초록 ▼

A wireless telecommunications system comprising a plurality of telecommunications nodes that include receivers and transmitters that are located in a suborbital plane. The telecommunications signals are broadband digital radio signals which are modulated by code division multiple access spread spect

A wireless telecommunications system comprising a plurality of telecommunications nodes that include receivers and transmitters that are located in a suborbital plane. The telecommunications signals are broadband digital radio signals which are modulated by code division multiple access spread spectrum technology. The receivers include a plurality of antennae that are operative to receive relatively weak telecommunications signals and which use spatial processing to identify their source so that maximum utilization of the spectrum is made available for use by the telecommunications signals without interference.

대표청구항 ▼

1. A wireless, telecommunications network system comprising: a plurality of telecommunications nodes,said nodes being located in a sub-orbital plane at about 12 to 35 miles above the earth,means for maintaining said nodes in preselected geographic locations in the sub-orbital plane,each of said node

1. A wireless, telecommunications network system comprising: a plurality of telecommunications nodes,said nodes being located in a sub-orbital plane at about 12 to 35 miles above the earth,means for maintaining said nodes in preselected geographic locations in the sub-orbital plane,each of said nodes comprising means for sending and receiving broadband, digital radio telecommunications signals over a wireless telecommunications channel between said node in the sub-orbital plane and a mobile ground communication device, said radio telecommunications signals being modulated by broadband code division multiple access spread spectrum technology,said means for sending and receiving said radio telecommunications signals further including a plurality of antennae that are operative to receive relatively weak telecommunications signals from said mobile ground communication device,means for decoding the telecommunications signals received by each of said antennae so that said node can identify said mobile ground communication device and its location, andsaid antennae and said decoding means being operative to increase the sensitivity of said node to signals identifying said mobile ground communication device and its location so that it can detect and receive relatively weak telecommunications signals, so that maximum utilization of a spectrum is made available for use by said telecommunications signals without interference. 2. A system as defined in claim 1 wherein said code division multiple access spread spectrum technology is direct sequence. 3. A system as defined in claim 1 wherein said broadcast telecommunications channel has a frequency band width that is greater than about eight MHz. 4. A wireless, telecommunications network system comprising: a plurality of telecommunications nodes, said nodes being located in a sub-orbital plane at about 12 to 35 miles above the earth,means for maintaining said nodes in preselected geographic locations in the sub-orbital plane,each of said nodes comprising means for sending and receiving broadband, digital radio telecommunications signals over a wireless telecommunications channel between said node in the sub-orbital plane and a mobile ground communication device, said radio telecommunications signals being modulated by broadband code division multiple access spread spectrum technology,said means for sending and receiving said radio telecommunications signals further including a plurality of antennae that are operative to receive relatively weak telecommunications signals from said mobile ground communication device,means for decoding the telecommunications signals received by each of said antennae so that said node can identify said mobile ground communication device and its location,said antennae and said decoding means being operative to increase the sensitivity of said node to signals identifying said mobile ground communication device and its location so that it can detect and receive relatively weak telecommunications signals, so that maximum utilization of a spectrum is made available for use by said telecommunications signals without interference, wherein said wireless telecommunications channel has a frequency bandwidth that is greater than about eight MHZ. 5. A system as defined in claim 1 wherein each of said nodes is maintained stationary over its own point on the earth. 6. A system as defined in claim 1 wherein said means for sending and receiving broadband, digital radio telecommunications signals over a wireless telecommunications channel comprises at least one transmitter and receiver, and said transmitter and receiver carry a plurality of duplex telecommunications channels. 7. A system as defined in claim 6 wherein said transmitter is low powered and light weight. 8. A system as defined in claim 1 including a terrestrial based telecommunications network, and means for connecting said wireless, telecommunications network system to said terrestrial based telecommunications network. 9. A system as defined in claim 8 wherein said means for connecting said wireless, telecommunications network system to said terrestrial based telecommunications network includes switches. 10. A system as defined in claim 9 wherein said switches are digital. 11. A system as defined in claim 9 wherein said switches are analog. 12. A system as defined in claim 1 wherein said nodes are supported by balloons. 13. A system as defined in claim 1 wherein said wireless telecommunication channels are the same as those allocated for terrestrial communications. 