seismic wave propagation and imaging in complex media: a european network suggestions for synthetic...
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Seismic wave Propagation and Imaging in Complex media: a European network
Suggestions for synthetic data storage
• The SPICE project
• Expected seismic simulation data
• Results of ORFEUS/SPICE Meeting May 7, 2004
• Examples
• The SPICE project
• Expected seismic simulation data
• Results of ORFEUS/SPICE Meeting May 7, 2004
• Examples
H., Igel, J. Wassermann, M. Stupazzini (Munich)J.-P. Vilotte (IPG Paris)B. Dost, T. Van Eck (ORFEUS)
Seismic wave Propagation In Complex media: a European network
• Marie Curie Research Training network in the 6th Framework Programme (Coordination: Munich seismology)
• 14 institutions (INGV Rome, IPG, ENS Paris, Oxford, Utrecht, Munich, Bratislava, Prague, Oslo, Dublin, Naples, Hamburg, Trieste, Zurich)
• 14 postdocs and 14 PhDs, 4-year project (start 2004)
• Training workshops, development of training material
• Four task groups in the fields of (1) Global seismology, (2) volcano seismology and reservoir seismics, (3) earthquake physics and (4) digital library
• Marie Curie Research Training network in the 6th Framework Programme (Coordination: Munich seismology)
• 14 institutions (INGV Rome, IPG, ENS Paris, Oxford, Utrecht, Munich, Bratislava, Prague, Oslo, Dublin, Naples, Hamburg, Trieste, Zurich)
• 14 postdocs and 14 PhDs, 4-year project (start 2004)
• Training workshops, development of training material
• Four task groups in the fields of (1) Global seismology, (2) volcano seismology and reservoir seismics, (3) earthquake physics and (4) digital library
One specific SPICE task:Develop archive with synthetic simulation data, www-interface for data access, visualization, extraction etc.
Expected simulation data:
Volcano seismology
Example: Merapi volcano, Indonesia
Example: Merapi volcano, Indonesia
From: Ripperger, Igel, Wassermann, 2004
Expected simulation data:
Dynamic rupture
From: Brietzke and Ben-Zion, 2004
Example: Rupture at material interfacesExample: Rupture at material interfaces
Expected simulation data:
Earthquake scenariosRoermond – earthquake M5.9, 1992
Cologne basin Germany
Expected simulation data: Global seismology
ORFEUS-SPICE Meeting May 7, 2004 – Results 1/2
• SEED/miniSEED seems to be the most appropriate synthetic data format for compatibility with the observational IT infrastructure
• We defined three synthetic data types:
• Type 1: Synthetic data (seismograms) that have been calculated for specific past earthquakes and are available for existing seismometer locations. These synthetic data should be stored with the corresponding UTC timing for the pre-determined origin time.
• Type 2: Synthetic data (seismograms) for virtual earthquakes calculated for
virtual networks. This could correspond to potential earthquake scenarios in a particular region and the virtual network could consist of the 2-D surface grid points (e.g. 2-D array) where synthetic seismograms have been calculated.
• Type 3: Synthetic seismogram data (i.e. complete wave fields) that are available for a 3D volume (e.g. sedimentary basin, whole Earth).
• SEED/miniSEED seems to be the most appropriate synthetic data format for compatibility with the observational IT infrastructure
• We defined three synthetic data types:
• Type 1: Synthetic data (seismograms) that have been calculated for specific past earthquakes and are available for existing seismometer locations. These synthetic data should be stored with the corresponding UTC timing for the pre-determined origin time.
• Type 2: Synthetic data (seismograms) for virtual earthquakes calculated for
virtual networks. This could correspond to potential earthquake scenarios in a particular region and the virtual network could consist of the 2-D surface grid points (e.g. 2-D array) where synthetic seismograms have been calculated.
• Type 3: Synthetic seismogram data (i.e. complete wave fields) that are available for a 3D volume (e.g. sedimentary basin, whole Earth).
ORFEUS-SPICE Meeting May 7, 2004 – Results 2/2
• Additional header information for Synthetic data types (Metadata) must include at least:
• Additional header information for Synthetic data types (Metadata) must include at least:
a pointer to information on the model structure
the numerical method employed
simulation information (e.g. valid frequency range of simulation, physical approximations, etc.)
earthquake source information
identification (software author, date of data generation, etc.)
Examples: Data Type 1Observations (X) and Synthetics ()⃞
If you read event data, a flag ()⃞ indicates that synthetics are available
Examples: Data Type 1Observations (X) and Synthetics ()⃞
Examples: Data Type 2virtual earthquake, virtual array
Necessary developments
• International working group and schedule for implementation
• Multi-national agreement on synthetic data format
• Provision for multi-component (>3C) data (e.g. strains, rotations, atmospheric parameters)
• Coordinated software development for data access, visualization etc.
• Development of a test data base accessible to the community with feed-back options
• International working group and schedule for implementation
• Multi-national agreement on synthetic data format
• Provision for multi-component (>3C) data (e.g. strains, rotations, atmospheric parameters)
• Coordinated software development for data access, visualization etc.
• Development of a test data base accessible to the community with feed-back options