JP2004260355A - Synchronous holer and synchronous holding method in w-cdma communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To vary the number of effective multipaths according to a receiving condition in a synchronous holding state of a W-CDMA communication system. <P>SOLUTION: For determining the number of effective multipaths per cell, a second adder 110 and a holder 111 add correlation values in the descending order to obtain the sum of the correlation values. When the sum of the correlation values exceeds an upper threshold, the addition of the correlation values is ended, and a first comparator 112 and an output unit 113 determine the number of the correlation values added up to this time as a number of effective multipaths. If the sum of the correlation values does not reach the upper threshold, the path search is ended. Based on the previous path search, it is constituted that the upper threshold rises or lowers when the receiving condition is good or bad, respectively, and the number of effective multipaths is decreased or increased when the receiving condition is good or bad, respectively. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a synchronization maintaining device and a synchronization maintaining method in a W-CDMA communication system, and more particularly to synchronization maintenance when receiving a signal spread spectrum by a scrambling code.
[0002]
As one of the IMT-2000 wireless access systems, there is a wideband code division multiple access (W-CDMA) system in which a spread transmission band of a direct sequence code division multiple access (DS-CDMA) system is spread over a wide band of 5 MHz. In this method, the transmitting side spreads transmission data into a wideband signal (chip) using a spreading code and transmits the signal. The transmitted signal arrives at the receiver as a plurality of signals having different propagation delay times via a plurality of propagation paths (multipaths) due to repetition of reflection and the like at an intermediate structure.
[0003]
The receiver separates signals received at different timings into a plurality of multipath component signals having a delay time equal to or longer than one chip length by despreading. Then, the information data is reproduced by estimating the phase variation of the received signal using the pilot signal for each of the separated paths, correcting the phase fluctuation, and combining the signals of the respective path components with the same phase (RAKE combining). I do. With this RAKE reception technique, high reception quality can be obtained.
[0004]
[Prior art]
In the W-CDMA system, in order to generate a phase and a chip timing of a spreading code used in the despreading process, it is necessary to measure a start point of demodulation of received data and to keep capturing the same. Therefore, when a wireless connection is established between the mobile station and the base station, the mobile station measures every 100 milliseconds whether or not synchronization has been deviated from the timing when demodulation was started last time, so that synchronization is not always deviated. Has been corrected. This is called synchronization maintenance or path search.
[0005]
The path search will be described with reference to the timing chart shown in FIG. In the path search, a maximum of 32 base stations that can be wirelessly connected to the mobile device are searched, and the demodulation start timing is detected for about 1 to 8 effective base stations. As shown in the upper part of FIG. 16, for an effective base station, a path search is performed over one frame (10 milliseconds). A path search for a station that is not a valid base station among the 32 base stations searched is performed in the remaining time of 100 milliseconds.
[0006]
Then, as shown in the lower part of FIG. 16, in one path search, a pilot signal for one frame is despread from each sample within a range of 640 samples before and after the previous path search timing. The obtained result is the power (I ² + Q ² ) And are added for one frame. Thereby, for example, a correlation result as shown in FIG. 17 is obtained. The correlation value indicated by the correlation result is path power obtained by performing a path search for each sample for each of a plurality of base stations that can be wirelessly connected.
[0007]
In the correlation results shown in FIG. 17, the sample showing the largest correlation value is the first valid path. Except for the first valid path and a range of a predetermined number of samples (for example, three samples) from this path, the sample having the next highest correlation value is the second valid path. With respect to the third valid path, the first and second valid paths and the samples having the maximum correlation value are excluded from these paths, except for a predetermined number of samples. Will be a valid path. Similarly, the fourth and subsequent paths, for example, eight valid paths are detected.
[0008]
Of the valid paths of all the detected valid base stations, for a predetermined number, for example, eight, of the valid paths, a plurality of, for example, eight of the same configurations provided in the RAKE receiver are provided. Receivers (fingers) are assigned one by one. The number of effective paths assigned to the finger is not limited to eight, but is fixed in advance by design specifications or the like.
[0009]
A conventional method of allocating fingers to a path search result will be described with reference to FIGS. 18 to 20 by taking an example in which the number of effective paths allocated to fingers is fixed to eight. In the example illustrated in FIG. 18, the number of valid base stations is 3, and eight valid paths are provided for each base station, for a total of 24, and eight valid paths are allocated to eight fingers.