14. A system as defined in claim 1 wherein said means for sending and receiving broadband, digital radio telecommunications signals over a wireless telecommunications channel comprises at least one transmitter and receiver and said transmitter and receiver carry a plurality of simplex telecommunications channels. 15. A system as defined in claim 14 wherein said transmitter is low powered and light weight. 16. A system as defined in claim 1 wherein said means for sending and receiving broadband, digital radio telecommunications signals over a wireless telecommunications channel comprises at least one transmitter and receiver, and said transmitter and receiver carry a plurality of half duplex telecommunications channels. 17. A system as defined in claim 16 wherein said transmitter is low powered and light weight. 18. A system as defined in claim 1 wherein said wireless telecommunication channels are the same as those allocated for orbital telecommunications. 19. A system as defined in claim 1 wherein said wireless telecommunication channels are exclusively used by said telecommunications system. 20. A method for making wireless telecommunications comprising the steps of: providing a plurality of telecommunications nodes, said nodes defining a network,locating said nodes in a sub-orbital plane at about 12 to 35 miles above the earth and maintaining said nodes in preselected geographic locations in the suborbital plane,providing each of said nodes with means for sending and receiving broadband, digital radio telecommunications signals over a wireless telecommunications channel between said node in the suborbital plane and a mobile ground communication device,providing each of said nodes with a plurality of antennae that are operative to receive relatively weak digital, radio telecommunications signals from said mobile ground communication device,modulating said telecommunications signals by broadband code division multiple access spread spectrum technology,decoding said telecommunications signals received by each of said antennae so that said node can identify said mobile ground communication device and its location, and said antennae and said decoding means being operative to increase the sensitivity of said nodes to signals identifying said mobile ground communication device and its location so that they can detect and receive said relatively weak telecommunications signals, so that maximum utilization of a spectrum is made available for use by said telecommunications signals without interference. 21. A method as defined in claim 20 wherein said code division multiple access spread spectrum technology is modified by direct sequence. 22. A method as defined in claim 20 wherein said code division multiple access spread spectrum technology is modified by frequency hopping. 23. A method for making wireless telecommunications comprising the steps of: providing a plurality of telecommunications nodes, said nodes defining a network,locating said nodes in a sub-orbital plane at about 12 to 35 miles above the earth and maintaining said nodes in preselected geographic locations in the suborbital plane,providing each of said nodes with means for sending and receiving broadband, digital radio telecommunications signals over a wireless telecommunications channel between said node in the suborbital plane and a mobile ground communication device,providing each of said nodes with a plurality of antennae that are operative to receive relatively weak digital, radio telecommunications signals from said mobile ground communication device,modulating said telecommunications signals by broadband code division multiple access spread spectrum technology,decoding said telecommunications signals received by each of said antennae so that said node can identify said mobile ground communication device and its location, said antennae and said decoding means being operative to increase the sensitivity of said nodes to signals identifying said mobile ground communication device and its location so that they can detect and receive said relatively weak telecommunications signals, so that maximum utilization of a spectrum is made available for use by said telecommunications signals without interference, wherein said wireless telecommunications channel has a frequency bandwidth that is greater than about eight MHZ. 24. A method as defined in claim 20 wherein each of said nodes is maintained over its own point on the earth. 25. A method as defined in claim 20 wherein said step of sending and receiving broadband, digital radio telecommunications signals over a wireless telecommunications channel comprises the step of providing a plurality of transmitters and receivers, and each of said transmitters carrying a plurality of duplex telecommunications channels. 26. A method as defined in claim 25 wherein said transmitters are low powered and light weight. 27. A method as defined in claim 20 including the steps of providing a terrestrial based telecommunications network, and connecting said wireless, telecommunications network system to said terrestrial based telecommunications network. 28. A method as defined in claim 27 including the step of providing switches for connecting said wireless, telecommunications network system to said terrestrial based telecommunications network. 29. A method as defined in claim 28 wherein said switches are digital. 30. A method as defined in claim 28 wherein said switches are analog. 31. A method as defined in claim 20 including the step of supporting said nodes by balloons. 32. A method as defined in claim 20 wherein said wireless telecommunication channels are the same as those allocated for terrestrial telecommunications. 