Overview of new work packages for the next SPENVIS phase D. Heynderickx BIRA, Ringlaan 3, B-1180 Brussel, Belgium
Management and development BIRA WP 100 WP 110: Project management WP 120: SPENVIS workshop WP 200 WP 210: Software lifecycle WP 220: Demonstration, accecptance, maintenance WP 230: Interface protocol WP 300 WP 310: MAGNETOCOSMICS WP 320: Radiation belt models WP 330: SEP models WP 340: Orbit generator WP 400 WP 410: GDML output WP 420: GRAS interface WP 430: Sector tool interface WP 440: Outgassing and contamination WP 500 WP 510: DICTAT WP 520: Surface charging WP 530: ESTEC ionosphere WP 600 WP 610: Solar cell degradation WP 620: Radiation effects WP 700 WP 710: Data base tool WP 720: Hosting of EDID
Commercialisation Rhea WP 800 WP 810: Analysis of user data base WP 820: business model development WP 830: business model implementation
Radiation environment models Implementation of MAGNETOCOSMICS (Geant4) Implementation of radiation belt models POLE GEO electron model SAMPEX/PET dynamic LEO proton model Jovian radiation belts Implementation of solar energetic proton models MSU model (Nymmik) ESP model for solar minimum (PSYCHIC) Extend the energy range of the JPL model below 5MeV and above 100MeV Upgrade of the orbit generator implement new trajectory types: hyperbolic, parabolic, interplanetary, escape modify other models and tools that use the orbit generator introduce flags for coordinate systems
Sectoring analysis tool Implementation of GDML output Implementation of GRAS interface Development of a sectoring tool interface establish user requirements for the interface identify existing freeware 3D tools for possible use Outgassing and contamination tool
Spacecraft charging Upgrade of the DICTAT tool: implementation of new version Upgrade of the surface charging tool implement the surface charging tool developed in the SPIGH project implement links to material data bases Implementation of the ESTEC ionosphere package
Radiation effects Upgrade of the solar cell degradation package Mathlab tool for generating RDCs SAVANT code (NIEL method) solar cell laboratory data (GADGET-2, Astrium RDCs) Upgrade of radiation effects tools implementation of electron NIEL implementation of ONERA effective dose estimates implementation of radiation damage to materials (glasses) implementation of SEU tools for digital, analog and mixed signal devices implementation of biological doses
Other Upgrades of the data base tool integrate new data bases update solar wind and magnetic indices when available investigate a migration to a relational (SQL) data base Hosting of EDID ( European Detector Impact Database) online database for the interactive retrieval of impact data from the GORID and DEBIE-1 impact detectors implement the system on a BIRA server provide access to the data base interface Interface with ECSS documents Spacecraft charging Radiation effects
Commercialisation Analysis of SPENVIS user data base analysis of existing users: usage modes, reason for selecting SPENVIS, user input on development requirements, terms of service exchange (e.g. with NASA management, users and model providers, ESA contractors) analysis of SPENVIS market position w.r.t. rival services and products (market share, pricing policy, etc.) market analysis to determine further distribution of SPENVIS Development of SPENVIS business model identification of business model criteria for trade-off analysis identification of different business models and associated technical modifications trade-off analysis and selection of a business model Implementation of SPENVIS business model specification of and implementation of support structures: maintenance support, release and upgrade structure, configuration control, identification of marketing and sales activities,... quality control of SPENVIS deliveries recognition and support of common standards exchange policy with model and data providers