Configuration of overhead channels in a mixed bandwidth system
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04B-007/00
H04Q-007/00
H04Q-007/20
출원번호
US-0298798
(1999-04-23)
§371/§102 date
20031001
(20031001)
발명자
/ 주소
Jou, Yu-Cheun
출원인 / 주소
Qualcomm, Incorporated
인용정보
피인용 횟수 :
11인용 특허 :
43
초록▼
A method and apparatus for transmitting broadcast information in a multi-carrier communication system. The Sync Channel of the multi-carrier system is transmitted a 1.25 MHz channel bandwidth (i.e., over a single carrier), and to specify the preferred channels for the Sync Channel transmission inste
A method and apparatus for transmitting broadcast information in a multi-carrier communication system. The Sync Channel of the multi-carrier system is transmitted a 1.25 MHz channel bandwidth (i.e., over a single carrier), and to specify the preferred channels for the Sync Channel transmission instead of the preferred channels for the entire multi-carrier system. The Sync Channel Message will carry additional information indicating the center frequency of a multi-carrier system within a reserved set of frequency bands and indicating the frequency of a single carrier system in the reserved set of frequency bands. Considering the A block of the PCS band again, the preferred channels for Sync Channel transmission can be selected as channels 75, 150 and 225. This selection ensures that one of the preferred channels will always be used by any multi-carrier system regardless of the location of its center channel.
대표청구항▼
1. A multi-frequency channel base station operating within a predetermined set of frequency channels wherein data components of forward link data are transmitted simultaneously on a plurality of frequency bands each band representing a frequency channel and having a carrier frequency, comprising:a f
1. A multi-frequency channel base station operating within a predetermined set of frequency channels wherein data components of forward link data are transmitted simultaneously on a plurality of frequency bands each band representing a frequency channel and having a carrier frequency, comprising:a first transmission subsystem for transmitting a sync channel message on a single frequency channel of said predetermined set of frequency channels, wherein said sync channel message indicates one of a center frequency channel of a multi-channel system and a single channel system, wherein the center frequency channel is used for reception of signals by a device receiving the sync channel message and is one of a set of a preferred frequency channels that correspond to a plurality of frequency bands that are arranged such that any combination of three adjacent bands includes the center frequency channel; and at least one additional transmission subsystem for transmitting remaining components of said forward link data on another frequency channel of said predetermined set of frequency channels. 2. The base station of claim 1 wherein said sync channel message indicates the frequency channel of a single channel system in said predetermined set of frequency channels.3. The base station of claim 1 wherein said sync channel message is transmitted on one of the set of a preferred frequency channels wherein the number of channels is less than the number of channels in said predetermined set of frequency channels.4. The base station of claim 3 wherein said set of predetermined frequency channels are the set of frequency channels in a personal communications system block of frequency channels.5. The base station of claim 4 wherein the channel numbers of the set of preferred frequency channels are 75, 150 and 225.6. A multi-frequency channel mobile station comprising:a control processor for controlling the operation of a plurality of receiver subsystems in accordance with frequency information indicated in a received sync channel message, wherein said sync channel message indicates one of a center frequency channel of a multi-channel system and a single channel system, wherein the center frequency channel is used for reception of signals by the mobile station and is one of a set of a preferred frequency channels that correspond to a plurality of frequency bands that are arranged such that any combination of three adjacent bands includes the center frequency channel; a first receiver subsystem for receiving said sync channel message on a single frequency channel and for providing said sync channel message to said control processor and for receiving a first portion of a multi-channel signal; and at least one additional receiver subsystem for receiving additional portions of said multi-channel signal. 7. The mobile station of claim 6 wherein said control processor decides whether to operate in a single frequency channel mode or a multi-frequency channel mode and directs said first receiver subsystem to tune to a frequency channel indicated in said sync channel message for the reception of a single channel system when said mobile station decides to operate in a single frequency channel mode and directs said at least one additional receiver subsystem to tune to at least one additional frequency channel when said mobile station decides to operate in a multi-frequency channel mode.8. The mobile station of claim 6 wherein said control processor directs said first receiver subsystem to tune to one of a predetermined set of preferred frequency channels.9. The mobile station of claim 6 wherein said mobile station is operating within a personal communication system (PCS) set of frequency channels and wherein said predetermined set of preferred frequency channels consist of the frequency channel numbers 75, 150 and 225.10. A method of transmitting data components of forward link data in a communication system, comprising:transmitting a sync channel message on a single frequency channel within a predetermined set of frequency channels, wherein said sync channel message indicates one of a center frequency channel of a multi-channel system and a single channel system, wherein the center frequency channel is used for reception of signals by a device receiving the sync channel message and is one of a set of a preferred frequency channels that correspond to a plurality of frequency bands that are arranged such that any combination of three adjacent bands includes the center frequency channel; and transmitting remaining components of said forward link data on another frequency channel within said predetermined set of frequency channels. 