Astrodynamics project simulating METEOSAT 9’s orbital insertion from GTO to geostationary orbit using PSIMU software. Calculated optimal ΔV budgets, designed multi-phase maneuvers respecting fuel constraints, and achieved precise orbital positioning with <0.005% error. Combined theoretical orbital mechanics with practical mission planning methodologies.
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During September 2025, I completed an advanced astrodynamics laboratory project within the Master’s program in Space Tools and Systems at the Paris Observatory - PSL. This practical work focused on the detailed analysis and simulation of METEOSAT 9’s geostationary orbit insertion using PSIMU software developed by CNES. The main objective was to determine the ΔV budget required for the satellite’s transition from the Geostationary Transfer Orbit (GTO) to its final operational circular orbit, while accounting for fuel tank constraints and propellant management limitations
The project combined orbital mechanics theory with specialized space mission design software to simulate the complete orbital insertion sequence. My approach integrated three complementary methodologies: precise characterization of the initial GTO orbit based on Ariane 5 user manual specifications, theoretical calculation and simulation of circularization and radial correction maneuvers, and analysis of fuel management constraints related to the satellite’s four spherical propellant tanks. The work required mastering PSIMU’s complex parameter configuration for satellite modeling (mass distribution, propulsion systems, tank architecture) and implementing a multi-phase maneuver strategy to respect the 244 kg capacity limitation of each fuel tank
This astrodynamics laboratory provided invaluable hands-on experience with professional space mission design tools and methodologies used in the European space industry. The project successfully bridged theoretical orbital mechanics concepts with practical engineering constraints, demonstrating the precision and complexity required for successful geostationary satellite operations. The experience reinforced my interest in space systems engineering and provided concrete foundations for advanced studies in spacecraft mission design and orbital dynamics applications.
Download the full project report for in-depth technical documentation and detailed findings.
![image of engineers working on satellite components [team]](https://cdn.prod.website-files.com/68b8a2f09cb5f6e554409260/68cd6e9b052cc2758eaa3152_Meteosat_Geostasjon%C3%A6r_satellitt.jpg)
![image of engineers working on satellite components [team]](https://cdn.prod.website-files.com/68b8a2f09cb5f6e554409260/68cd6ecfe3d7d6153e0a14cf_Capture%20d%E2%80%99e%CC%81cran%202025-09-19%20a%CC%80%2016.55.03.png)
![image of engineers working on satellite components [team]](https://cdn.prod.website-files.com/68b8a2f09cb5f6e554409260/68cd6f14ff26f2d47b19038d_Capture%20d%E2%80%99e%CC%81cran%202025-09-19%20a%CC%80%2016.56.13.png)
