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Seismo logy VO

This presentation provides an overview of the Seismology Virtual Organization, including general information, metrics, dissemination activities, user forum, training agenda, international collaboration, and status updates of applications and data collection. It also highlights major dissemination and training activities, as well as relevant papers and ongoing projects.

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Seismo logy VO

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  1. Seismology VO PSC05 Meeting, Sept.9th 2009 Can Özturan Seismology VO Leader Dept. Of Computer Eng. Boğaziçi University, Istanbul ozturaca@boun.edu.tr The SEE-GRID-SCI initiative is co-funded by the European Commission under the FP7 Research Infrastructures contract no. 211338

  2. Overview • Overview of Presentation: • General VO Information / Metrics • Dissemination Activities • User Forum Regional Seismology VO Training Agenda • International Collaboration • Status of Applications • Status of Data Collection • Action Points

  3. General VO Information / Metrics Wiki: http://wiki.egee-see.org/index.php/SEE-GRID_Wiki Some countries/organizations/persons have not signed up for VO membership

  4. General VO Information / Metrics Current VO members Collaborators

  5. Major Dissemination & Training Activities • Wiki pages • Seismology brochure • Presentation and poster in the EGEE 08 Conference in Istanbul (Sep 08) • Poster and demo presentation of the Seismology-VO in the ICT 2008 conference, (Nov.08, Lyon) • Local training event: Grid Usage and Seismology VO Training, Boğaziçi University, Jan. 29-30 2009 • Presentation of the Seismology VO at the BASARIM09 High Performance and Grid Conference, Ankara, 15-18 April 2009 in a special dissemination session devoted to the SEE-GRID-SCI project • 4th EGEE User Forum Presentations, Catania, Sicily, Italy (March 2009) • SRA: Seismic Risk Assessment Application Framework, Poster Presentation • NMMC3D: Enabling Numerical Modeling of Mantle Convection on the Grid, Oral Presentation • Poster Presentations at the Annual Meeting of the NERIES Project, Utrech, the Netherlands (June 29-July 1, 2009). • Seismology VO poster • MDSSP-WA poster • Poster presentations of the Seismology, Metereology and Environment VOs at the GEO European Projects Workshop /8, Istanbul (Oct. 8-9, 2009)

  6. Major Dissemination & Training Activities • Papers: • ELF : M. Y., R.A. ,M.S.G, C. O, B. B “Parallelization of the Earthquake Location Finding Application Using JDL Workflows”,BASARIM09 High Performance and Grid Conference, Ankara, 15-17 April 2009. • NMMC3D: A. B., M. K., B. S., B. B, “Enabling Numerical Modeling of Mantle Convection on the Grid”, MIPRO 2009, 25-29, May 2009 • Seismology VO: C. O., B. B., M. Y.,C. Ş., “Challenges Faced in Building A Seismology VO for Southeastern Europe”, e-Challenges Conference, Istanbul, Oct. 2009. • NMMC3D: ISGTW article updated. • MDSSP-WA: ICT Innovations, Ohrid 09 (in preparation).

  7. SEEGRID-SCI User Forum- Regional Seismology VO Training Agenda • Proposed Training Agenda • Overview of the Seismology VO (half hour) • SDS Application service (1 and half hours) • Seegrid plug-ins for NERIES Web Services. (1 and half hours) • Selected Seismology VO Applications (2 and half hours)

  8. International Cooperation Activities • Upon invitation by Dr. Torild van Eck (ORFEUS General Secretary), C. Özturan and L. Jordanovski attended the Third Annual Meeting of the NERIES Project, Utrecht, the Netherlands on June 29-July 1, 2009. The costs of travel, lodging and registration were sponsored by the NERIES project. • Had technical talks with the IT personnel Allessandro Spinuso and Luca Trani of ORFEUS/KNMI about the newly released NERIES web services that provide seismology data during the Third Annual Meeting of the NERIES Project. • Started development of a high level C++ based grid plug-in for accessing seismology data by using the NERIES web services. • A preliminary version of the plug-in for downloading waveform files has been released (can be downloaded at the seismology wiki page)

