IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0325696
(2006-01-04)
|
등록번호 |
US-RE43137
(2012-01-24)
|
발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
Myers Bigel Sibley & Sajovec, P.A.
|
인용정보 |
피인용 횟수 :
2 인용 특허 :
142 |
초록
▼
A satellite radiotelephone system includes a space-based component, a plurality of ancillary terrestrial components, and a plurality of radiotelephones. The space-based component is configured to provide wireless radiotelephone communications using satellite radiotelephone frequencies. The plurality
A satellite radiotelephone system includes a space-based component, a plurality of ancillary terrestrial components, and a plurality of radiotelephones. The space-based component is configured to provide wireless radiotelephone communications using satellite radiotelephone frequencies. The plurality of ancillary terrestrial components include a plurality of ancillary terrestrial component antennas configured to provide wireless radiotelephone communications using at least one of the satellite radiotelephone frequencies in a radiation pattern that increases radiation below the horizon compared to above the horizon. The plurality of radiotelephones are configured to communicate with the space-based component and with the plurality of ancillary terrestrial components. Each radiotelephone also includes a GPS signal processor and a GPS mode filter that is configured to suppress energy at (1575.42−Δ) MHz, where 0Δ≦16.42 MHz. Related radiotelephones and methods are also discussed.
대표청구항
▼
1. A satellite radiotelephone system comprising: a space-based component that is configured to provide wireless radiotelephone communications using satellite radiotelephone frequencies;a plurality of ancillary terrestrial components including a plurality of ancillary terrestrial component antennas t
1. A satellite radiotelephone system comprising: a space-based component that is configured to provide wireless radiotelephone communications using satellite radiotelephone frequencies;a plurality of ancillary terrestrial components including a plurality of ancillary terrestrial component antennas that are configured to provide wireless radiotelephone communications using at least one of the satellite radiotelephone frequencies in a radiation pattern that increases radiation below the horizon compared to above the horizon; anda plurality of radiotelephones that are configured to communicate with the space-based component and with the plurality of ancillary terrestrial components, the radiotelephones also including a GPS signal receiver and a GPS mode filter that is configured to suppress energy at and/or below (1575.42−Δ) MHz, where 0<Δ≦16.42 MHz. 2. The satellite radiotelephone system according to claim 1, wherein the GPS mode filter is configured to suppress at least 10 dB of energy at and/or below (1575.42−Δ) MHz. 3. The satellite radiotelephone system according to claim 2, wherein the GPS mode filter is configured to suppress at least 10 dB of energy at frequencies less than (1575.42−Δ) MHz. 4. The satellite radiotelephone system according to claim 1, wherein the GPS mode filter is configured to suppress at least 10 dB of energy at and below (1575.42−Δ) MHz. 5. The satellite radiotelephone system according to claim 1, wherein the radiotelephones are further configured to suppress processing of GPS signals when actively communicating with the space-based component and/or one of the ancillary terrestrial components. 6. The satellite radiotelephone system according to claim 5, wherein the GPS mode filter is coupled between an antenna and a low noise amplifier used in reception of GPS signals. 7. The satellite radiotelephone system according to claim 1, wherein the satellite radiotelephone frequencies comprise a satellite downlink frequency band and a satellite uplink frequency band and wherein GPS signals are transmitted from GPS satellites over a GPS frequency band between the satellite downlink and uplink frequency bands. 8. The satellite radiotelephone system according to claim 7, wherein the satellite downlink frequency band comprises frequencies between 1525 MHz and 1559 MHz, and wherein the satellite uplink frequency band comprises frequencies between 1626.5 MHz and 1660.5 MHz. 9. The satellite radiotelephone system according to claim 7, wherein the GPS frequency band comprises frequencies between 1559 MHz and 1605 MHz. 10. The satellite radiotelephone system according to claim 1, wherein Δ is greater than at least 1 MHz. 11. The satellite radiotelephone system according to claim 1, wherein the wireless radiotelephone communications are not subjected to the GPS mode filter. 12. The satellite radiotelephone system according to claim 1, wherein the GPS mode filter comprises a high pass filter. 13. The satellite radiotelephone system according to claim 1, wherein the radiotelephones are further configured to receive incoming call pages during GPS mode operations. 