IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0759549
(2007-06-07)
|
등록번호 |
US-8169955
(2012-05-01)
|
발명자
/ 주소 |
- Ansari, Arif
- Bories, Jean-Michel
- Cohen, Michel
- Corbel, Erwan
|
출원인 / 주소 |
|
대리인 / 주소 |
Myers Bigel Sibley & Sajovec
|
인용정보 |
피인용 횟수 :
3 인용 특허 :
150 |
초록
▼
Methods for controlling orthogonal frequency division multiple access (OFDMA) communications over satellite links. The methods include estimating a differential delay in a satellite spotbeam between a mean propagation delay in the spotbeam and a propagation delay between a user terminal in the spotb
Methods for controlling orthogonal frequency division multiple access (OFDMA) communications over satellite links. The methods include estimating a differential delay in a satellite spotbeam between a mean propagation delay in the spotbeam and a propagation delay between a user terminal in the spotbeam and a satellite, estimating an overlap between an OFDMA uplink frame and an OFDMA downlink frame as a result of the differential delay, and providing a guard band in the OFDMA uplink frame and/or the OFDMA downlink frame to reduce an overlap between remaining portions of the OFDMA uplink frame and the OFDMA downlink frame other than the guard band. Corresponding systems and devices are also disclosed.
대표청구항
▼
1. A method for controlling orthogonal frequency division multiple access (OFDMA) communications over satellite links, comprising: estimating a differential delay in a satellite spotbeam between a mean propagation delay in the spotbeam and a propagation delay between a user terminal in the spotbeam
1. A method for controlling orthogonal frequency division multiple access (OFDMA) communications over satellite links, comprising: estimating a differential delay in a satellite spotbeam between a mean propagation delay in the spotbeam and a propagation delay between a user terminal in the spotbeam and a satellite;estimating an overlap between an OFDMA uplink frame and an OFDMA downlink frame as a result of the differential delay; andproviding a guard band in the OFDMA uplink frame and/or the OFDMA downlink frame to reduce an overlap between remaining portions of the OFDMA uplink frame and the OFDMA downlink frame other than the guard band. 2. The method of claim 1, wherein the guard band has a duration that is at least twice the differential delay. 3. The method of claim 1, wherein the propagation delay between the user terminal and the satellite is less than the mean propagation delay, and wherein providing the guard band comprises providing the guard band at an end portion of the OFDMA uplink frame and/or at a beginning portion of the OFDMA downlink frame. 4. The method of claim 3, wherein providing the guard band comprises providing a first guard band at the end portion of the OFDMA uplink frame and providing a second guard band at the beginning portion of the OFDMA downlink frame. 5. The method of claim 4, wherein the first guard band and the second guard band have a total duration that is at least twice the differential delay. 6. The method of claim 1, wherein the propagation delay between the user terminal and the satellite is greater than the mean propagation delay, and wherein providing the guard band comprises providing the guard band at a beginning portion of the OFDMA uplink frame and/or at an end portion of the OFDMA downlink frame. 7. The method of claim 6, wherein providing the guard band comprises providing a first guard band at the beginning portion of the OFDMA uplink frame and providing a second guard band at the end portion of the OFDMA downlink frame. 8. The method of claim 7, wherein the first guard band and the second guard band have a total duration that is at least twice the differential delay. 9. The method of claim 1, wherein the OFDMA uplink frame comprises a plurality of subregions, and wherein providing a guard band in the OFDMA uplink frame comprises designating at least one of the plurality of subregions as unused. 10. The method of claim 9, wherein a subregion comprises a plurality of symbols in an OFDMA subchannel, and wherein the subregion includes at least one pilot symbol. 11. The method of claim 10, wherein the subregion includes at least two data symbols. 12. The method of claim 9, wherein the propagation delay between the user terminal and the satellite is less than the mean propagation delay, and wherein providing the guard band comprises designating at least one subregion at an end portion of the OFDMA uplink frame and/or at a beginning portion of the OFDMA downlink frame as unused. 