reason scign org 1. MOSES Concept Links Data...
Transcript of reason scign org 1. MOSES Concept Links Data...
This project is funded by the National Aeronautics and Space Administration
(http://reason.scign.org)
0. Abstract0. Abstract
SCIGN-REASoN/SENH GPS/Seismic
QuakeSIM
RDAHMM
High-fidelitydeformation database
MetadataPositionsReal-Time DisplacementsTime seriesVelocity mapsStrain mapsQuality control
Deformation modelingutilities
.
.
.Inversion ValidationServo-Grid
QuakeSIM portalst_filter
SCIGN portal
ACCESS
Web services enableddirect interaction betweenmodeler and data provider
Utility feeds-back dataquality parameters to
database
Use of high-leveldata production tools
for modeling
Unified portal architecture
ScientistsResearchers
SurevyorsDecision Makers
Non-Access Dev.
Access Dev.
GPS/Seismic Meter
1. MOSES Concept Links Data Products 1. MOSES Concept Links Data Products with Geophysical Modeling Toolswith Geophysical Modeling Tools
Prototype GPS Explor-
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RDAHMM time series segmentation results for SCIGN GPS data collected in Claremont, CA. The method automatically identifies all of the major modes of the system. This capabili-tyis used to identify both real physical events and data anomalies. Archived GPS data can be augmented by notation of these behavior modes.
st_filter Principal Component (PC) Analysis of common-mode error in vertical compo-nent. The arrows represent the element values of the normalized eigenvectors. The up and down arrows represent positive and negative responses to the scaled PC. Time variations are in upper panel (solid line) and normalized spatial eigenvectors are in lower panel..
4c. On-the-fly Modeling
Bock, Yehuda (SIO), Frank Webb (JPL), Sharon Kedar (JPL), Marlon Pierce (IU), Michael Bock, Yehuda (SIO), Frank Webb (JPL), Sharon Kedar (JPL), Marlon Pierce (IU), Michael Scharber (SIO), Don Argus (JPL), Galip Aydin (IU), Ruey-Juin Chang (SIO), Danan Scharber (SIO), Don Argus (JPL), Galip Aydin (IU), Ruey-Juin Chang (SIO), Danan Dong (JPL), Peng Fang (SIO), Robert Granat (JPL), Paul Jamason (SIO), Brian Newport Dong (JPL), Peng Fang (SIO), Robert Granat (JPL), Paul Jamason (SIO), Brian Newport (JPL), Sue Owen (JPL), Jay Parker (JPL), Linette Prawirodirdjo (SIO), Keith Stark (JPL), (JPL), Sue Owen (JPL), Jay Parker (JPL), Linette Prawirodirdjo (SIO), Keith Stark (JPL), Frank Vernon (SIO), George Wadsworth (SIO), Zhigang Qi (IU)Frank Vernon (SIO), George Wadsworth (SIO), Zhigang Qi (IU)
We are in the process of merging the capabilities of three NASA-funded projects We are in the process of merging the capabilities of three NASA-funded projects under the umbrella of the NASA Access Project, "Munder the umbrella of the NASA Access Project, "Modeling and On-the-fly Solutions odeling and On-the-fly Solutions for Solid Earth Sciences (MOSES)for Solid Earth Sciences (MOSES)” to facilitate data mining and modeling of rapidly to facilitate data mining and modeling of rapidly expanding multi-disciplinary geoscience data sets:(1) The SCIGN-REASoN project is expanding multi-disciplinary geoscience data sets:(1) The SCIGN-REASoN project is focused on the combination, validation, archive, and delivery of high-level data focused on the combination, validation, archive, and delivery of high-level data products and data mining capabilities from space geodetic measurements, in products and data mining capabilities from space geodetic measurements, in particular from over 600 CGPS stations in Western N.A.;(2) The QuakeSim project is particular from over 600 CGPS stations in Western N.A.;(2) The QuakeSim project is developing linked Web service environments for sup-porting high performance developing linked Web service environments for sup-porting high performance models of crustal deformation from a variety of geo-physicmodels of crustal deformation from a variety of geo-physical sensors, including GPS al sensors, including GPS and seismic instruments;(3) The SENH-Applications GPS/Seismic integration project and seismic instruments;(3) The SENH-Applications GPS/Seismic integration project has developed a proto-type real-time GPS/seismic displacement meter for seismic has developed a proto-type real-time GPS/seismic displacement meter for seismic hazard mitigation and monitoring of critical infrastructure. hazard mitigation and monitoring of critical infrastructure.