[0010]
As shown in FIG. 18, among the eight valid paths of the first base station, the path having the first path when arranged in the order of the path power, that is, the correlation value, and the second base station Similarly, a path having the first path order and a path having the first path order for the third base station are similarly assigned to three fingers. The remaining five fingers include seven paths having a first base station with a path ranking of 2 to 8, a second base station with seven paths having a path ranking of 2 to 8, and a third base station. Out of the seven paths having the second to eighth ranks, five paths are allocated in ascending order of path power.
[0011]
In the example illustrated in FIG. 18, the remaining five fingers include three paths of the first base station having the second to fourth ranks, a path of the second base station having the second rank, and a third base station. Of the base station is assigned the second highest path. If the number of valid base stations is 8, the eight fingers will be filled with the first-ranked path for each of the eight valid base stations. There is no assignment.
[0012]
The example shown in FIG. 19 is a case where there is only one valid base station. Since the number of fingers assigned to one base station is limited to four, the path of the first to fourth ranks of the only valid base station is assigned to four fingers. The remaining four fingers have no path assignment.
[0013]
The example shown in FIG. 20 is a case where there are two valid base stations. In this case, the four paths of the first base station having the first to fourth ranks and the four paths of the second base station having the first to fourth ranks are allocated to eight fingers. Since the number of assignable fingers per base station is limited to four, as shown in FIG. 20, the fifth path of the first base station is higher than the fourth path of the second base station. Even if the path power is high, it is not assigned to a finger.
[0014]
The path assigned to the finger as described above is used as an effective multipath for in-phase synthesis and data demodulation processing. Here, an effective path and an effective multipath are paths that greatly contribute to improvement in power in RAKE reception. As described above, in order to obtain a valid multipath, detection of a predetermined number of valid base stations, detection of a predetermined number of valid paths for each base station, sorting of all detected valid paths, and the like are performed. For this reason, current consumption increases, but a technique for reducing current consumption in a path search has been proposed (see Patent Document 1).
[0015]
[Patent Document 1]
JP 2000-101549 A
[0016]
[Problems to be solved by the invention]
As described above, in the conventional path search, the number of effective multipaths is fixed according to design specifications or the like. Therefore, when there are few effective base stations, even if the reception state is good, eight effective multipaths are equal to eight. Assigned to one finger. Also, when there is one valid base station, four valid multipaths are allocated to the four fingers regardless of whether the reception condition is good or bad. Even if there is one effective base station, if the reception condition is good, high reception quality can be obtained without assigning four effective multipaths to the fingers. Nevertheless, since a fixed number of fingers are operated, there is a problem that wasteful power is consumed.
[0017]
In addition, when the number of effective base stations is small and the reception state is poor, sufficient reception quality may not be obtained even if a predetermined number of fingers are operated. In such a case, if RAKE combining can be performed by allocating as many effective multipaths as possible to the fingers, when performing demodulation and error correction, the correction capability becomes higher and the reception quality can be improved. . However, conventionally, since only a predetermined number of fingers operate, the reception quality cannot be improved.
[0018]
The present invention has been made in view of the above problems, and provides a synchronization holding device and a synchronization holding method in a W-CDMA communication system that can increase or decrease the number of effective multipaths according to a reception state. With the goal.
[0019]
[Means for Solving the Problems]
In order to achieve the above object, according to the present invention, when determining the effective number of multipaths for each cell, correlation values are added in order from a higher order by an integrating means (a second adding unit and a holding unit), and the sum of the correlation values is calculated. Is determined, and when the sum of the correlation values exceeds the upper limit threshold, the addition of the correlation values is terminated, and the number of correlation values added up to that time is validated by the determining means (first comparing unit and output unit). The number of multipaths is determined. In addition, before the sum of the correlation values exceeds the upper limit threshold, the determining means (the first comparison unit and the output unit) determines that the maximum number of correlation values that have been added reaches the maximum number of effective multipaths. The number of valid multipaths is determined as the number of valid multipaths.
[0020]
Further, a lower limit threshold value is provided. If the sum of the correlation values does not reach the lower limit threshold value, it is determined that all the obtained correlation values are noise, and a request (path search stop flag) for ending the path search is issued. It has means for issuing. Further, based on the result of the previous path search, the upper limit threshold is updated by the upper limit threshold updating unit (the first upper threshold changing unit or the second upper threshold changing unit), and the lower threshold updating unit (lower limit) is changed. (Threshold variation unit) to lower the lower threshold.
[0021]
According to the present invention, when the reception state is good, the number of effective multipaths is reduced by increasing the upper threshold. When the reception state is poor, the number of effective multipaths is increased by lowering the lower threshold.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing an example of a multipath detection module of the synchronization holding device according to the present invention. As shown in FIG. 1, the multipath detection module includes a sequencer unit 1, a matched filter (MF) unit 2, a power conversion unit 3, a first addition unit (addition unit 1) 4, an integration RAM 5, a peak detection unit 6, A result register 7, a setting register 8, and a threshold controller 9 are provided.
