JP4267805B2 - CDMA receiver and path detection control method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention detects a optimum path under a multipath environment in a mobile communication system to which a CDMA (Code Division Multiple Access) system is applied, and enables a high-speed pull-in and high-speed path following control and a path detection control. Regarding the method.
[0002]
[Prior art]
FIG. 10 is an explanatory diagram of a conventional example and shows a main part of a CDMA receiver of a base station in a mobile communication system to which a CDMA system is applied, where 101-1 to 101-N are a plurality of sectors 1 to N. A corresponding antenna, 102 is a reception processing unit, 103 and 104 are selectors, 105 is a searcher unit, 106 is a finger unit, 107 is an MRC unit that performs rake combining, and 108 is a common synchronization detection unit. The reception processing unit 102 converts I and Q signals having intermediate frequencies obtained by orthogonally demodulating the reception signals from the antennas 101-1 to 101 -N corresponding to the sectors into digital signals and inputs the digital signals to the selectors 103 and 104. In addition, the searcher unit 105 and the finger unit 106 are configured to perform time division processing.
[0003]
The selector 103 is controlled by a selection setting signal from a control unit (not shown) to select I and Q signals corresponding to a maximum of M (<N) sectors out of N sectors, and to the searcher unit 105. input. The searcher unit 105 has a configuration including a matched filter (MF) and a profile memory. The searcher unit 105 obtains a correlation value between the selected I and Q signals corresponding to the M sectors and the spreading code by using a matched filter. A delay profile comprising peaks of correlation values is stored in the profile memory. Then, L paths are selected in descending order of correlation value, and the selector 104 is notified of a single or a plurality of selected sectors, and the path timing for each finger of the finger unit 106 composed of L fingers 1 to L is selected. To be notified.
[0004]
Each finger of the finger unit 106 generates a spreading code according to the path timing from the searcher unit 105, performs despreading processing, performs synchronous detection processing, outputs demodulated data, and outputs demodulated data corresponding to L fingers. This is input to the MRC unit 107 and rake synthesis is performed by maximum ratio synthesis. The common synchronization detection unit 108 performs synchronization detection using the pilot symbol of the combined output data from the MRC unit 107 and notifies the searcher unit 105 of the detection result. The synchronization detection signal is used as a synchronization signal for processing the rake synthesized demodulated data.
[0005]
The searcher unit 105 moves the search window (timing interval where path detection is possible) following the movement of the maximum correlation value (maximum path timing). Further, as described above, the common synchronization detection unit 108 performs synchronization detection using the pilot symbols after the rake synthesis by the MRC unit 107, and the searcher unit 105 performs a path following operation in the synchronous state, and enters the asynchronous state. In this case, the path following operation is controlled to be stopped.
[0006]
[Problems to be solved by the invention]
In the mobile communication system, the delay profile obtained by the searcher unit 105 changes as the mobile station communicating with the base station moves. Therefore, the searcher unit 105 performs path follow-up control in which the search window is moved so as to follow the change in timing of the maximum correlation value. However, in a burst signal transmission off section or a section or sector where no effective path exists, a path with a large correlation value may be recognized by chance due to an interference wave or noise. Shift. Therefore, there is a problem that when the burst signal transmission is received during reception, the effective path is deviated from the search window, and a normal path cannot be detected at high speed.
[0007]
Further, since the common synchronization detection unit 108 performs synchronization detection using the pilot symbols after the rake combination, the synchronization detection as a channel is performed. Then, the path following control in the searcher unit 105 is turned on / off according to the synchronization detection result. When a plurality of sectors are received, the existence status of the valid path differs depending on the sector, and the sector having no valid path is detected. Therefore, there is a problem in that path follow-up control is performed, causing malfunction. In addition, the number of synchronization protection stages is fixedly set in advance and does not follow changes in the environment. Therefore, there is a problem that the time required for synchronization pull-in becomes long or the possibility of erroneous synchronization detection increases. .
[0008]
An object of the present invention is to solve the problems of the conventional example, and to enable high-speed detection of an optimal path and high-speed tracking control of an optimal path.