33. A method as defined in claim 20 wherein said step of sending and receiving broadband, digital radio telecommunications signals over a wireless telecommunications channel comprises the step of providing at least one transmitter and one receiver, and said transmitter and receiver carry a plurality of simplex telecommunications channels. 34. A method as defined in claim 33 wherein said transmitter is low powered and light weight. 35. A method as defined in claim 20 wherein said step of sending and receiving broadband, digital telecommunications signals over a wireless telecommunications channel comprises the step of providing at least one transmitter and one receiver, and said transmitter and receiver carry a plurality of half duplex telecommunications channels. 36. A method as defined in claim 35 wherein said transmitter is low powered and light weight. 37. A method as defined in claim 20 wherein said wireless telecommunication channels are the same as those allocated for orbital telecommunications. 38. A method as defined in claim 20 wherein said wireless telecommunication channels are exclusively used by said telecommunications system. 39. A cellular-type wireless communications system comprising: a wireless switching center connected to a telephone network;a plurality of airborne base stations each associated with a cell corresponding to a specific geographic area, each airborne base station operable to directly transmit and receive communication signals to/from individual subscriber terminals within the associated cell and to/from said wireless switching center to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals, said plurality of airborne base stations including at least one antenna for communicating with said wireless switching center and with individual subscriber terminals in an associated cell; andeach of said plurality of airborne base stations being supported by at least one airborne platform including a propulsion system, the propulsion system being mounted on the airborne platform and being operable to maintain the platform airborne above a geographic area being serviced by the airborne base station; andeach of said plurality of airborne base stations being operative, in conjunction with the wireless switching center, to hand off communication sessions with subscriber terminals to at least one other airborne base station. 40. A wireless communications system according to claim 39 wherein the platform includes a high altitude balloon. 41. A wireless communications system according to claim 39 wherein the propulsion system includes a propeller driven by an electric motor. 42. A wireless communication system according to claim 41 further including an energy storage system and a solar panel, said energy storage system and said solar panel being operable to power said propulsion system. 43. A wireless communications system according to claim 42 wherein said solar panel is operable to recharge said energy storage system. 44. A wireless communications system according to claim 42 wherein said energy storage system is operable to power said propulsion system during nighttime operation and said solar panel is operable to power said propulsion system during daytime operation. 45. A wireless communications system according to claim 39 wherein said propulsion system maintains said platform at an altitude of about 15 to about 20 miles above sea level. 46. A wireless communications system according to claim 45 wherein the platform is maintained at an altitude of about 15 miles above sea level. 47. A wireless communications system according to claim 39 wherein said at least one antenna comprises a high gain, narrow beam antenna array. 48. A wireless communications system according to claim 39 wherein the platform includes an aircraft. 49. A wireless communication system according to claim 39, wherein the at least one airborne base station includes first and second airborne base stations, said first airborne base station communicating with said second airborne base station via a microwave link. 50. A method for wireless communications in a geographic area comprising: positioning a mobile switching center at a location to facilitate communication in the geographic area, said mobile switching center switching calls between ones of a plurality of airborne base stations and a telephone network;positioning and maintaining a plurality of airborne platforms above the geographic area;supporting said plurality of airborne base stations having at least one antenna on said respective plurality of airborne platforms for directly transmitting/receiving communication signals with a plurality of individual mobile subscriber terminals on the ground in said geographic area and with said mobile switching center, to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals; andhanding off communication sessions of subscriber terminals from one of said plurality of airborne base stations to at least one other of said plurality of airborne base stations. 51. A method according to claim 50 wherein the step of positioning the platform comprises positioning the platform at a location to minimize interference with transient airplanes. 52. A method according to claim 50 wherein the step of positioning the platform further comprises positioning the platform at an altitude of about 15 to about 20 miles above sea level. 53. A method according to claim 50 wherein the step of positioning the platform comprises positioning the platform at an altitude of approximately 15 miles above sea level. 