11. The method of claim 10 wherein said sync channel message is transmitted on one of a set of a preferred frequency channels wherein the number of channels is less than the number of channels in said predetermined set of frequency channels.12. The method of claim 11 wherein said set of predetermined frequency channels are the set of frequency channels in a personal communications system block of frequency channels.13. The method of claim 12 wherein the channel numbers of the set of preferred frequency channels are 75, 150 and 225.14. A method of receiving data components of forward link data in a communication system, comprising:receiving a sync channel message and a first portion of a multi-channel signal on a single frequency channel, wherein said sync channel message indicates one of a center frequency channel of a multi-channel system and a single channel system, wherein the center frequency channel is used for reception of signals and is one of a set of a preferred frequency channels that correspond to a plurality of frequency bands that are arranged such that any combination of three adjacent bands includes the center frequency channel; controlling operation of a plurality of receiver subsystems in accordance with frequency information indicated in said received sync channel message; and receiving additional portions of said multi-frequency channel signal on another frequency channel. 15. The method of claim 14 further comprising deciding whether to operate in a single frequency channel mode or a multi-frequency channel mode and tuning to a frequency channel indicated in said sync channel message for the reception of a single frequency channel signal when deciding to operate in a single frequency channel mode and tuning to at least one additional frequency channel when deciding to operate in a multi-frequency channel mode.16. A multi-frequency channel base station operating within a predetermined set of frequency channels wherein data components of forward link data are transmitted simultaneously on a plurality of frequency bands each band representing a frequency channel and having a carrier frequency, said base station comprising:means for transmitting a sync channel message on a single frequency channel within a predetermined set of frequency channels, wherein said sync channel message indicates one of a center frequency channel of a multi-channel system and a single channel system, wherein the center frequency channel is used for reception of signals by a device receiving the sync channel message and is one of a set of a preferred frequency channels that correspond to a plurality of frequency bands that are arranged such that any combination of three adjacent bands includes the center frequency channel; and means transmitting remaining components of said forward link data on another frequency channel within said predetermined set of frequency channels. 17. The base station of claim 16 wherein said sync channel message is transmitted on one of a set of a preferred frequency channels wherein the number of channels is less than the number of channels in said predetermined set of frequency channels.18. The base station of claim 17 wherein said set of predetermined frequency channels are the set of frequency channels in a personal communications system block of frequency channels.19. The base station of claim 18 wherein the channel numbers of the set of preferred frequency channels are 75, 150 and 225.20. A multi-frequency channel mobile station comprising:means for controlling the operation of a plurality of receiver subsystems in accordance with frequency information indicated in a received sync carrier message, wherein said sync channel message indicates one of a center frequency channel of a multi-channel system and a single channel system, wherein the center frequency channel is used for reception of signals and is one of a set of a preferred frequency channels that correspond to a plurality of frequency bands that are arranged such that any combination of three adjacent bands includes the center frequency channel; means for receiving said sync channel message on single frequency channel and for providing said sync carrier message to said means for controlling and for receiving a first portion of a multi-channel signal; and means for receiving additional portions of said multi-frequency channel signal on another frequency channel. 21. The mobile station of claim 20 wherein said means for controlling decides whether to operate in a single frequency channel mode or a multi-frequency channel mode and directs said first receiver subsystem to a frequency channel indicated in said sync channel message for the reception of a single frequency channel signal when said mobile station decides to operate in a single frequency channel mode and directs said at least one additional receiver subsystem to tune to at least one additional frequency channel when deciding to operate in a multi-frequency channel mode.22. The mobile station of claim 20 wherein said means for controlling directs said first receiver subsystem to tune to one of a predetermined set of preferred frequency channels.23. The mobile station of claim 20 wherein said mobile station is operating within a personal communication system (PCS) set of frequency channels and wherein said predetermined set of preferred frequency channels consist of the frequency channel numbers 75, 150 and 225.24. An apparatus operable in at least one of a single carrier system and a multi-carrier system, comprising:a demultiplexer that demultiplexes a forward link signal into a forward link data stream comprising broadcast channel data including a sync channel message; a fist transmission subsystem, coupled to the demultiplexer, that transmits a first portion of the forward link data stream on a first carrier frequency; a second transmission subsystem, coupled to the demultiplexer, that transmits a second portion of the forward link data stream on a second carrier frequency; and a third transmission subsystem, coupled to the demultiplexer, that transmits a third portion of the forward link data stream on a third carrier frequency, wherein the synch channel message is transmitted on a preferred channel by a selected one of the first, second and third transmission subsystems for transmission at a selected one of the first, second and third carrier frequencies, and wherein the preferred channel is used for reception of signals by a device receiving the sync channel message and is one of a set of a preferred frequency channels that correspond to a plurality of frequency bands arranged such that any combination of three adjacent bands includes the preferred frequency channel. 