14. A radiotelephone comprising: a radio front end that is configured to provide wireless radiotelephone communications using radiotelephone frequencies, and that is configured to receive global positioning satellite (GPS) signals from a plurality of global positioning satellites;a signal processor that is configured to determine a measure of location of the radiotelephone using GPS signals received at the radio front end when providing GPS mode operations and that is configured to process communications that are received at and/or transmitted from the radio front end when providing wireless radiotelephone communications; anda GPS mode filter that is configured to filter GPS signals received at the radio front end before being provided to the signal processor, wherein the GPS mode filter is configured to suppress energy at and/orand below (1575.42−Δ) MHz, where 0<Δ≦16.42 MHz. 15. The radiotelephone according to claim 14, wherein the radio front end is configured to provide radiotelephone communications with a space-based component using satellite radiotelephone frequencies and to provide wireless radiotelephone communications with a plurality of ancillary terrestrial components using at least one of the satellite radiotelephone frequencies. 16. The radiotelephone according to claim 14, wherein the wireless radiotelephone communications are not subjected to the GPS mode filter. 17. The radiotelephone according to claim 14, wherein the GPS mode filter is coupled between an antenna and a low noise amplifier used in reception of GPS signals. 18. The radiotelephone according to claim 14, wherein the GPS mode filter is configured to suppress at least 10 dB of energy at (1575.42−Δ) MHz. 19. The radiotelephone according to claim 18, wherein the GPS mode filter is configured to suppress at least 10 dB of energy at frequencies less than (1575.42−Δ) MHz. 20. The radiotelephone according to claim 1415, wherein processing of GPS signals at the signal processor is suppressed when actively providing radiotelephone communications with the space-based component and/or one of the ancillary terrestrial components. 21. The radiotelephone according to claim 1415, wherein the satellite radiotelephone frequencies comprise a satellite downlink frequency band and a satellite uplink frequency band and wherein GPS signals are transmitted from GPS satellites over a GPS frequency band between the satellite downlink and uplink frequency bands. 22. The radiotelephone according to claim 21, wherein the satellite downlink frequency band comprises frequencies between 1525 MHz and 1559 MHz, and wherein the satellite uplink frequency band comprises frequencies between 1626.5 MHz and 1660.5 MHz. 23. The radiotelephone according to claim 21, wherein the GPS frequency band comprises frequencies between 1559 MHz and 1605 MHz. 24. The radiotelephone according to claim 14, wherein Δ is greater than at least 1 MHz. 25. The radiotelephone according to claim 14, wherein the GPS mode filter comprises a high pass filter. 26. The radiotelephone according to claim 14, wherein the radio front end is further configured to receive incoming call pages during GPS mode operations and wherein the signal processor is further configured to process incoming call pages during GPS operations. 27. A method of providing radiotelephone communications at a radiotelephone comprising a radio front end that is configured to provide wireless radiotelephone communications using radiotelephone frequencies, and that is configured to receive global positioning satellite (GPS) signals from a plurality of Global positioning satellites, the method comprising: during GPS mode operations, suppressing energy at and/orand below (1575.42−Δ) MHz for GPS signals received from the radio front end, where 0<Δ≦16.42 MHz;during GPS mode operations, determining a measure of location of the radiotelephone using the GPS signals having suppressed energy at and/orand below (1575.42−Δ) MHz; andduring wireless radiotelephone communications, processing communications that are received at and/or transmitted from the radio front end. 28. The method according to claim 27, wherein the radio front end is configured to provide wireless radiotelephone communications with a space-based component using satellite radiotelephone frequencies and to provide wireless radiotelephone communications with a plurality of ancillary terrestrial components using at least one of the satellite radiotelephone frequencies. 