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Tag: exomars
Saft Li-ion Battery to Power the ExoMars Rover as it Searches for Life on the Red Planet
2015-08-12 12:31:12| Industrial Newsroom - All News for Today
Paris Saft, the world's leading designer and manufacturer of advanced technology batteries for industry, has signed a contract worth over one million euros from Airbus Defence and Space Ltd (UK) to develop, qualify and test a specific lithium-ion (Li-ion) battery system to power the ExoMars Rover vehicle. The...
Saft Li-ion battery system to power ExoMars Rover; >1M contract
2015-07-09 17:55:31| Green Car Congress
Tags: system
power
contract
battery
PA and Safety Support to Exomars Rover Instruments
2015-05-28 15:02:22| Space-careers.com Jobs RSS
HE Space is a successful international space company. For over 30 years, we have been supporting our customers with qualified experts in the field of engineering, science and administration. We are currently looking for a PA and Safety Support to Exomars Rover Instruments to support our customer in the Netherlands. PA and Safety Support to Exomars Rover Instruments Key Tasks and Responsibilities As part of the team, you will have the following responsibilities PA responsible for the Rover instruments of the Exomars 2018 mission 9 PI provided instruments Participation in Instrument Design reviews, NRBs, coordinating DRBs for instrument model deliveries Interfacing with PI development teams and ESAIndustry Payload team as well as Rover teams Coordinating functional support for interface related PA issues Giving PA support to other elements of the Exomars project, if necessary Significant travel to partner locations Skills Experience You will have the following qualifications and relevant experience University Degree in a relevant discipline Experience in dealing with instrument teams and general PA background Several years experience in PAAIT domain Several years experience in management of PAS programmes. Fluency in English is mandatory knowledge of another European language is an advantage. This job is located in Noordwijk. We welcome applicants who are available from July 2015 or as soon as possible thereafter. If you think you have what it takes for this job, please send us your CV together with a letter of motivation both in English and in Word to Ms Julia Niehaus at jobshespace.com, quoting job NLSC2629 before 08Jun15. An exciting and dynamic international working environment awaits you!
Tags: support
safety
instruments
rover
Support to Science Operations JUICE MEX ExoMars
2015-05-07 18:04:56| Space-careers.com Jobs RSS
Great opportunity and salary conditions to work in ESAC The European Space Astronomy Centre in Madrid, Spain with The Server Labs. The Server Labs, an European well established and leader software development and technology consultancy is now expanding its team at ESAC. We offer an excellent package, including highest salary, company benefits, extra holidays 30 days holidays plus public and local holidaysand health and dental medical insurance. Important Candidates must hold a European Passport and be willing to work in Spain Company Description The Server Labs is an European technology services company, leader in software engineering solutions and handson technology consulting, in areas such as Continuous integration and delivery, Devops, Cloud computing, Grid architectures and HPCBig data. We collaborate with our clients to obtain success, committed to innovation, enjoying what we do every day and growing with every challenge. The Server Labs works with different industries and business verticals. Within the Space industry, The Server Labs works with the European Space Agency ESA, with ESAC, near Madrid, with ESOC, in Darmstadt, near Frankfurt, with ESTEC, in Noorwijk near Amsterdam and with ESRIN, in Frascati. We provide specialists to ESA, but we also deliver services and successful projects to provide additional value in the technology initiatives led by ESA. By working with The Server Labs, you will be part of a multinational team in a fast growing technology company based in London, Madrid and Frankfurt. Please send your CV with cover letter to resumetheserverlabs.combefore 18th of May 2015. Job Description Support to Science Operations JUICE MEX ExoMars This work package defines the tasks involved in providing service support to Mars Express MEX, ExoMars 2016 and JUICE Science Ground Segments SGS and defines the necessary tasks to be developed for the service support. All these activities are based at ESAC. Each of the Science Ground Segments of the three missions are at different stages of their lifetime, with Mars Express in operations, ExoMars in implementation and Juice in early development. The following paragraphs provide a background overview. JUICE is the first large mission of the Cosmic Vision Program to be implemented by ESA. JUICE will perform detailed investigations of Jupiter and its system components in all their interrelations and complexity, with particular emphasis on Ganymede as a planetary body and potential habitat. The investigations of the neighbouring moons, Europa and Callisto, will complete a comparative picture of the Galilean moons and their potential habitability. The mission was adopted in November 2014. The JUICE Science Operations Centre SOC, based at ESAC, is responsible for the implementation of the Science Ground Segment SGS following the requirements defined by the Project Scientist. An important task of the SOC in this early phase is to support the analysis of the operational scenarii defined by the Science Working Team during the mission development to verify the ability of the mission to deliver the expected science return within the operational constraints. ExoMars 2016 is the first mission of the ExoMars programme and it consists of a Trace Gas Orbiter plus an Entry, Descent and Landing Demonstrator