[0009]
[Means for Solving the Problems]
Referring to FIG. 1, the CDMA receiver of the present invention includes a searcher unit 3 and a finger unit 4, and a selector 1 selects a predetermined number of sector-corresponding reception signals from among a plurality of sector-corresponding reception signals. Is input to the searcher unit 3 to obtain a correlation value with the spreading code, and follow up the path of the maximum path timing among the path timings according to the correlation value to perform despread demodulation processing in the finger unit 4 The CDMA receiving apparatus performs the synchronization detection by inputting the demodulated data of the finger unit 4 corresponding to the sector-corresponding maximum path timing by the searcher unit 3, and performs the path follow-up control in the searcher unit 3 in the synchronized state. And a synchronization detecting unit 6 for stopping the path following control in the searcher unit 3 in the asynchronous state.
[0010]
Also, a demodulated data obtained by rake-combining the demodulated data of each finger of the finger unit 4 by the MRC unit 5 is input, and a common sync detecting unit for detecting synchronization as a channel is provided, and demodulated data of each finger of the finger unit 4 is input. The synchronization detection unit 6 is configured to switch a parameter for performing sector-specific synchronization detection corresponding to the synchronization detection result of the common synchronization detection unit, and the searcher unit 3 corresponds to the synchronization detection result of the synchronization detection unit 6. Thus, one or both of the search interval and the pass averaging number is switched. In addition, a demodulated data obtained by rake-combining demodulated data of each finger of the finger unit 4 is input, and an SIR measuring unit for measuring a signal wave-to-interference wave power ratio is provided. The synchronization detecting unit 6 includes a measurement result of the SIR measuring unit. Correspondingly, the synchronization detection parameter can be switched.
[0011]
Also, the path detection control method of the present invention obtains a correlation value with a spreading code by inputting a predetermined number of sector-corresponding reception signals from among a plurality of sector-corresponding reception signals, and includes a path timing according to the correlation value. Is a path detection control method that performs tracking control of the path of the maximum path timing of the input signal, and receives the demodulated data of the finger part corresponding to the maximum path timing corresponding to the sector by the searcher part to detect synchronization corresponding to the sector, This includes a process of performing path tracking control in the searcher unit and stopping path tracking control in the searcher unit when in an asynchronous state. Also, based on the demodulated data obtained by combining the demodulated data of the finger part with the maximum ratio, synchronous detection or signal wave-to-interference wave power ratio measurement is performed, and the searcher corresponding to the synchronization detection result or signal wave-to-interference wave power ratio measurement result The demodulating data of the finger part corresponding to the maximum path timing corresponding to the sector by the part can be input and the process of switching the synchronization detection parameter for synchronous detection corresponding to the sector can be included.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is an explanatory diagram of a first embodiment of the present invention, wherein 1, 2 are selectors, 3 is a searcher unit, 4 is a finger unit, 5 is an MRC unit, 6 is a synchronization detection unit, and 10 is an IF (intermediate) Frequency) part. Further, the case where the number of sectors N = 6, the maximum number of sectors M to detect the path in the searcher unit 3 = 4, and the number of fingers L of the finger unit 4 is shown as 8 is shown. An IF unit 10 indicated by a dotted line receives a signal obtained by orthogonally demodulating the received signals corresponding to sectors 1 to 6 by a high frequency unit (not shown), and converts the intermediate frequency I and Q signals converted into digital signals to the selectors 1 and 2. To enter.
[0013]
The selector 1 is controlled by a selection setting signal from a control unit (not shown), selects I and Q signals corresponding to a maximum of four sectors out of six sectors, and inputs them to the searcher unit 3. 2 inputs to the finger unit 4 I or Q signals corresponding to a single sector or a plurality of sectors according to the notification of the selected sector from the searcher unit 3. The finger unit 4 shows an eight-finger configuration, performs spreading code generation, despreading processing, and synchronous detection processing according to the path timing from the searcher unit 3, and inputs demodulated data from each finger to the MRC unit 5. Similar to the conventional example, the MRC unit 5 performs rake combining by maximum ratio combining of demodulated data corresponding to fingers, and transfers the result to a subsequent processing circuit (not shown). In this case, since the subsequent processing circuit needs to process the demodulated data in synchronization with the pilot symbol of the demodulated data from the MRC unit 5, a common synchronization detecting unit (not shown) is provided.
[0014]
The searcher unit 3 obtains a correlation value of I and Q signals corresponding to a maximum of four sectors selected by the selector 1 by a matched filter (MF), stores a delay profile including a correlation value peak in a profile memory, and 8 paths having a large correlation value are selected, a selection signal indicating a sector including these 8 paths is notified to the selector 2, and the path timings of the 8 paths are set to the 8 fingers of the finger unit 4. Notify The synchronization detection unit 6 is notified of the finger number of the finger unit 4 to which the maximum path timing corresponding to the sector selected by the selector 2 is assigned.