The focus of the MOSES project is to enable direct interaction between modelers The focus of the MOSES project is to enable direct interaction between modelers and data/data-product providers using Web services, within a unified portal archi-and data/data-product providers using Web services, within a unified portal archi-tecture. Modeling applications include, for example, time series analysis of continu-tecture. Modeling applications include, for example, time series analysis of continu-ous and rous and real-time data (e.g., RDAHMM and st_filter programs) and fault dislocation eal-time data (e.g., RDAHMM and st_filter programs) and fault dislocation modeling (e.g., Simplex program). Community resources include access to exten-modeling (e.g., Simplex program). Community resources include access to exten-sive infrastructure and distributed data archive holdings, an on-line map sive infrastructure and distributed data archive holdings, an on-line map server/client linked to a GIS database, a "GPS Explorer" data portal that is extensible server/client linked to a GIS database, a "GPS Explorer" data portal that is extensible to heterogeneous data sets, and "Geophysical Resource Web Services." We present to heterogeneous data sets, and "Geophysical Resource Web Services." We present an interactive display of the current capabilities of the unified data portal and solicit an interactive display of the current capabilities of the unified data portal and solicit feedback from communitfeedback from community members. y members.
IntegrationEvent detectionPattern recognitionAttached processesZero latency
http://reason.scign.org Maps
Timeseries
Velocities
Strain
Metadata
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ticket creation using SOAPa
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SOAP request-response
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T Combinedime Series
V yelocitField
SOPACTime Series
JPLTime Series
Strain
GeophysicalParameters
FlexibilityXSLTCGI ProxiesShell Script Wrappers
SecurityAuthenticationSession trackingLocation independent
DistributedAnalysesScalable provider tierCommon product formatsFast re-processingNetwork reconfiguration
Centralized StorageOracle RDBMSCommon data modelsWell-defined integrity constraints
ValidationXML Schema
OGCStandardsGMLFilter EncodingWFSWMS
ExplorationVisualizationExtractionSubscriptionUser notificationSummarizationEducation
Time Series ModelingApplications
Data Analysis &Modeling Environment
3. Using Geophysical Resources Web Services (GRWS) Infrastructurearchived Products and Tools are integrated through web services to the Portal
~1800 CGPS sites/metadata archived daily,including all PBO and many CORS
~ 75% in Western Hemisphere
~85 sites streaming @ 1 Hz (CRTN)
~ 3M ftp retrievals/month/~ 1 Hz (1 file/s)
All CGPS data and data products collected since early 1990’s on-line
SOSOPAC ArchivAC Archive
1. Extensive Infrastructure, Data Archive2. On-line Map Server/Client, linked to GIS Database and Resources3. GPS Explorer Data Portal Ð extensible to display and manipulation of heterogeneous data sets (e.g., seismic, strainmeter, geology, InSAR4. Geophysical Resource Web Services (GRWS)
2. This includes access to our archive, 2. This includes access to our archive, an extensive Community Resourcean extensive Community Resource
with data and data productswith data and data products
Earth Science Community IT Resources through a Unified Data Analysis and Modeling Portal
4a. SOPAC Online Mapping Interface (SOMI)
http://ex.ucsd.edu/maps
geoapp.ucsd.edu ex.ucsd.edu
CSS
HTML
JS
CGI
Examples of SOMI-generated maps Examples of SOMI-generated maps embedded in Web pagesembedded in Web pages
4. The GPS Explorer Portal contains mapping and modeling tools for 4. The GPS Explorer Portal contains mapping and modeling tools for (real-time) GPS data products(real-time) GPS data products
5. Users get logins to the portal where they can select, explore, and model the data products and save their results for future sessions.
Tool development, implementation, and output functions are being extended.
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User MarkupSOMI ServiceHost
Architecture and interfaces allow other analysis centers to
4b. Application Integration with Real- Real-Time Filters for GPS Time Filters for GPS StreamsStreams
CombinesGeospatial Data with
Time S eries
Inter-portlet communication
used to pass
information
Clicking
on site inSOMI shows
information
andadds site to
analysis group
Site S election
usingbounding box,
metadata
criteria, etc.
Selected sitescan be saved
and passed
on to other portlets for processing
Linked with
Geophysical Modeling
Applications
Allowing
DirectInteractionbetweenModeler
&
Data P rovider via
Data Analysis
&
Modeling
Portal
Infrastructure uses gridsphere portal server, inter-web 2.0 functionality via AJAX and
back-end web services
The real-time RDAHMM plots available via SOMI.
Portlets are JSR-168 portlet specification compliant, and
exportable to other portal servers
WFS