Module EDM that will be launched together in January 2016 on a Proton rocket and will fly to Mars in a mated configuration scheduled for arrival after a 9month cruise phase. Three days before reaching the atmosphere of Mars, the EDM will be ejected from the Orbiter, entering the Martian atmosphere and landing on the surface of the planet. The ExoMars Trace Gas Orbiter will be inserted into an elliptical orbit around Mars and will then sweep through the atmosphere during a long aerobraking phase of several months to finally settle into a circular, 400km altitude, orbit ready to conduct its scientific mission starting in late 2017. The main objectives of this mission are to search for evidence of trace atmospheric gases that could be signatures of active biological or geological processes and to test key technologies in preparation for ESAs contribution to subsequent missions to Mars. The Trace Gas Orbiter will also serve as a data relay asset for the 2018 rover mission of the ExoMars programme until the end of 2022. The ExoMars Science Operations Centre at ESAC is responsible for the development and implementation of the SGS and thus the Science Operations and Data Handling Concept following the Science Implementation Requirements provided by the Project Scientist, This covers all the operational activities originating from the mission science objectives defined by the Science Working Team SWT including interactions with the Instrument Teams, the Russian SOC at IKI in Moscow, and the Mission Operations Centre MOC at ESOC, for the routine science operations, and ending in the generation and processing of science data that is then archived in the Planetary Science Archive PSA. The Mars Express mission was launched in June 2003 and has been providing great amounts of data since its arrival at Mars in December 2003, covering a wide range of science objectives at all levels, from the surface and subsurface geology, atmosphere dynamics and composition, up to the interaction with the magnetosphere and the characterization of the Martian system including its two moons, Phobos and Deimos. The Mars Express SOC at ESAC is responsible for the coordination of the scientific requests from the experiment teams and the implementation of the detailed science plan with the pointing and instrument observation timelines, aiming to obtain the maximum scientific return of the mission while respecting the operational constraints. We detail in what follows the different types of services required to cover the needs of all three SGSs. All services listed below are applicable on all three missions. However, not all services will be performed at the same time, as the services needs will evolve with mission and time. Service Specific Tasks Science Ground Segment Coordination Tasks Coordination of Science Ground Segment operational activities and overall organization and scheduling of routine planning processes. Coordination of scientific activities and specific interfaces with Principal Investigator teams, Project Scientist and Science Working Team Coordination of engineering activities and interfaces with the Mission Operations Centre and ESA DTEC MAPPS development team. Coordination and preparation of scientific and operational meetings, including the Science Operations Working Group, Science Working Team and Mission Operations and Harmonization of Interfaces Meetings, in close collaboration with the Development or Mission Manager and the Project Scientist. Routine Science Operation Support Tasks Support to routine Long Term Planning LTP activities through scientific and engineering analysis of future planning seasons, in order to identify and study scientific observation campaigns and operationally constrained seasons. Scientific analysis of future observation campaigns in coordination with the Science Working Team SWT and the Science Operations Working Group SOWG. Operational analysis of potentially constrained seasons, in collaboration with the Mission Operations Centre, in particular in preparation for the Mission Operations Usage and Harmonization of Interfaces Meeting. Support to nonroutine Long Term Planning activities linked to the availability of new orbit trajectory products or other long term operational files coming from ESOC andor PIs, for coordination and preparation of all geometrical, scientific and operational products based on new trajectory ephemeris and long term resource files. Support to routine Medium Term Planning MTP activities, coordinating the harmonization of pointing and instrument observation timelines in MTP cycles covering 4 weeks. Scientific support for the preparation of science observation campaigns and dedicated pointing requests, in coordination with the Science Operations Working Group. Engineering support for the resolution of nonroutine planning anomalies and the coordination of any planning conflict with experiment teams andor the Mission Operations Centre at ESOC. Exceptional support may also be required in case of unavailability of any of the mission planners, serving as a backup resource for all LTPMTPSTP routine activities. Support to routine Short Term Planning STP activities, including the generation of detailed instrument command sequences and resource allocation, coordinating the detailed iterations with experiment teams. Expansion of Mars Express Request files MREQs instrument modes into operational activities for the generation of command sequences. Modelling and simulation of instrument resources including data rates and power profiles Generation of Payload Operation Requests PORs and Instrument Timelines ITLs for STP iterations with the Experiment teams and final delivery to the MOC. System Engineering Support Tasks Technical coordination with TEC, MOC and Experiment teams for the development of MAPPSEPS tools and the maintenance of the MEX Science Operations repository. Definition and