A Novel GPU-Based Acceleration Algorithm for a Longwave Radiative Transfer Model

Graphics processing unit (GPU)-based computing for climate system models is a longstanding research area of interest. The rapid radiative transfer model for general circulation models (RRTMG), a popular atmospheric radiative transfer model, can calculate atmospheric radiative fluxes and heating rate...

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Bibliographic Details
Published in:Applied sciences 2020-01, Vol.10 (2), p.649
Main Authors: Wang, Yuzhu, Zhao, Yuan, Jiang, Jinrong, Zhang, He
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Atmospheric circulation
Central processing units
Climate models
Climate system
compute unified device architecture
Cooling
CPUs
Efficiency
Fluxes
General circulation models
graphics processing unit
Graphics processing units
high performance computing
Long wave radiation
Meteorological satellites
Programming languages
Radiation
radiation transfer
Radiative transfer
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Summary:Graphics processing unit (GPU)-based computing for climate system models is a longstanding research area of interest. The rapid radiative transfer model for general circulation models (RRTMG), a popular atmospheric radiative transfer model, can calculate atmospheric radiative fluxes and heating rates. However, the RRTMG has a high calculation time, so it is urgent to study its GPU-based efficient acceleration algorithm to enable large-scale and long-term climatic simulations. To improve the calculative efficiency of radiation transfer, this paper proposes a GPU-based acceleration algorithm for the RRTMG longwave radiation scheme (RRTMG_LW). The algorithm concept is accelerating the RRTMG_LW in the g- p o i n t dimension. After implementing the algorithm in CUDA Fortran, the G-RRTMG_LW was developed. The experimental results indicated that the algorithm was effective. In the case without I/O transfer, the G-RRTMG_LW on one K40 GPU obtained a speedup of 30.98× over the baseline performance on one single Intel Xeon E5-2680 CPU core. When compared to its counterpart running on 10 CPU cores of an Intel Xeon E5-2680 v2, the G-RRTMG_LW on one K20 GPU in the case without I/O transfer achieved a speedup of 2.35×.
ISSN:2076-3417
2076-3417
DOI:10.3390/app10020649