Methods and apparatus relating to wireless terminal beacon signal generation, transmission, and/or use
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04B-007/00
H04W-036/00
출원번호
US-0621955
(2007-01-10)
등록번호
US-8774846
(2014-07-08)
발명자
/ 주소
Laroia, Rajiv
Rangan, Sundeep
Das, Arnab
Lane, Frank A.
Li, Junyi
출원인 / 주소
QUALCOMM Incorporated
대리인 / 주소
O'Hare, James K.
인용정보
피인용 횟수 :
2인용 특허 :
122
초록▼
A portable wireless terminal generates and transmits a beacon signal. The beacon signal includes a sequence of beacon signal bursts, each beacon signal burst including one or more beacon symbols. A beacon symbol is transmitted using the air link resources of a beacon symbol transmission unit at a re
A portable wireless terminal generates and transmits a beacon signal. The beacon signal includes a sequence of beacon signal bursts, each beacon signal burst including one or more beacon symbols. A beacon symbol is transmitted using the air link resources of a beacon symbol transmission unit at a relatively high transmission power level with respect to user data symbols transmitted from the same wireless terminal, thus facilitating easy detection by other wireless terminals. The beacon symbols of the beacon signal occupy a small fraction of the total available air link resources. Beacon signals can, and sometimes do, convey wireless terminal identification information, via the location of the beacon symbols within the portion of the air link resource reserved for beacon symbol transmission units.
대표청구항▼
1. A method of operating a first wireless terminal comprising: transmitting a beacon signal burst during a beacon transmission time period in accordance with a timing structure including said beacon transmission time period and a beacon receive time period which recur in accordance with said timing
1. A method of operating a first wireless terminal comprising: transmitting a beacon signal burst during a beacon transmission time period in accordance with a timing structure including said beacon transmission time period and a beacon receive time period which recur in accordance with said timing structure, said beacon receive time period being longer than said beacon transmission time period, said beacon signal burst including one or more beacon symbols, each beacon symbol occupying a beacon symbol transmission unit;monitoring for beacon signals from other devices during said beacon receive time period in accordance with said timing structure, said other devices including a second wireless terminal;communicating data symbols using OFDM symbol transmission units during a user data time period which occurs in said timing structure following said beacon receive time period, said user data time period being distinct from said beacon receive time period in said timing structure; andwherein said timing structure is used by both the first and second wireless terminals but with the start of the timing structure used by the first wireless terminal being offset from the start of the timing of the timing structure used by the second wireless terminal by an amount which is greater than the duration of the beacon transmission time period and less than the duration of the beacon receive time period and the start of the of the beacon transmission time period of the second wireless terminal following the end of the beacon transmission time period of the first wireless terminal by an amount which is less than the duration of the beacon transmission time period. 2. The method of claim 1, wherein said beacon symbols each have a duration of 3 or 4 OFDM symbol times;the method further comprising:providing transmission power used for transmitting the beacon signal burst from a battery power source. 3. The method of claim 1, wherein transmitting a beacon signal burst during a beacon transmission time period includes transmitting no transmission power during a majority of beacon symbol transmission time periods in the beacon signal burst, said beacon symbol time periods in which no transmission power is transmitted corresponding to nulls in said beacon signal burst, said nulls occupying the majority of beacon symbol transmission units in the beacon signal burst. 4. The method of claim 3, wherein transmitting a beacon signal burst further includes: using a hopping sequence to determine the position of beacon symbols in a time frequency grid. 5. The method of claim 1, wherein said beacon transmission time period is an uninterrupted contiguous time period including multiple sequential occurring symbol transmission time periods. 6. The method of claim 5, wherein at least some different beacon signal bursts transmitted in a sequence of beacon signal bursts have periods of different lengths. 7. The method of claim 1, wherein the average per symbol transmission power level of each beacon symbol transmitted during a first period of time is at least 10 dB higher than the average per symbol transmission power level of symbols used to transmit user data during said first period of time. 8. The method of claim 1, wherein said beacon symbols are transmitted using OFDM tone symbols, said beacon symbols occupying less than 1 percent of the tone symbols of a transmission resource used by said wireless terminal during a period of time including multiple beacon signal bursts. 9. The method of claim 8, wherein beacon symbols occupy less than 0.1 percent of the tone symbols in a portion of said period of time, said portion of said period of time including one beacon signal burst and one interval between successive beacon signal bursts. 10. The method of claim 9, further comprising: transmitting user data on at least 10 percent of the tone symbols of the transmission resource used by said wireless terminal during said period of time including multiple beacon signal bursts. 