geoss adc architecture implementation pilot 2 disaster management scenario caribbean flood pilot...
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GEOSS ADC Architecture Implementation Pilot 2 Disaster Management Scenario
Caribbean Flood Pilot Sensor Web Report from the AIP2 Kick-off Meeting Boulder, Colorado 25-26 September 2008
Stuart Frye
Pilot Leader and Technical POC
NASA-GSFC-SGT
stuart.frye@nasa.gov
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Outline
• GEOSS AIP2 Overview• Background• Objectives of Flood Pilot• Input• Outputs• Outcomes• Capacity Building• Relevance• User and Architecture Requirements• Results to Date• AIP Kickoff• Partners
GEOSS AIP-2 Overview
• Societal Benefit Area Scenarios– Disaster Response– Climate Change and Biodiversity– Renewable Energy– Air Quality and Health
• Transverse Technology Areas– Clearinghouse - Catalogue - Registry - Metadata– Access Services – Workflow and Alerts– Portals and Application Clients– Test Facility
DM Background (1/2)
• GEO Workplan includes task to address “Use of satellites for risk management”: DI-06-09; DI-06-09 addresses all four phases of disaster management: mitigation, warning, response and recovery and examines user requirements and system architecture for a global multi-hazard approach, including developing pilots to demonstrate usefulness
• UN-SPIDER recognizes the critical importance of compiling user requirements, and can serve as a bridge between space and disaster management communities
• UN-SPIDER workshop in Barbados in July 2008 served as catalyst to define “Caribbean Pilot” to focus attention on how EO can better support disaster management in the Caribbean
• Flooding identified as best place by Caribbean users
• AIP Call for Participation identified as best vehicle to frame proposal and move pilot forward
DM Background (2/2)
Participation in this Pilot anticipates
• Refinement and augmentation of the GEOSS Common Infrastructure including GEO Web Portal, Clearinghouse and Registries solutions (available for Pilot)
• Registration of components and services hosted by the participating organization in the GEOSS Registry to support access by the Clearinghouse and Portal, and that to support demonstration of a set of user scenarios.
• Participation in the development of a set of user scenarios that support the GEO Societal Benefit Areas.
• Participation in the refinement of the initial architecture based upon the pilot activities.
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Flood Pilot Objectives
• To provide information on which flooding relevant data and models are already available for the Caribbean region
• To produce a one year flooding composite image from various satellites, and
• To make relevant data and services accessible via the GEO Portal
Flood Pilot Inputs
• Satellite data:– MODIS– ASTER– Landsat– AMSR-E– TRMM– RADARSAT– ALOS– ALI and Hyperion (EO-1)– ENVISAT
• Other data sets:– Socio-economic data (administrative boundaries, populations, cadastral data,
transportation networks, energy infrastructure)– Land cover, DEMs, catchment boundaries– Historical precipitation data and forecast precipitation data
Outputs
• Services and virtual infrastructure to support services:– Geospatially enabled campaign manager: visualization of
available data products over given geographic area; automatic tasking of satellites and automated data retrieval mechanisms
– Flood products: UM global flood potential product from TRMM data and DFO Satellite-based Flood Detection and Flood Risk Assessment to be adapted to regional context. Other flood products based on MODIS, ALOS, ENVISAT, EO-1 and RADARSAT data
– Decision support tools: software marrying input from satellites and socio-economic data sets
– Train the trainer modules: dedicated capacity building tools to support training in Caribbean region
Outcomes
• Decision makers: better enabled to take critical decisions in context of flood planning and response
• Regional civil protection agencies: better able to face flooding, find information and increase awareness of flood impacts
• The public: more aware of flood impact during and after events
• Data suppliers: increased awareness of gaps in data supply and need for support during mitigation and warning phases, rather than only during response
