JP3835724B2 - Synchronization method and synchronization circuit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a synchronization circuit used on the receiver side of a mobile station apparatus in a spread spectrum communication system in mobile communication, and in particular, a synchronization method in which communication is not momentarily interrupted even during DHO (Diversity Hand Over). And a synchronization circuit.
[0002]
[Prior art]
During communication, when a mobile station moves from one cell to another, it is necessary to switch the corresponding base station. This switching operation between cells during communication is called hand-off or hand-over.
[0003]
The CDMA (Code Division Multiple Access) system based on spread spectrum communication is based on the fact that the frequency in each cell is the same, so FDMA (Frequency Division Multiple Access). Unlike the case of the method, it does not require frequency switching.
[0004]
A specific operation of the handover will be described below.
A mobile station in the vicinity of a cell boundary receives signals from a plurality of related base stations and informs the base station of the cell of their levels. Depending on the notified situation, the station that controls the line management transmits the same signal as the signal transmitted from the base station that is currently communicating to the base station corresponding to the new cell that the mobile station intends to move. Instruct them to do so.
[0005]
The mobile station performs diversity reception by receiving the same signal transmitted from the two base stations, and continues the diversity reception until the two signal levels exceed a predetermined value, and then the base station of the new cell Switch to sending and receiving. Such handoff or handover is called soft handoff or diversity handover (DHO) and is one of the features of CDMA.
[0006]
Conventional DHO will be described with reference to FIGS. 2, 3, and 4. FIG. FIG. 2 is an explanatory diagram showing a radio frame configuration of a downlink perch channel, FIG. 3 is a timing chart showing transmission timing of a dedicated physical channel, and FIG. 4 shows a process of establishing synchronization at the time of DHO. It is a timing chart figure.
[0007]
When the mobile station performs DHO, it receives the perch channel of the DHO destination radio base station (BTS).
The perch channel is a physical channel subject to reception level measurement for cell selection of the mobile station, and is a physical channel that is first captured when the power of the mobile station is turned on. In order to speed up the cell selection at the start-up in the mobile station, it is spread only by the short code in the system, and it is spread by the first perch channel that is always transmitted and the short code corresponding to the downlink long code, and partly There is a second perch channel that is transmitted only in the symbol portion.
Note that the short code used in the second perch channel is different from the short code system used in other physical channels.
[0008]
The perch channel 101 transmitted from the base station is divided into a plurality of radio slots as shown in FIG. As described above, the perch channel includes the first perch channel 102 and the second perch channel 103, which are simultaneously transmitted from the base station to the mobile station.
[0009]
When performing DHO, it is necessary to measure the time difference between the currently transmitted uplink dedicated physical channel and the perch channel (DHO destination perch) of the DHO destination BTS, and therefore must be synchronized with the DHO destination perch.
As shown in FIG. 4, the mobile station despreads the DHO destination perch received from the DHO destination BTS with a long code, establishes correlation, and establishes synchronization. The long code used at this time is reported from the DHO source BTS, and the phase thereof is the same as the phase of the DHO destination perch.
[0010]
When synchronization with the DHO destination perch is established, the mobile station measures the time difference between the frames of the same frame number of the uplink dedicated physical channel being transmitted (transmitting from the DHO source BTS) and the perch, and this is measured as the DHO source. The DHO destination BTS is notified via the BTS.
[0011]
FIG. 3A shows a DHO destination perch channel (ch) radio frame, FIG. 3B shows a mobile station uplink individual physical ch radio frame, FIG. 3C shows a DHO source downlink individual physical ch reception radio frame, FIG. 3D shows a DHO destination BTS downlink dedicated physical channel transmission radio frame and timing.
The mobile station determines the frame time difference measurement value T from (a) and (b) in FIG. _DHO To get. Also, since the time difference between the uplink individual physical ch and the downlink individual physical ch is 1280 chips from FIGS. 3B and 3C, the downlink individual physical ch transmitted from the DHO destination BTS to the mobile station is T _DHO The mobile station notifies the DHO destination BTS so that the timing is -1280 chips.
[0012]
The DHO destination BTS is notified of the notified time difference (T _DHO -A downlink dedicated physical channel is transmitted based on -1280 chip). The mobile station receives the downlink dedicated physical channel from the DHO destination BTS and establishes chip synchronization. When chip synchronization is established, the mobile station starts maximum ratio combining with the downlink dedicated physical channel from the DHO destination BTS.