maintenance of all experiments and spacecraft subsystem models, including all configuration settings for the plan simulation and constraint validation. Development and maintenance of additional tools for the generation and processing of all operational files used for planning, science opportunity analysis and data generation. Maintenance of the MEX science operations data management system and interfaces, including SGS web site, centralized CVS repository, file transfer services and online database. Science Implementation Analysis Tasks Support to the Project Scientist and the Science Operations Development Manager in the development of Science Implementation Requirements, flagging those that will introduce deltas to the system design Support to the Project Scientist, Deputy Project Scientist and Instrument Operations Scientist in the operational analysis of the different mission phases, to monitor the mission expected science return against baseline operational assumptions as well as to understand and report the impact of operational assumptions changes. Iterate on the SIRDSIP requirements and traceability identifying the system implications Iterate on the operations concept and toplevel process within the system design System Requirements Analysis Tasks Derive the SGS Technical Requirements Specifications to provide an overview of the SOC functionalities to demonstrate SIRD compliance Define the SGS Technical Requirements Specifications, including justification, taking into account the main drivers coming from the SIRD and the SGS Operations Concept. Produce High Level SGS Technical Requirements Specifications compliant with the SIRD Baseline System Design Tasks Produce the baseline design of the core system, including the architecture, demonstrating traceability to the SGS system technical requirements. Analyse the SGS operations processes and system requirements, mapping the SGS system requirements to individual process steps Consolidate the system design, identifying main SGS functionalities, by grouping SGS system requirements and commonalities among process steps, taking into account all necessary actorsroles. Document the SGS design including a preliminary analysis of the potential for reuse of existing multimission software systems and infrastructure. Critical System Design Tasks Iterate on the SGS technical specification to keep it compatible with generic crossmission updates made to the core system, producing the detailed design of the core system Analyse the impact of Operations ConceptProcess changes on the requirements and core component modifications MAPPSEPS. Assign technical requirements to SGS development deliveries e.g. core system, nominal science system Consolidate the detailed design by analysing the SGS operations processes and system requirements, mapping the system requirements to individual subprocess steps, identifying commonalities between subprocess steps taking into account all necessary actorsroles. Document the detailed SOC design including the reuse of existing multimission software systems and infrastructure, plus any additional specific requirements needed to extend beyond generic functionality Preliminary System Implementation Tasks Iterative implementation of baseline SGS core uplink systems Ensure the System Readiness for endtoend type tests and preflight simulations or rehearsals SOVT, ATB, ORs , including Generic planning tool system configuration, validation of the generic planning tool modules, system level validation, support to operations acceptance tests, and setup the required operational interfaces. System Implementation Tasks Iterative implementation of SGS core uplink systems Ensure that the requirements derived from the needs of the different stakeholders, and related to the core SGS, have been implemented Elicit further requirements to be added to the baseline requirements for the next increments of the SGS system design Complete the SGS system design defining a fullbaseline for all the components, finalizing the architecture and completing the interface service requirements for all stakeholders Support integration of all SGS Systems in time for launch. System Validation and Verification Tasks Validate and verify the SGS systems against the system requirements with demonstrated upwards traceability to the technical specification and ultimately the SIRD. Qualify the SGS System implementation in time for launch Support endtoend type tests and preflight simulations or rehearsals SOVT, ATB, ORs Support of the checkout activities Output and Service Performance Monitoring ESA will formally define the service delivery in terms of delivery times, performance targets and similar measurable parameters Key Performance Indicators. This shall be agreed with the service provider and shall be assessed, and modified as needed, during regular progress meetings typically monthly. The service provider shall manage the service provision and provide ESA with the necessary data and corresponding evidence. The service provider shall be measured and assessed on the basis of System development reports following Science Ground Segment progress meetings System engineering reports following technical implementation meetings with DTEC System engineering reports following operational meetings with Mission Operations Centre System technical requirements, architecture design documents for system design review System implementation documents for implementation reviews System test specifications and validation reports Dedicated Science Operations reports to Science Operations Working Group meetings System and Science Operations documentation i.e. Geometrical, Scientific and Operational technical notes, Planning reports, etc Interactions The service provider will coordinate its activities with all collaborating partners, in close contact with the Development Manager. Coordination with Principal Investigator