11. The method of claim 10, wherein the time duration of a beacon signal burst time period occurring in said period of time is at least 50 times shorter than a time period occurring between two consecutive beacon signal bursts during said period of time. 12. The method of claim 8, wherein the time spacing between beacon signal bursts occurring during a first period including multiple beacon signal bursts is constant with said beacon signal bursts occurring in a periodic manner during said first period of time. 13. The method of claim 12, wherein duration of beacon signal bursts during said first time period is constant. 14. The method of claim 8, wherein the time spacing between beacon signal bursts occurring during a first period including multiple beacon symbol transmission bursts varies, with said beacon symbol bursts occurring during said first period of time in accordance with a predetermined pattern. 15. The method of claim 14, wherein duration of beacon signal bursts during said first time period is constant. 16. The method of claim 14, wherein said predetermined pattern various depending on the wireless terminal performing said transmitting step. 17. The method of claim 16, wherein said predetermined pattern is the same for all wireless terminals in a system. 18. The method of claim 14, wherein said pattern is a pseudo random pattern. 19. The method of claim 1, wherein said first wireless terminal includes an OFDM transmitter which transmits said beacon signal burst and wherein said beacon signal burst is communicated using a resource which is a combination of frequency and time. 20. The method of claim 1, wherein said first wireless terminal includes a CDMA transmitter which transmits said beacon signal burst and wherein said beacon signal burst is communicated using a resource which is a combination of code and time. 21. A portable wireless terminal comprising: a beacon signal generation module for generating a beacon signal including a sequence of beacon signal bursts, each beacon signal burst including one or more beacon symbols;a transmission module for transmitting a beacon signal burst during a beacon transmission time period in accordance with a timing structure including said beacon transmission time period and a beacon receive time periods which recur in accordance with said timing structure, using beacon signal transmission units, said beacon receive time period being longer than said beacon transmission time period, each beacon symbol occupying a beacon symbol transmission unit;a detection module for monitoring and detecting beacon signals from other devices during said beacon receive time period in accordance with said timing structure, said other devices including a second wireless terminal;wherein said transmission module is configured to transmit data symbols using OFDM symbol transmission units during a user data time period which occurs in said timing structure following said beacon receive time period, said user data time period being distinct from said beacon receive time period in said timing structure; andwherein the portable wireless terminal is a first wireless terminal, said timing structure is used by both the first and second wireless terminals but with the start of the timing structure used by the first wireless terminal being offset from the start of the timing of the timing structure used by the second wireless terminal by an amount which is greater than the duration of the beacon transmission time period and less than the duration of the beacon receive time period and the start of the of the beacon transmission time period of the second wireless terminal following the end of the beacon transmission time period of the first wireless terminal by an amount which is less than the duration of the beacon transmission time period. 22. The portable wireless terminal of claim 21 further comprising: a battery power source for providing transmission power used for transmitting the beacon signal burst; andwherein said beacon symbols each have a duration of 3 or 4 OFDM symbol times. 23. The portable wireless terminal of claim 21, wherein said stored beacon characteristic information identifies which beacon transmission units in a beacon signal burst are to be occupied by intentional nulls, and wherein the majority of beacon symbol transmission units in a transmitted beacon signal burst are to occupied by intentional nulls. 24. The portable wireless terminal of claim 21, further comprising: a user data signal generation module for generating a user data signal, said user data signal including data symbols, and wherein said transmitter module transmits said user data signal in addition to said beacon signal burst;a transmission power control module for controlling the transmission power level of beacon symbols and data symbols, and wherein the transmission power control module controls, during a first period of time, the data symbols to be transmitted at an average per symbol power level that is at least 50 percent lower than the average per beacon symbol power level of beacon symbols transmitted during said first period of time. 25. The portable wireless terminal of claim 21, wherein said beacon transmission time period is an uninterrupted contiguous time period including multiple sequential occurring symbol transmission time periods. 26. The portable wireless terminal of claim 25, wherein at least some different beacon signal bursts transmitted in a sequence of beacon signal bursts have periods of different lengths. 27. The portable wireless terminal of claim 21, further comprising: a transmission power control module, and wherein the transmission power control module controls the average per symbol transmission power level of each beacon symbol transmitted during a first period of time to be at least 10 dB higher than the average per symbol transmission power level of symbols used to transmit user data during said first period of time. 28. The portable wireless terminal of claim 21, wherein said transmission module is an OFDM transmitter, and wherein said beacon symbols are transmitted using OFDM tone symbols, said beacon symbols occupying less than 1 percent of the tone symbols of a transmission resource used by said wireless terminal during a period of time including multiple beacon signal bursts. 