[0023]
The sequencer unit 1 performs sequence control of data processing in each unit of the matched filter (MF) unit 2, the power conversion unit 3, the first addition unit 4, the integration RAM 5, and the peak detection unit 6. The matched filter unit 2 despreads the input data according to the code provided from the sequencer unit 1 and outputs the result. The input data is a soft-decision signal that has been converted into a digital signal and has not been subjected to gain control.
[0024]
The power conversion section 3 calculates the despread result given from the matched filter section 2 as I ² + Q ² Is calculated, and the result is output. The first addition unit 4 and the integration RAM 5 output a correlation result obtained by adding one frame of data serially transmitted from the power conversion unit 3 for each symbol. The peak detection unit 6 detects the peak of the correlation value based on the correlation result output from the integration RAM 5, and detects the top eight paths having the highest correlation value. The result register 7 stores the eight paths detected by the peak detection.
[0025]
The maximum number of valid multipaths, the upper limit threshold, the upper limit increase threshold 1, the upper limit increase width 1, the upper limit decrease threshold 1, the upper limit decrease width 1, and the upper limit increase are written into the setting register 8 by external writing or writing by the threshold controller unit 9. Threshold 2, upper limit 2, upper limit 2, lower limit 2, upper limit of upper limit, lower limit of upper limit, upper limit change enable 1, upper limit change enable 2, lower limit, lower lower limit, lower limit A total of 21 parameters of the number of times of lowering, the lowering width, the lower initial value, the lower limit of the lower threshold, and the lower threshold variation enable are set. The contents of each parameter will be described later.
[0026]
The threshold controller 9 controls updating of various thresholds, which will be described later, based on various parameters set in the setting register 8 and the correlation values and the ranks of the paths detected by the peak detection unit 6. And setting a path search stop flag. The detailed configuration and operation of the threshold controller 9 will be described later.
[0027]
The contents of the above 21 parameters will be described. The maximum number of valid multipaths is an allowable value of the number of valid multipaths. The upper threshold value is the upper limit value of the sum of correlation values when determining the number of effective multipaths.
[0028]
The upper limit raising threshold 1 is an effective multipath power, that is, a threshold of the average value of the correlation values when the upper limit threshold is raised. If the average value of the valid multipath correlation values is greater than the upper threshold 1, the upper threshold is raised. If the average value of the effective multipath correlation values is equal to or less than the upper threshold 1, the upper threshold is not raised, but is left unchanged or lowered. The upper limit increase width 1 is a value of the increase amount of the upper limit increase threshold 1.
[0029]
The upper limit lowering threshold 1 is a threshold value of the average value of effective multipath correlation values when lowering the upper limit threshold. When the average value of the effective multipath correlation values is smaller than the upper limit lowering threshold 1, the upper limit threshold is lowered. When the average value of the effective multipath correlation values is equal to or more than the upper limit lowering threshold value 1, the upper limit threshold value is not reduced and is left as it is or is raised. The upper limit lowering range 1 is a value of the lowering range of the upper limit lowering threshold 1.
[0030]
The upper limit raising threshold 2 is a threshold of the number of effective multipaths when raising the upper limit threshold. If the number of valid multipaths is greater than the upper limit threshold 2, the upper limit threshold is increased. If the number of valid multipaths is equal to or less than the upper limit raising threshold 2, the upper limit threshold is not raised, but is left as it is or is lowered. The upper limit increase width 2 is a value of the increase amount of the upper limit increase threshold value 2.
[0031]
The upper limit lowering threshold 2 is a threshold of the number of effective multipaths when lowering the upper limit threshold. If the number of valid multipaths is smaller than the upper limit lowering threshold 2, the upper limit threshold is lowered. If the number of valid multipaths is equal to or more than the upper limit lowering threshold 2, the upper limit threshold is not lowered, but is left as it is or is raised. The upper limit lowering range 2 is a value of the lowering range of the upper limit lowering threshold 2.
[0032]
The upper limit of the upper threshold is the maximum allowable value of the upper threshold when the upper threshold is increased. The lower limit of the upper threshold is the minimum allowable value of the upper threshold when lowering the upper threshold. That is, the upper threshold value is a value in the range from the lower limit value of the upper threshold value to the upper limit value of the upper threshold value.
