Baseband wireless network for isochronous communication
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A04Q-007/00
H04J-003/00
H04B-007/212
출원번호
US-0393126
(1999-09-10)
발명자
/ 주소
Aiello,Roberto
Gehring,Stephan
Lynch,William
Rahardja,Krisnawan K.
Rogerson,Gerald
Sparell,Carlton J.
출원인 / 주소
Pulse LINK, Inc.
대리인 / 주소
Pulse LINK, Inc
인용정보
피인용 횟수 :
47인용 특허 :
145
초록▼
A wireless communication network system apparatus which provides for isochronous data transfer between node devices of the network, which provides at least one master node device which manages the data transmission between the other node devices of the network, which avoids or reduces interference f
A wireless communication network system apparatus which provides for isochronous data transfer between node devices of the network, which provides at least one master node device which manages the data transmission between the other node devices of the network, which avoids or reduces interference from other wireless products and which resolves random errors associated with wireless technology including multipath fading. The system provides a communication protocol which shares the wireless transport medium between the node devices of the network, and which provides each node device on the network a designated transmit time slot for data communication.
대표청구항▼
What is claimed is: 1. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured
What is claimed is: 1. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured to manage data transmission between said transceivers, and a Medium Access Control hardware interface comprising a multiplexer/demultiplexer unit and a plurality of slot allocation units, said multiplexer/demultiplexer unit operatively coupled to said plurality of slot allocation units, wherein said transceivers operate according to a Medium Access Control protocol having a time division multiple access frame definition, said protocol structured and configured to operate in aloha mode and time division multiple access mode. 2. The system of claim 1, further comprising a frame definition having a master slot, a command slot, and a plurality of data slots, said master having a master sync code, a protocol operating in slotted aloha mode and time division multiple access mode, said master device managing said protocol and said data slots in said protocol. 3. The system of claim 2, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses. 4. The system of claim 3, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 5. The system of claim 4, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 6. The system of claim 2, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band wireless technology and said receivers are structured and configured to receive radio frequency pulses. 7. The system of claim 6, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 8. The system of claim 7, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 9. An ultra-wideband wireless communication network system comprising at least three transceivers each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured to manage data transmission between said transceivers, and a Medium Access Control hardware interface comprising a multiplexer/demultiplexer unit and a plurality of slot allocation units, said multiplexer/demultiplexer unit operatively coupled to said plurality of slot allocation units, and a frame definition having a master slot, a command slot, and a plurality of data slots, said master having a master sync code, a protocol operating in slotted aloha mode and time division multiple access mode, said master device managing said protocol and said data slots in said protocol. 10. The system of claim 9, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses. 11. The system of claim 10, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 12. The system of claim 11, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 13. The system of claim 9, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band wireless technology and said receivers are structured and configured to receive radio frequency pulses. 14. The system of claim 13, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 15. The system of claim 14, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 16. The system of claim 1, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses. 17. The system of claim 16, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 18. The system of claim 17, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 19. The system of claim 1, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band wireless technology and said receivers are structured and configured to receive radio frequency pulses. 20. The system of claim 19, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 21. The system of claim 20, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 22. The system of claim 1, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 23. The system of claim 22, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 24. The system of claim 1, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 25. The system of claim 22, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses. 26. The system of claim 25, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 27. An ultra-wideband wireless communication network system, comprising: at least three transceivers, one of which is structured and configured as a master device to manage data transmission between said transceivers; a transmitter in each said transceiver; a receiver in each said transceiver; and a Medium Access Control unit including a Physical layer interface, a multiplexer/demultiplexer unit operatively coupled to said Physical layer interface, a plurality of slot allocation units operatively coupled to said multiplexer/demultiplexer, an interface to higher level protocols operatively coupled to said plurality of slot allocation units. 28. The system of claim 27, wherein said master device includes a time division multiple access frame definition and a framing control function to frame data transmission between said transceivers. 29. The system of claim 28, wherein said transceivers operate according to a time division multiple access frame definition to synchronize said network system. 30. The system of claim 29, wherein each said transceiver further comprises: (a) a data modulator; and (b) a data demodulator. 31. The system of claim 30, further comprising a time division multiple access frame structure having a master slot, a command slot, and a plurality of data slots. 32. The system of claim 27, wherein said transceivers operate according to a time division multiple access frame definition to synchronize said network system. 33. The system of claim 32, wherein each said transceiver further comprises: (a) a data modulator; and (b) a data demodulator. 