[0015]
The synchronization detection unit 6 performs synchronization detection using a pilot symbol of demodulated data from the finger corresponding to the finger number notified from the searcher unit 3. That is, synchronization detection is performed using pilot symbols of demodulated data of the fingers that demodulate the signal corresponding to the sector selected by the selector 2, and synchronization detection is performed for the sector selected by the selector 2. The synchronization detection result is notified to the searcher unit 3. The synchronization detection parameters (tolerance, number of front protection steps, number of rear protection steps) can be set on a sector basis. For example, if the synchronization detection parameters in the channel unit of the conventional example are tolerance = 8, the number of forward protection stages = 2, and the number of backward protection stages = 10, it is difficult to determine the synchronization detection parameter in the sector unit as out of synchronization. In order to facilitate the establishment determination, for example, tolerance = 4, front protection stage number = 4, and rear protection stage number = 5.
[0016]
The searcher unit 3 performs path follow-up control during synchronization in response to the synchronization detection result from the synchronization detection unit 6, and stops path follow-up control during asynchronous. The search interval for obtaining the correlation value or the number of times of averaging is switched between the path following control and the path non-following control. That is, during the path following control, the search interval is shortened. Or increase the number of averaging. On the contrary, during the path non-following control, the search interval is lengthened and the search window is equivalently widened. Alternatively, the number of times of averaging is reduced to shorten the profile memory update cycle, thereby speeding up path detection.
[0017]
FIG. 2 is an explanatory diagram of the main part of one embodiment of the searcher unit of the present invention, showing the main part configuration corresponding to one sector of the searcher unit 3 in FIG. 1, 11 is an MF correlation value detection unit, A code generation unit, 13 an averaging processing unit, 14 a search control unit, 15 a memory control unit, and 16 a profile memory.
[0018]
The MF correlation value detection unit 11 has a matched filter (MF) configuration, and obtains a correlation value between an intermediate frequency (IF) signal corresponding to a certain sector and a spread code from the code generation unit 12. The correlation value is averaged for a plurality of frames, for example, by the averaging unit 13 and stored in the profile memory 16 under the control of the memory control unit 15. Based on the data stored in the profile memory 16, path selection is performed by path selection means (not shown).
[0019]
The search control unit 14 controls the MF correlation value detection unit 11, the code generation unit 12, and the memory control unit 15 to switch the window or interval, that is, the search window or search interval. The follow-up ON / OFF signal applied to the search control unit 14 and the memory control unit 15 is a synchronization detection result signal from the synchronization detection unit 6 (see FIG. 1). And
[0020]
In the case of tracking OFF, path detection must be performed over a wide range. Therefore, it is conceivable to enlarge the search window. In this case, if the search interval is the same, it is necessary to increase the capacity of the profile memory 16. Therefore, if the search interval is X times that when tracking is OFF, the timing accuracy of path detection is degraded, but the detection range (search window) is X times even if the capacity of the profile memory 16 is the same. For example, if X = 2 and the search interval is doubled, the detection range can be doubled without increasing the capacity of the profile memory 16. That is, the search control unit 14 can speed up the synchronization detection from the asynchronous state by switching the search interval in accordance with the follow ON / OFF signal.
[0021]
FIG. 3 is an explanatory diagram showing the main part of another embodiment of the searcher unit according to the present invention. Like FIG. 2, the main part corresponding to one sector of the searcher unit 3 in FIG. A correlation value detection unit, 22 is a code generation unit, 23 is an averaging processing unit, 24 is a search control unit, 25 is a memory control unit, and 26 is a profile memory.
[0022]
The searcher unit of this embodiment adds a follow-up ON / OFF signal to the averaging unit 23 and the memory control unit 25 to perform switching control of the number of averagings and storage processing control to the profile memory 26. When tracking is on, the averaging unit 23 increases the number of times of averaging to increase the path detection accuracy. When tracking is off, the number of times of averaging is reduced in order to detect the path at high speed. The update cycle of the profile memory 26 is shortened. In this case as well, path detection can be performed with the profile memory 26 having the same capacity. As indicated by the dotted line, a follow-up ON / OFF signal is also input to the search control unit 24 to perform path follow-up control when follow-up is ON, and control so as not to perform path follow-up control when follow-off is performed.