[0033]
The upper limit threshold variation enable 1 is a flag for setting whether or not to perform control for varying the upper limit threshold by the upper limit threshold 1 and the lower limit threshold 1. The upper limit threshold variation enable 2 is a flag for setting whether or not to perform control for varying the upper limit threshold by the upper limit threshold 2 and the lower limit threshold 2.
[0034]
The lower limit threshold value is a lower limit value of the sum of correlation values when determining the number of effective multipaths. The lower limit lowering threshold is an allowable value of the number of times that the sum of the correlation values may be smaller than the lower limit threshold. The lower limit lowering frequency is an allowable value of the number of times the lower threshold can be changed. As long as the number of times that the sum of the correlation values becomes smaller than the lower limit threshold exceeds a predetermined number (lower limit lowering threshold) and does not exceed the allowable value (lower limit lowering number), the lower threshold can be lowered. Exceeds the allowable value (the lower limit number of times), the lower threshold cannot be lowered.
[0035]
The lower limit reduction width is a value of the lower limit threshold reduction width. The lower limit initial value is an initial value of the lower limit threshold value. The lower limit of the lower threshold is the minimum allowable value of the lower threshold when lowering the lower threshold. That is, the lower threshold value can be reduced only to the lower limit value of the lower threshold value. The lower threshold variation enable is a flag for setting whether or not to perform control for varying the lower threshold by the lower threshold.
[0036]
Next, the threshold controller 9 will be described. FIG. 2 shows a top symbol of the threshold controller 9 and its input / output signals. As shown in FIG. 2, the threshold value controller section 9 includes a correlation value of the path search result and the order of the correlation value, the number of masked paths, the value of each parameter stored in the setting register 8, the path search start timing clock, and the like. , A target base station change timing clock, and a clock for each path detection. The threshold controller 9 outputs the number of valid multipaths, the path search stop flag, and the updated value of the setting register 8. The updated parameters are an upper threshold and a lower threshold.
[0037]
FIG. 3 is a block diagram illustrating an example of a schematic configuration of the threshold controller 9. As shown in FIG. 3, the threshold controller 9 includes a multipath number detector 11 that determines the number of effective multipaths, and a first upper threshold variation unit (upper limit) that functions as an upper threshold update unit that performs variation control of the upper threshold. A threshold variation unit 1) 13 and a second upper threshold variation unit (upper threshold variation unit 2) 15 and a lower threshold variation unit 17 functioning as a lower threshold updating unit for performing variation control of the lower threshold are provided. There is no logic between the multipath number detecting unit 11, the first upper threshold changing unit 13, the second upper threshold changing unit 15, and the lower threshold changing unit 17.
[0038]
FIG. 4 is a block diagram illustrating an example of the configuration of the multipath number detection unit 11. As shown in FIG. 4, the multipath number detection unit 11 includes a second addition unit (addition unit 2) 110, for example, a holding unit 111 including a flip-flop circuit, a first comparison unit (comparison unit 1) 112, and an output. A portion 113 is provided. The correlation values detected in descending order of the correlation values by the same peak detection as in the related art with respect to the correlation results obtained by the path search are sent to the multipath number detection unit 11 together with the rank at the end of each peak detection.
[0039]
The second adding unit 110 adds the transmitted correlation value to the sum of the correlation values sent up to the previous time, and updates the sum of the correlation values. The sum of the correlation values sent up to the previous time is held in the holding unit 111. The holding unit 111 outputs the sum of the held correlation values in synchronization with the clock for each path detection. The total sum of the correlation values output from the holding unit 111 is supplied to the second adding unit 110 for updating the total sum of the correlation values at the next time, and is also supplied to the first comparing unit 112 and a subsequent block. . The holding unit 111 holds the new sum of the correlation values updated by the second adding unit 110 until the next update of the sum of the correlation values. The second adding unit 110 and the holding unit 111 have a function as an integrating unit.
[0040]
The first comparing unit 112 compares the sum of the correlation values supplied from the holding unit 111 with the upper threshold value supplied from the setting register 8. Further, the first comparing unit 112 compares the rank of the correlation value with the maximum number of effective multipaths supplied from the setting register 8. As a result of the two comparisons, the first comparing unit 112 outputs “0” to the output unit 113 when the sum of the correlation values is smaller than the upper threshold and the rank of the correlation values is equal to or less than the maximum number of effective multipaths. Is output. In addition, the first comparing unit 112 outputs “1” to the output unit 113 when the sum of the correlation values is equal to or larger than the upper threshold or when the rank of the correlation values is larger than the maximum number of valid multipaths.
