IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
UP-0463120
(2006-08-08)
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등록번호 |
US-7831202
(2010-11-25)
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발명자
/ 주소 |
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출원인 / 주소 |
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대리인 / 주소 |
Myers Bigel Sibley & Sajovec, P.A.
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인용정보 |
피인용 횟수 :
29 인용 특허 :
146 |
초록
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A satellite communications system includes a plurality of feeder link antennas, a primary satellite, and an auxiliary satellite. The feeder link antennas are substantially co-located relative to one another. The primary satellite is configured to receive information over a plurality of return servic
A satellite communications system includes a plurality of feeder link antennas, a primary satellite, and an auxiliary satellite. The feeder link antennas are substantially co-located relative to one another. The primary satellite is configured to receive information over a plurality of return service links from radioterminals, to communicate a first portion of the information over at least one return feeder link directly to a first one of the feeder link antennas, and to communicate a second portion of the information over at least one inter-satellite link. The auxiliary satellite is spaced apart from the primary satellite, and configured to receive the second portion of the information from the primary satellite via the at least one inter-satellite link, and to communicate the second portion of the information across at least one return feeder link to a second one of the feeder link antennas.
대표청구항
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What is claimed is: 1. A satellite communications system comprising: a plurality of feeder link antennas that are substantially co-located therebetween and are connected to a same gateway processor; a primary satellite that is configured to receive information from radioterminals through a pluralit
What is claimed is: 1. A satellite communications system comprising: a plurality of feeder link antennas that are substantially co-located therebetween and are connected to a same gateway processor; a primary satellite that is configured to receive information from radioterminals through a plurality of return service links, to communicate a first portion of the information over at least one return feeder link to a first one of the feeder link antennas, and to communicate another second portion of the information over at least one inter-satellite link; and an auxiliary satellite that is spaced apart from the primary satellite, and configured to receive the second portion of the information from the primary satellite via the at least one inter-satellite link, and to communicate the second portion of the information over at least one return feeder link to a second one of the feeder link antennas, wherein the primary satellite is further configured to distribute an aggregate of signal spectrum associated with the return service links across a combination of signal spectrum of the at least one return feeder link to the first one of the feeder link antennas and, via the inter-satellite link, signal spectrum of the at least one return feeder link from the auxiliary satellite to the second one of the feeder link antennas. 2. The satellite communications system of claim 1, wherein the primary satellite uses a first set of frequencies to communicate with the first one of the feeder link antennas and the auxiliary satellite uses a second set of frequencies to communicate with the second one of the feeder link antennas, wherein the first set of frequencies and the second set of frequencies include at least one common frequency. 3. The satellite communications system of claim 1, wherein the primary satellite and the auxiliary satellite are spaced apart therebetween to provide an antenna discrimination between the primary satellite and the second one of the feeder link antennas, and to provide an antenna discrimination between the auxiliary satellite and the first one of the feeder link antennas. 4. The satellite communications system of claim 3, wherein the primary satellite and the auxiliary satellite are located in respective substantially geostationary orbits relative to Earth, and have a separation angle therebetween of about 2° or more. 5. The satellite communications system of claim 1, wherein the auxiliary satellite is devoid of any configuration that allows the auxiliary satellite to communicate directly with radioterminals. 6. The satellite communications system of claim 1, wherein: the first one of the feeder link antennas is configured to provide a substantially higher gain in a direction associated with the primary satellite and a substantially lower gain in a direction associated with the auxiliary satellite; and the second one of the feeder link antennas is configured to provide a substantially higher gain in a direction associated with the auxiliary satellite and a substantially lower gain in a direction associated with the primary satellite. 7. The satellite communications system of claim 6, further comprising a plurality of auxiliary satellites configured to receive portions of the information from the primary satellite via a plurality of inter-satellite links, and to communicate the portions of the information over a plurality of return feeder links to a plurality of feeder link antennas, wherein each feeder link antenna of the plurality of feeder link antennas, is configured to provide a substantially higher gain in a direction associated with a respective auxiliary satellite and a substantially lower gain in a direction associated with an auxiliary satellite other than the respective auxiliary satellite. 8. The satellite communications system of claim 7, wherein two feeder link antennas of the plurality of feeder link antennas are separated therebetween by about 3000 meters or less. 9. The satellite communications system of claim 8, wherein two feeder link antennas of the plurality of feeder link antennas are separated therebetween by about 300 meters or less. 10. The satellite communications system of claim 9, wherein two feeder link antennas of the plurality of feeder link antennas are spaced therebetween by about 30 meters or less. 11. The satellite communications system of claim 1, further comprising a plurality of auxiliary satellites, wherein the primary satellite is further configured to distribute the aggregate of signal spectrum associated with the return service links across a combination of signal spectrum of the at least one return feeder link to the first one of the feeder link antennas and signal spectrum of a plurality of return feeder links associated with the auxiliary satellites. 