34. The system of claim 33, further comprising a time division multiple access frame structure having a master slot, a command slot, and a plurality of data slots. 35. The system of claim 34, wherein each said transceiver further comprises: (a) a data modulator; and (b) a data demodulator. 36. The system of claim 34, further comprising a time division multiple access frame structure having a master slot, a command slot, and a plurality of data slots. 37. The system of claim 27, further comprising a time division multiple access frame structure having a master slot, a command slot, and a plurality of data slots. 38. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and said master device structured and configured to manage data transmission between said transceivers, wherein each said transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transceivers operate according to a Medium Access Control protocol having a time division multiple access frame definition, said protocol structured and configured to operate in aloha mode and time division multiple access mode, said system further comprising a frame definition having a master slot, a command slot, and a plurality of data slots, said master device having a master sync code, a protocol operating in slotted aloha mode and time division multiple access mode, said master device managing said protocol and said data slots in said protocol, and a Medium Access Control hardware interface comprising a multiplexer/demultiplexer unit and a plurality of slot allocation units, said multiplexer/demultiplexer unit operatively coupled to said plurality of slot allocation units. 39. The system of claim 38, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses. 40. The system of claim 39, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 41. The system of claim 40, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 42. An ultra-wideband wireless communication network system comprising at least three transceivers, with each transceiver including a Medium Access Control protocol having a time division multiple access frame definition, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, said master device structured and configured to manage direct data transmission between said at least three transceivers, wherein each transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band technology and said receivers are structured and configured to receive said radio pulses. 43. The system of claim 42, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 44. The system of claim 43, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 45. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and said master device structured and configured to manage data transmission between said transceivers, wherein each said transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, said system further comprising a frame definition having a master slot, a command slot, and a plurality of data slots, said master device having a master sync code, a protocol operating in slotted aloha mode and time division multiple access mode, said master device managing said protocol and said data slots in said protocol. 46. The system of claim 45, further comprising a Medium Access Control hardware interface comprising a multiplexer/demultiplexer unit and a plurality of slot allocation units, said multiplexer/demultiplexer unit operatively coupled to said plurality of slot allocation units. 47. The system of claim 46, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses. 48. The system of claim 47, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 49. The system of claim 48, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 50. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured to manage data transmission between said transceivers, wherein each said transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transceivers operate according to a Medium Access Control protocol having a time division multiple access frame definition, said protocol structured and configured to operate in aloha mode and time division multiple access mode, and further, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band wireless technology and said receivers are structured and configured to receive radio frequency pulses. 51. The system of claim 50, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 52. The system of claim 51, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 53. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured to manage data transmission between said transceivers, wherein each said transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, said system further comprising a Medium Access Control hardware interface comprising a multiplexer/demultiplexer unit and a plurality of slot allocation units, said multiplexer/demultiplexer unit operatively coupled to said plurality of slot allocation units. 54. The system of claim 53, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses. 55. The system of claim 54, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 56. The system of claim 55, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 57. The system of claim 53, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band wireless technology and said receivers are structured and configured to receive radio frequency pulses. 58. The system of claim 57, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 59. The system of claim 58, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 60. An ultra-wideband wireless communication network system comprising at least three transceivers, with each transceiver including a Medium Access Control protocol having a time division multiple access frame definition, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured to manage data transmission between said transceivers, wherein each said transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses, and further wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 61. The system of claim 60, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 62. An ultra-wideband wireless communication network system comprising at least three transceivers, with each transceiver including a Medium Access Control protocol having a time division multiple access frame definition, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, said master device structured and configured to manage direct data transmission between said at least three transceivers, wherein each transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band technology and said receivers are structured and configured to receive said radio pulses. 