, 50 (04)

[2] Simulation of fusion plasmas: Current status and future direction [J].

Batchelor, D. A. ;

Beck, M. ;

Becoulet, A. ;

Budny, R. V. ;

Chang, C. S. ;

Diamond, P. H. ;

Dong, J. Q. ;

Fu, G. Y. ;

Fukuyama, A. ;

Hahm, T. S. ;

Keyes, D. E. ;

Kishimoto, Y. ;

Klasky, S. ;

Lao, L. L. ;

Li, K. ;

Lin, Z. ;

Ludaescher, B. ;

Manickam, J. ;

Nakajima, N. ;

Ozeki, T. ;

Podhorszki, N. ;

Tang, W. M. ;

Vouk, M. A. ;

Waltz, R. E. ;

Wang, S. J. ;

Wilson, H. R. ;

Xu, X. Q. ;

Yagi, M. ;

Zonca, F. .

PLASMA SCIENCE & TECHNOLOGY, 2007, 9 (03) :312-387

[3] The way towards thermonuclear fusion simulators [J].

Becoulet, A. ;

Strand, P. ;

Wilson, H. ;

Romanelli, M. ;

Eriksson, L.-G. .

COMPUTER PHYSICS COMMUNICATIONS, 2007, 177 (1-2) :55-59

[4] Development of the ITER baseline inductive scenario [J].

Casper, T. ;

Gribov, Y. ;

Kavin, A. ;

Lukash, V. ;

Khayrutdinov, R. ;

Fujieda, H. ;

Kessel, C. .

NUCLEAR FUSION, 2014, 54 (01)

[5]

Coster D.P., 2010, T PLASMA SCI, V38, P2085

[6]

Crotinger J A, 1997, LLNL Report UCRL-ID-126284 NTIS #PB2005-102154

[7] The European Integrated Tokamak Modelling (ITM) effort: achievements and first physics results [J].

Falchetto, G. L. ;

Coster, D. ;

Coelho, R. ;

Scott, B. D. ;

Figini, L. ;

Kalupin, D. ;

Nardon, E. ;

Nowak, S. ;

Alves, L. L. ;

Artaud, J. F. ;

Basiuk, V. ;

Bizarro, Jao P. S. ;

Boulbe, C. ;

Dinklage, A. ;

Farina, D. ;

Faugeras, B. ;

Ferreira, J. ;

Figueiredo, A. ;

Huynh, Ph ;

Imbeaux, F. ;

Ivanova-Stanik, I. ;

Jonsson, T. ;

Klingshirn, H-J ;

Konz, C. ;

Kus, A. ;

Marushchenko, N. B. ;

Pereverzev, G. ;

Owsiak, M. ;

Poli, E. ;

Peysson, Y. ;

Reimer, R. ;

Signoret, J. ;

Sauter, O. ;

Stankiewicz, R. ;

Strand, P. ;

Voitsekhovitch, I. ;

Westerhof, E. ;

Zok, T. ;

Zwingmann, W. .

NUCLEAR FUSION, 2014, 54 (04)

[8] Easy use of high performance computers for fusion simulations [J].

Frauel, Y. ;

Coster, D. ;

Guillerminet, B. ;

Imbeaux, F. ;

Jackson, A. ;

Konz, C. ;

Owsiak, M. ;

Plociennik, M. ;

Scott, B. ;

Strand, P. .

FUSION ENGINEERING AND DESIGN, 2012, 87 (12) :2057-2062

[9] Bootstrap current and neoclassical transport in tokamaks of arbitrary collisionality and aspect ratio [J].

Houlberg, WA ;

Shaing, KC ;

Hirshman, SP ;

Zarnstorff, MC .

PHYSICS OF PLASMAS, 1997, 4 (09) :3230-3242

[10] A generic data structure for integrated modelling of tokamak physics and subsystems [J].

Imbeaux, F. ;

Lister, J. B. ;

Huysmans, G. T. A. ;

Zwingmann, W. ;

Airaj, M. ;

Appel, L. ;

Basiuk, V. ;

Coster, D. ;

Eriksson, L-G. ;

Guillerminet, B. ;

Kalupin, D. ;

Konz, C. ;

Manduchi, G. ;

Ottaviani, M. ;

Pereverzev, G. ;

Peysson, Y. ;

Sauter, O. ;

Signoret, J. ;

Strand, P. .

COMPUTER PHYSICS COMMUNICATIONS, 2010, 181 (06) :987-998

← 1 2 →