25. The apparatus recited in claim 24, wherein the first transmission subsystem, comprises:a first modulator that modulates the forward link data signal; and a first up converter that receives modulated forward link data signal from the first modulator and up converts the modulated forward link data signal with the first carrier frequency to generate the first portion of time forward link data stream on the first carrier frequency. 26. The apparatus recited in claim 25, wherein the second transmission subsystem, comprises:a second modulator that modulates the forward link data signal; and a second up converter that receives modulated forward link data signal from the second modulator and up converts the modulated forward link data signal with the second carrier frequency to generate the second portion of the forward link data stream on the second carrier frequency. 27. The apparatus recited in claim 26, wherein the third transmission subsystem, comprises:a third modulator that modulates the forward link data signal; and a third up converter that receives modulated forward link data signal from the third modulator and up converts the modulated forward link data signal with the third carrier frequency to generate the third portion of the forward link data stream on the third carrier frequency. 28. The apparatus recited in claim 27, wherein the forward link data stream, further comprises:a pilot symbol stream; dedicated channel data for a specific mobile station; and a common channel message. 29. The apparatus recited in claim 28, wherein the common channel message comprises a plurality of common channel messages transmitted to at least a set of subscriber stations within a coverage area of the apparatus.30. The apparatus recited in claim 28, wherein the first modulator that modulates the forward link data signal, comprises:a first Walsh spreader that receives the pilot symbol stream and spreads the pilot symbol stream using a Walsh sequence. 31. The apparatus recited in claim 30, wherein the first modulator that modulates the forward link data signal, further comprises:a first message formatter that receives the synch channel message and generates a first act of cyclic redundancy check (CRC) bits and appends the first set of CRC bits to the sync channel message to produce a formatted synch channel message; a first encoder that encodes the formatted synch channel message with a first predetermined forward error correction coding algorithm and generates first encoded symbols; a first interleaver interleaves the first encoded symbols with a first predetermined interleaving format to generate first reordered symbols; and a second Walsh spreader that receives the first reordered symbols and spreads the first reordered symbols in accordance with a first predetermined code sequence to generate a first Walsh spread signal. 32. The apparatus recited in claim 31, wherein the second modulator that modulates the forward link data signal, comprises:a second message formatter that receives the common channel message and generates a second set of cyclic redundancy check (CRC) bits end appends the second set of CRC bits to the common channel message to produce a formatted common channel message; a second encoder that encodes the formatted common channel message with a second predetermined forward error correction coding algorithm and generates second encoded symbols; a second interleaver interleaves the second encoded symbols with a second predetermined interleaving format to generate second reordered symbols; and a third Walsh spreader that receives the second reordered symbols and spreads the second reordered symbols in accordance with a second predetermined code sequence to generate a second Walsh spread signal. 33. The apparatus recited in claim 32, wherein the third modulator that modulates the forward link data signal, comprises:a third message formatter that receives the dedicated channel data and generates a third set of cyclic redundancy check (CRC) bits and appends the third set of CRC bits to the dedicated channel data to produce a frame of dedicated channel data; a third encoder that encodes the frame of dedicated channel data with a third predetermined forward error correction coding algorithm and generates third encoded symbols; a third interleaver interleaves the third encoded symbols with a third predetermined interleaving format to generate third reordered symbols; and a fourth Walsh spreader that receives the third reordered symbols and spreads the third reordered symbols in accordance with a third predetermined code sequence to generate a third Walsh spread signal. 34. The apparatus recited in claim 32, further comprising:a complex PN despreader that despreads the Walsh spread pilot symbol stream, the first Walsh spread signal, the second Walsh spread signal and the third Walsh spread signal, with two separately generated pseudonoise (PN) sequences to generate complex PN spread data; and a transmitter that receives the complex PN spread data, and up converts, filters and amplifies the complex PN spread data. 35. The apparatus recited in claim 24, wherein channel numbers of the preferred channel comprise at least one of 75, 150 and 225.36. The apparatus recited in claim 35, wherein the sync channel message is only transmitted by a selected one of first, second and third modulators.37. The apparatus recited in claim 36, wherein the multicarrier system comprises a plurality of bands arranged such that any combination of three adjacent bands includes a preferred channel and wherein the sync channel message indicates the center frequency of a multi-carrier system in the current band of frequencies, if one exists.38. The apparatus recited in claim 37, wherein the sync channel message indicates the frequency of a single carrier system in the current set of frequency bands, if one exists.39. The apparatus recited in claim 24, wherein the sync channel message is distinguished from other channels of information by being spread by a unique first predetermined code sequence.
