The European Space Agency, in partnership with the University of Bern’s Astronomical Institute, conducted a study to understand the unpredictable tumbling of defunct satellites in space. This research is crucial for ESA’s Clean Space initiative, which seeks to safely remove these satellites from crowded orbits.
ESA and the University of BernFounded in 1834, the University of Bern (German: Universität Bern, French: Université de Berne, Latin: Universitas Bernensis) is located in the Swiss capital of Bern. It offers a broad choice of courses and programs in eight faculties and some 150 institutes.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>University of Bern conducted a study to understand and predict the tumbling of defunct satellites. This research supports ESA’s efforts to remove these satellites from busy orbits, considering various influencing factors like gravity and solar radiation.
Down on the ground, death equals stillness – but not in space. Abandoned satellites are prone to tumble in unpredictable ways and an ESA project with the Astronomical Institute of the University of Bern sought to better understand this behavior.
ESA’s Clean Space initiative has plans to remove dead satellites from highly trafficked orbits. The preferred method of ‘Active Debris Removal’ involves grabbing the target object, in which case knowledge of its precise orientation and motion will be vital. So the need is clear to understand the tumbling that almost all satellites and rocket bodies undergo after their mission end-of-life.
The project combined optical, laser ranging, and radar observations to refine an existing ‘In-Orbit Tumbling Analysis’ computer model, aiming to identify, understand, and predict the attitude motion of a fully defunct satellite within a few passes. More than 20 objects were observed during a two-year campaign.
Credit: ESA/University of Bern
The long list of perturbation triggers includes ‘eddy currents’ as internal magnetic fields interact with Earth’s magnetosphere, drag from the vestigial atmosphere, gravity gradients between the top of an object and its bottom, outgassing and fuel leaks, the faint but steady push of sunlight – known as ‘solar radiation pressure’ – micrometeoroid and debris impacts, even the sloshing of leftover fuel.
Among the study findings were rocket bodies and satellites in lower orbits are mostly influenced by gravity gradients and eddy currents, while up at geostationary altitudes, satellites with large solar panels are sensitive to solar radiation pressure.
The project was supported through ESA’s General Support Technology Programme, developing promising technologies for space.
Source: SciTechDaily