54. A method for wireless communications in a geographic area comprising: positioning a switching center at a location to facilitate communication in the geographic area, said switching center switching calls between ones of a plurality of airborne base stations and a telephone network;positioning and maintaining a plurality of airborne platforms above the geographic area;supporting said plurality of airborne base stations having at least one antenna on said respective plurality of airborne platforms for directly transmitting/receiving communication signals with a plurality of individual mobile subscriber terminals on the ground in said geographic area and with said switching center, to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals; andhanding off communication sessions of subscriber terminals from one of said plurality of airborne base stations to at least one other of said plurality of airborne base stations. 55. A method according to claim 54 wherein the step of positioning the platform comprises positioning the platform at a location to minimize interference with transient airplanes. 56. A method according to claim 54 wherein the step of positioning the platform further comprises positioning the platform at an altitude of about 15 to about 20 miles above sea level. 57. A method according to claim 54 wherein the step of positioning the platform comprises positioning the platform at an altitude of approximately 15 miles above sea level. 58. A cellular-type wireless communications system comprising: a wireless switching center connected to a telephone network;a plurality of airborne base stations each associated with a cell corresponding to a specific geographic area, each airborne base station operable to directly transmit and receive communication signals to/from individual subscriber terminals within the associated cell and to/from said wireless switching center to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals, said plurality of airborne base stations including at least one antenna for communicating with said wireless switching center and with individual subscriber terminals in an associated cell; andeach of said plurality of airborne base stations being supported by at least one airborne platform including a propulsion system, the propulsion system being mounted on the airborne platform and being operable to maintain the platform airborne above a geographic area being serviced by the airborne base station. 59. A wireless communications system according to claim 58 wherein the platform includes a high altitude balloon. 60. A wireless communications system according to claim 58 wherein the propulsion system includes a propeller driven by an electric motor. 61. A wireless communication system according to claim 60 further including an energy storage system and a solar panel, said energy storage system and said solar panel being operable to power said propulsion system. 62. A wireless communications system according to claim 61 wherein said solar panel is operable to recharge said energy storage system. 63. A wireless communications system according to claim 61 wherein said energy storage system is operable to power said propulsion system during nighttime operation and said solar panel is operable to power said propulsion system during daytime operation. 64. A wireless communications system according to claim 58 wherein said propulsion system maintains said platform at an altitude of about 15 to about 20 miles above sea level. 65. A wireless communications system according to claim 64 wherein the platform is maintained at an altitude of about 15 miles above sea level. 66. A wireless communications system according to claim 58 wherein said at least one antenna comprises a high gain, narrow beam antenna array. 67. A wireless communications system according to claim 58 wherein the platform includes an aircraft. 68. A wireless communication system according to claim 58, wherein the at least one airborne base station includes first and second airborne base stations, said first airborne base station communicating with said second airborne base station via a microwave link. 69. A method for wireless communications in a geographic area comprising: positioning a mobile switching center at a location to facilitate communication in the geographic area, said mobile switching center switching calls between ones of a plurality of airborne base stations and a telephone network;positioning and maintaining a plurality of airborne platforms above the geographic area; andsupporting said plurality of airborne base stations having at least one antenna on said respective plurality of airborne platforms for directly transmitting/receiving communication signals with a plurality of individual mobile subscriber terminals on the ground in said geographic area and with said mobile switching center, to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals. 70. A method according to claim 69 wherein the step of positioning the platform comprises positioning the platform at a location to minimize interference with transient airplanes. 71. A method according to claim 69 wherein the step of positioning the platform further comprises positioning the platform at an altitude of about 15 to about 20 miles above sea level. 72. A method according to claim 69 wherein the step of positioning the platform comprises positioning the platform at an altitude of approximately 15 miles above sea level. 73. A method for wireless communications in a geographic area comprising: positioning a switching center at a location to facilitate communication in the geographic area, said switching center switching calls between ones of a plurality of airborne base stations and a telephone network;positioning and maintaining a plurality of airborne platforms above the geographic area; andsupporting said plurality of airborne base stations having at least one antenna on said respective plurality of airborne platforms for directly transmitting/receiving communication signals with a plurality of individual mobile subscriber terminals on the ground in said geographic area and with said switching center, to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals. 74. A method according to claim 73 wherein the step of positioning the platform comprises positioning the platform at a location to minimize interference with transient airplanes. 