teams for science operations system implementation Coordination with ESA MOCFDyn for engineering activities and interface definitions Coordination with Russian SOC NNK for engineering activities and interface definitions Coordination with ESA DTEC for MAPPSEPS development requirements and design Coordination with Project Scientists for Science Working Team meeting preparations Coordination with PSESOCPIs for longmediumshot term operational and scientific strategies Coordination within ExoMarsMEXJUICE SGS team for design and implementation activities Representation of SGS in SWT, SOWG, PI team meetings, conferences and workshops Specific Qualification Requirements The service to be provided requires that the personnel should possess a university education PhD or MSc in a scientific or technical subject and relevant professional experience in line with the requirements of the job class. In particular, the following experience is required for the service provider personnel Experience in science operations for solar system missions Experience in scientific analysis of planetary spectral and imaging data Experience in remote sensing of planetary surfaces and atmosphere Experience in data generation and calibration of planetary data Experience in data handling and archiving following Planetary Data System standards Experience in payload modeling, simulation and commanding Experience with planetary geometry and ancillary information tools SPICE Experience with planetary science operation tools MAPPS, EPS, etc Experience with software programming and scripting languages IDL, shellscript, DOS bash, etc Conditions of contract Permanent position Excellent package with salary and bonus Benefits 30 days holidays plus public and local holidays, medical insurance, dental insurance, assistance with relocation if needed, laptop, smartphone, training. Please apply to this position Send CV to resumetheserverlabs.com and cover letter, with indication of Position ID TSLSRE109 Deadline 18th of May 2015 Location Madrid, Spain Support Start Date 1 July 2015 Support End Date 31 December 2016
Tags: support
science
operations
juice
Support to Science Operations JUICE MEX ExoMars
2015-05-06 14:04:54| Space-careers.com Jobs RSS
A Spanish leader company in Aerospace Engineering and Scientific services with more than 45 years of experience working for NASA and 35 years working for ESA seeks a candidate for a System and Software Engineering for Science Operations. Work Package Overview This work package defines the tasks involved in providing service support to Mars Express MEX, ExoMars 2016 and JUICE Science Ground Segments SGS and defines the necessary tasks to be developed for the service support. All these activities are based at ESAC. Each of the Science Ground Segments of the three missions are at different stages of their lifetime, with Mars Express in operations, ExoMars in implementation and Juice in early development. The following paragraphs provide a background overview. JUICE is the first large mission of the Cosmic Vision Program to be implemented by ESA. JUICE will perform detailed investigations of Jupiter and its system components in all their interrelations and complexity, with particular emphasis on Ganymede as a planetary body and potential habitat. The investigations of the neighbouring moons, Europa and Callisto, will complete a comparative picture of the Galilean moons and their potential habitability. The mission was adopted in November 2014. The JUICE Science Operations Centre SOC, based at ESAC, is responsible for the implementation of the Science Ground Segment SGS following the requirements defined by the Project Scientist. An important task of the SOC in this early phase is to support the analysis of the operational scenarii defined by the Science Working Team during the mission development to verify the ability of the mission to deliver the expected science return within the operational constraints. ExoMars 2016 is the first mission of the ExoMars programme and it consists of a Trace Gas Orbiter plus an Entry, Descent and Landing Demonstrator Module EDM that will be launched together in January 2016 on a Proton rocket and will fly to Mars in a mated configuration scheduled for arrival after a 9month cruise phase. Three days before reaching the atmosphere of Mars, the EDM will be ejected from the Orbiter, entering the Martian atmosphere and landing on the surface of the planet. The ExoMars Trace Gas Orbiter will be inserted into an elliptical orbit around Mars and will then sweep through the atmosphere during a long aerobraking phase of several months to finally settle into a circular, 400km altitude, orbit ready to conduct its scientific mission starting in late 2017. The main objectives of this mission are to search for evidence of trace atmospheric gases that could be signatures of active biological or geological processes and to test key technologies in preparation for ESAs contribution to subsequent missions to Mars. The Trace Gas Orbiter will also serve as a data relay asset for the 2018 rover mission of the ExoMars programme until the end of 2022. The ExoMars Science Operations Centre at ESAC is responsible for the development and implementation of the SGS and thus the Science Operations and Data Handling Concept following the Science Implementation Requirements provided by the Project Scientist, This covers all the operational activities originating from the mission science objectives defined by the Science Working Team SWT including interactions with the Instrument Teams, the Russian SOC at IKI in Moscow, and the Mission Operations Centre MOC at ESOC, for the routine science operations, and ending in the generation and processing of science data that is then archived in the Planetary Science Archive PSA. The Mars Express mission was launched in June 2003 and has been providing great amounts of data since its