12. The satellite communications system of claim 11, wherein the primary satellite is further configured to control a bandwidth utilization of the return feeder link of the primary satellite and to control a bandwidth utilization of the plurality of return feeder links associated with the auxiliary satellites. 13. The satellite communications system of claim 1, wherein the auxiliary satellite is further configured to communicate the second portion of the information received from the primary satellite substantially unchanged to the second one of the feeder link antennas. 14. The satellite communications system of claim 1, wherein: the auxiliary satellite is further configured to receive forward link information over at least one forward feeder link from the second one of the feeder link antennas, and to communicate the forward link information to the primary satellite over at least one inter-satellite link; and the primary satellite is further configured to communicate the forward link information to the radioterminals over a plurality of forward service links. 15. The satellite communications system of claim 1, wherein the primary satellite is further configured to receive first forward link information from the first one of the feeder link antennas and receive second forward link information from the second one of the feeder link antennas and to route the first and second forward link information through selected ones of a plurality forward service links to the radioterminals. 16. The satellite communications system of claim 1, further comprising a gateway processor that is configured to receive return feeder link signals from at least the first one of the feeder link antennas and the second one of the feeder link antennas, and to process the received return feeder link signals to reduce interference in at least one of the return feeder link signals. 17. The satellite communications system of claim 16, wherein the gateway processor is further configured to time align at least some of the return feeder link signals relative to one another, and to reduce interference in at least one of the return feeder link signals in response to the time aligned return feeder link signals. 18. The satellite communications system of claim 17, wherein the gateway processor is further configured to time align a return feeder link signal received from the first one of the feeder link antennas relative to a return feeder link signal received from the second one of the feeder link antennas, and to generate an interference correction signal from the time aligned return feeder link signals that is indicative of interference caused by at least one return feeder link from the primary satellite to at least one return feeder link received by the second one of the feeder link antennas. 19. The satellite communications system of claim 18, wherein the gateway processor is further configured to reduce interference in at least one return feeder link signal received from the second one of the feeder link antennas in response to the interference correction signal. 20. The satellite communications system of claim 17, wherein the gateway processor is further configured to time align a return feeder link signal received from the first one of the feeder link antennas relative to a return feeder link signal received from the second one of the feeder link antennas, and to generate an interference correction signal from the time aligned return feeder link signals that is indicative of interference caused by at least one return feeder link from the auxiliary satellite to at least one return feeder link received by the first one of the feeder link antennas. 21. A method of communicating in a satellite communications system, the method comprising: receiving information at a primary satellite from radioterminals through a plurality of return service links; communicating a first portion of the information from the primary satellite over at least one return feeder link to a first one of a plurality of feeder link antennas that are connected to a same gateway processor; communicating another second portion of the information from the primary satellite over at least one inter-satellite link to an auxiliary satellite that is spaced apart from the primary satellite; communicating the second portion of the information from the auxiliary satellite over at least one return feeder link to a second one of the feeder link antennas that is substantially co-located with the first one of the feeder link antennas, wherein communication of the first and second portions of the information is carried out to distribute an aggregate of signal spectrum associated with the return service links across a combination of signal spectrum of the at least one return feeder link to the first one of the feeder link antennas and, via the inter-satellite link, signal spectrum of the at least one return feeder link from the auxiliary satellite to the second one of the feeder link antennas. 22. The method of claim 21, further comprising using first feeder link frequencies to communicate information between the primary satellite and the first one of the feeder link antennas and second feeder link frequencies to communicate information between the auxiliary satellite and the second one of the feeder link antennas, wherein the first and second feeder link frequencies comprise at least one common frequency. 23. The method of claim 21, further comprising maintaining a distance between the primary satellite and the auxiliary satellite to provide a discrimination between the primary satellite and the second one of the feeder link antennas, and to provide a discrimination between the auxiliary satellite and the first one of the feeder link antennas. 24. The method of claim 23, further comprising maintaining the primary satellite and the auxiliary satellite in respective substantially geostationary orbits relative to Earth with about a 2° or more separation angle therebetween. 25. The method of claim 21, wherein communicating a second portion of the information from the primary satellite over at least one inter-satellite link to an auxiliary satellite comprises communicating the second portion of the information from the primary satellite over at least one inter-satellite link to an auxiliary satellite that is devoid of any configuration that allows the auxiliary satellite to communicate directly with radioterminals. 26. The method of claim 21, further comprising: configuring the first one of the feeder link antennas to provide a substantially higher gain in a direction associated with the primary satellite and a substantially lower gain in a direction associated with the auxiliary satellite; and configuring the second one of the feeder link antennas to provide a substantially higher gain in a direction associated with the auxiliary satellite and a substantially lower gain in a direction associated with the primary satellite. 