09 September 2016
The BEESAT-4 pico-satellite is installed in the BIROS fire detection satellite by a staff member of TU Berlin before BIROS was launched into space on June 22 2016. The pico-satellite is expected to gather precise position and orbital determination information as well as use a camera to take series of photos and individual images of the Earth’s surface during its one-year mission. The telemetry values and image data collected are then sent to BIROS that then forwards it to the TU Berlin ground station for analysis.
The illustration shows a BEESAT-4flight model. Following its ejection from the larger BIROS satellite, the cubic pico-satellite (CubeSat) with sides ten centimetres long is expected to support the AVANTi experiment on board BIROS with GPS data, among other things. This data is sent to the BIROS fire detection satellite via an inter-satellite link.
Technical University of Berlin.
The BEESAT-4 picosatellite contains a redundant on-board computer, batteries and a communication system, as well as sensors needed for determining the position. In addition, the DLR Phoenix GPS receiver is used for precise position and orbital determination. An installed camera is used to take various images of the surface of the Earth to determine the position of the satellite.
On 9 September 2016 at 13:00 CEST, the BIROS (Bi-Spectral Infrared Optical System) fire detection satellite developed and built by the German Aerospace Center (Deutsches Zentrum für Luft- und Raumfahrt; DLR) released BEESAT-4 (Berlin Educational and Experimental Picosatellite) into space 515 kilometres above the Norwegian Svalbard archipelago. The cubic satellite with sides 10 centimetres long was developed and built by staff and students at the Technical University of Berlin (TU Berlin) and was supported by the DLR Space Administration with funds from the German Federal Ministry for Economic Affairs and Energy (Bundesministerium für Wirtschaft und Energie; BMWi).
BEESAT-4 should now be able to use the on-board Phoenix GPS receiver to gather precise position and orbit determination information, as well as take series of photographs and individual images of Earth's surface with a special camera to confirm the position of the satellite. The telemetry and image data will then be sent to the BIROS 'mother ship' that then forwards it to the TU Berlin ground station for analysis. BIROS was successfully launched from the Satish Dhawan Space Centre in India on 22 June 2016.
"Precise knowledge of the position of the picosatellite (CubeSat) is a prerequisite for formation flights for multiple satellites. With the picosatellite class in particular, formation flights offer the advantage that tasks and functions can be allocated to different satellites. Furthermore, multiple satellites enable longer overflight times over ground stations for the transmission of telemetry and payload data. In addition, regions of interest can be flown over multiple times," explains Sascha Weiss, the BEESAT-4 project leader at TU Berlin, adding: "We are continuing our sequence of picosatellites with BEESAT-4. We specifically want to determine the position of the satellite over the next 12 months using the Phoenix GPS receiver so we can predict the orbit of BEESAT-4."
The BEESAT-4 mission builds on the knowledge and experience of previous BEESAT missions, so the majority of the work is not spent on the construction of the satellite but on developing the complex software. "Two science staff and two students have been on our team since 2013. With the development and operation of BEESAT-4, we have been able to reinforce the practical aspects of student training at TU Berlin’s Institute of Aerospace. Numerous undergraduates have completed their theses within the scope of the mission," explains Weiss.
Last modified:09/09/2016 16:32:40