[0023]
FIG. 4 is an explanatory view of the main part of still another embodiment of the searcher unit according to the present invention, and shows the configuration of the main part corresponding to one sector of the searcher unit 3 in FIG. 1, as in FIGS. , 31 is an MF correlation value detection unit, 32 is a code generation unit, 33 is an averaging processing unit, 34 is a search control unit, 35 is a memory control unit, and 36 is a profile memory.
[0024]
The searcher unit of this embodiment performs switching control of the number of times of averaging and switching control of the search interval in addition to the follow-up ON / OFF signal to the averaging unit 33, the memory control unit 35, and the search control unit 34. When follow-up is ON, path search control is performed by shortening the search interval of the search control unit 34 and increasing the averaging count of the averaging processing unit 33, and when follow-off is OFF, the search control unit 34 The search interval is increased, and the averaging processing unit 33 is controlled to reduce the number of averagings so that the path following control is not performed. As a result, the accuracy of the path following control can be increased, and the time required for the synchronous pull-in after the tracking OFF can be shortened without increasing the capacity of the profile memory 36.
[0025]
FIG. 5 is an explanatory diagram of the search interval and the number of times of averaging. (A) shows the search interval at the time of tracking, (b) shows the search interval at the time of non-tracking, and (a) at the time of tracking, that is, in a synchronized state. When tracking is ON, the search interval is set to t, for example, and sample data 1, 2, 3, 4, and 5 are stored in the addresses 1, 2, 3, 4, and 5 of the profile memory. Let the search window at that time be w, for example. Corresponding to the change in the maximum path timing among the five samples, the path follow-up control is performed while keeping the size of the search window w as it is.
[0026]
When (b) is not following, that is, when tracking is OFF in the asynchronous state, the search interval is set to 2t, for example, and sample data 1, 2, 3, 4, 5 are stored in the address 1, 2, 3, 4, 5 of the profile memory. 5 is stored. The capacity of the profile memory is the same as that at the time of tracking, and the search window is set to 2w, so that a wide range can be searched. In that case, the timing accuracy is ½, but the synchronization pull-in becomes easy by widening the search range. If the search interval t at non-following is quadrupled with respect to the search interval t at follow-up, the search window will be quadrupled, and the search range is widened without increasing the profile memory capacity. Detection is easy.
[0027]
(C) shows the number of times of averaging at the time of tracking, and (d) shows the number of times of averaging at the time of non-tracking. For example, when averaging four frames for a radio frame at the time of following (c), the profile memory The update timing for is updated 1, 2, 3 corresponding to the path average 1, 2, 3. In contrast to the following time, when the non-following of (d) is performed, if the wireless frame is switched so as to average two frames, the update timing for the profile memory is the path average 1, 2, 3, 4, 5, 6 Updates 1, 2, 3, 4, 5, and 6 shown corresponding to. That is, the number of pass averaging in the case of path non-following control is made smaller than the number of pass averaging in the case of path following control. In this case, by updating the profile memory at twice the speed, Can be speeded up. Therefore, if the number of times of averaging at the time of non-following is set to 1 / n of the number of times of averaging at the time of following, synchronous pull-in can be performed at a speed n times that at the time of non-following.
[0028]
FIG. 6 is an explanatory diagram of the second embodiment of the present invention, wherein 40 is an IF unit, 41 and 42 are selectors, 43 is a searcher unit, 44 is a finger unit, 45 is an MRC unit, 46 is a synchronization detection unit, Reference numeral 47 denotes an SIR (signal wave to interference wave power ratio) measuring unit.
[0029]
In this embodiment, as in FIG. 1, an IF signal based on a reception signal corresponding to six sectors is output from the IF unit 40, and the selector 41 searches the IF signal corresponding to a maximum of four sectors according to the selection setting signal. The selector 42 inputs the sector-corresponding IF signal according to the sector selection signal from the searcher unit 43 to the finger unit 44, and the finger unit 44 has eight fingers. The finger-corresponding path timing signal is input to the finger unit 44, and the demodulated data of each finger is subjected to rake combining by maximum ratio combining in the MRC unit 45.