  9. Seismic Risk Assesment - SRA • Main Developer: CevatŞener, Middle East Tech. Univ., Turkey • Description • A framework that allows embedding of assessment models and produces seismic • hazard maps forthe SEE region • Useful for determination of earthquake insurance premiums. • Regional collaborators and their roles • Collaborate on developing models : Geophysical Institute of BAS (BG) • Exchange of attenuation relations : Inst. of Geo. and Seismo. of ASM (MD) • Collaborate by supplying data and SDSAS: Boğaziçi University (TR) • Number of registered users : 7 • Web page / Documentation: • Some scientific/technical details http://sra.ceng.metu.edu.tr • Web interface: http://www.ceng.metu.edu.tr/~e1395466/sra/sra.html

  10. Seismic Risk Assesment – SRA • Current state : • Second Grid-mode prototype deployed • Application Architecture • SRA uses JRA1 SDSAS and P-GRADE Portal. • Future services to be used: AWT, Event Logger, • MEWS and P-GRADE Portal extensions (JRA1) • Quarter-5 Activities • Different PDFs studied / coded • Attenuation models inserted • Various formulations studied / prepared • Hazard spectrum drawing codes developed • Time dep. Renewal model surveyed • Web site development • Country information requirements for • SRA identified • Future plans • M16 – Testing Grid-mode • M18 – Deployed at production-level

  11. Seismic Risk Assesment - SRA SRA web interface http://www.ceng.metu.edu.tr/~e1395466/sra/sra.html

  12. Earthquake Location Finding - ELF • Main Developer:MehmetYılmazer, Boğaziçi University, Turkey • Description • A HYPO71 based application that finds earthquake locations and magnitudes • from continuous waveform data files reported by stations. • After an earthquake, the location of an earthquake needs to be reported to • various authorities for necessary actions to be taken. • Regional collaborators and their roles • Collaboration in usage: METU – TR, Armenia • Collaboration by data supplying: U. of Ss Cyril and Methodius (MK) • Number of registered users : 9 • Web page / Documentation: • Computed earthquake results can be displayed using SDS web interface: • http://erciyes.cmpe.boun.edu.tr/seegridsci/sds • Documentation not ready • Current state : • Testing Grid-mode

  13. Earthquake Location Finding - ELF • Application Architecture • Application uses continuous waveform data archived by the JRA1 • SDSAS • Quarter-5 Activities • Helped Armenia install and run ELF application. Armenia is testing the • application. • A bug was discovered in one of the test cases reported by Armenia – currently • working on resolving it. • Future plans • Perform tests on massive historical data • Train/help other partners on using this program

  14. Massive Digital Seismological Signal Processing with the Wavelet Analysis- MDSSP-WA • Main Developer: LjupcoJordanovski, U. of Ss Cyril and Methodius (MK) • Description • Computes various earthquake parameters needed in seismic hazard and risk • analysis • Does mapping of the given earthquake prone regions in terms selected parameters • Regional collaborators and their roles • Supply data via SDSAS : Boğaziçi University (TR) • Exch. of various data/parameters/research results: Geophysical Inst. of BAS (BG) • Exch. of various data/parameters/research results : Seismological Survey of Serbia (RS) • Various studies of Valandovo, Strumica and Skopje regions : Institute of • Geodesy, BAS (BG) • Geomagnetic field/data/research: Inst. Nuclear Res. & Nuclear Energy, • BAS (BG) • Number of registered users: 5 • Web page / Documentation: • No web interface, no documentation yet

  15. Massive Digital Seismological Signal Processing with the Wavelet Analysis- MDSSP-WA Compute Characteristic 1 Compute Characteristic 2 Analyze and Classify the EQ EQ job start Compute Characteristic N • Current state : • Testing Grid-mode • Application Architecture • Uses JRA1 SDSAS and AWT • Quarter-5 Activities: • Some processes are made to work • in grid mode • Developed a simple workflow and testing it now • Presented poster at NERIES Meeting • Preparing a paper for ICT Innovations, • Ohrid Conference • Future plans • Develop more advanced workflow • Actual performance will be • measured in the next phase of • development. • ULMON (JRA1) monitoring tool will be used • to analyze application performance