27. The method of claim 26, further comprising: communicating portions of the information received at the primary satellite from radioterminals over a plurality of the inter-satellite links to a plurality of auxiliary satellites; communicating the portions of the information over a plurality of return feeder links from the plurality of auxiliary satellites to a respective plurality of feeder link antennas that are substantially co-located therebetween; and configuring each feeder link antenna of the plurality of feeder link antennas to provide a substantially higher gain in a direction associated with a respective auxiliary satellite and to provide a substantially lower gain in a direction associated with an auxiliary satellite other than the respective auxiliary satellite. 28. The method of claim 21, further comprising distributing an aggregate information over the at least one return feeder link of the primary satellite and over a plurality of return feeder links associated with a plurality of auxiliary satellites. 29. The method of claim 28, further comprising controlling a bandwidth utilization of the at least one return feeder link of the primary satellite and controlling a bandwidth utilization of the plurality of return feeder links of the auxiliary satellites. 30. The method of claim 21, wherein communicating the second portion of the information from the auxiliary satellite over at least one return feeder link to a second one of the feeder link antennas that is substantially co-located with the first one of the feeder link antennas comprises: communicating the second portion of the information received by the auxiliary satellite from the primary satellite substantially unchanged to the second one of the feeder link antennas. 31. The method of claim 21, further comprising: receiving forward link information at the auxiliary satellite through at least one forward feeder link from the second one of the feeder link antennas; communicating the forward link information over at least one inter-satellite link to the primary satellite; and communicating the forward link information from the primary satellite to the radioterminals over a plurality of forward service links. 32. The method of claim 21, further comprising: receiving at the primary satellite first forward link information from the first one of the feeder link antennas; receiving at the primary satellite second forward link information from the second one of the feeder link antennas; and routing the first and second forward link information from the primary satellite through selected ones of a plurality forward service links to the radioterminals. 33. The method of claim 21, further comprising: receiving return feeder link signals at a gateway processor from at least the first one of the feeder link antennas and the second one of the feeder link antennas; and processing the received return feeder link signals at the gateway processor to reduce interference in at least one of the return feeder link signals. 34. The method of claim 33, further comprising: time aligning at least some of the return feeder link signals relative to one another; and reducing interference in at least one of the return feeder link signals in response to the time aligned return feeder link signals. 35. The method of claim 34, wherein time aligning at least some of the return feeder link signals relative to one another comprises: time aligning at least one return feeder link signal received from the first one of the feeder link antennas relative to at least one return feeder link signal received from the second one of the feeder link antennas; and generating an interference correction signal from the time aligned return feeder link signals that is indicative of interference caused by the at least one return feeder link from the primary satellite to the at least one return feeder link received by the second one of the feeder link antennas. 36. The method of claim 35, wherein processing the received return feeder link signals at the gateway processor to reduce interference in at least one of the return feeder link signals comprises: reducing interference in the at least one received return feeder link signal from the second one of the feeder link antennas in response to the interference correction signal. 37. The method of claim 34, wherein time aligning at least some of the received return feeder link signals relative to one another comprises: time aligning the at least one return feeder link signal provided by the first one of the feeder link antennas relative to the at least one return feeder link signal provided by the second one of the feeder link antennas; and generating an interference correction signal from the time aligned return feeder link signals that is indicative of interference caused by the at least one return feeder link from the auxiliary satellite to the at least one return feeder link received by the first one of the feeder link antennas. 38. A primary satellite comprising: a return service link receiver that is configured to receive information over a plurality of return service links from radioterminals; an information spreader that is configured to distribute the information into at least a first portion and another second portion; a feeder link transmitter that is configured to transmit the first portion of the information over at least one return feeder link directly to a first one of a plurality of feeder link antennas that are connected to a same gateway processor; and an inter-satellite link transmitter that is configured to transmit the second portion of the information over at least one inter-satellite link to an auxiliary satellite for transmission over at least one return feeder link to a second one of the feeder link antennas that is substantially co-located relative to the first one of the feeder link antennas and that is connected to the same gateway processor as the first one of the feeder link antennas, wherein the information spreader is further configured to distribute an aggregate of signal spectrum associated with the return service links across a combination of signal spectrum of the at least one return feeder link to the first one of the feeder link antennas and, via the inter-satellite link, signal spectrum of the at least one return feeder link from the auxiliary satellite to the second one of the feeder link antennas. 