29. The portable wireless terminal of claim 28, wherein beacon symbols occupy less than 0.1 percent of the tone symbols in a portion of said period of time, said portion of said period of time including one beacon signal burst and one interval between successive beacon signal bursts. 30. The portable wireless terminal of claim 29, wherein said transmission module transmits user data in addition to said beacon signal burst, and wherein user data is transmitted on at least 10 percent of the tone symbols of the transmission resource used by said wireless terminal during said period of time including multiple beacon signal bursts. 31. The portable wireless terminal of claim 30, wherein the time duration of a beacon signal burst time period occurring in said period of time is at least 50 times shorter than a time period occurring between two consecutive beacon signal bursts during said period of time. 32. The portable wireless terminal of claim 28, wherein the time spacing between beacon signal bursts occurring during a first period including multiple beacon signal bursts is constant with said beacon signal bursts occurring in a periodic manner during said first period of time. 33. The portable wireless terminal of claim 32, wherein duration of beacon signal bursts during said first time period is constant. 34. The portable wireless terminal of claim 28, further comprising: memory including stored transmission timing structure information used by the beacon signal generation module to generate said beacon signal, andwherein the stored transmission timing structure information includes information defining the time spacing between beacon signal bursts occurring during a first period including multiple beacon symbol transmission bursts to vary, with said beacon symbol bursts occurring during said first period of time in accordance with a predetermined pattern. 35. The portable wireless terminal of claim 34, wherein said memory further includes beacon signal characteristic information used by said beacon signal generation module in generating said beacon signal; andwherein the beacon signal characteristic information defines the duration of beacon signal bursts during said first time period to be constant. 36. The portable wireless terminal of claim 34, wherein said predetermined pattern various depending on the wireless terminal performing said transmitting step. 37. The portable wireless terminal of claim 36, wherein said predetermined pattern is the same for all wireless terminals in a system. 38. The portable wireless terminal of claim 34, wherein said pattern is a pseudo random pattern. 39. The portable wireless terminal of claim 21, wherein said transmission module is an OFDM transmitter which transmits said beacon signal burst and wherein said beacon signal burst is communicated using a resource which is a combination of frequency and time. 40. The portable wireless terminal of claim 21, wherein said transmission module is a CDMA transmitter which transmits said beacon signal burst and wherein said beacon signal burst is communicated using a resource which is a combination of code and time. 41. A portable wireless terminal comprising: means for generating a beacon signal including a sequence of beacon signal bursts, each beacon signal burst including one or more beacon symbols;means for transmitting said beacon signal burst during a beacon transmission time period in accordance with a timing structure including said beacon transmission time period and a beacon receive time period which recur in accordance with said timing structure, said beacon receive time period being longer than said beacon transmission time period, said beacon signal burst including one or more beacon symbols, each beacon symbol occupies a beacon symbol transmission unit;means for monitoring for beacon signals from other devices during said beacon receive time period in accordance with said timing structure, said other devices including a second wireless terminal;wherein said means for transmitting said beacon signal burst includes means for transmitting data symbols using OFDM symbol transmission units during a user data time period which occurs in said timing structure following said beacon receive time period, said user data time period being distinct from said beacon receive time period in said timing structure; andwherein the portable wireless terminal is a first wireless terminal, said timing structure is used by both the first and second wireless but with the start of the timing structure used by the first wireless terminal being offset from the start of the timing of the timing structure used by the second wireless terminal by an amount which is greater than the duration of the beacon transmission time period and less than the duration of the beacon receive time period and the start of the of the beacon transmission time period of the second wireless terminal following the end of the beacon transmission time period of the first wireless terminal by an amount which is less than the duration of the beacon transmission time period. 42. The portable wireless terminal of claim 41, further comprising: means for storing energy for providing transmission power used for transmitting the beacon signal burst; andwherein said beacon symbols each have a duration of 3 or 4 OFDM symbol times. 