13. The method of claim 12, wherein providing the guard band comprises designating at least one subregion at the end portion of the OFDMA uplink frame and at least one subregion at the beginning portion of the OFDMA downlink frame as unused. 14. The method of claim 9, wherein the propagation delay between the user terminal and the satellite is greater than the mean propagation delay, and wherein providing the guard band comprises designating at least one subregion at a beginning portion of the OFDMA uplink frame and/or at an end portion of the OFDMA downlink frame as unused. 15. The method of claim 14, wherein providing the guard band comprises designating at least one subregion at the beginning portion of the OFDMA uplink frame and at least one subregion at the end portion of the OFDMA downlink frame as unused. 16. The method of claim 1, wherein estimating the differential delay comprises defining a ranging window that has a duration of at least a duration of an OFDMA uplink frame plus twice a maximum expected differential delay for OFDMA uplink frames, and receiving a ranging codeword within the ranging window. 17. The method of claim 16, wherein the ranging codeword comprises a plurality of ranging symbols. 18. The method of claim 17, wherein the ranging codeword is spread over a plurality of OFDMA subchannels. 19. The method of claim 16, further comprising transmitting a ranging response in response to the ranging code word, wherein the ranging response designates a timing delay for use in synchronizing uplink transmissions. 20. The method of claim 19, wherein the ranging response designates guardband(s) to be used on uplink and/or OFDMA downlink frames and/or designates at least one subregion of an OFDMA uplink frame and/or an OFDMA downlink frame as unused. 21. A system for controlling orthogonal frequency division multiple access (OFDMA) communications over satellite links, comprising: a satellite;a user terminal configured to communicate with the satellite via a satellite frequency over one of the satellite links,a scheduler configured to estimate a differential delay in a satellite spotbeam between a mean propagation delay in the spotbeam and a propagation delay between the user terminal in the spotbeam and the satellite, configured to estimate an overlap between an OFDMA uplink frame and an OFDMA downlink frame as a result of the differential delay, and configured to provide a guard band in the OFDMA uplink frame and/or the OFDMA downlink frame to reduce an overlap at the user terminal between remaining portions of the OFDMA uplink frame and the OFDMA downlink frame other than the guard band. 22. The system of claim 21, wherein the guard band has a duration that is at least twice the differential delay. 23. The system of claim 21, wherein the propagation delay between the user terminal and the satellite is less than the mean propagation delay, and wherein the scheduler is configured to provide the guard band at an end portion of the OFDMA uplink frame and/or at a beginning portion of the OFDMA downlink frame. 24. The system of claim 23, wherein the scheduler is configured to provide a first guard band at the end portion of the OFDMA uplink frame and a second guard band at the beginning portion of the OFDMA downlink frame. 25. The system of claim 24, wherein the first guard band and the second guard band have a total duration that is at least twice the differential delay. 26. The system of claim 21, wherein the propagation delay between the user terminal and the satellite is greater than the mean propagation delay, and wherein the scheduler is configured to provide the guard band at a beginning portion of the OFDMA uplink frame and/or at an end portion of the OFDMA downlink frame. 27. The system of claim 26, wherein the scheduler is configured to provide a first guard band at the beginning portion of the OFDMA uplink frame and a second guard band at the end portion of the OFDMA downlink frame. 28. The system of claim 27, wherein the first guard band and the second guard band have a total duration that is at least twice the differential delay. 29. The system of claim 21, wherein the OFDMA uplink frame comprises a plurality of subregions, and wherein the scheduler is configured to designate at least one of the plurality of subregions as unused. 30. The system of claim 29, wherein a subregion comprises a plurality of symbols in an OFDMA subchannel, and wherein the subregion includes at least one pilot symbol. 31. The system of claim 30, wherein the subregion includes at least two data symbols. 