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European Network for Earth System Modeling (ENES) The PRISM Project Guy P. Brasseur Max Planck Institute for Meteorology Hamburg, Germany. The Climate System.
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European Network for Earth System Modeling (ENES) The PRISM Project Guy P. Brasseur Max Planck Institute for Meteorology Hamburg, Germany
The Climate System • The climate system includes the atmosphere (dynamics, physics and chemistry), the ocean (dynamics and biogeochemistry), sea-ice, continental vegetation. • It is subject to natural variability, and is affected by “external” perturbations (solar variability, volcanic eruptions, land-use changes, fossil fuel consumption, etc.)
Climate Modelling • Climate simulations will require: • High resolution integrations (from 300 km to 30 km) • Ensemble integrations (with different initial conditions, and different model configurations) • Long-term integrations (several centuries) • More complex models (including the biological and chemical processes) • Progress is limited by the availability of computing power.
European Network for Earth System Modelling (ENES) • Network of university departments, research centres, meteorological services, computer centres and industrial partners working together towards: • the development, intercomparison and evaluation of Earth system models, • the exchanges of software, • the development of high-performance computing capability dedicated to high-resolution, multi-model ensemble integrations.
Two Projects • PRISM: Programme for Integrated Earth System Modelling • CLIMSTER: Climate Data Storage and Distribution as European Infrastructure
PRogramme for Integrated earth System Modelling(PRISM) • An Infrastructure Project for Climate Research in Europe
The PRISM Project and coupling issues Context -Expertise in Europe is widely distributed -Development and application of sophisticated climate models localised in few national climate research centres - Multi-tera-scale supercomputer available within a few years but access to supercomputers restricted through national priorities -American and Japanese efforts: - USA: Accelerated Climate PRediction Initiative» (ACPRI) - Japan: «Earth Simulator Project» and «Frontier Research System» -> Europe needs to pool national efforts to establish a unified approach for Earth system modeling and match other initiatives
The PRISM Project and coupling issues • Overall PRISM Objectives • -> Develop a European portable, efficient and user-friendly Global Climate Modelling System based on actual models, and associated diagnostic/visualisation soft wares • -> Undertake a pilot infrastructure project toward the establishment of a European Climate and Earth System Modeling Supercomputer Facility.
PRISM Contributing Partners: -MPG-IMET, Germany (Dr. Guy Brasseur, coordinator) -KNMI, The Netherlands -MPI-MAD, Germany -Met-Office, United Kingdom -UREADMY, United Kingdom -IPSL, France -Météo-France, France -CERFACS, France -DMI, Denmark -SHMI, Sweden -NERSC, Norway -ETH Zurich, Switzerland -ING, Italy -MPI-BGC, Germany -PIK, Germany -ECMWF, Europe -UCL-ASTR, Belgium -NEC Deutschland -FECIT/Fujitsu -SGI Deutschland -SUN, Germany The PRISM Project -> 97 person years (48 funded by European Commission for 4,8MEuros)
The PRISM Project PRISM components: Atmospheric Chemistry -MPG-IMET -UREADMY -IPSL -Met. Office -Météo-France -KNMI Atmosphere: -MPG-IMET(ECHAM) -Météo-France (ARPEGE) -IPSL (LMDZ) -Met. Office (Unified Model) -UREADMY -ING Land Surface -IPSL (Orchidée) -Met. Office -MPG-IMET -UREADMY -Météo-France (ISBA) Regional Climate: -SHMI -DMI -Met. Office Coupler CERFACS (Oasis) Sea Ice: -NERSC -UCL-ASTR -Met. Office -IPSL -MPG-IMET Ocean Bio-geochemistry: -MPI-BGC -IPSL -MPG-IMET -Met. Office Ocean: -Met. Office (FOAM) -MPG-IMET (HOPE) -IPSL (OPA/ORCA) -UREADMY
The PRISM Project • T1: Detailed definition of a standard physical interfaces (nature of information to be exchanged) between the components. • T2: Technical development of the coupler and coupling model interface library. • T3: Physical and technical interfacing of existing state-of-art models European models. • T4: Development of common diagnostic/visualization tools and data management system. • T5: Development of a web-based interface for assembling and submitting a global climate model on the PRISM target platforms and for controlling the database archiving and post-processing. • T6: Perform test runs to demonstrate the usefulness of the system.
The PRISM Project • European Computers Available for PRISM Activities • 1. ECMWF Europe Fujitsu VPP5000 and IBM SP4 • 2. DMI Denmark NEC SX-4 • 3. Météo-France France Fujitsu VPP5000 • 4. Idris France NEC SX-5 and IBM • 5. ING Italy NEC SX-4 • 6. SARA The Netherlands Cray C-90 • 7. U. of Bergen Norway Cray T3E • 8. SMHI Sweden Cray T3E, SGI 3000 • 9. CSCS Switzerland NEC SX-4 & SX-5 • 10. Hadley Centre United Kingdom Cray T3E • 11. DKRZ Germany NEC SX-6
The future PRISM coupler: questions and concepts • Develop a coupler, i.e. model coupling interface library + additional coupling processes, that will answer the PRISM system requirements. • Key concepts for the PRISM coupler design: • modularity and flexibility • portability • scalability and efficiency • evolutivity
The future PRISM coupler: questions and concepts • Questions to answer for PRISM coupler design • -Characteristics of the PRISM coupled system (static or dynamic configuration, number of components, global or partial system, etc.) • -Characteristics of the component models (CPU load, memory requirement, etc.) • -Characteristics of the coupling fields (type, resolution, grid type, data decomposition, static or dynamically evolving, etc.) • -Coupling parameters (number of coupling fields, frequency of exchange, …) • -Target platform architecture (distributed memory vs shared memory, vector vs scalar, etc.) • -Technical constraints (ex: implementation of message passing standards on the different machines) and operating system constraints • => For present and next-generation climate modelling systems
PRISM coupler development • Development of a Model Coupling Interface library (mo 1-12): • CERFACS • -> coupling initialisation • -> parallel sending of coupling fields to sequential OASIS process • -> parallel receiving of coupling fields from sequential OASIS process • -> parallel exchange directly with other parallel model O A O A O A OASIS A O O A A O O
A possible PRISM configuration T1 T2 time D D AC A c c LS c c c I+C A c LS bc A AC c c LS c c I+C c I+C A c LS bc A AC c c LS c c I+C c I+C A c LS bc AC c I+C C I C C I C c c c O OB c c O c c SI c c c O OB c c O c c SI
Today, with current capability: • To run an ensemble of 10 coupled climate models for 100 yrs: • Atmosphere: 50 km resolution, 70 levels, 50 chemical species, timestep=5 min. • Ocean: 0.1 degrees resolution, 50 levels timestep=20 min. • Computer time required would be 60 years (20 years without chemistry) on the most advanced supercomputers.
ENES: The Project • To develop a European Supercomputing Facility providing at least 5-10 Tflops (sustained) with associate data storage system and networking, remotely accessible to the Earth System scientific community.
ENES: The Project • Budget: 200-300 Millions Euros • Architecture should be adapted to the specific needs of the climate modelling. community, and take advantage of most recent technology. • Should complement existing national facilities. • Cooperation with Data-GRID
ENES: Conclusions • A factor 100 increase in computing capability is urgently needed for climate modeling. • Such increase is key for maintaining the influence of European efforts in future international climate assessments • Such project can only be carried out at the European level with national participation. • European networking of climate centres needs to be simultaneously enhanced.