75. A method according to claim 73 wherein the step of positioning the platform further comprises positioning the platform at an altitude of about 15 to about 20 miles above sea level. 76. A method according to claim 73 wherein the step of positioning the platform comprises positioning the platform at an altitude of approximately 15 miles above sea level. 77. A cellular-type wireless communications system comprising: a wireless switching center connected to a telephone network;a plurality of airborne base stations each associated with a cell corresponding to a specific geographic area, each of said plurality of airborne base stations operable to directly transmit and receive communication signals to/from individual subscriber terminals within the associated cell and to/from said wireless switching center to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals; andat least one of said plurality of airborne base stations having at least one antenna for communicating with said wireless switching center and with individual subscriber terminals in a specific geographic region, said plurality of airborne base stations comprising at least a first airborne base station supported by a first aircraft above the geographic region and a second airborne base station supported by a second aircraft. 78. The wireless communications system of claim 77, wherein said first airborne base station is operative to hand off communication sessions with subscriber terminals to the second airborne base station, said wireless switching center coordinating handoffs between the first and second airborne base stations. 79. The wireless communications system of claim 77, wherein each said aircraft flies in a pattern. 80. A cellular-type wireless communications system comprising: a wireless switching center connected to a telephone network;a plurality of airborne stations each associated with a cell corresponding to a specific geographic area, each airborne station operable to directly transmit and receive communication signals to/from individual subscriber terminals within the associated cell and to/from said wireless switching center to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals, said plurality of airborne stations including at least one antenna for communicating with said wireless switching center and with individual subscriber terminals in an associated cell; andeach of said plurality of airborne stations being supported by at least one airborne platform including a propulsion system, the propulsion system being mounted on the airborne platform and being operable to maintain the platform airborne above a geographic area being serviced by the airborne station; andeach of said plurality of airborne stations being operative, in conjunction with the wireless switching center, to hand off communication sessions with subscriber terminals to at least one other airborne station. 81. A wireless communications system according to claim 80 wherein the platform includes a high altitude balloon. 82. A wireless communications system according to claim 80 wherein the propulsion system includes a propeller driven by an electric motor. 83. A wireless communication system according to claim 82 further including an energy storage system and a solar panel, said energy storage system and said solar panel being operable to power said propulsion system. 84. A wireless communications system according to claim 83 wherein said solar panel is operable to recharge said energy storage system. 85. A wireless communications system according to claim 83 wherein said energy storage system is operable to power said propulsion system during nighttime operation and said solar panel is operable to power said propulsion system during daytime operation. 86. A wireless communications system according to claim 80 wherein said propulsion system maintains said platform at an altitude of about 15 to about 20 miles above sea level. 87. A wireless communications system according to claim 86 wherein the platform is maintained at an altitude of about 15 miles above sea level. 88. A wireless communications system according to claim 80 wherein said at least one antenna comprises a high gain, narrow beam antenna array. 89. A wireless communications system according to claim 80 wherein the platform includes an aircraft. 90. A wireless communication system according to claim 80, wherein the at least one airborne station includes first and second airborne stations, said first airborne station communicating with said second airborne station via a microwave link. 91. A method for wireless communications in a geographic area comprising: positioning a mobile switching center at a location to facilitate communication in the geographic area, said mobile switching center switching calls between ones of a plurality of airborne stations and a telephone network;positioning and maintaining a plurality of airborne platforms above the geographic area;supporting said plurality of airborne stations having at least one antenna on said respective plurality of airborne platforms for directly transmitting/receiving communication signals with a plurality of individual mobile subscriber terminals on the ground in said geographic area and with said mobile switching center, to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals; andhanding off communication sessions of subscriber terminals from one of said plurality of airborne stations to at least one other of said plurality of airborne stations. 