  16. Fault Plane Solution - FPS • Main Developer: MehmetYılmazer, Boğaziçi University, Turkey • Description • Computes source parameters and moment magnitude of an earthquake • Inputs a crust model and actual seismic waveform data. • Outputs fault parameters of the earthquake. • Results obtained can help in risk analysis • Regional collaborators and their roles • Development of a workflow for the application: Computer and Automation Res. • Inst. (SZTAKI) of HAS (HU) • Number of registered users : 4 • Web page / Documentation: • No web interface, no documentation yet • Current state : • Developing Grid-mode

  17. Fault Plane Solution - FPS • Application Architecture • Uses regional seismic moment tensor • inversion methodology • Application uses continuous waveform • data archived by the JRA1 SDSAS • Quarter-5 Actvities • Major code reorganization needed to • be done for gridification • Development of a workflow • Future plans • Complete development by M17 • (revised from M16)

  18. Numerical Modeling of MantleConvection – NMMC3D • Main Developer: BálintSüle, Hungarian Academy of Sciences, Hungary • Description • Provides model of the thermal convection in the Earth's mantle • Solves numerically the equations of thermal convection • The mantle convection is the driving force of the plate tectonics • Results will help us to understand better the dynamics of the Earth • Regional collaborators and their roles • Collaboration in testing of the application and interpretation of the results: • Boğaziçi University (TR) • Number of registered users : 5 • Web page / Documentation: • P-GRADE portal, • Online material on GASUC web page: http://www.lpds.sztaki.hu/gasuc/index.php?m=6&r=6 • Current state: • Grid-mode deployed, Testing in Grid-mode

  19. Numerical Modeling of MantleConvection – NMMC3D • Application Architecture • The gridification process included developing a specialized web interface • extension to P-GRADE Portal, specifically tailored for the application's needs. • An interface suitable for this was developed using the Application Specific • Module of P-GRADE Portal 2.7. • Quarter-5 Activities • Further developments • User interface enhanced • Updated ISGTW article • Future plans • Training scenario with P-GRADE

  20. Seismic Data Server SDS web interface • Main Developer: Can Özturan, Boğaziçi University, Turkey • Description • Web interface to seismic data archive organized by the JRA1 SDSAS • Let the users visually display various kinds of information about the seismology • waveform data files, earthquakes and stations • Regional collaborators and their roles • Collaboration in usage: Ss Cyril and Methodius University of Skopje (MK) • Collaboration in usage: METU, (TR) • Number of registered users : 4 • Web page / Documentation: • http://erciyes.cmpe.boun.edu.tr/seegridsci/sds • Current state : • Cluster-mode deployed

  21. Seismic Data Server SDS web interface • Application Architecture • Records of seismology data are kept in AMGA server • Invokes programs that utilize JRA1 SDSAS to retrieve information about • earthquakes, stations and waveform files as a Google kml fileand display them • in browser window • Quarter-5 Activities • A prototype was developed • which was shown in the 1st year • review demo • Future plans • Additional functionality will be • introduced so that the ELF • application user can display • the results of ELF runs by giving • job ids

  22. SDSASApplication Service • Main Developer: Can Özturan, Boğaziçi University, Turkey • Description • Various scripts for seismic data organization using AMGA and LFC • C++ iterators providing high level access to seismology data • Web page / Documentation: • Documentation available for the version released in April • Quarter-5 Activities • Installation at Armenian site • Development of a plug-in for accessing NERIES data on grid • Provide a high level C++ interface to NERIES web services so that seismologists can access NERIES data on the grid without the need not to learn soap, xml, xml parsing • Develop using libcurl and libxml which are readily available on SL • Release of a preliminary version of the plug-in

  23. SDSASApplication Service

  24. Status of Data Collection • Note: • Greek,Romanian,Bulgarian and Hungarian data can be obtained from NERIES, so there is no problem. • Serbian and Albanian networks are not on NERIES. We should get data from these countries (today we have received a seismic data DVD from Albania)

  25. Action Points Paper submissions to User Forum – all application developers Application developer / collaborators should sign up as users of VO Complete development of NERIES grid plug-in – Can Ozturan Implement additional SDSAS methods as further needed by applications (e. g. return data within a circle ) – C. Ozturan Documentation of applications – all application developers Web sites for applications – all application developers Attract new regional and international VO users – C. Ozturan Prepare Seismology VO Training material – C. Ozturan + application developers

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