39. The primary satellite of claim 38, further comprising: a feeder link receiver that is configured to receive forward link information directly from the first one of the feeder link antennas over at least one forward feeder link; an inter-satellite link receiver that is configured to receive forward link information over the at least one inter-satellite link from the second one of the feeder link antennas indirectly via the auxiliary satellite; and a forward service link transmitter that is configured to transmit an aggregate of the forward link information received by the feeder link receiver and the inter-satellite link receiver over a plurality of forward service links to the radioterminals. 40. The primary satellite of claim 39, further comprising an information combiner configured to aggregate a signal associated with at least one forward feeder link from the first one of the feeder link antennas with a signal associated with at least one inter-satellite link from the auxiliary satellite. 41. The primary satellite of claim 38, wherein the feeder link transmitter is configured to transmit the information to the first one of the feeder link antennas using at least some of the same frequencies as are used by the auxiliary satellite to transmit to the second one of the feeder link antennas. 42. An auxiliary satellite comprising: an inter-satellite link receiver that is configured to receive information over at least one inter-satellite link from a primary satellite that received the information from radioterminals through a plurality of return service links; and a feeder link transmitter that is configured to transmit the information over at least one return feeder link directly to a first one of a plurality of feeder link antennas that is substantially co-located relative to a second one of the plurality of feeder link antennas that the primary satellite is transmitting to directly over at least one return feeder link to distribute an aggregate of signal spectrum associated with the return service links across a combination of signal spectrum of the at least one return feeder link to the first one of the feeder link antennas and signal spectrum of the at least one return feeder link from the primary satellite to the second one of the feeder link antennas, wherein the first and second feeder link antennas are connected to a same gateway processor. 43. The auxiliary satellite of claim 42, wherein the feeder link transmitter is configured to transmit the information to the first one of the feeder link antennas using at least some of the same frequencies as are used by the primary satellite to transmit to the second one of the feeder link antennas. 44. The auxiliary satellite of claim 42, further comprising: a feeder link receiver that is configured to receive forward link information directly from the first one of the feeder link antennas over at least one forward feeder link; and an inter-satellite link transmitter that is configured to transmit the forward link information over at least one inter-satellite link to the primary satellite for transmission over a plurality of forward service links to the plurality of radioterminals. 45. Satellite communications equipment comprising: a plurality of feeder link antennas that are substantially co-located therebetween, are connected to a same gateway processor, and are configured to transmit and/or receive information over feeder links to a primary satellite and to at least one auxiliary satellite, wherein a first one of the feeder link antennas is configured to provide a substantially higher gain in a direction associated with the primary satellite and a substantially lower gain in a direction associated with the at least one auxiliary satellite, and a second one of the feeder link antennas is configured to provide a substantially higher gain in a direction associated with one of the at least one auxiliary satellite and a substantially lower gain in a direction associated with the primary satellite; and a gateway processor that is configured to distribute information that is directed to a plurality of radioterminals simultaneously over at least one forward feeder link to the primary satellite and over at least one forward feeder link to the at least one auxiliary satellite for subsequent aggregation of the information at the primary satellite and retransmission of the information by the primary satellite to the radioterminals over a plurality of forward service links to distribute an aggregate of signal spectrum of the plurality of forward service links across a combination of the signal spectrum of the at least one forward feeder link to the primary satellite and the at least one forward feeder link to the at least one auxiliary satellite. 46. The satellite communications equipment of claim 45, wherein the first one of the feeder link antennas and second one of the feeder link antennas are each configured to use at least some common frequencies to communicate with the primary satellite and the at least one auxiliary satellite. 47. The satellite communications equipment of claim 45, wherein the first one of the feeder link antennas and second one of the feeder link antennas are configured to provide maximum gain in respective directions associated with the primary satellite and the at least one auxiliary satellite. 48. The satellite communications equipment of claim 45, wherein two feeder link antennas of the plurality of feeder link antennas are separated therebetween by about 3000 meters or less. 49. The satellite communications equipment of claim 48, wherein two feeder link antennas of the plurality of feeder link antennas are separated therebetween by about 300 meters or less. 50. The satellite communications equipment of claim 49, wherein two feeder link antennas of the plurality of feeder link antennas are separated therebetween by about 30 meters or less. 51. The satellite communications equipment of claim 45, wherein the gateway processor is further configured to receive return feeder link signals from the first one of the feeder link antennas and the second one of the feeder link antennas, and to process the received return feeder link signals to reduce interference in at least one of the return feeder link signals. 52. The satellite communications equipment of claim 51, wherein the gateway processor is further configured to time align at least some of the received return feeder link signals relative to one another prior to reducing interference in at least one of the return feeder link signals. 53. The satellite communications equipment of claim 52, wherein the gateway processor is further configured to generate an interference correction signal and to reduce interference in at least one return feeder link signal in response to the interference correction signal. 54. The auxiliary satellite of claim 52, wherein the auxiliary satellite is devoid of any configuration that allows the auxiliary satellite to communicate directly with radioterminals.
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