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dc.contributor.authorSANTOS, Marcelo C. Dos-
dc.contributor.authorPEREIRA, Claudio M. N. A.-
dc.contributor.authorSCHIRRU, Roberto-
dc.contributor.authorPINHEIRO, André-
dc.date.accessioned2018-01-18T18:47:09Z-
dc.date.available2018-01-18T18:47:09Z-
dc.identifier.urihttp://carpedien.ien.gov.br:8080/handle/ien/2145-
dc.languageengpt_BR
dc.publisherInstituto de Engenharia Nuclearpt_BR
dc.rightsopenAccesspt_BR
dc.subjectRADIOACTIVE MATERIALpt_BR
dc.subjectATMOSPHERIC TRANSPORTpt_BR
dc.titleGPU-BASED PARALLEL COMPUTING IN REAL-TIME MODELING OF ATMOSPHERIC TRANSPORT AND DIFFUSION OF RADIOACTIVE MATERIALpt_BR
dc.typeconferenceObjectpt_BR
dc.description.resumoAtmospheric radionuclide dispersion systems (ARDS) are essential mechanisms to predict the consequences of unexpected radioactive releases from nuclear power plants. Considering, that during an eventuality of an accident with a radioactive material release, an accurate forecast is vital to guide the evacuation plan of the possible affected areas. However, in order to predict the dispersion of the radioactive material and its impact on the environment, the model must process information about source term (radioactive materials released, activities and location), weather condition (wind, humidity and precipitation) and geographical characteristics (topography). Furthermore, ARDS is basically composed of 4 main modules: Source Term, Wind Field, Plume Dispersion and Doses Calculations. The Wind Field and Plume Dispersion modules are the ones that require a high computational performance to achieve accurate results within an acceptable time. Taking this into account, this work focuses on the development of a GPU-based parallel Plume Dispersion module, focusing on the radionuclide transport and diffusion calculations, which use a given wind field and a released source term as parameters. The program is being developed using the C ++ programming language, allied with CUDA libraries. In comparative case study between a parallel and sequential version of the slower function of the Plume Dispersion module, a speedup of 11.63 times could be observed.pt_BR
dc.publisher.countryBrasilpt_BR
dc.publisher.initialsIENpt_BR
dc.citation.issue2017pt_BR
dc.creator.affiliationInstituto de Engenharia Nuclear, CNEN.-
dc.creator.affiliationInstituto de Engenharia Nuclear, CNEN.-
dc.creator.affiliationPrograma de Engenharia Nuclear – COPPE Universidade Federal do Rio de Janeiro-
dc.creator.affiliationPrograma de Engenharia Nuclear – COPPE Universidade Federal do Rio de Janeiro-
Aparece nas coleções:Realidade Virtual Aplicada na Área Nuclear - Trabalhos de Congresso

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