arrival at Mars in December 2003, covering a wide range of science objectives at all levels, from the surface and subsurface geology, atmosphere dynamics and composition, up to the interaction with the magnetosphere and the characterization of the Martian system including its two moons, Phobos and Deimos. The Mars Express SOC at ESAC is responsible for the coordination of the scientific requests from the experiment teams and the implementation of the detailed science plan with the pointing and instrument observation timelines, aiming to obtain the maximum scientific return of the mission while respecting the operational constraints. We detail in what follows the different types of services required to cover the needs of all three SGSs. All services listed below are applicable on all three missions. However, not all services will be performed at the same time, as the services needs will evolve with mission and time. Service Specific Tasks Science Ground Segment Coordination Tasks Coordination of Science Ground Segment operational activities and overall organization and scheduling of routine planning processes. Coordination of scientific activities and specific interfaces with Principal Investigator teams, Project Scientist and Science Working Team Coordination of engineering activities and interfaces with the Mission Operations Centre and ESA DTEC MAPPS development team. Coordination and preparation of scientific and operational meetings, including the Science Operations Working Group, Science Working Team and Mission Operations and Harmonization of Interfaces Meetings, in close collaboration with the Development or Mission Manager and the Project Scientist. Routine Science Operation Support Tasks Support to routine Long Term Planning LTP activities through scientific and engineering analysis of future planning seasons, in order to identify and study scientific observation campaigns and Operationally constrained seasons. o Scientific analysis of future observation campaigns in coordination with the Science Working Team SWT and the Science Operations Working Group SOWG. o Operational analysis of potentially constrained seasons, in collaboration with the Mission Operations Centre, in particular in preparation for the Mission Operations Usage and Harmonization of Interfaces Meeting. o Support to nonroutine Long Term Planning activities linked to the availability of new orbit trajectory products or other long term operational files coming from ESOC andor PIs, for coordination and preparation of all geometrical, scientific and operational products based on new trajectory ephemeris and long term resource files. Support to routine Medium Term Planning MTP activities, coordinating the harmonization of pointing and instrument observation timelines in MTP cycles covering 4 weeks. o Scientific support for the preparation of science observation campaigns and dedicated pointing requests, in coordination with the Science Operations Working Group. o Engineering support for the resolution of nonroutine planning anomalies and the coordination of any planning conflict with experiment teams andor the Mission Operations Centre at ESOC. o Exceptional support may also be required in case of unavailability of any of the mission planners, serving as a backup resource for all LTPMTPSTP routine activities. Support to routine Short Term Planning STP activities, including the generation of detailed instrument command sequences and resource allocation, coordinating the detailed iterations with experiment teams. o Expansion of Mars Express Request files MREQs instrument modes into operational activities for the generation of command sequences. o Modelling and simulation of instrument resources including data rates and power profiles o Generation of Payload Operation Requests PORs and Instrument Timelines ITLs for STP iterations with the Experiment teams and final delivery to the MOC. System Engineering Support Tasks Technical coordination with TEC, MOC and Experiment teams for the development of MAPPSEPS tools and the maintenance of the MEX Science Operations repository. Definition and maintenance of all experiments and spacecraft subsystem models, including all configuration settings for the plan simulation and constraint validation. Development and maintenance of additional tools for the generation and processing of all operational files used for planning, science opportunity analysis and data generation. Maintenance of the MEX science operations data management system and interfaces, including SGS web site, centralized CVS repository, file transfer services and online database. Science Implementation Analysis Tasks Support to the Project Scientist and the Science Operations Development Manager in the development of Science Implementation Requirements, flagging those that will introduce deltas to the system design Support to the Project Scientist, Deputy Project Scientist and Instrument Operations Scientist in the operational analysis of the different mission phases, to monitor the mission expected science return against baseline operational assumptions as well as to understand and report the impact of operational assumptions changes. Iterate on the SIRDSIP requirements and traceability identifying the system implications Iterate on the operations concept and toplevel process within the system design System Requirements Analysis Tasks Derive the SGS Technical Requirements Specifications to provide an overview of the SOC functionalities to demonstrate SIRD compliance Define the SGS Technical Requirements Specifications, including justification, taking into account the main drivers coming from the SIRD and the SGS Operations Concept. Produce High Level SGS Technical Requirements Specifications compliant with the SIRD Baseline System Design Tasks Produce the baseline design of the core system, including the architecture, demonstrating traceability