[0030]
The synchronization detection unit 46 performs synchronization detection corresponding to each sector based on the pilot symbol of the demodulated data of the finger according to the finger number of the maximum path timing corresponding to the sector from the searcher unit 43, and the result is searched. Notify the unit 43. The SIR measurement unit 47 performs SIR measurement based on the level information of the demodulated data after rake synthesis by the MRC unit 45, determines whether or not a preset threshold value is exceeded, and the synchronization detection unit 46 By switching the tolerance and the number of protection stages, it is possible to perform the follow-up control even when the SIR deteriorates. The searcher unit 43 can be configured to correspond to the sectors shown in FIGS.
[0031]
FIG. 7 is an explanatory diagram of a third embodiment of the present invention, in which 50 is an IF unit, 51 and 52 are selectors, 53 is a searcher unit, 54 is a finger unit, 55 is an MRC unit, 56 is a synchronization detection unit, Reference numeral 57 denotes a common synchronization detector. Except for the synchronization detection unit 56 and the common synchronization detection unit 57, the configuration is substantially the same as in FIGS. 1 and 6, and a duplicate description is omitted.
[0032]
The common synchronization detection unit 57 performs synchronization detection based on the rake combined demodulated data from the MRC unit 55 and adds the detection result to the synchronization detection unit 56. A synchronization signal obtained by synchronization detection is added to a subsequent processing circuit (not shown) for processing demodulated data from the MRC unit 55. The synchronization detection unit 56 detects the synchronization corresponding to the sector based on the demodulated data from the finger of the maximum path timing corresponding to the sector, and detects the synchronization corresponding to the synchronization detection result from the common synchronization detection unit 57. The synchronization detection parameters (tolerance, number of forward protection stages, number of rear protection stages) of the unit 56 are switched, and the sector-related synchronization detection result is added to the searcher unit 53. The searcher unit 53 can be configured to correspond to the sectors shown in FIGS.
[0033]
FIG. 8 is an explanatory diagram of a fourth embodiment of the present invention, in which 60 is an IF unit, 61 and 62 are selectors, 63 is a searcher unit, 64 is a finger unit, 65 is an MRC unit, 66 is a synchronization detection unit, Reference numeral 67 denotes a common synchronization detection unit. Except for the searcher unit 63 and the common synchronization detection unit 57, the configuration is almost the same as in FIGS. 1 and 6, and a duplicate description is omitted. The common synchronization detection unit 67 corresponds to the common synchronization detection unit 57 in FIG. 7, but inputs the detection result to the searcher unit 63.
[0034]
The common synchronization detection unit 67 performs synchronization detection based on the rake-combined demodulated data from the MRC unit 65, inputs the detection result to the searcher unit 63, and the synchronization detection unit 66 includes the synchronization detection unit 6 of FIG. Similarly, the sector-related synchronization detection result is input to the searcher unit 63. The searcher unit 63 switches the search interval, the number of times of averaging, and the like in accordance with the detection results of the sector synchronization / asynchronization by the synchronization detection unit 66 and the channel synchronization / asynchronization by the common synchronization detection unit 67, and The path follow-up control is switched.
[0035]
FIG. 9 is an explanatory diagram of parameters. FIG. 9A shows path detection parameters. The IF signal is assumed to be an oversampled signal at 8 times the spreading factor, and the search interval is specified in units of chips. One chip is a diffusion period, and oversampling of 8 times is sampled at an interval of 1/8 chip.
[0036]
When the path detection control is performed with the synchronization detection result in the synchronous state, the search interval is 1/8 chip, the number of the path averaged frames is 8 frames, the synchronization detection result is in the asynchronous state, and the path non-tracking control is performed. The search interval is ½ chip, and the number of pass averaged frames is one frame. Accordingly, as described in FIGS. 5A and 5B, the capacity of the profile memory is the same, the search interval is four times that of the path follow-up control during the path non-follow-up control, and 1/8. By using this path update cycle, it is possible to widen the search range (search window) and enable path detection at high speed.
[0037]
That is, in the search control units 14 and 34 in FIGS. 2 and 4, the search interval is switched as described above by the follow ON / OFF signal, and in the averaging processing units 23 and 33 in FIGS. Thus, the number of times of averaging is switched by the follow-up ON / OFF signal, so that the search range when follow-off is widened and high-speed synchronous pull-in can be performed.
[0038]
9B shows the synchronization detection parameter, and shows the synchronization detection parameter of the synchronization detection unit 46 when the SIR measurement unit 47 of FIG. 6 is provided. The number of sectors is 6, the maximum number of sectors for path detection of the searcher unit 43 is 4, the number of fingers of the finger unit 44 is 8, and the number of protection frames is shown as the number of radio frames and the tolerance is the number of allowable errors.