Sohner Harold K. (Richardson TX) Hoyloak Joel N. (Lucas TX) Spradling John T. (Van Alstyne TX), Communication system using spread spectrum and leaky transmission line.
Hustig Charles H. (Hudson WI) Ward Jeffrey L. (Hudson WI) Moses Donald W. (Minneapolis MN) Bradford Robert S. (Woodland Hills CA), Data and voice communications system.
Blakeney ; II Robert D. (San Diego CA) Weaver ; Jr. Lindsay A. (Boulder CO) Ziv Noam A. (San Diego CA) Williamson Paul T. (San Diego CA) Padovani Roberto (San Diego CA), Demodulation element assignment in a system capable of receiving multiple signals.
Kaufmann Hans (Gossau CHX) Kueng Roland (Wolfhausen CHX) Grob Urs (Goldach CHX) Welti Arnold (Brugg CHX), Digital radio transmission system for a cellular network, using the spread spectrum method.
Gilhousen Klein S. (San Diego CA) Padovani Roberto (San Diego CA) Wheatly ; III Charles E. (Del Mar CA), Diversity receiver in a CDMA cellular telephone system.
Dean Richard F. (Escondido CA) Antonio Franklin P. (Del Mar CA) Gilhousen Klein S. (Bozeman MT) Wheatley ; III Charles E. (Del Mar CA), Dual distributed antenna system.
Gilhousen Klein S. (San Diego CA) Padovani Roberto (San Diego CA) Wheatley ; III Charles E. (Del Mar CA), Method and apparatus for controlling transmission power in a CDMA cellular mobile telephone system.
Anja Klein DE; Michael Farber DE; Christian Luders DE, Method and radio communications system for assigning a frequency channel to a radio station and appropriate radio station.
Tiedemann ; Jr. Edward G. ; Terasawa Daisuke ; Sarkar Sandip ; Jou Yu-Cheun ; Odenwalder Joseph P. ; Shanbhag Abihijit ; Willenegger Serge,CHX, Method and system for handoff between an asynchronous CDMA base station and a synchronous CDMA base station.
Gilhousen Klein S. (San Diego CA) Padovani Roberto (San Diego CA) Wheatley ; III Charles E. (Del Mar CA), Method and system for providing a soft handoff in communications in a CDMA cellular telephone system.
Rydberg James T. (Hoffman Estates IL) Hallman Kenneth B. (Arlington Hts. IL), Method for assigning frequency channels in a cellular communication system and for identifying critical existing fixed m.
Yamada Jun (Yokohama GA JPX) Callahan Kevin (Norcross GA) Jacobs Charles A. (Woodstock GA), Method for automatic mode selection for a dual-mode telephone handset for use in a cellular mobile telephone system and.
Gilhousen Klein S. (San Diego CA) Jacobs Irwin M. (La Jolla CA) Weaver ; Jr. Lindsay A. (San Diego CA), Spread spectrum multiple access communication system using satellite or terrestrial repeaters.
Gilhousen Klein S. (San Diego CA) Jacobs Irwin M. (La Jolla CA) Padovani Roberto (San Diego CA) Weaver ; Jr. Lindsay A. (San Diego CA) Wheatley ; III Charles E. (Del Mar CA) Viterbi Andrew J. (La Jol, System and method for generating signal waveforms in a CDMA cellular telephone system.
Cho, Joon-Young; Lee, Ju-Ho; Jeong, Kyeong-In, Method and apparatus for transmitting and receiving common channel in a cellular wireless communication system supporting scalable bandwidth.
Nabar, Rohit U.; Zhang, Hongyuan; Palanivelu, Arul Durai Murugan; Lou, Hui-Ling; Wu, Songping, Methods and apparatus for adaptively selecting a communications mode in high frequency systems.
Nabar, Rohit U.; Zhang, Hongyuan; Palanivelu, Arul Durai Murugan; Lou, Hui-Ling; Wu, Songping, Methods and apparatus for adaptively selecting a communications mode in high frequency systems.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.