1. Work Group Meeting on HTAP-Relevant IT Techniques, Tools and Philosophies: DataFed Experience and Perspectives Rudolf B. Husar CAPITA, Washington University, St. Louis, MO Ispra, JRC, March 14. 2004 Data handling approach Software tools Participant involvement Data dissemination Integration problems Summary

2. Policy Guidance for HTAP IT Terry Keating, HTAP Task Force Co-Chair: Transparency of the HTAP Process –Acceptance of the Tech Report will depend on openness Inclusiveness and Ease of Participation –Facilitate participation by smaller contributors

3. Current Air Quality Information ‘Ecosystem’ AQ info is distributed over many ‘dimensions’: Geography, Content, Agency, Program… AQ info content includes: emissions, ambient & satellite data and model outputs Info is provided and consumed by different agencies, (NASA, NOAA, EPA…) Providers have different access protocols, formats, and information usage conditions Lack of Interoperability Poor data & model utilization Less informed decision making

4. GEOSS Info Flow Architecture A General Framework Accepted by Members Model Data

5. Federated Network for Air Quality Data and Processing Services Project Team: Software Architecture: R. Husar Software Implementation: K. Höijärvi Data and Applications: S. Falke, R. Husar Data Handling Approach

6. The challenge is to design a general supportive infrastructure Simply connecting the relevant provides and users for each info product is messy Federated Data System for Air Quality The info system infrastructure needs to facilitate the creation of info products AQ Compliance Nowcast/Forecast Status & Trends Find Data Gaps ID New Problems ……… Info Needs Reports Providers supply the ‘raw material’ (data and models) for ‘refined’ info products Emission Surface Satellite Model Single Datasets Providers Wrappers Where? What? When? Federate Data Structuring Structuring the heterogeneous data into where-when-what ‘cubes’ simplifies the mess Slice & Dice Explore Data Viewers The ‘cubed’ data can be accessed and explored by slicing-dicing tools Programs Integrate Understand More elaborate data integration and fusion can be done by web service chaining Non-intrusive Linking & MediationData UsersData Providers

7. Data Handling Approach: DataFed Approach: Mediation Between Users and Data Providers DataFed assumes autonomous data management (a la Internet) Non-intrusive third-party data wrapping for unified web service (WS) access End-user programming of applications through chaining of WS components Applications Building browsers and analysis tools for distributed monitoring data Serve as data and service resources for user programs (science, GIS tools) Support application projects, e.g. FASTNET, Exceptional Event Rule

8. Typical DataFed AQ Analysis Tools ConsolesConsoles: Data from diverse sources are displayed to create a rich context for exploration and analysis CATTCATT: Combined Aerosol Trajectory Tool for the browsing backtrajectories for specified chemical conditions Tool Viewer: Viewer: General purpose spatio-temporal data browser and view editor applicable for all DataFed datasets

9. Quebec Smoke July, 7, 2002 SeaWiFS Satellite Aerosol Chemical Air Trajectory Map Boarder Web Service Composition

10. Software Tools: Demo: Networked Data Access, Processing and Fusion AeroCOM – VIEWS SO4 http://webapps.datafed.net/dvoy_services/datafed.aspx?page=KYU_VIEWS http://webapps.datafed.net/dvoy_services/datafed.aspx?page=KYU_V http://webapps.datafed.net/dvoy_services/datafed.aspx?page=VIEWS_KYU Networking

11. Visualization Goal: 4D, User-selectable layers Image below completed in 1998 Satellite Data Layers: Land Reflectance (SeaWiFS) Fire Pixels (ASTR Night) High Cloud (GOES, Meteosat, GMS2) Aerosol AOT (AVHRR)

12. 4D Dynamic Visualization Demonstrate interactions, allow exploration ‘Google Earth’ for Earth Science is now possible

13. Partners N ASA NOAA EPA USGS DOE NSF Industry… Earth Science Information Partners Air Quality Cluster 1. Serve as facilitator to Earth Science information community. 2. Promote efficient flow of ES data from collection to end-use. 3. Improve quality and usability of ES data and info systems 4. Expand the use of Earth science information Participant Involvement

14. Data Dissemination & Use – Service Based Provide Catalog Services (Publish, Find data) Allow Data Access (‘Bind’) – Use International Standards Add tools for exploration and analysis Near Real Time Data Integration Delayed Data Integration Surface Air Quality AIRNOWO3, PM25 ASOS_STIVisibility, 300 sites METARVisibility, 1200 sites VIEWS_OL40+ Aerosol Parameters Satellite MODIS_AOTAOT, Idea Project GASPReflectance, AOT TOMSAbsorption Indx, Refl. SEAW_USReflectance, AOT Model Output NAAPSDust, Smoke, Sulfate, AOT WRFSulfate Fire Data HMS_FireFire Pixels MODIS_FireFire Pixels Surface Meteorology RADARNEXTRAD SURF_METTemp, Dewp, Humidity… SURF_WINDWind vectors ATADTrajectory, VIEWS locs.