[0039]
When the measured SIR is good, when it is not good (not good), and channel synchronization, when the SIR is good, 6 frames of forward protection are used to determine that the synchronization state has changed to the asynchronous state. Suppose that the back protection for judging that the asynchronous state is changed to the synchronous state is 2 frames, the tolerance (number of allowable error bits) is 6 bits, and when the SIR is not good, the forward protection is 8 frames and the backward protection is 1 frame. The parameter is changed so that the tolerance is 8 bits, and the channel synchronization is 4 frames forward protection, 4 frames backward protection, and 10 bits tolerance. Accordingly, when the SIR is good, the parameter is more easily changed from the synchronous state to the asynchronous state than when the SIR is not good, and is not easily changed from the asynchronous state to the synchronous state. In other words, when the SIR is good, the path detection state and the channel synchronization state tend to approximate each other, so that accurate path following control can be performed.
[0040]
FIG. 9C shows parameters of the pass averaging number, the search interval, and the window position. In FIG. 7 or FIG. 8, sector synchronization by the synchronization detection units 56 and 66 and common synchronization detection unit 57 are shown. , 67 in the case of sector synchronization and channel synchronization (1) normal tracking state, sector synchronization and channel asynchronous (2) high-speed tracking operation, sector asynchronous and channel synchronization (3) normal The case of non-tracking operation, sector asynchronous and channel asynchronous is set to (4) initial pull-in state.
[0041]
That is, (1) in the normal follow-up operation, the pass averaging count is 8 frames, the search interval is 1/8 chip, the window position is follow-up, and (2) in the high-speed follow-up state, the pass averaging count is 4 frames. The search interval is 1/8 chip and the window position is tracking. In other words, compared to the normal tracking operation, in the case of high-speed tracking operation that is asynchronous with the channel, the number of times of path averaging is ½ that of the normal tracking operation, and the update interval of the profile memory is shortened, and path tracking control is performed. Speed up.
[0042]
(3) In the normal non-following operation, the search interval is set to 1/4 chip, the search window is widened by the high-speed following operation, and the window position is fixed when it becomes asynchronous. In addition, (4) the initial pull-in state is the case where synchronous pull-in is performed from (3) normal non-following operation, and is the same as the parameters for normal non-following operation. Therefore, the path can be detected at high speed by updating the profile memory at high speed with a wide search window.
[0043]
(Supplementary Note 1) A searcher unit and a finger unit are included, and a predetermined number of sector-corresponding received signals among the received signals corresponding to a plurality of sectors are input to the searcher unit to obtain a correlation value with a spreading code, and the correlation value Corresponding to the maximum path timing corresponding to the sector by the searcher unit in a CDMA receiver that performs despread demodulation processing in the finger unit by following the path of the maximum path timing in the path timing according to Synchronous detection in which the demodulated data of the finger unit is input and synchronously detected, the path tracking control in the searcher unit is performed in the synchronous state, and the path tracking control in the searcher unit is stopped in the asynchronous state A CDMA receiver characterized by comprising a unit.
(Supplementary Note 2) A demodulated data obtained by rake-combining demodulated data of each finger of the finger unit is input, and a common sync detecting unit for detecting synchronization as a channel is provided, and demodulated data of each finger of the finger unit is input. The synchronization detection unit has a configuration for switching a parameter for performing sector-specific synchronization detection corresponding to the synchronization detection result of the common synchronization detection unit, and the searcher unit corresponds to the synchronization detection result of the synchronization detection unit. The CDMA receiver according to appendix 1, wherein either one or both of the search interval and the number of times of path averaging is switched.
(Supplementary Note 3) An SIR measurement unit that inputs demodulated data obtained by rake combining demodulated data of each finger of the finger unit and measures a signal wave to interference wave power ratio is provided, and the synchronization detection unit includes the SIR measurement unit And the searcher unit switches either or both of the search interval and the number of times of path averaging in accordance with the synchronization detection result of the synchronization detection unit. The CDMA receiver according to appendix 1, which has a configuration.
[0044]
(Supplementary Note 4) The synchronization detection unit increases the number of forward protection stages when the signal wave-to-interference wave power ratio is not good compared with the case where the signal wave to interference wave power ratio is good, corresponding to the measurement result of the SIR measurement unit. The CDMA receiving apparatus according to appendix 3, wherein the synchronization detection parameter is switched to reduce the number of stages and to increase the number of allowable error bits as tolerance.
