Configuration of overhead channels in a mixed bandwidth system
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04B-007/00
H04Q-007/38
H04J-003/06
출원번호
US-0879764
(2004-06-28)
등록번호
US-7486653
(2009-02-03)
발명자
/ 주소
Jou,Yu Cheun
출원인 / 주소
Qualcomm, Incorporated
대리인 / 주소
Rouse,Thomas
인용정보
피인용 횟수 :
0인용 특허 :
62
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▼
I claim: 1. A method of acquiring a sync channel by a mobile station in a mixed bandwidth communications system, said mobile station operable in at least one of a multi-carrier mode and a single carrier mode, comprising: tuning to a first preferred channel of a selected set of preferred channels; a
I claim: 1. A method of acquiring a sync channel by a mobile station in a mixed bandwidth communications system, said mobile station operable in at least one of a multi-carrier mode and a single carrier mode, comprising: tuning to a first preferred channel of a selected set of preferred channels; attempting to detect a pilot signal on the first preferred channel, wherein the pilot signal has a unique pilot signal offset; receiving a sync channel message, if the pilot signal is detected on the first preferred channel; tuning to a second preferred channel of the selected set of preferred channels, if the pilot signal is not detected on the first preferred channel; if the sync channel message is received, determining the center frequency of a multi-carrier system from the sync channel message in the current set of bands if one exists; and determining the location of a single carrier band in the current set of bands if one exists. 2. The method according to claim 1, wherein attempting to detect a pilot signal on the first preferred channel, wherein the pilot signal has a unique pilot signal offset, further comprises: searching possible PN offset hypotheses; and testing each PN offset hypothesis. 3. The method according to claim 2, wherein testing each PN offset hypothesis, further comprises: computing the correlation between the received signal on the first preferred channel within the preferred frequency band and each PN hypothesis being tested to determine if the received signal is the pilot signal having a unique pilot signal offset. 4. The method according to claim 3, wherein the pilot signal is not detected on the first preferred channel if the correlation energy for all PN hypotheses is less than a threshold value. 5. The method according to claim 4, wherein the pilot signal is detected on the first preferred channel when a sufficient correlation energy is detected between the received signal at the preferred channel frequency and a PN offset hypothesis. 6. The method according to claim 1, wherein the sync channel message is transmitted in a single 1��. band, and a frame boundary of a sync channel frame and an interleaver boundary are aligned with a short PN sequence used to spread the pilot channel signal such that upon detection of the pilot channel signal the sync channel message can be de-interleaved and decoded. 7. The method according to claim 1, wherein if the mobile station decides to operate in multi-carrier mode the mobile station uses the received Sync Channel message to determine the center frequency of a multi-carrier system in the current set of frequency bands if one exists, further comprising: initiating RF hardware in the mobile station for multi-carrier reception; receiving a broadcast channel (BCH) signal and from that channel learns among other information the number of common control channels used by the communication system; and hashing the number of common control channels to determine the code channel that it should use to receive pages. 8. The method according to claim 1, wherein if the mobile station decides to operate in single carrier mode further comprises: initiating RF hardware in the mobile station for single-carrier reception; and receiving a general page message on a predetermined code channel that states the number of paging channels used by the system; hashing the number of paging channels used to determine the code channel that it will use to receive directed pages from the serving base station. 9. A wireless device, operable in at least one of a multi-carrier mode and a single carrier mode, and configured to acquire a sync channel in a mixed bandwidth communications system, comprising: means for tuning to a first preferred channel of a selected set of preferred channels; means for attempting to detect a pilot signal on the first preferred channel, wherein the pilot signal has a unique pilot signal offset; means for receiving a sync channel message, if the pilot signal is detected on the first preferred channel; means for tuning to a second preferred channel of the selected set of preferred channels, if the pilot signal is not detected on the first preferred channel if the sync channel message is received, means for determining the center frequency of a multi-carrier system from the sync channel message in the current set of bands if one exists; and means for determining the location of a single carrier band in the current set of bands if one exists. 10. The wireless device according to claim 9, wherein means for attempting to detect a pilot signal on the first preferred channel, comprises: means for searching possible PN offset hypotheses; and means for testing each PN offset hypothesis. 11. The wireless device according to claim 10, wherein means for testing each PN offset hypothesis, comprises: means for computing the correlation between the received signal on the first preferred channel within the preferred frequency band and each PN hypothesis being tested to determine if the received signal is the pilot signal having a unique pilot signal offset. 12. The wireless device according to claim 11, wherein the pilot signal is not detected on the first preferred channel if the correlation energy for all PN hypotheses is less than a threshold value. 13. The wireless device according to claim 12, wherein the pilot signal is detected on the first preferred channel when a sufficient correlation energy is detected between the received signal at the preferred channel frequency and a PN offset hypothesis. 14. The wireless device according to claim 9, wherein the sync channel message is transmitted in a single 10�� band, and a frame boundary of a sync channel frame and a boundary are aligned with a short PN sequence used to spread the pilot channel signal such that upon detection of the pilot channel signal the sync channel message can be de-interleaved and decoded. 15. The wireless device according to claim 9, wherein if the wireless device decides to operate in multi-carrier mode the wireless device uses the received sync channel message to determine the center frequency of a multi-carrier system in the current set of frequency bands if one exists, further comprising: means for initiating RF hardware in the wireless device for multi-carrier reception; means for receiving a broadcast channel (BCH) signal and from that channel learns among other information the number of common control channels used by the communication system; and means for hashing the number of common control channels to determine the code channel that it should use to receive pages. 16. The wireless device according to claim 9, wherein if the wireless device decides to operate in single carrier mode further comprises: means for initiating RF hardware in the wireless device for single-carrier reception; means for receiving a general page message on a predetermined code channel that states the number of paging channels used by the system; and means for hashing the number of paging channels used to determine the code channel that it will use to receive directed pages from the serving base station. 17. A mobile station, operable in at least one of a multi-carrier mode and a single carrier mode, and configured to acquire a sync channel in a mixed bandwidth communications system, comprising: a receiver for tuning to a first preferred channel of a selected set of preferred channels; a control processor for attempting to detect a pilot signal on the first preferred channel, wherein the pilot signal has a unique pilot signal offset; the receiver for receiving a sync channel message, if the pilot signal is detected on the first preferred channel; the receiver for tuning to a second preferred channel of the selected set of preferred channels, if the pilot signal is not detected on the first preferred channel; if the sync channel message is received, the control processor for determining the center frequency of a multi-carrier system from the sync channel message in the current set of bands if one exists; and the control processor for determining the location of a single carrier band in the current set of bands if one exists. 18. The mobile station according to claim 17, wherein if the mobile station decides to operate in multi-carrier mode the mobile station uses the received sync channel message to determine the center frequency of a multi-carrier system in the current set of frequency bands if one exists, further comprising: the control processor for initiating RF hardware in the mobile station for multi-carrier reception; the receiver for receiving a broadcast channel (BCH) signal and from that channel learns among other information the number of common control channels used by the communication system; and the control processor for hashing the number of common control channels to determine the code channel that it should use to receive pages. 19. The mobile station according to claim 17, wherein if the wireless device decides to operate in single carrier mode further comprises: the control processor for initiating RF hardware in the wireless device for single-carrier reception; the receiver for receiving a general page message on a predetermined code channel that states the number of paging channels used by the system; and the control processor for hashing the number of paging channels used to determine the code channel that it will use to receive directed pages from the serving base station.
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