32. The system of claim 29, wherein the propagation delay between the user terminal and the satellite is less than the mean propagation delay, and wherein the scheduler is configured to designate at least one subregion at an end portion of the OFDMA uplink frame and/or at a beginning portion of the OFDMA downlink frame as unused. 33. The system of claim 32, wherein the scheduler is configured to designate at least one subregion at the end portion of the OFDMA uplink frame and at least one subregion at the beginning portion of the OFDMA downlink frame as unused. 34. The system of claim 29, wherein the propagation delay between the user terminal and the satellite is greater than the mean propagation delay, and wherein the scheduler is configured to designate at least one subregion at a beginning portion of the OFDMA uplink frame and/or at an end portion of the OFDMA downlink frame as unused. 35. The system of claim 34, wherein the scheduler is configured to designate at least one subregion at the beginning portion of the OFDMA uplink frame and at least one subregion at the end portion of the OFDMA downlink frame as unused. 36. The system of claim 21, wherein the scheduler is configured to estimate the differential delay by defining a ranging window that has a duration of at least a duration of an OFDMA uplink frame plus twice a maximum expected differential delay for OFDMA uplink frames, and receiving a ranging codeword within the ranging window. 37. The system of claim 36, wherein the ranging codeword comprises a plurality of ranging symbols. 38. The system of claim 37, wherein the ranging codeword is spread over a plurality of OFDMA subchannels. 39. The system of claim 36, wherein the scheduler is configured to cause the satellite to transmit a ranging response in response to the ranging code word, wherein the ranging response designates a timing delay for use in synchronizing uplink transmissions. 40. The system of claim 39, wherein the ranging response designates guardband(s) to be used on uplink and/or OFDMA downlink frames and/or designates at least one subregion of an OFDMA uplink frame and/or an OFDMA downlink frame as unused. 41. A scheduler for controlling orthogonal frequency division multiple access (OFDMA) communications over satellite links between a satellite and a user terminal, wherein the scheduler is configured to estimate a differential delay in a satellite spotbeam between a mean propagation delay in the spotbeam and a propagation delay between the user terminal in the spotbeam and the satellite, configured to estimate an overlap between an OFDMA uplink frame and an OFDMA downlink frame as a result of the differential delay, and configured to provide a guard band in the OFDMA uplink frame and/or the OFDMA downlink frame to reduce an overlap at the user terminal between remaining portions of the OFDMA uplink frame and the OFDMA downlink frame other than the guard band. 42. The scheduler of claim 41, wherein the guard band has a duration that is at least twice the differential delay. 43. The scheduler of claim 41, wherein the propagation delay between the user terminal and the satellite is less than the mean propagation delay, and wherein the scheduler is configured to provide the guard band at an end portion of the OFDMA uplink frame and/or at a beginning portion of the OFDMA downlink frame. 44. The scheduler of claim 43, wherein the scheduler is configured to provide a first guard band at the end portion of the OFDMA uplink frame and a second guard band at the beginning portion of the OFDMA downlink frame. 45. The scheduler of claim 44, wherein the first guard band and the second guard band have a total duration that is at least twice the differential delay. 46. The scheduler of claim 41, wherein the propagation delay between the user terminal and the satellite is greater than the mean propagation delay, and wherein the scheduler is configured to provide the guard band at a beginning portion of the OFDMA uplink frame and/or at an end portion of the OFDMA downlink frame. 47. The scheduler of claim 46, wherein the scheduler is configured to provide a first guard band at the beginning portion of the OFDMA uplink frame and a second guard band at the end portion of the OFDMA downlink frame. 48. The scheduler of claim 47, wherein the first guard band and the second guard band have a total duration that is at least twice the differential delay. 49. The scheduler of claim 41, wherein the OFDMA uplink frame comprises a plurality of subregions, and wherein the scheduler is configured to designate at least one of the plurality of subregions as unused. 