43. The portable wireless terminal of claim 41, further comprising: means for generating a user data signal, said user data signal including data symbols, and wherein said means for transmitting transmits said user data signal in addition to said beacon signal burst;means for controlling transmission power levels of beacon symbols and data symbols, and wherein the means for controlling transmission power levels controls, during a first period of time, the data symbols to be transmitted at an average per symbol power level that is at least 50 percent lower than the average per beacon symbol power level of beacon symbols transmitted. 44. The portable wireless terminal of claim 41, wherein said beacon transmission time period is an uninterrupted contiguous time period including multiple sequential occurring symbol transmission time periods. 45. The portable wireless terminal of claim 44, wherein at least some different beacon signal bursts transmitted in a sequence of beacon signal bursts have periods of different lengths. 46. The portable wireless terminal of claim 41, further comprising: means for controlling transmission power, and wherein the means for controlling transmission power controls the average per symbol transmission power level of each beacon symbol transmitted during a first period of time to be at least 10 dB higher than the average per symbol transmission power level of symbols used to transmit user data during said first period of time. 47. The portable wireless terminal of claim 41, wherein said means for transmitting includes means for performing OFDM transmission, and wherein said beacon symbols are transmitted using OFDM tone symbols, said beacon symbols occupying less than 1 percent of the tone symbols of a transmission resource used by said wireless terminal during a period of time including multiple beacon signal bursts. 48. A non-transitory computer readable storage medium embodying machine executable instruction for controlling a portable wireless terminal in a wireless communications system, the non-transitory computer readable medium comprising: instructions for causing the portable wireless terminal to transmit a beacon signal burst during a beacon transmission time period in accordance with a timing structure including said beacon transmission time period and a beacon receive time period which recur in accordance with said timing structure, said beacon receive time period being longer than said beacon transmission time period, said beacon signal burst including one or more beacon symbols, each beacon symbol occupying a beacon symbol transmission unit; andinstructions for causing the portable wireless terminal to monitor for beacon signals from other devices during said beacon receive time period in accordance with said timing structure, said other devices including a second wireless terminal;instructions for causing the portable wireless terminal to transmit data symbols using OFDM symbol transmission units during a user data time period which occurs in said timing structure following said beacon receive time period, said user data time period being distinct from said beacon receive time period in said timing structure; andwherein said timing structure is used by both the first and second wireless terminals but with the start of the timing structure used by the first wireless terminal being offset from the start of the timing of the timing structure used by the second wireless terminal by an amount which is greater than the duration of the beacon transmission time period and less than the duration of the beacon receive time period and the start of the of the beacon transmission time period of the second wireless terminal following the end of the beacon transmission time period of the first wireless terminal by an amount which is less than the duration of the beacon transmission time period. 49. The non-transitory computer readable storage medium of claim 48 further embodying machine executable instructions for: controlling the transmission power level used for transmitting the beacon signal burst, wherein the transmission power is from a battery power source; andwherein said beacon symbols each have a duration of 3 or 4 OFDM symbol times. 50. The non-transitory computer readable storage medium of claim 48, further embodying machine executable instructions for: controlling the transmission, during a first time interval, of user data in addition to said beacon symbols, said user data being transmitted using data symbols transmitted at an average per symbol power level that is at least 50 percent lower than the average per beacon symbol power level of beacon symbols transmitted during said first time interval. 51. The non-transitory computer readable storage medium of claim 48, wherein said beacon transmission time period is an uninterrupted contiguous time period including multiple sequential occurring symbol transmission time periods. 52. An apparatus comprising: a first communications device processor configured to: control wireless transmission of a beacon signal burst from a first communications device during a beacon transmission time period in accordance with a timing structure including said beacon transmission time period and a beacon receive time period which recur in accordance with said timing structure, said beacon receive time period being longer than said beacon transmission time period, each beacon signal burst including one or more beacon symbols, each beacon symbol occupying a beacon symbol transmission unit;control monitoring for beacon signals from other devices during said beacon receive time period in accordance with said timing structure, said other devices including a second wireless terminal;control a transmitter to transmit data symbols using OFDM symbol transmission units during a user data time period which occurs in said timing structure following said beacon receive time period, said user data time period being distinct from said beacon receive time period in said timing structure; andwherein said timing structure is used by both the first and second communications devices but with the start of the timing structure used by the first communications device being offset from the start of the timing of the timing structure used by the second communications device by an amount which is greater than the duration of the beacon transmission time period used by said first and second communications devices and less than the duration of the beacon receive time period and the start of the of the beacon transmission time period of the second wireless terminal following the end of the beacon transmission time period of the first wireless terminal by an amount which is less than the duration of the beacon transmission time period. 