Stalled improvement in a numerical weather prediction model as horizontal resolution increases to the Sub-Kilometer Scale

Junshi Ito; Syugo Hayashi; Akihiro Hashimoto; Hideaki Ohtake; Fumichika Uno; Hiromasa Yoshimura; Teruyuki Kato; Yoshinori Yamada

doi:10.2151/sola.2017-028

Stalled improvement in a numerical weather prediction model as horizontal resolution increases to the Sub-Kilometer Scale

Junshi Ito, Syugo Hayashi, Akihiro Hashimoto, Hideaki Ohtake, Fumichika Uno, Hiromasa Yoshimura, Teruyuki Kato, Yoshinori Yamada

SCI - Geophysics

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

This study evaluated the performance of a regional weather prediction model. The horizontal resolution is increased to the sub-kilometer scale in a series of experiments over areas of Japan through the summer or winter seasons of 2015-2016. The performance improves less when increasing the horizontal resolution from 2 km to 1 km or 500 m than it does from 5 km to 2 km, especially when topography and ice microphysics are less relevant. Although the velocity and magnitude of updrafts, cloud size, and convection in the boundary layer indeed change with the horizontal resolution, these differences turn out to have little impact on the model performance.

Original language	English
Pages (from-to)	151-156
Number of pages	6
Journal	Scientific Online Letters on the Atmosphere
Volume	13
DOIs	https://doi.org/10.2151/sola.2017-028
Publication status	Published - 2017

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10.2151/sola.2017-028

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title = "Stalled improvement in a numerical weather prediction model as horizontal resolution increases to the Sub-Kilometer Scale",

abstract = "This study evaluated the performance of a regional weather prediction model. The horizontal resolution is increased to the sub-kilometer scale in a series of experiments over areas of Japan through the summer or winter seasons of 2015-2016. The performance improves less when increasing the horizontal resolution from 2 km to 1 km or 500 m than it does from 5 km to 2 km, especially when topography and ice microphysics are less relevant. Although the velocity and magnitude of updrafts, cloud size, and convection in the boundary layer indeed change with the horizontal resolution, these differences turn out to have little impact on the model performance.",

author = "Junshi Ito and Syugo Hayashi and Akihiro Hashimoto and Hideaki Ohtake and Fumichika Uno and Hiromasa Yoshimura and Teruyuki Kato and Yoshinori Yamada",

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AU - Ito, Junshi

AU - Hayashi, Syugo

AU - Hashimoto, Akihiro

AU - Ohtake, Hideaki

AU - Uno, Fumichika

AU - Yoshimura, Hiromasa

AU - Kato, Teruyuki

AU - Yamada, Yoshinori

N1 - Funding Information: We would like to thank two anonymous reviewers for helpful suggestions and comments. This work is partly supported by FLAGSHIP 2020, MEXT within priority study 4 (Advancement of Meteorological and Global Environmental Predictions Utilizing Observational "Big Data"). Publisher Copyright: © 2017, the Meteorological Society of Japan.

PY - 2017

Y1 - 2017

N2 - This study evaluated the performance of a regional weather prediction model. The horizontal resolution is increased to the sub-kilometer scale in a series of experiments over areas of Japan through the summer or winter seasons of 2015-2016. The performance improves less when increasing the horizontal resolution from 2 km to 1 km or 500 m than it does from 5 km to 2 km, especially when topography and ice microphysics are less relevant. Although the velocity and magnitude of updrafts, cloud size, and convection in the boundary layer indeed change with the horizontal resolution, these differences turn out to have little impact on the model performance.

AB - This study evaluated the performance of a regional weather prediction model. The horizontal resolution is increased to the sub-kilometer scale in a series of experiments over areas of Japan through the summer or winter seasons of 2015-2016. The performance improves less when increasing the horizontal resolution from 2 km to 1 km or 500 m than it does from 5 km to 2 km, especially when topography and ice microphysics are less relevant. Although the velocity and magnitude of updrafts, cloud size, and convection in the boundary layer indeed change with the horizontal resolution, these differences turn out to have little impact on the model performance.

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JO - Scientific Online Letters on the Atmosphere

JF - Scientific Online Letters on the Atmosphere

ER -

Stalled improvement in a numerical weather prediction model as horizontal resolution increases to the Sub-Kilometer Scale

Abstract

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