29. The method according to claim 27, wherein processing communications that are received at and transmitted from the radio front end during wireless radiotelephone communications comprises processing the communications without suppressing energy of the communications at and/or below (1575.42−Δ) MHz. 30. The method according to claim 27, wherein suppressing energy at and/orand below (1575.42−Δ) MHz comprises suppressing at least 10 dB of energy at and/orand below (1575.42−Δ) MHz. 31. The method according to claim 30, wherein suppressing energy at and/orand (1575.42−Δ) MHz comprises suppressing at least 10 dB of energy at frequencies less than (1575.42−Δ) MHz. 32. The method according to claim 31, wherein suppressing energy at and/orand below (1575.42−Δ) MHz comprises suppressing at least 10 dB of energy at (1575.42−Δ) MHz and at frequencies less than (1575.42−Δ) MHz. 33. The method according to claim 2728, wherein processing of GPS signals is suppressed when actively providing radiotelephone communications with the space-based component and/or one of the ancillary terrestrial components. 34. The method according to claim 28, wherein the satellite radiotelephone frequencies comprise a satellite downlink frequency band and a satellite uplink frequency band and wherein GPS signals are transmitted from GPS satellites over a GPS frequency band between the satellite downlink and uplink frequency bands. 35. The method according to claim 34, wherein the satellite downlink frequency band comprises frequencies between 1525 MHz and 1559 MHz, and wherein the satellite uplink frequency band comprises frequencies between 1626.5 MHz and 1660.5 MHz. 36. The method according to claim 34, wherein the GPS frequency band comprises frequencies between 1559 MHz and 1605 MHz. 37. The method according to claim 27, wherein Δ is greater than at least 1 MHz. 38. The method according to claim 27, further comprising: receiving an incoming call page during GPS mode operations; andprocessing the incoming call page during GPS operations. 39. The method according to claim 27, further comprising: during GPS mode operations prior to determining the measure of location, providing low noise amplification of the GPS signals having suppressed energy at and/or below (1575.42−Δ) MHz. 40. The satellite radiotelephone system according to claim 1 wherein the GPS mode filter is configured to suppress energy at and below (1575.42−Δ) MHz, where 0<Δ≦16.42 MHz. 41. A satellite radiotelephone system comprising: a space-based component that is configured to provide wireless radiotelephone communications using satellite radiotelephone frequencies;at least one ancillary terrestrial component including at least one antenna that is configured to provide wireless radiotelephone communications using satellite radiotelephone frequencies in a radiation pattern that increases a radiation level below the horizon compared to a radiation level above the horizon; andat least one radiotelephone that is configured to communicate with the space-based component and/or with the at least one ancillary terrestrial component, the at least one radiotelephone including a GPS signal processor and a GPS filter that is configured to selectively attenuate signal energy that is associated with Radio Frequencies (RF) at and/or below (1575.42−Δ) MHz, where 0<Δ≦16.42 MHz. 42. The satellite radiotelephone system according to claim 41, wherein the GPS filter is configured to suppress at least 10 dB of signal energy that is associated with Radio Frequencies at and/or below (1575.42−Δ) MHz. 43. The satellite radiotelephone system according to claim 41, wherein the GPS filter is a band-pass filter. 44. The satellite radiotelephone system according to claim 41, wherein the at least one radiotelephone is further configured to suppress processing of GPS signals when communicating with the space-based component, and/or with the at least one ancillary terrestrial component. 45. The satellite radiotelephone system according to claim 41, wherein the GPS filter is coupled between an antenna and a low noise amplifier used in reception of GPS signals. 46. The satellite radiotelephone system according to claim 41, wherein the satellite radiotelephone frequencies comprise a satellite downlink frequency band and a satellite uplink frequency band and wherein GPS signals are transmitted from GPS satellites over a GPS frequency band between the satellite downlink and uplink frequency bands. 47. The satellite radiotelephone system according to claim 46, wherein the satellite downlink frequency band comprises frequencies between 1525 MHz and 1559 MHz, and wherein the satellite uplink frequency band comprises frequencies between 1626.5 MHz and 1660.5 MHz. 48. The satellite radiotelephone system according to claim 47, wherein the GPS frequency band comprises frequencies between 1559 MHz and 1605 MHz. 49. The satellite radiotelephone system according to claim 41, wherein Δ is greater than 1 MHz. 50. The satellite radiotelephone system according to claim 41, wherein the wireless radiotelephone communications are not subjected to the GPS filter. 