53. The apparatus of claim 52, wherein said processor is further configured to: control transmission power levels used for transmitting the beacon signal burst, said transmission power being from a battery power source; andwherein said beacon symbols each have a duration of 3 or 4 OFDM symbol times. 54. The apparatus of claim 52, wherein said processor is further configured to: control wireless transmission, during a first time interval, of user data in addition to said beacon symbols, said user data being transmitted using data symbols transmitted at an average per symbol power level that is at least 50 percent lower than the average per beacon symbol power level of beacon symbols transmitted during said first time interval. 55. The apparatus of claim 52, wherein said beacon transmission time period is an uninterrupted contiguous time period including multiple sequential occurring symbol transmission time periods. 56. The method of claim 1, wherein each beacon symbol has a duration longer than the duration of an OFDM symbol transmission unit. 57. The portable wireless terminal of claim 21, wherein each beacon symbol has a duration longer than the duration of an OFDM symbol transmission unit. 58. The portable wireless terminal of claim 41, wherein each beacon symbol has a duration longer than the duration of an OFDM symbol transmission unit. 59. The non-transitory computer readable medium of claim 48, wherein each beacon symbol has a duration longer than the duration of an OFDM symbol transmission unit. 60. The apparatus of claim 52, wherein each beacon symbol has a duration longer than the duration of an OFDM symbol transmission unit. 61. The method of claim 1, wherein said timing structure includes a single beacon receive time period for each beacon transmission time period included in said timing structure. 62. The method of claim 61, wherein each beacon receive time period in said timing structure follows a corresponding beacon transmission time period. 63. The method of claim 1, wherein said beacon signal burst includes two beacon symbols separated in time by a plurality of symbol time periods, no receive time periods occurring between said two beacon symbols. 64. The method of claim 1, wherein said beacon receive time period immediately follows said beacon transmit time period in said timing structure; andwherein said user data time period immediately follows said beacon receive time period in said timing structure. 65. The method of claim 1, wherein said user data time period is a time period in which said first wireless terminal can receive user data, the number of user data time periods in said timing structure in which said first wireless terminal can receive user data from another device being the same as the number of beacon receive time periods in said timing structure and wherein the number of beacon transmit time periods in which the first wireless terminal can transmit is equal to said number of user data time periods in said timing structure in which the first wireless terminal can receive user data, said user data time period being a distinct time period which does not overlap said beacon receive time period. 66. The method of claim 1, wherein said timing structure includes the beacon transmission time period which is immediately followed by the beacon receive time, the beacon receive time period being immediately followed by said user data time period, said user data time period being immediately followed by a silence time period; andwherein said recurring timing structure includes a single one of each of said beacon transmission time period, said beacon receive time period, said user data time periods and said silence time period. 67. The method of claim 5, wherein said beacon transmission time period does not include a beacon receive time period or a user data receive time period. 68. The method of claim 1, wherein each time period defined in said timing structure used by the first and second wireless terminals is of the same duration for the first and second wireless terminals.
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Stanforth,Peter, Ad hoc peer-to-peer mobile radio access system interfaced to the PSTN and cellular networks.
Laroia, Rajiv; Li, Junyi; Lane, Frank A., Base station base methods and apparatus for supporting break before making handoffs in a multi-carrier system.
Tanishima Yasuo,JPX ; Mashima Rikihiko,JPX ; Yamashita Atsushi,JPX ; Sogo Hiroyuki,JPX ; Seta Mitsuru,JPX ; Ishikawa Hitoshi,JPX ; Kubo Tsudoi,JPX ; Shirota Masahiko,JPX ; Hamada Yutaka,JPX, Base transceiver station and subscriber unit in wireless local loop system using personal handy-phone system and method for operating same.
Erlick, John Richard; Hanson, Duke Edward; Hogberg, Shawn; Eteminan, Isaac, Communications unit for seamless handover between networks and method of use therefor.
Delprat Marc (Le Chesnay FRX) Gourgue Frederic (Paris FRX) Pequet Eric (Jamioulx BEX), Dummy burst structure in a cellular digital radio-communications system using the TDMA principle, and a base station for.
Hansen, Christopher J.; Trachewsky, Jason A.; Moorti, R. Tushar; Fischer, Matthew J.; Young, Christopher, MIMO wireless communication greenfield preamble formats.