[0013]
The above is the description of the conventional operation at the time of DHO.
Next, a synchronization circuit in a conventional mobile station apparatus will be described with reference to FIG. FIG. 5 is a configuration block diagram of a conventional synchronization circuit. In the example of FIG. 5, the number of space diversity branches used for reducing the influence of fading is two.
[0014]
As shown in FIG. 5, the conventional synchronization circuit includes an antenna 1 for branch 1, an antenna 2 for branch 2, a radio unit 3 for branch 1, a radio unit 4 for branch 2, and an A / D converter for branch 1. 5, an A / D converter 6 in branch 2, a spread code generator 7, a searcher 8 in branch 1, a searcher 9 in branch 2, a profile unit 10 in branch 1, and a profile unit 11 in branch 2. A sliding correlator 12 of the branch 1, a sliding correlator 13 of the branch 2, and a RAKE combining unit 14 are provided, and a synchronizing unit 20 for establishing synchronization at the time of DHO is further provided.
The synchronization unit 20 includes a searcher 21, a profile unit 22, and a sliding correlator 23.
[0015]
Next, each part of the conventional synchronization circuit will be specifically described.
The antenna 1 of the branch 1 and the antenna 2 of the branch 2 are antennas that receive incoming signals.
The radio unit 3 of the branch 1 is a radio unit that converts a high-frequency signal received by the antenna 1 of the branch 1 into a baseband signal, and the radio unit 4 of the branch 2 has a high-frequency signal received by the antenna 2 of the branch 2. It is a radio unit that converts the frequency of a signal into a baseband signal.
[0016]
The A / D converter (A / D) 5 of the branch 1 is a converter that converts an analog signal output from the radio unit 3 of the branch 1 into a digital signal. The A / D converter (A / D) of the branch 2 A converter 6 converts an analog signal output from the wireless unit 4 of the branch 2 into a digital signal.
[0017]
The spread code generation unit 7 sets a spread code number notified from the base station on the transmission side from the outside, generates a long code and a short code corresponding to the number, and multiplies the generated long code and short code. A spread signal used for despreading the received baseband signal is generated. It should be noted that a code can be independently generated for each timing of a plurality of delay paths in each of the branches 1 and 2.
[0018]
The matched filter (searcher) 8 of the branch 1 is an output of the A / D converter 5 of the branch 1 and a code obtained by multiplying the long code generated by the spread code generating unit 7 and the short code, or a code including only the short code. It is a matched filter that calculates correlation.
The matched filter (searcher) 9 of the branch 2 is a combination of an output of the A / D converter 6 of the branch 2 and a code obtained by multiplying the long code generated by the spread code generating unit 7 and the short code, or a code including only the short code. It is a matched filter that calculates correlation.
[0019]
The profile unit (Profile) 10 of the branch 1 estimates the delay path timing by taking the absolute value of the correlation calculation result of the matched filter 8 of the branch 1 and averaging it over a plurality of symbols.
The profile part (Profile) 11 of the branch 2 estimates the delay path timing by taking the absolute value of the correlation calculation result of the matched filter 9 of the branch 2 and averaging it over a plurality of symbols.
[0020]
The sliding correlator (SC) 12 of the branch 1 is a spreading code obtained by multiplying the baseband signal converted into a digital value by the A / D converter 5 of the branch 1 and the long code and the short code generated by the spreading code generation unit 7. Are despread at the path timing estimated by the profile unit 10 of the branch 1 and output.
The sliding correlator (SC) 13 of the branch 2 is a spread code obtained by multiplying the baseband signal converted into a digital value by the A / D converter 6 of the branch 2 and the long code and the short code generated by the spread code generating unit 7. Are despread at the path timing estimated by the profile unit 11 of the branch 2 and output.
[0021]
The RAKE combining unit 14 demodulates the received signal by combining the results of correlation calculation of delay paths having different phases of the sliding correlators (SC) 12 and 13 of the branch 1 and the branch 2 with a maximum ratio.
[0022]
In DHO, each unit of the synchronization unit 20 for receiving the perch channel of the DHO destination BTS and establishing synchronization will be described.