63. The system of claim 62, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 64. The system of claim 63, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 65. An ultra-wideband wireless communication network system comprising at least three transceivers, with each transceiver including a Medium Access Control protocol having a time division multiple access frame definition, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, said master device structured and configured to manage direct data transmission between said at least three transceivers, wherein each transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 66. The system of claim 65, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 67. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and said master device structured and configured to manage data transmission between said transceivers, wherein other transceivers of said at least three transceivers being structured and configured as slave transceivers, each of said slave transceivers further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized to said master clock, wherein said transceivers operate according to a Medium Access Control protocol structured and configured to operate in aloha mode and time division multiple access mode, said system further comprising a frame definition having a master slot, a command slot, a plurality of data slots, said master device having a master sync code, a protocol operating in slotted aloha mode and time division multiple access mode, said master device managing said protocol and said data slots in said protocol, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers structured and configured to receive radio frequency pulses, and further wherein said transceivers are structured and configured to transfer data to other transceivers isochronously. 68. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured to manage data transmission between said transceivers, wherein each said stave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock, wherein said transceivers operate according to a Medium Access Control protocol having a time division multiple access frame definition, said protocol structured and configured to operate in aloha mode and time division multiple access mode, said system further comprising a frame definition having a master slot, a command slot, and a plurality of data slots, said master having a master sync code, a protocol operating in slotted aloha mode and time division multiple access mode, said master device managing said protocol and said data slots in said protocol, and further, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band wireless technology and said receivers are structured and configured to receive radio frequency pulses. 69. The system of claim 68, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 70. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured to manage data transmission between said transceivers, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock, said system further comprising a frame definition having a master slot, a command slot, and a plurality of data slots, said master having a master sync code, a protocol operating in slotted aloha mode and time division multiple access mode, said master device managing said protocol and said data slots in said protocol, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses, and further, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 71. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured to manage data transmission between said transceivers, wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock, said system further comprising a frame definition having a master slot, a command slot, and a plurality of data slots, said master having a master sync code, a protocol operating in slotted aloha mode and time division multiple access mode, said master device managing said protocol and said data slots in said protocol, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band wireless technology and said receivers are structured and configured to receive radio frequency pulses. 72. The system of claim 71, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously. 73. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, said master device structured and configured to manage direct data transmission between said at least three transceivers, wherein each transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band technology and said receivers are structured and configured to receive said radio pulses, and wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously, and wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 74. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, and master device structured and configured to manage data transmission between said transceivers, wherein each said transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transmitters are structured and configured to emit radio frequency pulses operating with baseband wireless technology and said receivers are structured and configured to receive radio frequency pulses, and further wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously, and wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 75. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, said master device structured and configured to manage direct data transmission between said at least three transceivers, wherein each transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transmitters are structured and configured to emit radio frequency pulses operating with ultra-wide band technology and said receivers are structured and configured to receive said radio pulses, and wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously, and wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock. 76. An ultra-wideband wireless communication network system comprising at least three transceivers, each said transceiver having a transmitter and a receiver, one of said transceivers being structured and configured as a master device, said master device structured and configured to manage direct data transmission between said at least three transceivers, wherein each transceiver further comprises a framing controller, said framing controller having means for generating and maintaining time frame information for said network system, wherein said transceivers are structured and configured to transfer data to other said transceivers isochronously, and wherein each said slave transceiver further comprises a local clock therein, said master transceiver further comprising a master clock therein, each said local clock synchronized with said master clock.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (145)
Hodzic Migdat I. ; Brennan James M., Adaptive digital wireless communications network apparatus and process.
Watanabe Fujio,FIX ; Buot Theodore,FIX ; Kuntze Roland,FIX ; Jokela Jari,FIX, Apparatus, and associated method for selecting a size of a contention window for a packet of data system.