Ault Jan C. ; Williamson Paul T. ; Peer Ilan ; Isaac Jennifer A. ; Holcman Alejandro R. ; Bayley Gwain, Method and apparatus for system determination in a multi-mode subscriber station.
Ramaswamy, Venkateshwaran; Dyck, Jeffrey Alan; Devara, Kavitha Vallari; Nookala, Sriram Nagesh, Method and apparatus for updating mobile Ip data connectivity on transitions between wireless networks.
Cain,Joseph Bibb, Method and device for establishing communication links and for estimating overall quality of a directional link and reporting to OLSR in a communication system.
Sorrells,David F.; Bultman,Michael J.; Cook,Robert W.; Looke,Richard C.; Moses, Jr.,Charley D., Method and system for frequency up-conversion with modulation embodiments.
Doyle,James T.; Maksimovic,Dragan, Method and system for minimizing power consumption in mobile devices using cooperative adaptive voltage and threshold scaling.
Sharma,Sanjeev K., Method and system for synchronizing two end terminals using beacon synchronization with multiple channels in a wireless local area network.
Lee Steven G. (Elgin IL) Iehl Brian D. (Hoffman Estates IL) Manya Omer (Palatine IL) Schellinger Michael J. (Vernon Hills IL) D\Avello Robert F. (Lake Zurich IL), Method for adjusting reference frequencies in a communication system.
Gerlach, Christian Georg; Buné, Paul A. M.; Litzenburger, Manfred, Method for subcarrier allocation and modulation scheme selection in wireless multicarrier transmission system.
Mayor, Michael A.; Rasmussen, Donald J.; Whitehill, Eric A.; Simmons, Charles A.; McCrady, Dennis, Methods and apparatus for organizing selection of operational parameters in a communication system.
Centore, III,Michael A., Methods and apparatus for utilizing radio frequency spectrum simultaneously and concurrently in the presence of co-channel and/or adjacent channel television signals by adjusting transmitter power or.
Hansson,Bj?rn; Jendbro,Magnus, Methods, servers, mobile stations, and computer program products using GPS referenced time and delay information in messages for GPS time assistance.
Umeda,Hidekazu, Multi-hop peer-to-peer telecommunications method in a wireless network, radio terminal telecommunications method, and medium recording a program for causing a processor to implement the radio termina.
Goodall, David S.; Ryan, Philip J.; Myles, Andrew F.; de Souza, Ludovico N., Selecting an access point according to a measure of received signal quality.
Laroia, Rajiv; Li, Junyi; Rangan, Sundeep; Uppala, Sathyadev Venkata, Signal construction, detection and estimation for uplink timing synchronization and access control in a multi-access wireless communication system.
Narasimhan,Ravi; Wong,Piu Bill; Scherzer,Shimon B.; Wu,Jiangfeng, Space-time and space-frequency hopping for capacity enhancement of mobile data systems.
Hasty, Jr., William V.; Baenen, Charles E.; Welsh, Shawn P., System and method for auto-configuration and discovery of IP to MAC address mapping and gateway presence in wireless peer-to-peer ad-hoc routing networks.
Hottinen, Ari; Teittinen, Marko; Sunay, M. Oguz, System and method for effecting information transmission and soft handoff between frequency division duplex and time division duplex communications systems.
Periyalwar, Shalini; Zhang, Hang; Senarath, Nimal; Yu, Derek; Au, Kelvin Kar Kin; Mann, Karl, System and method for peer-to-peer communication in cellular systems.
Masood, Garahi; Elkington, William C., System and method for providing wireless telematics store and forward messaging for peer-to-peer and peer-to-peer-to-infrastructure a communication network.
Bohnke, Ralf; Izumi, Seiichi, Transmission method and transmission apparatus for transmitting signals on the basis of a OFDM/TDMA-system with pilot symbols.
Cheng, Terry Si-Fong; Huang, Ching; Koo, Yuen-Yin L.; Lin, Shen-De; Weaver, Carl Francis; Kuo, Wen-Yi, Triggering handdowns and handoffs of mobile stations between bordering cells of cellular wireless communication systems.
Iwasaki,Jun; Sugaya,Shigeru; Konya,Satoshi; Mizoguchi,Yasuhiko; Iwami,Hideki, Wireless communication system, wireless communication apparatus, and wireless communication method.
Sakoda, Kazuyuki; Nishikawa, Kenzo; Morioka, Yuichi; Suzuki, Mitsuhiro, Wireless communication system, wireless communication apparatus, wireless communication method and computer program.
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