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www.geongrid.org GEOSCIENCE NEEDS & CHALLENGES Dogan Seber San Diego Supercomputer Center University of California, San Diego, USA
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www.geongrid.org Earth science research is moving towards a “systems approach”. To understand the Earth we need to look at it as a whole. Scientists have expertise in specific areas in their sub- disciplines and knowledge about sister disciplines is limited. Can cyberinfrastructure help?
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www.geongrid.org Some common IT problems in the Geosciences Exponential increase in data volumes Diversity and complexity of data sets Data storage, access and preservation Data integration (semantic and syntactic) Computational challenges and access to HPC Advance visualization (3D/4D) Archiving publications with reusable components
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www.geongrid.org A Scientific Effort Vector Background Background Research Research Data Collection and Data Collection and Compilation/ Compilation/ Software issues Science Back- Back- ground ground Research Research Data Collection Data Collection and andCompilation/ Software Issues Science Science Science - Analysis, Modeling, Interpretation, Discovery Source: R. Keller
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www.geongrid.org Enabling Scientific Discoveries: Pathway to Discovery AccessProcessAnalyzeInterpretDiscovery DataKnowledge
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www.geongrid.org Large/Complex Data Volumes National/International Observatories/projects EarthScope ES is a US project to collect data across the entire US over the next 10 years. Includes seismic, GPS and drill hole data LiDAR data Airborne and ground based data collection (large volumes of data sets) Global Observations A variety of satellites gathering data at different resolutions Hydrology, Environmental, Natural resource development projects, etc. Small projects Individual researchers maintain a lot of data sets, such as geology maps, geochemistry databases, earthquake catalogues, etc. Collectively reusable data reach large volumes and complex dimensions Challenge: How to manage these data so that vast amounts of data can be used by all scientists in an easy-to-use environment
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www.geongrid.org Data Storage, Access and Preservation Preservation of digital and legacy data sets Since research needs and styles of each scientist vary, each researcher has his/her own data with their own “flavors” Access to other scientist’s data is limited When scientists do not continue to maintain their data, it is lost forever! Challenge: How to build a framework to exchange data and help preserving collected data sets
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www.geongrid.org Data Integration Issues Integration requires both syntactic and semantic level integration. e.g., How can a geologist merge multiple geology maps to make a seamless (“integrated”) map that overlaps with national and international boundaries.
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www.geongrid.org Integrate Geologic Data From Multiple Sources What is available is multiple distinct data sets
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www.geongrid.org Integration Across Disciplines Earthquakes Aquifers Tectonics Moho depth Geology Faults Magnetics Mines Topography Focal Mechanisms Sediment thickness Gravity
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www.geongrid.org Computational Challenges in Geosciences Developing/Accessing community codes Parallelizing software for efficient runs Accessing small to very large clusters Technical expertise to use high-end systems/clusters Challenges: How to build a system that helps scientists run advance software without having access to significant resources (computers and technical) How to build a system that helps scientists to focus on science rather than technological challenges/problems
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www.geongrid.org (Goldstein 2001) Example: Can we build a system that not only a few privileged, but also the entire community could use to run 3D seismic modeling?
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www.geongrid.org Geosciences are Visualization Oriented Once large volume data sets are accessed, how can we visualize them to get a better understanding of each data set? To build an effective visualization environment powerful software and hardware needed. Challenge: How to build a visualization system that helps scientists analyze large and complex data sets dynamically.
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www.geongrid.org Archiving results and publications with reusable components Science progresses incrementally. New knowledge is built on top of existing knowledge. Scientific validity is shown by repeatability. Challenges: How to preserve scientific results and help others to repeat the analysis as efficiently as possible? How to share algorithms and processing flows with others?
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www.geongrid.org Efforts underway… Numerous projects are funded to address these questions E.g., GEON, SCEC ITR, CUAHSI, EarthChem NSF funding opportunities in GEO and CISE directorates Professional societies getting involved in CI GSA Geoinformatics Division AGU Earth and Space informatics focus group Extensive level of outreach and learning activities taking place
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www.geongrid.org Lessons Learned 1/2 Building cyberinfrastructure resources is a “social experimentation” Equal partnerships between domain and IT is a must Understand the needs of the domain sciences Community outreach is critical (workshops, seminars, scientific meetings, etc) Get it right the first time! Define the goals clearly, and publicize them Learn to differentiate “a system that works” and “a system that is usable”
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www.geongrid.org Work with those who are willing and interested Identify “killer apps”, use them to attract more interest Teach! Help building a community of users and resource builders Problems are similar. Work with other communities, solutions may be out there Lessons Learned 2/2
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