to the SGS system technical requirements. Analyse the SGS operations processes and system requirements, mapping the SGS system requirements to individual process steps Consolidate the system design, identifying main SGS functionalities, by grouping SGS system requirements and commonalities among process steps, taking into account all necessary actorsroles. Document the SGS design including a preliminary analysis of the potential for reuse of existing multimission software systems and infrastructure. Critical System Design Tasks Iterate on the SGS technical specification to keep it compatible with generic crossmission updates made to the core system, producing the detailed design of the core system Analyse the impact of Operations ConceptProcess changes on the requirements and core component modifications MAPPSEPS. Assign technical requirements to SGS development deliveries e.g. core system, nominal science system Consolidate the detailed design by analysing the SGS operations processes and system requirements, mapping the system requirements to individual subprocess steps, identifying commonalities between subprocess steps taking into account all necessary actorsroles. Document the detailed SOC design including the reuse of existing multimission software systems and infrastructure, plus any additional specific requirements needed to extend beyond generic functionality Preliminary System Implementation Tasks Iterative implementation of baseline SGS core uplink systems Ensure the System Readiness for endtoend type tests and preflight simulations or rehearsals SOVT, ATB, ORs , including Generic planning tool system configuration, validation of the generic planning tool modules, system level validation, support to operations acceptance tests, and setup the required operational interfaces. System Implementation Tasks Iterative implementation of SGS core uplink systems Ensure that the requirements derived from the needs of the different stakeholders, and related to the core SGS, have been implemented Elicit further requirements to be added to the baseline requirements for the next increments of the SGS system design Complete the SGS system design defining a fullbaseline for all the components, finalizing the architecture and completing the interface service requirements for all stakeholders Support integration of all SGS Systems in time for launch. System Validation and Verification Tasks Validate and verify the SGS systems against the system requirements with demonstrated upwards traceability to the technical specification and ultimately the SIRD. Qualify the SGS System implementation in time for launch Support endtoend type tests and preflight simulations or rehearsals SOVT, ATB, ORs Support of the checkout activities Output and Service Performance Monitoring ESA will formally define the service delivery in terms of delivery times, performance targets and similar measurable parameters Key Performance Indicators. This shall be agreed with the service provider and shall be assessed, and modified as needed, during regular progress meetings typically monthly. The service provider shall manage the service provision and provide ESA with the necessary data and corresponding evidence. The service provider shall be measured and assessed on the basis of System development reports following Science Ground Segment progress meetings System engineering reports following technical implementation meetings with DTEC System engineering reports following operational meetings with Mission Operations Centre System technical requirements, architecture design documents for system design review System implementation documents for implementation reviews System test specifications and validation reports Dedicated Science Operations reports to Science Operations Working Group meetings System and Science Operations documentation i.e. Geometrical, Scientific and Operational technical notes, Planning reports, etc Interactions The service provider will coordinate its activities with all collaborating partners, in close contact with the Development Manager. Coordination with Principal Investigator teams for science operations system implementation Coordination with ESA MOCFDyn for engineering activities and interface definitions Coordination with Russian SOC NNK for engineering activities and interface definitions Coordination with ESA DTEC for MAPPSEPS development requirements and design Coordination with Project Scientists for Science Working Team meeting preparations Coordination with PSESOCPIs for longmediumshot term operational and scientific strategies Coordination within ExoMarsMEXJUICE SGS team for design and implementation activities Representation of SGS in SWT, SOWG, PI team meetings, conferences and workshops Specific Qualification Requirements The service to be provided requires that the personnel should possess a university education PhD or MSc in a scientific or technical subject and relevant professional experience in line with the requirements of the job class. In particular, the following experience is required for the service provider personnel Experience in science operations for solar system missions Experience in scientific analysis of planetary spectral and imaging data Experience in remote sensing of planetary surfaces and atmosphere Experience in data generation and calibration of planetary data Experience in data handling and archiving following Planetary Data System standards Experience in payload modeling, simulation and commanding Experience with planetary geometry and ancillary information tools SPICE Experience with planetary science operation tools MAPPS, EPS, etc Experience with software programming and scripting languages IDL, shellscript, DOS bash, etc APPLICATIONS Interested candidates should send cv and cover letter to seleccionisdefe.es. The job code must included on the subjet.
Tags: support
science
operations
juice