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ASUCA: The JMA Operational Non-hydrostatic Model

Junichi Ishida, Kohei Aranami, Kohei Kawano, Kengo MATSUBAYASHI, Yuji Kitamura, Chiashi Muroi

2022Journal of the Meteorological Society of Japan Ser II42 citationsDOIOpen Access PDF

Abstract

The non-hydrostatic numerical weather prediction (NWP) model ASUCA developed by the Japan Meteorological Agency (JMA) was launched into operation as 2 and 5 km-resolution regional models in 2015 and 2017, respectively. This paper outlines specifications of ASUCA with focus on the dynamical core and its configuration/accuracy as an operational model. ASUCA is designed for high computational stability and efficiency, mass conservation and forecast accuracy. High computational stability is achieved via a time-split integration scheme to compute acoustic terms and an advection scheme with a flux-limiter function to avoid numerical oscillation. In addition, vertical advection and sedimentation are calculated together with another exclusive time-splitting technique. ASUCA adopts hybrid parallelization using Message Passing Interface (MPI) and Open Multi Processing (OpenMP) for high computational efficiency on massive parallel scalar computers. The three-dimensional arrays are allocated such that the vertical direction is the stride-one innermost dimension to make effective use of cache and multi-thread parallelization. This is particularly advantageous for physical processes evaluated in a vertical column. To ensure mass conservation, density rather than pressure is integrated as a prognostic variable in flux-form fully compressible governing equations. ASUCA exhibited better performance than the previous operational model in idealized and NWP tests.

Topics & Concepts

Numerical weather predictionAdvectionComputer scienceHydrostatic equilibriumScalar (mathematics)Numerical stabilityComputational fluid dynamicsMeteorologyComputational scienceParallel computingMechanicsNumerical analysisPhysicsMathematicsGeometryMathematical analysisThermodynamicsQuantum mechanicsMeteorological Phenomena and SimulationsClimate variability and modelsPrecipitation Measurement and Analysis
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