Capacity Building
• Capacity building is central to the success of the pilot• Pilot plans to link technical personnel from end-user
organizations with those knowledgeable with regard to satellite resources and their tasking
• In-person training sessions with willing end users planned
• Virtual capacity building to be developed through “train the trainer” modules that make up part of pilot’s outputs
Relevance
• Pilot will raise awareness of usefulness of satellite EO in area strongly affected by disasters
• Flooding is most serious and common disaster both in Caribbean and on global basis
• Caribbean offers “smaller” scale to work out technical issues and strong willingness of user community to collaborate
• Pilot expected to showcase need for increase data with regard to mitigation and warning phases
• Limited commitment in pilot context should encourage stronger participation from space agencies and other suppliers
User Requirements
• Establish user requirements (for each disaster type and phase):– Identify region of interest (priority areas)– Identify target characteristics (what do we want to
see?)– Identify temporal revisit period– Establish timeliness/latency requirements– Identify end use for data by intermediate user
(application, service, etc)
Architecture Options
• Establish architecture requirements (for each disaster type and phase):– What type of satellite data? (SAR, optical,
altimetry, etc)– Number of satellites and coverage mode? – Ground segment– Application
• Roll-up across all disaster types to establish overall requirements of virtual constellation
• Simulate architecture options
Floods
©The World Bank – Natural Disaster Hotspots: A Global Risk Analysis
User Requirements-Floods
Phase
Requirements
Mitigation Warning Response Recovery
Target/data Topography
Hydrological models
Historical atlas of floods
Flood models/simulations
New infrastructure, houses
Land-use classification
Monitoring of dikes and dams
Precipitation
Water level (rivers, lakes)
Weather forecast
Soil moisture
Snow-water equivalent
Signs of catastrophic infra failure
Water level (rivers, lakes)
Extent of flood
Status of critical infrastructure
Weather forecast
Status of critical infrastructure
Damage assessment
Flooded areas
Revisit 1 to 3 years (imagery)
5 to 10 yrs (topography)
Daily or better during high risk period
Daily in early morning; twice daily if possible
Weekly (major floods) for several weeks to several months
Timeliness Weeks Hours Hours (2-4 max) 1 day
End use Integration in land use planning/zoning
Baseline for response
Decision support for warnings & evacuation
Situational awareness
Resource allocation support
Initial damage assessment
Tracking affected assets
Charting progress
Architecture Requirements-Floods1
Phase
Requirements
Mitigation Warning Response Recovery
Data type Low res DEM for flow rates (radar, stereo, laser)
Higher res DEM (DTED-2 or better) for extent and location (radar, stereo, laser)_
Medium to high res (scale, other image sources, urban/rural) Optical or radar overlay (geo-coded, ortho-rect.)
Archived imagery of previous floods
Interferometric analysis of subsidence (and other changes)
Met sats
Precipitation radar
X, C or L-band SAR 10-50m data
Passive microwave (for soil moisture)
Hi res optical upstream for slow flood
Altimeters
Interferometric analysis of subsidence (and other changes)
Precipitation radar
X, C or L-band SAR 10-50m data (extent of flood – large areas) ; higher res radar and optical for urban areas or flash floods (damage)
Met
Altimeters
Med to high res optical and radar
Interferometric coherent change maps
Coverage and revisit
Continuity of existing optical and radar missions (need to develop background mission coverage in areas on flood map)
Daily coverage in regional areas affected
Pre-dawn or dawn required
Daily early morning coverage in regional areas affected
Continuity of existing optical and radar missions
Architecture Requirements-Floods2
Phase
Requirements
Mitigation Warning Response Recovery
Potential data source
SRTM (background)
SRTM DTED-2, Tandem-X DTED-3, Cosmo, etc….
GPM
3-4 radar satellites on same orbit; 2-3 satellites using same frequency in same orbits
Optical: comparable?
