Computational performance of ultra-high-resolution capability in the Community Earth System Model

John M. Dennis; Mariana Vertenstein; Patrick H. Worley; Arthur A. Mirin; Anthony P. Craig; Robert Jacob; Sheri Mickelson

doi:10.1177/1094342012436965

Computational performance of ultra-high-resolution capability in the Community Earth System Model

John M. Dennis, Mariana Vertenstein, Patrick H. Worley, Arthur A. Mirin, Anthony P. Craig, Robert Jacob, Sheri Mickelson

Application Scalability and Performance Group

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

60 Scopus citations

Abstract

With the fourth release of the Community Climate System Model, the ability to perform ultra-high-resolution climate simulations is now possible, enabling eddy-resolving ocean and sea-ice models to be coupled to a finite-volume atmosphere model for a range of atmospheric resolutions. This capability was made possible by enabling the model to use large scale parallelism, which required a significant refactoring of the software infrastructure. We describe the scalability of two ultra-high-resolution coupled configurations on leadership class computing platforms. We demonstrate the ability to utilize over 30,000 processor cores on a Cray XT5 system and over 60,000 cores on an IBM Blue Gene/P system to obtain climatologically relevant simulation rates for these configurations.

Original language	English
Pages (from-to)	5-16
Number of pages	12
Journal	International Journal of High Performance Computing Applications
Volume	26
Issue number	1
DOIs	https://doi.org/10.1177/1094342012436965
State	Published - Feb 2012

Keywords

application optimization
climate modeling
Earth system modeling
high-resolution
Performance engineering

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title = "Computational performance of ultra-high-resolution capability in the Community Earth System Model",

abstract = "With the fourth release of the Community Climate System Model, the ability to perform ultra-high-resolution climate simulations is now possible, enabling eddy-resolving ocean and sea-ice models to be coupled to a finite-volume atmosphere model for a range of atmospheric resolutions. This capability was made possible by enabling the model to use large scale parallelism, which required a significant refactoring of the software infrastructure. We describe the scalability of two ultra-high-resolution coupled configurations on leadership class computing platforms. We demonstrate the ability to utilize over 30,000 processor cores on a Cray XT5 system and over 60,000 cores on an IBM Blue Gene/P system to obtain climatologically relevant simulation rates for these configurations.",

keywords = "application optimization, climate modeling, Earth system modeling, high-resolution, Performance engineering",

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AU - Dennis, John M.

AU - Vertenstein, Mariana

AU - Worley, Patrick H.

AU - Mirin, Arthur A.

AU - Craig, Anthony P.

AU - Jacob, Robert

AU - Mickelson, Sheri

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AB - With the fourth release of the Community Climate System Model, the ability to perform ultra-high-resolution climate simulations is now possible, enabling eddy-resolving ocean and sea-ice models to be coupled to a finite-volume atmosphere model for a range of atmospheric resolutions. This capability was made possible by enabling the model to use large scale parallelism, which required a significant refactoring of the software infrastructure. We describe the scalability of two ultra-high-resolution coupled configurations on leadership class computing platforms. We demonstrate the ability to utilize over 30,000 processor cores on a Cray XT5 system and over 60,000 cores on an IBM Blue Gene/P system to obtain climatologically relevant simulation rates for these configurations.

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KW - Earth system modeling

KW - high-resolution

KW - Performance engineering

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Computational performance of ultra-high-resolution capability in the Community Earth System Model

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Keywords

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