50. The scheduler of claim 49, wherein a subregion comprises a plurality of symbols in an OFDMA subchannel, and wherein the subregion includes at least one pilot symbol. 51. The scheduler of claim 50, wherein the subregion includes at least two data symbols. 52. The scheduler of claim 49, wherein the propagation delay between the user terminal and the satellite is less than the mean propagation delay, and wherein the scheduler is configured to designate at least one subregion at an end portion of the OFDMA uplink frame and/or at a beginning portion of the OFDMA downlink frame as unused. 53. The scheduler of claim 52, wherein the scheduler is configured to designate at least one subregion at the end portion of the OFDMA uplink frame and at least one subregion at the beginning portion of the OFDMA downlink frame as unused. 54. The scheduler of claim 49, wherein the propagation delay between the user terminal and the satellite is greater than the mean propagation delay, and wherein the scheduler is configured to designate at least one subregion at a beginning portion of the OFDMA uplink frame and/or at an end portion of the OFDMA downlink frame as unused. 55. The scheduler of claim 54, wherein the scheduler is configured to designate at least one subregion at the beginning portion of the OFDMA uplink frame and at least one subregion at the end portion of the OFDMA downlink frame as unused. 56. The scheduler of claim 51, wherein the scheduler is configured to estimate the differential delay by defining a ranging window that has a duration of at least a duration of an OFDMA uplink frame plus twice a maximum expected differential delay for OFDMA uplink frames, and receiving a ranging codeword within the ranging window. 57. The scheduler of claim 56, wherein the ranging codeword comprises a plurality of ranging symbols. 58. The scheduler of claim 57, wherein the ranging codeword is spread over a plurality of OFDMA subchannels. 59. The scheduler of claim 56, wherein the scheduler is configured to cause the satellite to transmit a ranging response in response to the ranging code word, wherein the ranging response designates a timing delay for use in synchronizing uplink transmissions. 60. The scheduler of claim 59, wherein the ranging response designates guardband(s) to be used on uplink and/or OFDMA downlink frames and/or designates at least one subregion of an OFDMA uplink frame and/or an OFDMA downlink frame as unused. 61. A radioterminal configured to communicate with a satellite using orthogonal frequency division multiple access (OFDMA) communications, wherein the radioterminal is configured to receive a designation of a guardband to be used for an OFDMA uplink frame transmitted by the radioterminal to the satellite, and wherein the radioterminal is configured not to transmit OFDMA signals during the uplink guardband so as to reduce an overlap between the OFDMA uplink frame mad an OFDMA downlink frame; wherein the guard band has a duration that is at least twice a differential delay in a satellite spotbeam between a mean propagation delay in the spotbeam and a propagation delay between the radioterminal and the satellite. 62. The radioterminal of claim 61, wherein a propagation delay between the radioterminal and the satellite is less than the mean propagation delay, and wherein the guard band is provided at an end portion of the OFDMA uplink frame. 63. The radioterminal of claim 61, wherein the propagation delay between the radioterminal and the satellite is greater than the mean propagation delay, and wherein the guard band is provided at a beginning portion of the OFDMA uplink frame. 64. The radioterminal of claim 61, wherein the OFDMA uplink frame comprises a plurality of subregions, and wherein at least one of the plurality of subregions is unused by the radioterminal. 65. The radioterminal of claim 64, wherein a subregion comprises a plurality of symbols in an OFDMA subchannel, and wherein the subregion includes at least one pilot symbol. 66. The radioterminal of claim 65, wherein the subregion includes at least two data symbols. 67. The radioterminal of claim 64, wherein the propagation delay between the radioterminal and the satellite is less than the mean propagation delay, and wherein at least one subregion at an end portion of the OFDMA uplink frame is unused. 68. The radioterminal of claim 64, wherein the propagation delay between the radioterminal and the satellite is greater than the mean propagation delay, and wherein at least one subregion at a beginning portion of the OFDMA uplink frame is unused.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.