3-6 radar satellites on same orbitOptical hi res (2 or more)
2 radar satellites using same frequency
Optical hi res (1)
Ground segment
(need for development)
Using existing ground segments
Fast download, fast tasking (northern/southern stations, geostationary com links)
Very fast download and tasking (northern/southern stations, geostationary com links)
Using existing ground segments
Application Integration with risk map
Land cover maps
Information used for bulletins and evacuation, warnings
Situational awareness products
Tracking affected assets
Disaster Response
This image from September 8, 2008 was provided by the U.S. Navy. Homes seen in Port De Paix, Haiti remain flooded after four storms in one month devastated the area and killed 800+ people. The amphibious assault ship USS Kearsarge was diverted from the scheduled Continuing Promise 2008 humanitarian assistance deployment in the western Caribbean to conduct hurricane relief operations in Haiti. (Getty Images)
Disaster Response
The surge before the Hurricane Ike swamps Galveston Island, Texas, and a fire destroys homes along the beach as the storm approaches Friday, Sept. 12, 2008. (AP Photo/David J. Phillip). Top left: Gilchrist, TX on 14 Sep 08 (David J. Phillip-Pool/Getty Images).
Results to date• Consensus on methodology to collect user requirements for
multi-hazard disaster management for all phases• Buy-in to process from large representative user body
(including civil defense, international organizations)• Commitment from space agencies to provide support to
modeling scenarios, and to work towards solution in context of CEOS
• Negotiations underway with International Charter:– Mechanisms for broadening of Authorized User community
(those that activate the Charter during response) to include all GEO Member States currently under discussion
– Advice sought on how to better access archived data to support other phases (beyond response)
AIP-2 Kickoff Workshop Results. Summary of Disaster Responses (1/2)
Speaker/Organization Title
Stu Frye – Session Lead (NASA) Overview of GEOSS Pilot and GEO Tasks for Disaster Response
Ron Lowther* (NGC) Agenda, Timelines, and List of Primary Participants
Didier Giacobbo* (Spot Image) List of Services and Components from Primary Participants
Morris Brill (NGC) Northrop Grumman (NGC) Response to GEOSS AIP-II CFP
Stu Frye (NASA/SGT) Caribbean Flood Pilot Sensor Web
Didier Giacobbo (Spot Image) Spot Image Response to the GEOSS AIP-2 CFP
Jeff de La Beaujardiere (NOAA IOOS)
NOAA IOOS Data Integration Framework (DIF) Contribution to the GEO AIP-II
Ken McDonald (NOAA) and Dr. Liping Di (GMU)
NOAA-NASA GOES-R and GMU CSISS joint efforts for persistent GOES data services, weather scenarios, Web geoprocessing services, and BPEL-based workflows
Prof. Natalia Kussul, SRI NASU-NSAU (GEO-Ukraine)
Sensor Web for Flood Applications
* Ron Lowther and Didier Giacabbo co-leads for the AIP-2 Disaster Management Scenario
AIP-2 Kickoff Workshop Results. Summary of Disaster Responses (2/2)
Satoko H. MIURA and Kengo AIZAWA (JAXA)
Catalog Server for ALOS data
Steve Del Greco (NCDC) The Next Generation Weather Radar system
SURA/SCOOP, GoMOOS, and NIMSAT
Communication of Disasters and Mitigation of Post-Disaster Damage
ICAN (Oregan State U.) International Coastal Atlas Network (ICAN)
(CNES) CENTRE NATIONAL D’ETUDES SPATIALES
Disaster Charter Catalog Server for GML-EO Metadata Harvesting and HMA-compliant Web Services Access
(ERDAS) The Earth to Business Company
Geospatial Collaboration and Information Sharing Infrastructure for GEOSS
Work Plan Development / Open Discussion
What is missing and still needed: services, components, and data/product gaps?
“ What would result in paradigm shifts to meeting our objectives rather than simple evolutionary paths?
Adjourn Session Co-Leads will present summary of the session and work plan (with dates/actions) at closing Plenary
Speaker/Organization Title
PartnersFlood Pilot includes range of partners at this time, with further
partners expected:• NASA Goddard SFC (Lead)• CEOS Disaster SBA Team (advisory role)• UNOOSA/UN-SPIDER (advisory role)• Caribbean Disaster Emergency Response Agency (CDERA)• CATHALAC/SERVIR• ESA• Caribbean URISA Charter • West Indies University• American Institute of Technology (ITLA) • School of Earth & Environmental Sciences at the University of
Portsmouth, UK • Others invited to join
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