92. A method according to claim 91 wherein the step of positioning the platform comprises positioning the platform at a location to minimize interference with transient airplanes. 93. A method according to claim 91 wherein the step of positioning the platform further comprises positioning the platform at an altitude of about 15 to about 20 miles above sea level. 94. A method according to claim 91 wherein the step of positioning the platform comprises positioning the platform at an altitude of approximately 15 miles above sea level. 95. A method for wireless communications in a geographic area comprising: positioning a switching center at a location to facilitate communication in the geographic area, said switching center switching calls between ones of a plurality of airborne stations and a telephone network;positioning and maintaining a plurality of airborne platforms above the geographic area;supporting said plurality of airborne stations having at least one antenna on said respective plurality of airborne platforms for directly transmitting/receiving communication signals with a plurality of individual mobile subscriber terminals on the ground in said geographic area and with said switching center, to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals; andhanding off communication sessions of subscriber terminals from one of said plurality of airborne stations to at least one other of said plurality of airborne stations. 96. A method according to claim 95 wherein the step of positioning the platform comprises positioning the platform at a location to minimize interference with transient airplanes. 97. A method according to claim 95 wherein the step of positioning the platform further comprises positioning the platform at an altitude of about 15 to about 20 miles above sea level. 98. A method according to claim 95 wherein the step of positioning the platform comprises positioning the platform at an altitude of approximately 15 miles above sea level. 99. A cellular-type wireless communications system comprising: a wireless switching center connected to a telephone network;a plurality of airborne stations each associated with a cell corresponding to a specific geographic area, each airborne station operable to directly transmit and receive communication signals to/from individual subscriber terminals within the associated cell and to/from said wireless switching center to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals, said plurality of airborne stations including at least one antenna for communicating with said wireless switching center and with individual subscriber terminals in an associated cell; andeach of said plurality of airborne stations being supported by at least one airborne platform including a propulsion system, the propulsion system being mounted on the airborne platform and being operable to maintain the platform airborne above a geographic area being serviced by the airborne station. 100. A wireless communications system according to claim 99 wherein the platform includes a high altitude balloon. 101. A wireless communications system according to claim 99 wherein the propulsion system includes a propeller driven by an electric motor. 102. A wireless communication system according to claim 101 further including an energy storage system and a solar panel, said energy storage system and said solar panel being operable to power said propulsion system. 103. A wireless communications system according to claim 102 wherein said solar panel is operable to recharge said energy storage system. 104. A wireless communications system according to claim 102 wherein said energy storage system is operable to power said propulsion system during nighttime operation and said solar panel is operable to power said propulsion system during daytime operation. 105. A wireless communications system according to claim 99 wherein said propulsion system maintains said platform at an altitude of about 15 to about 20 miles above sea level. 106. A wireless communications system according to claim 105 wherein the platform is maintained at an altitude of about 15 miles above sea level. 107. A wireless communications system according to claim 99 wherein said at least one antenna comprises a high gain, narrow beam antenna array. 108. A wireless communications system according to claim 99 wherein the platform includes an aircraft. 109. A wireless communication system according to claim 99, wherein the at least one airborne station includes first and second airborne stations, said first airborne station communicating with said second airborne station via a microwave link. 110. A method for wireless communications in a geographic area comprising: positioning a mobile switching center at a location to facilitate communication in the geographic area, said mobile switching center switching calls between ones of a plurality of airborne stations and a telephone network;positioning and maintaining a plurality of airborne platforms above the geographic area; andsupporting said plurality of airborne stations having at least one antenna on said respective plurality of airborne platforms for directly transmitting/receiving communication signals with a plurality of individual mobile subscriber terminals on the ground in said geographic area and with said mobile switching center, to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals. 111. A method according to claim 110 wherein the step of positioning the platform comprises positioning the platform at a location to minimize interference with transient airplanes. 112. A method according to claim 110 wherein the step of positioning the platform further comprises positioning the platform at an altitude of about 15 to about 20 miles above sea level. 