51. The satellite radiotelephone system according to claim 41, wherein the GPS filter comprises a high pass filter. 52. The satellite radiotelephone system according to claim 41, wherein the at least one radiotelephone is further configured to receive wireless radiotelephone communications and/or a page during GPS mode operations. 53. A radiotelephone comprising: a radio front end that is configured to provide wireless radiotelephone communications using radiotelephone frequencies, and that is configured to receive global positioning satellite (GPS) signals from a plurality of global positioning satellites;a signal processor that is configured to determine a measure of location of the radiotelephone using GPS signals received at the radio front end when providing GPS mode operations and that is configured to process communications that are received at and/or transmitted from the radio front end when providing wireless radiotelephone communications; anda GPS filter that is configured to filter signals received at the radio front end before being provided to the signal processor, wherein the GPS filter is configured to selectively attenuate signal energy that is associated with Radio Frequencies (RF) at and below (1575.42−Δ) MHz, where 0<Δ≦16.42 MHz. 54. The radiotelephone according to claim 53, wherein the radio front end is configured to provide radiotelephone communications with a space-based component using satellite radiotelephone frequencies, and to provide wireless radiotelephone communications with at least one ancillary terrestrial component using satellite radiotelephone frequencies. 55. The radiotelephone according to claim 53, wherein the wireless radiotelephone communications are not subjected to the GPS filter. 56. The radiotelephone according to claim 53, wherein the GPS filter is coupled between an antenna and a low noise amplifier used in reception of GPS signals. 57. The radiotelephone according to claim 53, wherein the GPS filter is configured to suppress at least 10 dB of signal energy that is associated with Radio Frequencies at and below (1575.42−Δ) MHz. 58. The radiotelephone according to claim 53, wherein the GPS filter is a band-pass filter. 59. The radiotelephone according to claim 53, wherein processing of GPS signals at the signal processor is suppressed responsive to the radiotelephone transmitting wireless radiotelephone communications. 60. The radiotelephone according to claim 53, wherein the radiotelephone frequencies comprise a satellite downlink frequency band and a satellite uplink frequency band and wherein GPS signals are transmitted from GPS satellites over a GPS frequency band that is between the satellite downlink and uplink frequency bands. 61. The radiotelephone according to claim 60, wherein the satellite downlink frequency band comprises frequencies between 1525 MHz and 1559 MHz, and wherein the satellite uplink frequency band comprises frequencies between 1626.5 MHz and 1660.5 MHz. 62. The radiotelephone according to claim 60, wherein the GPS frequency band comprises frequencies between 1559 MHz and 1605 MHz. 63. The radiotelephone according to claim 53, wherein Δ is greater than 1 MHz. 64. The radiotelephone according to claim 53, wherein the GPS filter comprises a high pass filter. 65. The radiotelephone according to claim 53, wherein the radio front end is further configured to receive communications and/or a page during GPS mode operations and wherein the signal processor is further configured to process the communications and/or the page during GPS mode operations. 66. A method of providing radiotelephone communications and a measure of location at a radiotelephone comprising a radio front end that is configured to provide wireless radiotelephone communications using radiotelephone frequencies and receive global positioning satellite (GPS) signals from a plurality of global positioning satellites, the method comprising: during GPS mode operations, selectively suppressing signal energy relating to Radio Frequencies (RF)at and below (1575.42−Δ) MHz, where 0<Δ≦16.42 MHz;during GPS mode operations, determining a measure of location of the radiotelephone using the GPS signals having suppressed energy relating to Radio Frequencies (RF) at and below (1575.42−Δ) MHz; andduring wireless radiotelephone communications, processing communications that are received at and/or transmitted from the radio front end. 67. The method according to claim 66, wherein the radio front end is configured to provide wireless radiotelephone communications with a space-based component using satellite radiotelephone frequencies, and to provide wireless radiotelephone communications with at least one ancillary terrestrial component using satellite radiotelephone frequencies. 