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High-resolution numerical modeling and predictability of atmospheric flows M. Ehrendorfer, A. Gohm and G. J. Mayr Institut für Meteorologie und Geophysik Universität Innsbruck Vortrag am Zweiter Mini-Workshop Konsortium Hochleistungsrechnen Universität Innsbruck, Austria 12. März 2004 http://www2.uibk.ac.at/meteo
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IMGI HPC workshop 2004 Outline High-Resolution Numerical Modeling and Predictability of Atmospheric Flows 1.Atmospheric models 2.Stability of flows specific error structures: singular vectors, data assimilation 3.Additional remarks 4.High-resolution modeling Past research: single-processor computing Current research: multi-processor parallel computing Introducing the numerical models Introducing the computing facilities An example: simulation of bora winds Outlook: numerical weather prediction for the Winter Universiade 2005
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7 Variables: wind v, density , potential temperature pressure p, temperature T budget equations: momentum, mass, energy
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P. Lynch, Met Éireann, Dublin 1922
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European Centre for Medium-Range Weather Forecasts ECMWF Reading, UK Operational models: 10^7 – 10^8 variables
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- sensitive dependence on i.c. - preferred directions of growth Lorenz 1984 model
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growing directions: stability of the flow correct for in initial condition zid-cc
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o3800 NAG
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ZID-CC French storm 24/12/1999/1200
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Nonlinear error growth 0.01% tau_d = 12 h
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o3800 12690^2 Optimized TL error growth data assimilation stability, error dynamics tau_d = 4.9 h
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SIAM Rev. 2003 Science Case for Large-scale Simulation pnl.gov/scales
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IMGI HPC workshop 2004 Outline High-Resolution Numerical Modeling and Predictability of Atmospheric Flows 1.Atmospheric models 2.Stability of flows specific error structures: singular vectors, data assimilation 3.Additional remarks 4.High-resolution modeling Past research: single-processor computing Current research: multi-processor parallel computing Introducing the numerical models Introducing the computing facilities An example: simulation of bora winds Outlook: numerical weather prediction for the Winter Universiade 2005
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IMGI HPC workshop 2004 High-Resolution Numerical Modeling of Atmospheric Flows flow over mountains orographically induced precipitation flow around mountains flow through mountain gaps Past Research – Single-processor computing (Origin XL, o2000)
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Current Research – Multi-processor parallel computing (Origin o3800, ZID-CC) High-Resolution Numerical Modeling of Atmospheric Flows IMGI HPC workshop 2004 Numerical modeling with realistic orography case studies weather prediction Flow around the AlpsFlow over the Alps
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boundary conditions analysis or forecast We are using two models Global Model (ECMWF*) * European Centre for Medium-Range Weather Forecasts (Reading, UK) ** Regional Atmospheric Modeling System (CSU, Ft. Collins, USA) spectral technique single global domain x 40 km (TL511) High-Resolution Numerical Modeling of Atmospheric Flows IMGI HPC workshop 2004 Limited Area Model (RAMS**) finite-difference technique several nested domains, covering limited areas, centered near the location of interest x 100 m – 1 km
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Global Model @ ECMWF (UK) IBM supercomputer 2 clusters, each with 30 servers (p690), each server having 32 processors (1.3 GHz Power4) Origin o3800 compute-server 48 processors (600 MHz MIPS R14000) RAMS @ ZID (IBK) ZID-CC compute-cluster 16 servers (Transtec), each with 2 processors (2.2 GHz Intel Xeon) ftp High-Resolution Numerical Modeling of Atmospheric Flows IMGI HPC workshop 2004
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RAMS model setup 5 nested grids x = 267 m to 65 km 56 vertical levels 6443024 grid points 1440 master time steps for 1-day forecast Parallel computing on ZID-CC cluster 8 processors master–slave configuration domain decomposition technique High-Resolution Numerical Modeling of Atmospheric Flows IMGI HPC workshop 2004 An example: Simulation of bora winds to the lee of the Dinaric Alps
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Computing time for RAMS at ZID-CC cluster with 8 CPUs ~180 seconds for a 60-second time step 73.8 hours for a 24-hour simulation number of time steps elapsed seconds } nodes } master Every time step: I/O communication Every 20 minutes: update with radiative transfer model Every hour: data I/O from/to hard disk by master node High-Resolution Numerical Modeling of Atmospheric Flows IMGI HPC workshop 2004
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An example: Simulation of bora winds to the lee of the Dinaric Alps High-Resolution Numerical Modeling of Atmospheric Flows IMGI HPC workshop 2004 DLR Falcon backscatter lidar observation Adriatic Sea Dinaric Alps flow simulation bora
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Outlook: Numerical Weather Prediction (NWP) @ IMGI/ZID High-Resolution Numerical Modeling of Atmospheric Flows IMGI HPC workshop 2004 Goal Set up RAMS as NWP model for the Innsbruck region Compute daily forecast on ZID-CC and/or Origin 3800 Benefit Resolving various weather phenomena occurring in different spatial scales: between the Alpine scale (L~100 km) and the valley scale (L~1 km)
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F. Rabier, Météo France Ehrendorfer et al. 1999 80.000^2 iterative Lanczos
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A. Simmons, ECMWF Heutige 5-Tages Prognose ebenso gut wie 4-Tages Prognose for 6 Jahren
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Temperatur- Unsicherheit aus Ensemble von 50 Vorhersagen (anfänglich leicht verschieden) ECMWF
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A. Simmons, ECMWF amplification of 1-day forecast error
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