A matched filter (searcher) 21 in the synchronization unit 20 calculates a correlation between the output of the A / D converter 6 of the branch 2 and a code obtained by multiplying the long code and the short code generated by the spread code generation unit 7. It is.
[0023]
The profile unit (Profile) 22 takes the absolute value of the correlation calculation result from the searcher 21 and averages it over a plurality of symbols to estimate the delay path timing.
The sliding correlator (SC) 23 is a path timing in which the profile unit 22 estimates a correlation operation between the baseband signal converted into a digital value by the A / D converter 6 of the branch 2 and the spread code generated by the spread code generation unit 7. Are despread and output.
[0024]
Thus, the synchronization unit 20 for receiving the DHO destination perch channel, despreading it, and determining the downlink long code and synchronizing the radio frame is required, and the matched filter (searcher) for the DHO destination perch channel is required. ) 21, a sliding correlator (SC) 23, and a profile unit 22 are prepared separately from the matched filters (searchers) 8 and 9, the sliding correlators 12 and 13, and the profile units 10 and 11 used in the two-branch space diversity. It was.
[0025]
The operation during DHO in the conventional example will be described below.
At the time of DHO, the mobile station measures the time difference between the radio frame of the uplink dedicated physical channel communicating with the DHO source BTS and the radio frame of the perch channel transmitted from the DHO destination BTS, and uses this measured value as the DHO source BTS. Via the DHO destination BTS.
[0026]
In order to measure this time difference, the DHO destination perch channel must be synchronized. The received DHO destination perch is converted into a baseband signal by the radio unit 4 and the A / D converter 6, and the correlation with the long code is calculated. The long code used at this time is notified of the long code number from the DHO source BTS, and the phase is the same as the perch of the DHO destination BTS.
[0027]
The long code is generated from the spread code generation unit 7, and the perch converted into the baseband signal is correlated with the matched filter (searcher) 21. When synchronization with the perch is established, the time difference between the frame of this DHO destination perch and the frame of the uplink dedicated physical channel currently being transmitted is measured and notified to the DHO destination BTS via the DHO source BTS.
[0028]
The DHO destination BTS transmits the downlink dedicated physical channel based on this information, and the mobile station receives the downlink dedicated physical channel from the DHO destination BTS and starts downlink chip synchronization. When the chip synchronization is established, the matched filter (searcher) 21 is operated, the plurality of delay path timings are detected by the profile unit 22, and the received signal is demodulated by the sliding correlator 23 while the synchronization is maintained, and the RAKE combining unit 14 Perform maximum ratio synthesis.
[0029]
The above is the operation of the mobile station during DHO in the conventional example.
Therefore, as a hardware configuration, a dedicated synchronization circuit portion for the DHO destination BTS is provided separately from the synchronization circuit portion for the DHO source BTS.
[0030]
In addition, as a prior art at the time of DHO, there exists Unexamined-Japanese-Patent No. 10-271549 "Mobile radio | wireless base station apparatus" (applicant: Kokusai Electric Inc., inventor: Shunji Abe) published on October 9, 1998.
This prior art relates to a mobile radio base station apparatus, which realizes soft handover by signal synthesis with a simple configuration and improves reception characteristics at the time of handover.
[0031]
[Problems to be solved by the invention]
However, in the above conventional synchronization circuit, a dedicated synchronization circuit part for the DHO destination BTS that operates only during DHO is provided separately from the synchronization circuit part for the DHO source BTS. There was a problem that electric power also increased.
[0032]
The present invention has been made in view of the above circumstances, and an object thereof is to provide a synchronization method and a synchronization circuit capable of suppressing an increase in circuit scale.
[0033]
[Means for Solving the Problems]
The present invention for solving the problems of the above-described conventional example includes: a radio unit that performs reception for each of a plurality of branches; and a correlation acquisition unit that obtains a correlation between signals received by the radio unit in order to perform diversity reception. In a synchronization circuit of a mobile station apparatus comprising combining means for combining correlation outputs from each correlation acquisition means, Handover Destination base station Received baseband signal obtained by receiving a high-frequency signal including the signal from and the signal from the handover source base station in communication, and converting the frequency of the high-frequency signal Signal memory Temporarily remember When the signal from the handover source base station is diversity-received, the signal for establishing synchronization of the handover source base station is not received. Wireless means and correlation acquisition means of any branch among multiple branches , Further The control means operates the combining means, Handover is performed by calculating the correlation between the stored signal and the spreading code of the handover destination base station. Establishes synchronization with the previous base station, suppresses increase in circuit scale, and increases power consumption The It can be suppressed.