Chuah Mooi Choo, Bandwidth reservation and collision resolution method for multiple access communication networks where remote hosts send reservation requests to a base station for randomly chosen minislots.
Hester Phillip (Indian Harbour Beach FL) Highsmith William (Indialantic FL) McDaniel Don (Indialantic FL) Lusk Alan (Dallas TX), Communication network with divisible auxilliary channel allocation.
Wolfe William H. (Burke VA) Osborne William P. (Leesburg VA), Demand assigned reformatting with an overflow area for time division multiple access communication.
Cho, Dong-Ho; Park, Seong-Soo; Kim, Sun-Mi, Device and method for controlling channel access by access slot reserving in a mobile communication system.
Wellig, Armin; Kuntze, Roland; Salokannel, Juha, Direct mode communication method between two mobile terminals in access point controlled wireless LAN systems.
Scott Charles Evans ; John Erik Hershey ; David Michael Davenport ; Harold Woodruff Tomlinson, Jr. ; Ralph Thomas Hoctor ; Kenneth Brakeley Welles, II ; Stephen Michael Hladik, Integrated wireless broadband communications network.
Frodigh Carl Magnus,SEX ; Hook Mikael,SEX ; Muller Frank,SEX ; Schramm Peter,DEX ; Skold Johan,SEX, Link adaptation method for links using modulation schemes that have different symbol rates.
Gross Kevin P. ; Anderson Charles W. ; Lieb Derek W. ; Rosenboom Gerrit E. ; Lowe William W., Media access control for isochronous data packets in carrier sensing multiple access systems.
Bauchot Frederic Jacques (St. Jeannet FRX) Lefevre Frederic Bernard (Cagnes sur Mer FRX) Revardel Luc Louis (La Gaude FRX), Medium access control scheme for wireless LAN using a variable length interleaved time division frame.
Dail James E. ; Li Chia-Chang ; Magill Peter D. ; Sriram Kotikalapudi, Method and apparatus enabling enhanced throughput efficiency by use of dynamically adjustable mini-slots in access prot.
Doshi Bharat Tarachand ; Dravida Subrahmanyam ; Kustka George John ; Magill Peter D. ; Siller Curtis A. ; Sriram Kotikalapudi, Method and apparatus enabling multiple access for multiple services and multiple transmission modes over a broadband communication network utilizing an adaptive digital access protocol.
Rybicki Mathew A. ; Jackson H. Spence ; Markison Timothy W. ; Kodra Gregg S. ; Margules Michael A., Method and apparatus for pulse position modulation.
Rybicki Mathew A. ; Jackson H. Spence ; Markison Timothy W. ; Kodra Gregg S. ; Margules Michael A., Method and apparatus of pulse position demodulation.
Matthew Paul Wakeley ; George McDavid, Method and system for negotiation of the highest common link rate among nodes of a fibre channel arbitrated loop.
Geiger Edward W. ; Fickes Stanley L. ; Mincher Richard W. ; Mullins Jeffrey L., Method and system for synchronization in a wireless local area network.
Gleeson Bryan J. (19400 Sorensen Ave. #206 Cupertino CA 95014) Altmaier Paulette R. (22605 Salem Ave. Cupertino CA 95014), Method for reducing unnecessary traffic over a computer network.
Takiyasu Yoshihiro (Higashimurayama JPX) Amada Eiichi (Tokyo JPX) Jusa Hidehiko (Higashimurayama JPX) Ishifuji Tomoaki (Tokyo JPX) Adachi Shuichi (Hadano JPX) Ishii Genichi (Hachioji JPX), Method of wireless communication between base station and mobile station and multiple access communication system.
Barrett Terence W. (1453 Beulah Rd. Vienna VA 22182), Oscillator-shuttle-circuit (OSC) networks for conditioning energy in higher-order symmetry algebraic topological forms a.
