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MarsSIpulami
V3.0
E-Mars Web-GIS data server
Loïc LOZAC’H
Ingénieur d’étude projet ERC e-Mars
MarsSIpulami V3.0 E-Mars Web-GIS data server Sommaire 1. Context - - PowerPoint PPT Presentation
MarsSIpulami V3.0 E-Mars Web-GIS data server Sommaire 1. Context - - PowerPoint PPT Presentation
Loc LOZACH Ingnieur dtude projet ERC e-Mars MarsSIpulami V3.0 E-Mars Web-GIS data server Sommaire 1. Context 2. Design architecture 3. Data Base 4. Geoserver 5. MarsSipulami : UI & System 6. Further development 1.
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- 1. Context
- 2. Design architecture
- 3. Data Base
- 4. Geoserver
- 5. MarsSipulami : UI & System
- 6. Further development
Sommaire
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Mars exploration history
- 1965 : Mariner-4 to Mariner-9
- 1976 : Viking 1 & 2
- 1996 : Pathfinder Rover and Mars Global Surveyor
- 2001 : Mars Odyssey
- 2003 : MERs et Mars Express (european mission)
- 2006 : Mars Reconnaissance Orbiter
- 6 août 2012 : Curiosity Rover landing
- 1. Context
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- 1. Context
Orbiter Mars surveyor instruments Mars Global Surveyor (MGS) MOLA (Mars Orbiter Laser Altimeter) MOC (Mars Observer Camera) TES (Thermal Emission Spectrometer) Mars Odyssey (ODY) THEMIS (Thermal Emission Imaging System) Mars Express (MEX) HRSC (High Resolution Stereo Camera) OMEGA (Observatoire pour la Minéralogie, l’Eau, les Glaces et l’Activité) Mars Reconnaissance Orbiter (MRO) CTX (Context Camera) HiRISE (High Resolution Imaging Science Experiment) CRISM (The Compact Reconnaissance Imaging Spectrometer for Mars)
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- 1. Context
THEMIS IR Day CTX CRISM HiRISE
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THEMIS IR Day CTX CRISM HiRISE
- 1. Context
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E-Mars project
- Leading by Mrs Quantin-Nataf on ERC funds in
LGLTPE laboratory
- Study of the geological evolution of Mars
- Based on the last 4 missions with embedded
imagery intruments
- Needs of large storage capacity
- Needs of large data management software
- 1. Context
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Software Development Lifecycle
- 1. Context
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- 2. Design architecture
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- 3. Database
Data Base server PostgreSQL
- PostGis : particular configuration of the database
allowing geometrical and geographical consideration
- f the Data
- Entity Model : reflect the fonctionnality of EmarsSI
- application. Allow persistance of the data used in the
application (ex: absolute path of rasters stocked on server)
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- 3. Database
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- 4. GeoServer
- GeoServer provides WMS and WFS protocol used
by Geomajas
- WMS : THEMIS IR Day and MOLA are regularly
tiled and GeoServer manages the resolution display in order to obtain optimal response to internet request
- WFS : same but for vector features. Provides the
attributes table of the footprints from PostGis
- Web interface allows the administration of the
different layers provided
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- 5. MarsSipulami : UI & System
- Client face has been developped thanks to
Geomajas’s API. It offers the basement to develop the GIS Web pages
- Communication between client face and server face
is ruled by the design command pattern :
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- 5. MarsSipulami : UI & System
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- 5. MarsSipulami : UI & System
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- 5. MarsSipulami : UI & System
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- 5. MarsSipulami : UI & System
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- 5. MarsSipulami : UI & System
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- 5. MarsSipulami : UI & System
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- 5. MarsSipulami : UI & System
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- 5. MarsSipulami : UI & System
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- 5. MarsSipulami : UI & System
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- 6. Further development
- Integrate IDL scripts for CRISM processing and other
- A new calculation cluster will be added to storage
server
- The new architecture fit the calculation cluster’s manipulation
- Use of script launching TORQUE command
- Improve image processing productivity
- Partnership under PNP propective and VO to develop
interoperability and database access
- VO-Planeto, IDIS, 3DView, SAMP protocol
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