[0034]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described with reference to the drawings.
The function realizing means described below may be any circuit or device as long as it can realize the function, and part or all of the function can be realized by software. is there. Furthermore, the function realizing means may be realized by a plurality of circuits, and the plurality of function realizing means may be realized by a single circuit.
[0035]
In the synchronization circuit in the mobile station apparatus according to the embodiment of the present invention, it is noted that the searcher that performs synchronization acquisition at the time of DHO operates on the pilot symbol portion and does not operate on other symbols. And a storage means that partially holds the received signal in one branch that is performing diversity, the DHO destination perch channel data is held in the storage means, and the DHO held in the storage means in portions other than the pilot symbols This is a synchronization circuit that synchronizes with the DHO destination BTS while continuing the 2-branch diversity of the data channel with the DHO source BTS by operating the searcher for the received signal of the destination perch channel.
[0036]
At the start of DHO, it is necessary to report to the DHO source BTS the time difference between the perimeter tree at the DHO destination and the uplink dedicated physical channel of the mobile station that is transmitting to the DHO source BTS.
Based on the reported time difference, the DTS destination BTS adjusts the radio frame timing to match the radio frame timing of the DHO source (more precisely, the received radio frame timing of the MS [radio mobile station apparatus]). The long code phase is the same as the perch channel timing.
[0037]
Further, since the long code number used at the DHO destination is notified from the DHO source BTS, the code is not determined.
Since the perch channel transmitted from each BTS is asynchronous between base stations, there is a possibility that the DHO source and the DHO destination may overlap. Therefore, the searcher (matched filter) is provided for the BTS to be the DHO target. In the synchronization circuit according to the embodiment of the present invention, which is a conventional example, synchronization with the DHO destination BTS is realized by holding temporary data in the storage means and using a searcher (matched filter) in a time-sharing manner. Is to measure.
[0038]
As long as the base stations are synchronized, the pilot symbol part of the perch channel can maintain a certain phase, so the long code is changed for each phase in the same searcher, and synchronization is established for both the DHO source and destination Therefore, a storage means such as a memory becomes unnecessary. Therefore, if the perches do not overlap, a memory is not required even when the base stations are asynchronous. However, since the perches do not always overlap, storage means such as a memory is provided in the present invention.
[0039]
The synchronization circuit in the mobile station apparatus according to the embodiment of the present invention includes a radio unit that performs reception for each of a plurality of branches and a correlation acquisition unit that obtains a correlation between signals received by the radio unit in order to perform diversity reception. And combining means for combining the correlation outputs from the respective correlation acquisition means, storage means for storing the signal of the base station that is the communication switching destination, controlling input / output of signals to the storage means, and a plurality of branches Of these, during the period when the wireless means and correlation acquisition means of any branch do not normally operate, the wireless means, the correlation acquisition means, and the combining means are operated to establish synchronization with the base station that is the communication switching destination. Control means.
[0040]
Next, a synchronization circuit according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a configuration block diagram of a synchronization circuit according to an embodiment of the present invention. In addition, the same code | symbol is attached | subjected and demonstrated about the part which takes the structure similar to FIG.
As shown in FIG. 1, the synchronization circuit according to the embodiment of the present invention includes an antenna 1 of a branch 1, an antenna 2 of a branch 2, a radio unit 3 of a branch 1, a radio unit 4 of a branch 2, and a branch 1 A / D converter 5, branch 2 A / D converter 6, spreading code generation unit 7, branch 1 searcher 8, branch 2 searcher 9, branch 1 profile unit 10, branch 2 Profile section 11, sliding correlator 12 of branch 1, sliding correlator 13 of branch 2, and RAKE combining section 14, and further, a memory 15 as storage means used for establishing synchronization during DHO, and the memory And a control unit 16 as control means for controlling 15 and the like.