(Supplementary Note 5) The searcher unit includes an MF correlation value detection unit, a code generation unit, an averaging processing unit, a search control unit, a memory control unit, and a profile memory, and the search control unit is a sector by the synchronization detection unit. Based on the corresponding synchronization detection result, it is configured to switch to path follow-up control in the synchronous state, non-path follow-up control in the asynchronous state, and to switch the search interval in the path non-follow-up to be shorter than the search interval in the path follow-up control. The CDMA receiver according to appendices 1 to 4, wherein:
(Supplementary Note 6) The searcher unit includes an MF correlation value detection unit, a code generation unit, an averaging processing unit, a search control unit, a memory control unit, and a profile memory, and the search control unit is a sector by the synchronization detection unit. Depending on the corresponding synchronization detection result, the path tracking control is switched to the synchronous state and the path non-tracking control is switched to the asynchronous state, and the averaging processing unit is configured to perform the path non-tracking control based on the number of times of averaging in the path tracking control. 6. The CDMA receiving apparatus according to any one of appendices 1 to 5, wherein the CDMA receiving apparatus has a configuration in which switching is performed so that the number of times of path averaging is reduced.
[0045]
(Supplementary note 7) A received signal corresponding to a predetermined number of sectors among received signals corresponding to a plurality of sectors is input to obtain a correlation value with a spreading code, and a path having the maximum path timing among path timings according to the correlation value In the path detection control method for tracking control, the demodulated data of the finger part corresponding to the maximum path timing corresponding to the sector by the searcher part is input to detect synchronization corresponding to the sector, and in the searcher part in the synchronized state A path detection control method comprising: performing path tracking control, and stopping path tracking control in the searcher unit in an asynchronous state.
(Appendix 8) According to the synchronization detection result corresponding to the sector, when the synchronization state is established, the search interval in the searcher unit is shortened to perform path follow-up control, and in the asynchronous state, the search interval in the searcher unit is set. The path detection control method according to appendix 7, which includes a step of stopping the path following control by increasing the length.
(Supplementary note 9) According to the synchronization detection result corresponding to the sector, the path follow-up control is performed by increasing the number of times of averaging in the searcher unit in the synchronous state, and the averaging in the searcher unit is performed in the asynchronous state. The path detection control method according to appendix 7, including a step of stopping the path following control by reducing the number of times.
(Additional remark 10) Based on the demodulated data obtained by synthesizing the demodulated data of the finger part at the maximum ratio, the common sync detecting part for detecting the sync and the demodulated data of each finger of the finger part are inputted to detect the sync corresponding to the sector. Corresponding to the synchronization detection result with the synchronization detection unit, the path averaging count and search interval in the searcher unit are switched, and path tracking control is performed at the time of synchronization determination by the synchronization detection unit, and path tracking control is performed at the time of asynchronous determination. The path detection control method according to appendix 7, wherein the path detection control method includes a step of canceling.
(Supplementary note 11) When the signal wave to interference wave power ratio is measured based on the demodulated data obtained by combining the demodulated data of the finger part with the maximum ratio, and the signal wave to interference wave power ratio is good, the case is not good The path detection control method according to claim 7, further comprising a step of switching to a synchronization detection parameter in which the number of forward protection stages is increased, the number of backward protection stages is reduced, and the number of allowable error bits is increased.
[0046]
【The invention's effect】
As described above, the present invention includes a searcher unit 3 and a finger unit 4, and is a CDMA receiving apparatus and path detection control method for processing a received signal corresponding to a plurality of sectors, which corresponds to the sector selected by the selector 1. Based on the IF signal, the searcher unit 3 performs a path search, adds a path timing to the finger of the finger unit 4, selects a sector, controls the selector 2, and selects the sector corresponding IF selected by the selector 2. The signal is input to the finger unit 4, despread demodulation processing and synchronous detection processing are performed to output demodulated data, and the synchronization detection unit 6 performs sector-specific synchronization detection using the finger-corresponding demodulated data, The path follow-up control in the searcher unit 3 is turned on / off according to the synchronization detection result, and the path detection of each sector is performed according to the sector-by-sector synchronization detection result. , And performs follow-up control. Therefore, accurate path following control is possible even when receiving a plurality of sectors.