15. WCS - Interoperable Data Access Service netCDF– Machine independent encoding ncML– XML data description CF– Naming, structure convention OGC Web Coverage Service - Interoperable Data Access Query Data Syntax + Semantics Coverage (parameter) BBOX Time Range netCDF Example Profile SERVICE=wcs‘service REQUEST=GetCoverage,VER=1.0‘service method COVERAGE=AIRNOW.pmfine‘what CRS=EPSG:4326‘projection BBOX=-125,22,-61,51,0,0‘where TIME=2005-06-6T15:00:00Z‘when FORMAT=netCDF‘return format

16. GALEON Interoperability Experiment Geo-interface for Atmosphere, Land, Earth, and Ocean netCDF Unify Earth Science & GIS Data Flows Strong European Participation IT – S. Nativi, L. Bigagli UK – Andrew Wolf DE – Peter Bauman) B. Domenico GALEON UNIDATA U Florence/CNR-IMMA WCS Server

17. OGC WCS Demonstration: THREDDS_GFS 4Dim DatasetTHREDDS_GFS Lat/Lon Box Elev Range Time Range Map: BBOX=-180,-90,180,90, 1350,1350& TIME=2005-12-06/2005-12-06/PT3H Time: BBOX=-34,49.05,-34,49.05, 1350,1350& TIME=2005-12-05/2005-12-08/PT3H Elev: BBOX=-34,49.05,-34,49.05, 0,18000 & TIME=2005-12-06/2005-12-06/PT3H The form of the WCS query is the same for all slices through the data cube (views) The only difference in the views is the thickness of the slices in each dimension Return grid is in multiple formats (NetCDF, CSV, GML, PNG, … ) Map View Services WCS Query Time View Services WCS Query Elevation View Services WCS Query WCS Query

18. Summary Current systems data & model analysis are heterogeneous Standardization is a key need for agile IT systems Non-intrusive mediators can achieve virtual standardization Technologies are currently available for dynamic NETWORKING We eager to share our networked data, tools and methods

19. OGC WCS Demonstration: Grid, Image, Station Data Types Coverage=THEEDDS.T& BBOX=-126,24,-65,52,0,0 &TIME=2002-07-07/2002-07-07&FORMAT=NetCDF Coverage=SURF.Bext& BBOX=-126,24,-65,52,0,0 &TIME=2002-07-07/2002-07-07&FORMAT=NetCDF-table Coverage=SEAW.Refl& BBOX=-126,24,-65,52,0,0 &TIME=2002-07-07/2002-07-07&FORMAT=GeoTIFF COVERAGE=sst& BBOX=-126,24,-65,52,0,0 &TIME=2001-01-01,2001-01-01&FORMAT=NetCDF UNIDATA – THREDDS/GALEON WCS THREDDS/GALEON WCS DataFed GALEON WCS U Florence, It GALEON WCS DataFed GALEON WCS Grid Image Station Services WCS Query Services WCS Query Services WCS Query Services WCS Query

20. Single Data Model for All AQ Data Most Views are slices through a cube of data organized by lat, lon, altitude, and time (X,Y,Z,T) Multidimensional Data Cube

21. OGC Web Coverage Service (WCS) Specification HTTP GET/POST based interfaces Services have XML service descriptions (“Capabilities”, “Description”) Filter parameters allow selection of subsets of source data Output formats advertised by each service instance OGC WCS getCoverage Schema Suitable for wrapping with SOAP envelope, WSDL access, loose coupling WCS is for "coverages" – information representing space-time-varying phenomena WCS describes, requests and delivers coverages in spatio-temporal domain WCS version 1.1 is limited to grids/"simple” coverages with homogeneous range sets

22. AQ Monitoring Network Data Storage and Delivery through OGC Protocols Relational Data Model Star Schema WMS WCSSOS SensorML WFS Observations Station Info. Param/Sensor/Method Data View Services WMS StationsPar-Meth Observations SOS WCS Data Access

23. Technology Support for ‘Integrated Solutions’ Air Quality Information System

24. through Data Access through Adapters DataFed SOAP,HTTP Get OGC WCS HTTP Get, Post OGC WMS HTTP Get Station-Point SQL Server, Files… Sequence Image, file nDim Grid OpenDAP NetCDF, … Other Traject., Event, Pic Sources Diverse formats Many data models Data Wrapper Data into geo-cubes Queries to views Virtual Data Cube Global geo-cube data model Makes queries data-neutral Others? e.g. OpenDAP Output Protocol dependent User specified GeoTable CSV,XLS,GML GeoGrid GML,NetCDF.. GeoImage GeoTIFF, PNG.. Other MS Dataset.. Query Adapter Maps query to protocol User selects protocols