[0041]
In the example of FIG. 1, the function realizing means is merely an example having a specific configuration, and the antennas 1 and 2, the radio units 3 and 4, and the A / D converters 5 and 6 correspond to the radio means. The spread code generation unit 7, the searchers 8 and 9, the profile units 10 and 11, and the sliding correlator 12 and 13 correspond to the correlation acquisition unit, the RAKE combining unit 14 corresponds to the combining unit, and the memory 15 The control unit 16 corresponds to the storage unit, and the control unit 16 corresponds to the control unit.
In addition, the memory 15 and the control unit 16 can be configured by one circuit.
[0042]
Next, each part of the synchronous circuit according to the embodiment of the present invention will be specifically described.
The antenna 1 of the branch 1 and the antenna 2 of the branch 2 are antennas that receive incoming signals.
The radio unit 3 of the branch 1 is a radio unit that converts a high-frequency signal received by the antenna 1 of the branch 1 into a baseband signal, and the radio unit 4 of the branch 2 has a high-frequency signal received by the antenna 2 of the branch 2. It is a radio unit that converts the frequency of a signal into a baseband signal.
[0043]
The A / D converter (A / D) 5 of the branch 1 is a converter that converts an analog signal output from the radio unit 3 of the branch 1 into a digital signal. The A / D converter (A / D) of the branch 2 A converter 6 converts an analog signal output from the wireless unit 4 of the branch 2 into a digital signal.
[0044]
The spread code generation unit 7 sets a spread code number notified from the base station on the transmission side from the outside, generates a long code and a short code corresponding to the number, and multiplies the generated long code and short code. A spread signal (spread code) used for despreading the received baseband signal is generated. It should be noted that a code can be independently generated for each timing of a plurality of delay paths in each of the branches 1 and 2.
[0045]
The matched filter (searcher) 8 of the branch 1 is an output of the A / D converter 5 of the branch 1 and a code obtained by multiplying the long code generated by the spread code generating unit 7 and the short code, or a code including only the short code. It is a matched filter that calculates correlation.
The matched filter (searcher) 9 of the branch 2 is a combination of an output of the A / D converter 6 of the branch 2 and a code obtained by multiplying the long code generated by the spread code generating unit 7 and the short code, or a code including only the short code. It is a matched filter that calculates correlation.
[0046]
The profile unit (Profile) 10 of the branch 1 estimates the delay path timing by taking the absolute value of the correlation calculation result of the matched filter 8 of the branch 1 and averaging it over a plurality of symbols.
The profile part (Profile) 11 of the branch 2 estimates the delay path timing by taking the absolute value of the correlation calculation result of the matched filter 9 of the branch 2 and averaging it over a plurality of symbols.
[0047]
The sliding correlator (SC) 12 of the branch 1 is a spreading code obtained by multiplying the baseband signal converted into a digital value by the A / D converter 5 of the branch 1 and the long code and the short code generated by the spreading code generation unit 7. Are despread at the path timing estimated by the profile unit 10 of the branch 1 and output.
The sliding correlator (SC) 13 of the branch 2 is a spread code obtained by multiplying the baseband signal converted into a digital value by the A / D converter 6 of the branch 2 and the long code and the short code generated by the spread code generating unit 7. Are despread at the path timing estimated by the profile unit 11 of the branch 2 and output.
[0048]
The RAKE combining unit 14 demodulates the received signal by combining the results of correlation calculation of delay paths having different phases of the sliding correlators (SC) 12 and 13 of the branch 1 and the branch 2 with a maximum ratio.
[0049]
The memory 15 as a storage means is a memory for holding the perch channel data of the DHO destination BTS at the time of DHO. Data corresponding to the perch channel of the DHO destination BTS is input from the A / D converter 6 at the control timing of the control unit 16 and held. Further, the data held at the control timing of the control unit 16 is output to the searcher 9 and the sliding correlator (SC) 13.
[0050]
The control unit 16 as a control unit controls input / output of data in the memory 15 and controls operation timings of the searcher 9, the profile unit 11, and the sliding correlator (SC) 13 at the time of DHO.
Specifically, the data corresponding to the perch channel of the DHO destination BTS is input from the A / D converter 6 and stored, and the part other than the pilot symbol part of the DHO source signal (the searcher 9 is not normally operated). In the period, the searcher 9, the profile unit 11, and the sliding correlator 13 are operated so as to obtain a correlation output.
[0051]
An operation during DHO in the synchronous circuit according to the embodiment of the present invention will be described.