113. A method according to claim 110 wherein the step of positioning the platform comprises positioning the platform at an altitude of approximately 15 miles above sea level. 114. A method for wireless communications in a geographic area comprising: positioning a switching center at a location to facilitate communication in the geographic area, said switching center switching calls between ones of a plurality of airborne stations and a telephone network;positioning and maintaining a plurality of airborne platforms above the geographic area; andsupporting said plurality of airborne stations having at least one antenna on said respective plurality of airborne platforms for directly transmitting/receiving communication signals with a plurality of individual mobile subscriber terminals on the ground in said geographic area and with said switching center, to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals. 115. A method according to claim 114 wherein the step of positioning the platform comprises positioning the platform at a location to minimize interference with transient airplanes. 116. A method according to claim 114 wherein the step of positioning the platform further comprises positioning the platform at an altitude of about 15 to about 20 miles above sea level. 117. A method according to claim 114 wherein the step of positioning the platform comprises positioning the platform at an altitude of approximately 15 miles above sea level. 118. A cellular-type wireless communications system comprising: a wireless switching center connected to a telephone network;a plurality of airborne stations each associated with a cell corresponding to a specific geographic area, each of said plurality of airborne stations operable to directly transmit and receive communication signals to/from individual subscriber terminals within the associated cell and to/from said wireless switching center to enable communication sessions to be maintained, through the telephone network, between individual subscriber terminals and other telecommunication terminals; andat least one of said plurality of airborne stations having at least one antenna for communicating with said wireless switching center and with individual subscriber terminals in a specific geographic region, said plurality of airborne stations comprising at least a first airborne station supported by a first aircraft above the geographic region and a second airborne station supported by a second aircraft. 119. The wireless communications system of claim 118, wherein said first airborne station is operative to hand off communication sessions with subscriber terminals to the second airborne station, said wireless switching center coordinating handoffs between the first and second airborne stations. 120. The wireless communications system of claim 118, wherein each said aircraft flies in a pattern. 121. A system as defined in claim 1, further comprising means for detecting drift of said nodes in the sub-orbital plane. 122. A system as defined in claim 5, further comprising means for detecting drift of said nodes in the sub-orbital plane. 123. A method as defined in claim 20, further comprising the step of detecting drift of said nodes in the sub-orbital plane. 124. A method as defined in claim 23, further comprising the step of detecting drift of said nodes in the sub-orbital plane. 125. A wireless communications system according to claim 39, further comprising means for detecting drift of said plurality of airborne base stations away from the geographic area being serviced by said airborne base stations. 126. A system as defined in claim 1 wherein each of said nodes is maintained stationary over its own point on the earth using a guidance module which is connected by a guidance antenna to a ground link antennae. 127. A method as defined in claim 20 wherein each of said nodes is maintained stationary over its own point on the earth using a guidance module which is connected by a guidance antenna to a ground link antennae. 128. A wireless, telecommunications network system comprising: a plurality of telecommunications nodes located in a sub-orbital plane at about 12 to 35 miles above the earth,means for maintaining said nodes stationary in the sub-orbital plane over preselected points on the earth; andeach of said nodes comprising means for sending and receiving telecommunications signals over a wireless telecommunications channel between said stationary node in the sub-orbital plane and a mobile ground communications device. 129. A system as defined in claim 128 wherein the means for sending and receiving said radio telecommunications signals further including a plurality of antennae that are operative to receive relatively weak telecommunications signals from said mobile ground communications device. 130. A system as defined in claim 129 further comprising means on said plurality of telecommunications nodes for decoding the telecommunications signals received by each of said antennae so that each node can identify said mobile ground communications device and its location, wherein said antennae and said decoding means being operative to increase the sensitivity of each node to signals identifying said mobile ground communications device and its location so that it can detect and receive relatively weak telecommunications signals, so that maximum utilization of a spectrum is made available for use by said telecommunications signals without interference. 131. A system as defined in claim 128 wherein the means for sending and receiving telecommunications signals on the telecommunications node is configured to receive telephone communication signals from a ground station or cellular telephone and then transmit it to another ground station or cellular telephone through another telecommunications node.