[0047]
Further, the searcher unit 3 controls either or both of the search interval and the number of times of path averaging in accordance with the sector-corresponding synchronization detection result by the synchronization detection unit 6, and shortens the search interval in the synchronization state. Or, increase the number of pass averaging times to perform path tracking control accurately. In the asynchronous state, increase the search interval, widen the search window, or reduce the number of pass averaging times. The update cycle of the profile memory can be shortened, and the speed of path detection in the path non-following control can be increased.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a first embodiment of the present invention.
FIG. 2 is an explanatory diagram of a main part of an embodiment of a searcher unit according to the present invention.
FIG. 3 is an explanatory diagram of a main part of another embodiment of a searcher unit according to the present invention.
FIG. 4 is an explanatory diagram of a main part of still another embodiment of a searcher unit according to the present invention.
FIG. 5 is an explanatory diagram of a search interval and an averaging count.
FIG. 6 is an explanatory diagram of a second embodiment of the present invention.
FIG. 7 is an explanatory diagram of a third embodiment of the present invention.
FIG. 8 is an explanatory diagram of a fourth embodiment of the present invention.
FIG. 9 is an explanatory diagram of parameters.
FIG. 10 is an explanatory diagram of a conventional example.
[Explanation of symbols]
1, 2 selector
3 Searchers
4 Finger part
5 MRC section
6 Synchronization detector
10 IF section

Claims (4)

A searcher unit and a finger unit are included, and a predetermined number of sector-corresponding received signals among the received signals corresponding to a plurality of sectors are input to the searcher unit to obtain a correlation value with a spreading code, and a path according to the correlation value In a CDMA receiver that performs a despreading demodulation process in the finger unit by following the path of the maximum path timing in the timing,
A synchronization detection unit for detecting synchronization by inputting demodulated data of the finger unit corresponding to the maximum path timing corresponding to the sector by the searcher unit ;
A common synchronization detection unit for detecting synchronization as a channel by inputting demodulated data obtained by rake combining demodulated data of each finger of the finger unit;
The synchronization detection unit has a configuration for switching the synchronization detection parameter based on the synchronization detection result of the common synchronization detection unit and the synchronization detection corresponding to the sector,
The CDMA receiving device , wherein the searcher unit is configured to switch either or both of a search interval and a path average number in accordance with a synchronization detection result of the synchronization detection unit. A demodulated data obtained by rake-combining demodulated data of each finger of the finger unit is input, and an SIR measuring unit that measures a signal wave-to-interference wave power ratio is provided, and the synchronization detecting unit includes a measurement result of the SIR measuring unit. Correspondingly , the searcher unit has a configuration for switching the synchronization detection parameter, and the searcher unit has a configuration for switching either or both of the search interval and the number of path averaging in accordance with the synchronization detection result of the synchronization detection unit . The CDMA receiver according to claim 1. A correlation signal with a spreading code is obtained by inputting a predetermined number of sector-corresponding reception signals among a plurality of sector-corresponding reception signals, and tracking control is performed for the path of the maximum path timing among the path timings according to the correlation value. In the path detection control method to
The process of detecting the synchronization as a channel by inputting demodulated data of the finger part corresponding to the maximum path timing corresponding to the sector by the searcher part ,
The process of switching the synchronization detection parameter based on the synchronization detection as a channel and the synchronization detection corresponding to the sector, and switching either or both of the search interval and the path averaging number corresponding to the synchronization detection as the channel; With
A path detection control method characterized by the above. By inputting a predetermined number of sector-corresponding received signals among a plurality of sector-corresponding received signals, a correlation value with a spreading code is obtained, and tracking control is performed for the path with the maximum path timing in the path timing according to the correlation value. In the path detection control method,
The process of detecting the synchronization corresponding to the sector by inputting the demodulated data of the finger corresponding to the maximum path timing corresponding to the sector by the searcher unit ,
Based on the demodulated data obtained by combining the demodulated data maximum ratio of the finger unit, synchronization detection or signal wave to interference wave power ratio measurement is performed, and the searcher corresponding to the synchronization detection result or signal wave to interference wave power ratio measurement result A path detection control method comprising: a step of inputting demodulated data of a finger part corresponding to the maximum path timing corresponding to a sector by the part and switching a synchronization detection parameter of a synchronization detecting part for detecting synchronization corresponding to the sector .

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