When performing DHO, the mobile station apparatus needs to report the time difference between the perimeter channel of the DHO destination BTS and the uplink dedicated physical channel of the mobile station transmitting to the DHO source BTS to the DHO source BTS. . Therefore, it is necessary to synchronize with the perch channel of the DHO destination BTS.
[0052]
Further, since the long code used for the DHO destination signal is already notified from the DHO source BTS, it is not necessary to determine the long code, and the phase thereof is the same as the phase of the DHO destination perch.
[0053]
The memory 15 holds a signal converted into a baseband signal by the radio unit 4 of the branch 2 and the A / D converter 6. Since the data to be held is considered to be severe due to hardware restrictions such as arithmetic processing for one symbol, it is held in the memory 15 in units of several symbols.
The arithmetic processing of the previously held data is performed by the sliding correlator 13, the searcher 9, and the profile unit 11. When the processing is completed, the data is discarded, the data is shifted, and the next data is written in the vacant place. I am doing so.
[0054]
Since the searcher 9 is a matched filter and operates on the pilot symbol portion of the DHO source signal, the data held in the memory 15 at the portion other than the pilot symbol that is not operating is controlled according to the control timing of the control unit 16. Capture and correlate with the long code generated by the spread code generation unit 7 from the long code number broadcast from the DHO source BTS, detect the path, maintain the synchronization, and select the effective path from the plurality of delay paths Detection is performed by the profile unit 11.
Then, based on the effective path detected by the profile unit 11, the mobile station establishes synchronization with the DHO destination BTS.
[0055]
Next, the mobile station device reports to the DHO source BTS the time difference between the perch channel of the DHO destination BTS and the uplink dedicated physical channel of the mobile station that is transmitting to the DHO source BTS. The DHO destination BTS notifies the DHO destination BTS, and based on the notified time difference, the DHO destination BTS adjusts the radio frame timing of the downlink dedicated physical channel to the DHO source radio frame timing (more precisely, the radio frame timing of the mobile station). To send.
[0056]
The mobile station receives the downlink dedicated physical channel of the DHO destination based on the reception timing of the DHO destination perch channel, and starts the chip synchronization process. After the chip synchronization is established, the received signal is demodulated by the sliding correlator 13, and the maximum ratio combining is performed by the RAKE combining unit 14 to establish the frame synchronization.
As described above, the mobile station apparatus can perform initial synchronization with the DHO destination base station while continuing the two-branch diversity with the DHO source.
[0057]
According to the synchronization circuit in the mobile station apparatus according to the embodiment of the present invention, the matched circuit that includes the memory 15 that partially retains the received signal at the time of DHO and the control unit 16 that controls the memory 15 or the like and performs intermittent operation. Since the searcher 9, the profile unit 11, the sliding correlator 13, etc. are operated to synchronize the DHO destination during the period when the filter (searcher) 9 does not operate, in order to synchronize the DHO destination base station, There is no need to add hardware such as a dedicated matched filter, sliding correlator, profile part, etc., and since 2-branch diversity with the DHO source continues, synchronization with the DHO source is achieved without interruption. There is an effect that can.
[0058]
Therefore, according to the synchronization circuit of the mobile station apparatus according to the embodiment of the present invention, a device such as the memory 15 is added instead of a conventional device that consumes power, such as a dedicated matched filter. Therefore, power consumption can be suppressed, and it is suitable for use in a battery-driven portable device.
[0059]
【The invention's effect】
According to the present invention, in order to perform diversity reception, each of the plurality of branches includes a wireless unit that performs reception, and a correlation acquisition unit that obtains a correlation between signals received by the wireless unit. In a synchronization circuit of a mobile station apparatus provided with combining means for combining correlation outputs, Handover Destination base station Received baseband signal obtained by receiving a high-frequency signal including the signal from and the signal from the handover source base station in communication, and converting the frequency of the high-frequency signal Signal memory Temporarily remember When the signal from the handover source base station is diversity-received, the signal for establishing synchronization of the handover source base station is not received. Wireless means and correlation acquisition means of any branch among multiple branches , Further The control means is operated by the combining means. Handover is performed by calculating the correlation between the stored signal and the spreading code of the handover destination base station. Establishes synchronization with the previous base station, suppresses increase in circuit scale, and increases power consumption The There is an effect that can be suppressed.