68. The method according to claim 66, wherein processing communications that are received at and/or transmitted from the radio front end during wireless radiotelephone communications comprises processing the communications without subjecting the communications to selectively suppressing energy thereof relating to Radio Frequencies (RF) at and below (1575.42−Δ) MHz. 69. The method according to claim 66, wherein selectively suppressing signal energy relating to Radio Frequencies (RF) at and below (1575.42−Δ) MHz comprises suppressing at least 10 dB of signal energy relating to Radio Frequencies (RF) at and below (1575.42−Δ) MHz. 70. The method according to claim 66, wherein selectively suppressing signal energy relating to Radio Frequencies (RF) at and below (1575.42−Δ) MHz comprises high-pass filtering. 71. The method according to claim 66, wherein determining a measure of location of the radiotelephone using the GPS signals is suppressed when the radiotelephone is transmitting communications. 72. The method according to claim 67, wherein the satellite radiotelephone frequencies comprise a satellite downlink frequency band and a satellite uplink frequency band and wherein GPS signals are transmitted from GPS satellites over a GPS frequency band that is between the satellite downlink and uplink frequency bands. 73. The method according to claim 72, wherein the satellite downlink frequency band comprises frequencies between 1525 MHz and 1559 MHz, and wherein the satellite uplink frequency band comprises frequencies between 1626.5 MHz and 1660.5 MHz. 74. The method according to claim 72, wherein the GPS frequency band comprises frequencies between 1559 MHz and 1605 MHz. 75. The method according to claim 66, wherein Δ is greater than 1 MHz. 76. The method according to claim 66, further comprising: receiving communications and/or a page during GPS mode operations; andprocessing the communications and/or the page during GPS mode operations. 77. The method according to claim 66, further comprising: during GPS mode operations prior to determining the measure of location, providing low noise amplification to the GPS signals having suppressed energy relating to Radio Frequencies at and below (1575.42−Δ) MHz. 78. A method of providing space-based and terrestrial wireless communications, the method comprising: configuring a space-based component to provide communications using satellite radiotelephone frequencies;configuring at least one ancillary terrestrial component including at least one antenna to provide wireless radiotelephone communications using satellite radiotelephone frequencies in a radiation pattern that increases a radiation level below the horizon compared to a radiation level above the horizon; andconfiguring at least one radiotelephone to communicate with the space-based component and/or with the at least one ancillary terrestrial component, the at least one radiotelephone including a GPS signal processor and a GPS filter that is configured to selectively attenuate signal energy that is associated with Radio Frequencies (RF) at and/or below (1575.42−Δ) MHz, where 0<Δ≦16.42 MHz. 79. The method according to claim 78, wherein the GPS filter is configured to suppress at least 10 dB of signal energy that is associated with Radio Frequencies at and/or below (1575.42−Δ) MHz. 80. The method according to claim 78, wherein the GPS filter is a band-pass filter. 81. The method according to claim 78, wherein the at least one radiotelephone is further configured to suppress processing of GPS signals when communicating with the space-based component and/or with the at least one ancillary terrestrial component. 82. The method according to claim 78, wherein the GPS filter is coupled between an antenna and a low noise amplifier used in reception of GPS signals. 83. The method according to claim 78, wherein the satellite radiotelephone frequencies comprise a satellite downlink frequency band and a satellite uplink frequency band and wherein GPS signals are transmitted from GPS satellites over a GPS frequency band that is between the satellite downlink and uplink frequency bands. 84. The method according to claim 83, wherein the satellite downlink frequency band comprises frequencies between 1525 MHz and 1559 MHz, and wherein the satellite uplink frequency band comprises frequencies between 1626.5 MHz and 1660.5 MHz. 85. The method according to claim 83, wherein the GPS frequency band comprises frequencies between 1559 MHz and 1605 MHz. 86. The method according to claim 78, wherein Δ is greater than 1 MHz. 87. The method according to claim 78, wherein the wireless radiotelephone communications are not subjected to the GPS filter. 88. The method according to claim 78, wherein the GPS filter comprises a high pass filter. 89. The method according to claim 78, wherein the at least one radiotelephone is further configured to receive wireless radiotelephone communications and/or a page during GPS mode operations.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.