%0 Journal Article %1 gábor2005space %A Tóth, Gábor %A Sokolov, Igor V. %A Gombosi, Tamas I. %A Chesney, David R. %A Clauer, C. Robert %A Zeeuw, Darren L. De %A Hansen, Kenneth C. %A Kane, Kevin J. %A Manchester, Ward B. %A Oehmke, Robert C. %A Powell, Kenneth G. %A Ridley, Aaron J. %A Roussev, Ilia I. %A Stout, Quentin F. %A Volberg, Ovsei %A Wolf, Richard A. %A Sazykin, Stanislav %A Chan, Anthony %A Yu, Bin %A Kóta, József %D 2005 %I American Geophysical Union %J J. Geophys. Res. %K magnetosphere model space %P -- %T Space Weather Modeling Framework: A new tool for the space science community %U http://dx.doi.org/10.1029/2005JA011126 %V 110 %X The Space Weather Modeling Framework (SWMF) provides a high-performance flexible framework for physics-based space weather simulations, as well as for various space physics applications. The SWMF integrates numerical models of the Solar Corona, Eruptive Event Generator, Inner Heliosphere, Solar Energetic Particles, Global Magnetosphere, Inner Magnetosphere, Radiation Belt, Ionosphere Electrodynamics, and Upper Atmosphere into a high-performance coupled model. The components can be represented with alternative physics models, and any physically meaningful subset of the components can be used. The components are coupled to the control module via standardized interfaces, and an efficient parallel coupling toolkit is used for the pairwise coupling of the components. The execution and parallel layout of the components is controlled by the SWMF. Both sequential and concurrent execution models are supported. The SWMF enables simulations that were not possible with the individual physics models. Using reasonably high spatial and temporal resolutions in all of the coupled components, the SWMF runs significantly faster than real time on massively parallel supercomputers. This paper presents the design and implementation of the SWMF and some demonstrative tests. Future papers will describe validation (comparison of model results with measurements) and applications to challenging space weather events. The SWMF is publicly available to the scientific community for doing geophysical research. We also intend to expand the SWMF in collaboration with other model developers.

@article{gábor2005space, abstract = {The Space Weather Modeling Framework (SWMF) provides a high-performance flexible framework for physics-based space weather simulations, as well as for various space physics applications. The SWMF integrates numerical models of the Solar Corona, Eruptive Event Generator, Inner Heliosphere, Solar Energetic Particles, Global Magnetosphere, Inner Magnetosphere, Radiation Belt, Ionosphere Electrodynamics, and Upper Atmosphere into a high-performance coupled model. The components can be represented with alternative physics models, and any physically meaningful subset of the components can be used. The components are coupled to the control module via standardized interfaces, and an efficient parallel coupling toolkit is used for the pairwise coupling of the components. The execution and parallel layout of the components is controlled by the SWMF. Both sequential and concurrent execution models are supported. The SWMF enables simulations that were not possible with the individual physics models. Using reasonably high spatial and temporal resolutions in all of the coupled components, the SWMF runs significantly faster than real time on massively parallel supercomputers. This paper presents the design and implementation of the SWMF and some demonstrative tests. Future papers will describe validation (comparison of model results with measurements) and applications to challenging space weather events. The SWMF is publicly available to the scientific community for doing geophysical research. We also intend to expand the SWMF in collaboration with other model developers.}, added-at = {2009-09-03T20:04:26.000+0200}, author = {Tóth, Gábor and Sokolov, Igor V. and Gombosi, Tamas I. and Chesney, David R. and Clauer, C. Robert and Zeeuw, Darren L. De and Hansen, Kenneth C. and Kane, Kevin J. and Manchester, Ward B. and Oehmke, Robert C. and Powell, Kenneth G. and Ridley, Aaron J. and Roussev, Ilia I. and Stout, Quentin F. and Volberg, Ovsei and Wolf, Richard A. and Sazykin, Stanislav and Chan, Anthony and Yu, Bin and Kóta, József}, biburl = {https://www.bibsonomy.org/bibtex/290bc981b12ce57c1600fb201a91149f8/asherp}, description = {Space Weather Modeling Framework: A new tool for the space science community}, interhash = {de03602337689d5f79e09050a365f3dd}, intrahash = {90bc981b12ce57c1600fb201a91149f8}, journal = {J. Geophys. Res.}, keywords = {magnetosphere model space}, month = {#dec#}, pages = {--}, publisher = {American Geophysical Union}, timestamp = {2009-09-03T20:04:26.000+0200}, title = {Space Weather Modeling Framework: A new tool for the space science community}, url = {http://dx.doi.org/10.1029/2005JA011126}, volume = 110, year = 2005 }