[Brief description of the drawings]
FIG. 1 is a configuration block diagram of a synchronization circuit according to an embodiment of the present invention.
FIG. 2 is an explanatory diagram showing a radio frame configuration of a downlink perch channel.
FIG. 3 is a timing chart showing dedicated physical channel transmission timing.
FIG. 4 is a timing chart showing a process for establishing synchronization during DHO.
FIG. 5 is a configuration block diagram of a conventional synchronization circuit.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1, 2 ... Antenna, 3, 4 ... Radio | wireless part, 5, 6 ... A / D converter, 7 ... Spreading code generation part, 8, 9 ... Searcher, 10, 11 ... Profile part, 12, 13 ... Sliding correlator, 14 ... RAKE combining unit, 15 ... memory, 16 ... control unit, 20 ... synchronizing unit, 21 ... searcher, 22 ... profile unit, 23 ... sliding correlator

Claims (3)

In a synchronization method in CDMA communication in a mobile station apparatus that performs diversity reception in a plurality of branches with a base station in communication, obtains a correlation output for each branch, and combines the correlation outputs ,
Receiving a high-frequency signal including a signal from a handover- destination base station and a signal from the handover-source base station in communication, and temporarily receiving a received baseband signal obtained by frequency-converting the high-frequency signal A period in which a signal for establishing synchronization of the handover source base station is not received when the signal from the handover source base station is diversity-received using one of the branches. And performing synchronization calculation between the stored signal and a spreading code of the handover destination base station to establish synchronization with the handover destination base station. A wireless means for performing diversity reception with a plurality of branches with a communicating base station, and calculating a correlation between a signal received by the wireless means and a spreading code of the communicating base station to obtain a correlation output In a synchronization circuit of a mobile station apparatus, comprising a correlation acquisition means for each branch , and a synthesis means for synthesizing correlation outputs from the correlation acquisition means.
A baseband obtained by frequency-converting a high-frequency signal including a signal from a handover destination base station received using any of the wireless means of the branch and a signal from the handover source base station that is in communication A memory for temporarily storing signals;
While controlling the input / output of signals in the memory , the wireless means receives diversity signals from the handover source base station , and any correlation acquisition means of the branch receives from the handover source base station. a period of not performing phase function operation using a pilot signal, prior SL reads the signals stored in the memory, and the correlation code of the handover destination is notified from the signal and the handover source base station to the correlation obtaining means to perform the correlation operation of synchronous circuits, characterized in that the synchronization acquisition of the handover destination base station is provided a row intends controller. In a synchronization circuit used in a receiver of a mobile station apparatus, an antenna of a first branch and an antenna of a second branch that receive incoming signals;
A radio unit of the first branch and a radio unit of the second branch for frequency-converting a received high-frequency signal into a baseband signal;
The A / D converter of the first branch and the A / D converter of the second branch for converting an analog signal from the radio unit into a digital signal;
A spreading code generator for generating a spreading code used for despreading the received baseband signal;
A searcher of the first branch and a searcher of the second branch for calculating a correlation between an output from the A / D converter and the generated spreading code;
Taking the absolute value of the correlation calculation result of the searcher and averaging over a plurality of symbols to estimate the delay path timing, the profile part of the first branch and the profile part of the second branch;
A sliding correlator of the first branch that despreads and outputs a correlation operation between the baseband signal converted into a digital value by the A / D converter and the generated spread code at a path timing estimated by the profile unit And a sliding correlator of the second branch;
A RAKE combining unit that performs maximum ratio combining of outputs from each of the sliding correlators and demodulates a received signal;
A memory for inputting and storing a baseband signal including perch channel data of a communication switching destination base station from the A / D converter of the second branch ;
A baseband signal including perch channel data of the base station to which communication is switched is input from the A / D converter of the second branch and stored in the memory, and other than pilot symbols of a signal from the base station in communication The second branch searcher, the second branch profile unit, the second branch sliding correlator, and the RAKE synthesis unit are operated to read the baseband signal stored in the memory. Te, that a control unit for controlling so as to perform synchronization establishment with the base station of the communication switching destination to obtain a correlation output of the spread code used in the said baseband signal and said perch channel Synchronous circuit characterized.

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