LAUSR

Geostationary orbit (GSO) satellite communication systems (SCSs) play an important role in nowadays satellite communication. Orbiting in the Clarke Belt, the GSO satellites provide voice, video, Internet access, and other data services to the users all over the world. The GSO SCSs are seeking for more spectrum resource to satisfy the growing demand of high downlink data rate, while the radio astronomy system (RAS) is suffering the inevitable radio-frequency interference (RFI) from the downlink of these GSO satellites. To solve the conflict between the GSO SCSs and the RAS in the spectrum allocation, we propose a spectrum sharing paradigm for the GSO SCS and the RAS with three potential RFI reduction methods. Depending on the radio astronomical observation (RAO) tasks of different observatories, the corresponding appropriate RFI reduction method combination can be chosen. Our analyses show that the proposed paradigm can guarantee most of the telescopes with the sample loss rate lower than 2% in both protected and unprotected RAS bands, while the SCS can obtain up to 13.88% extra average downlink throughput.