Kim Anderson H. (Toms River NJ) Weiner Maurice (Ocean NJ) Jasper ; Jr. Louis J. (Fulton MD) Youmans Robert J. (Brick NJ), Pulse sharpening using an optical pulse.
Ross Gerald F. (Longboat Key FL) Mara Richard M. (Tewskbury MA) Rollins Kenneth W. (North Reading MA), Short pulse microwave source with a high PRF and low power drain.
Paneth Eric,ILX ; Handzel Mark J. ; Morley Steven Allan ; Avis Graham M., Subscriber RF telephone system for providing multiple speech and/or data signals simultaneously over either a single or a plurality of RF channels.
Bisdikian Chatschik, System and a method for continuously adjustable, splitting group, multi-contention resolution in multi-access computer communication systems.
Gilhousen Klein S. ; Jacobs Irwin M. ; Padovani Roberto ; Weaver ; Jr. Lindsay A. ; Wheatley ; III Charles E. ; Viterbi Andrew J., System and method for generating signal waveforms in a CDMA cellular telephone system.
Richards James L. ; Kelly Donald A. ; Finn James S. ; Meigs David C. ; Welch ; Jr. William D., System and method for person or object position location utilizing impulse radio.
Takashi Kawabata JP; Youichi Moritani JP; Tomokazu Hamada JP; Tohru Sogabe JP, TDMA radio communication system achieving simultaneous assignment of channels to multiple terminal stations.
Morgan Harry C. (2720 E. Ponderosa ; Apt. 76 Camarillo CA 93010) Boyd William H. (3486 West Farrell Cr. Newbury Park CA 91320), Transmission of electronic information by pulse position modulation utilizing low average power.
Barrett Terence W. (1453 Beulah Rd. Vienna VA 22182), Ultrafast time hopping CDMA-RF communications: code-as-carrier, multichannel operation, high data rate operation and dat.
Cannon, Joseph M.; Mooney, Philip D., Adjustment of period of real-time slow drift correction of alignment of handset's local oscillator for a cordless telephone.
Sugaya, Shigeru; Takamura, Kazuhisa; Suzuki, Mitsuhiro, Communications system, communications control apparatus and method, and computer program therefor.
Sugaya,Shigeru; Takamura,Kazuhisa; Suzuki,Mitsuhiro, Communications system, communications control apparatus and method, and computer program therefor.
Jones,DeLon K., Method and apparatus for aligning the clock signals of transceivers in a multiple access communication system utilizing programmable, multi-tap phase-locked loops.
Kim, Soeng-Hun; Van Lieshout, Gert Jan; Jeong, Kyeong-In; Van Der Velde, Himke, Method and apparatus for buffer status report in mobile communication system.
Kim, Soeng-Hun; Van Lieshout, Gert Jan; Jeong, Kyeong-In; Van Der Velde, Himke, Method and apparatus for buffer status report in mobile communication system.
Kim, Soeng-Hun; Van Lieshout, Gert; Jeong, Kyeong-In; Van Der Velde, Himke, Method and apparatus for buffer status report in mobile communication system.
Gherardi, Luca; D'Andrea, Raffaello; Hehn, Markus; Waibel, Markus, Methods and systems for scheduling the transmission of localization signals and operating self-localizing apparatus.
Gherardi, Luca; D'Andrea, Raffaello; Hehn, Markus; Waibel, Markus, Methods and systems for scheduling the transmission of localization signals and operating self-localizing apparatus.
Roy,Subhash C.; Toebes,David K.; Renault,Michael M.; Benoit,Steven E.; Zhovnirovsky,Igor, Phase and frequency drift and jitter compensation in a distributed telecommunications switch.
Melick, Bruce D.; Snyder, David M.; Baych, Leslie D.; Probst, Gregory P.; Kennedy, Philip T., System and method for storing/caching, searching for, and accessing data.
Melick, Bruce D.; Snyder, David M.; Baych, Leslie D; Probst, Gregory P.; Kennedy, Philip T., System and method for storing/caching, searching for, and accessing data.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.