With the trend towards satellite Mega-Constellation more and more satellites are being placed into the
Low-Earth Orbit (LEO). Considering the number of satellites already in orbit, with and without inter-
satellite communication, it is now necessary and feasible to take measures for safe operation and safe orbit maintenance. In terms of operating more than hundreds or thousands of satellites for a single mission, on-board autonomy based on artificial intelligence is coming into focus. The rapid growth of AI-based technology enables the autonomous control of specific sub-systems, formation management, monitoring of each satellite in a cluster, or on-board decision-making during operation.
This paper presents a preliminary system concept for a LEO mega-constellation mission with on-board autonomy based on safety-guided design principles. To take measures considering emergent properties created by the interaction between different subsystems in a satellite and satellites in a cluster, the system theory-based hazard analysis method ‘System Theoretic Process Analysis’ is applied. Based on this hazard analysis, a preliminary system architecture including the control structure in a multi satellite system is derived. This work is divided into several parts according to autonomous architecture concepts
(centralized- and distributed coordination). Each part includes possible hazardous scenarios, associated causal factors, and derived safety requirements for safe autonomous operation in orbit.
«With the trend towards satellite Mega-Constellation more and more satellites are being placed into the
Low-Earth Orbit (LEO). Considering the number of satellites already in orbit, with and without inter-
satellite communication, it is now necessary and feasible to take measures for safe operation and safe orbit maintenance. In terms of operating more than hundreds or thousands of satellites for a single mission, on-board autonomy based on artificial intelligence is coming into focus. The ra...
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