RU97100944A - RADIO COMMUNICATION SYSTEM USING GEOSTATIONARY AND NON-GEOSTATIONARY SATELLITES - Google Patents

Claims (14)

1. A satellite communication system comprising at least one geostationary satellite and at least one satellite orbiting in the middle Earth orbit, designed to provide radio communication with a plurality of remote subscriber terminal devices, in which at least one geostationary satellite provides radio communication with said remote subscriber devices during periods when individual subscriber terminal devices cannot access at least one of the aforementioned utnikov medium earth orbit.  2. A satellite communication system comprising a geostationary satellite providing radio communication with a plurality of remote subscriber terminals when the first satellite operates in the middle Earth orbit, said first satellite in the middle Earth orbit complements the radio communication service of said geostationary satellite after the first satellite in the middle Earth orbit .  3. The system according to claim 2, characterized in that the said first satellite in the middle Earth orbit is placed with the possibility of coverage of at least one region of maximum radio traffic during peak hours.  4. The system according to claim 2, characterized in that it further comprises a plurality of additional satellites in the middle Earth orbit, which begin to function after the first satellite in the middle Earth orbit begins to function, said geostationary satellite orienting its bandwidth to serving areas, determined on the basis of the possibility of radio exchange and satellite servicing in the middle Earth orbit.  5. The system according to claim 1, characterized in that after the geostationary satellite, an increasing number of satellites are launched sequentially in the middle Earth orbit, said geostationary satellite providing either autonomous subscriber services or servicing subscribers added at peak periods via at least one satellite in medium orbit and the maintenance of zones in the coverage provided by the said satellites in medium Earth orbit.  6. The system according to claim 5, characterized in that the service provided by the said geostationary satellite is determined on the basis of the number of satellites in the middle Earth orbit.  7. A method for providing radio communication with a large number of terminal devices, according to which a satellite is launched into a geostationary orbit, radio communication service is provided with said plurality of terminal devices using only said geostationary satellite before launching additional satellites; launch a plurality of satellites into a mid-Earth orbit and provide radio communication services using a geostationary satellite and at least one of the plurality of satellites in a mid-Earth orbit.  8. The method according to claim 7, characterized in that at the said second stage, radio communication is additionally provided using at least one of the aforementioned satellites in mid-Earth orbit in order to supplement said service of said geostationary satellite before launching a predetermined number of said satellites in the middle near-Earth orbit, followed by radio communications, using the aforementioned geostationary satellite to supplement the service of the said satellites in the middle ok Earth orbit.  9. A satellite communication system designed to service a number of ground-based terminal stations with varying levels of activity, comprising a geostationary satellite located with the ability to be visible from the service site for 24 hours a day; at least one satellite in quasi-stationary orbit having a terrestrial relay path clocked to cover said service area at times of the expected peak activity of said terrestrial-based terminal stations.  10. The communication system according to claim 9, characterized in that it further comprises a central ground station associated with said geostationary satellite and said satellite in quasi-stationary orbit, when it is visible for signal transmission between the pay phone and said terminal device at least one of the mentioned satellites.  11. The communication system of claim 10, characterized in that it further comprises control means for controlling focused antenna beams of said geostationary satellite at locations currently not adequately served by said at least one satellite in quasi-stationary orbit.  12. The communication system according to claim 11, characterized in that the said control means is a beamforming computer.  13. The communication system of claim 12, wherein said beam forming computer is located at said central station.  14. A communication system designed to provide telephone communications between mobile wireless terminals and a public switched telephone system through satellites in orbit, comprising at least one geostationary relay satellite containing an electronically controlled antenna; at least one quasi-stationary orbit relay satellite; a network of tracking stations designed to track the instantaneous locations of the aforementioned satellite and transmit information to the communication stations of the gateway; at least one interconnect communication station connected to a public switched telephone exchange and together with said at least one geostationary relay satellite, said interconnection station comprising control means for controlling areas irradiated by said beams of a controlled antenna; routing means for routing signals between said portable terminal devices and a public switched telephone exchange through a satellite and an antenna beam controlled based on information from said tracking station network.