[0041]
When “1” is supplied from the first comparing unit 112, the output unit 113 outputs the order of the correlation value as the number of effective multipaths to the subsequent block and sets the reset signal to “0”. When the reset signal becomes “0”, the holding unit 111 is reset, and the sum of the correlation values held in the holding unit 111 is cleared. On the other hand, when “0” is supplied from the first comparing unit 112, the output unit 113 outputs “0” as the number of effective multipaths to the subsequent block and sets the reset signal to “1”. The first comparing unit 112 and the output unit 113 have a function as a determining unit.
[0042]
Here, if the upper limit threshold is set to a sufficiently large value, the rank of the correlation value becomes larger than the maximum number of effective multipaths in the first comparison unit 112 before the sum of the correlation values becomes equal to or larger than the upper limit threshold. That is, the maximum effective multipath number is output to the subsequent block as the effective multipath number. Therefore, by setting the upper limit threshold to a sufficiently large value and setting the maximum number of effective multipaths to a desired value, the number of effective multipaths can be forcibly set to a desired number.
[0043]
FIG. 5 is a block diagram illustrating an example of a configuration of the first upper threshold variation unit 13. As shown in FIG. 5, the first upper threshold variation unit 13 includes an averaging unit 130, a second comparison unit 131 (comparison unit 2), a first determination unit (determination unit 1) 132, and a third comparison unit. Section (comparing section 3) 133, second determining section (determining section 2) 134, third adding section (adding section 3) 135, first selector (selector 1) 136, first subtracting section (subtracting section). 1) 137, a second selector (selector 2) 138, and a third selector (selector 3) 139.
[0044]
The averaging unit 130 receives the sum of the correlation values, the number of valid multipaths, and the reset signal from the multipath number detection unit 11. Then, when the reset signal becomes “0”, the averaging section 130 divides the sum of the correlation values by the number of effective multipaths, and outputs the calculated sum of the correlation values to the second comparing section 131 and the third comparing section 133. Output the average value. When the reset signal is “1”, the averaging unit 130 does not perform the division, so that the average value of the correlation values is not output.
[0045]
The second comparing section 131 compares the average value of the correlation values supplied from the averaging section 130 with the upper limit raising threshold 1 supplied from the setting register 8. As a result of the comparison, if the average value of the correlation values is greater than the upper threshold 1, the second comparing unit 131 outputs “1” to the first determining unit 132 for each valid detection base station (cell). . If the average value of the correlation values is equal to or less than the upper threshold 1, the second comparing unit 131 outputs “0”.
[0046]
The first determination unit 132 captures the value output from the second comparison unit 131 in synchronization with the target base station change timing clock and the clock for each path detection. Then, the first determination unit 132 sets “3” to the third selector 139 when all the values received from the second comparison unit 131 are “1” for each valid detection base station (cell). Output. The first determination unit 132 outputs “0” when at least one value received from the second comparison unit 131 is “0”.
[0047]
The third comparing unit 133 compares the average value of the correlation values supplied from the averaging unit 130 with the upper limit lowering threshold value 1 supplied from the setting register 8. As a result of the comparison, if the average of the correlation values is smaller than the upper limit lowering threshold 1, the third comparing unit 133 outputs “1” to the second determining unit 134 for each valid detection base station (cell). . If the average value of the correlation values is equal to or greater than the upper limit lowering threshold 1, the third comparing unit 133 outputs “0”.
[0048]
The second determination unit 134 captures the value output from the third comparison unit 133 in synchronization with the target base station change timing clock and the clock for each path detection. Then, when all the values received from the third comparison unit 133 are “1” for each valid detection base station (cell), the second determination unit 134 sets “3” to the third selector 139. Output. The second determination unit 134 outputs “0” when at least one of the values received from the third comparison unit 133 is “0”.
[0049]
The third adder 135 adds the upper limit increase width 1 to the upper limit threshold supplied from the setting register 8 and outputs the result to the first selector 136. The first selector 136 selects the smaller one of the value supplied from the third adder 135 and the upper limit value of the upper limit threshold value supplied from the setting register 8, and sets the selected value to the third value. Output to selector 139. That is, the upper limit threshold is updated by the third adder 135 and the first selector 136 to a value larger by the upper limit increase width 1. However, if the value obtained by increasing the upper threshold by the upper limit increase width 1 becomes larger than the upper limit of the upper threshold, the upper threshold is updated to the upper limit of the upper threshold.
[0050]
The first subtraction unit 137 subtracts the upper limit lowering width 1 supplied from the setting register 8 from the upper limit threshold, and outputs the result to the second selector 138. The second selector 138 selects the larger one of the value supplied from the first subtractor 137 and the lower limit of the upper threshold supplied from the setting register 8, and sets the selected value to the third value. Output to selector 139. That is, the upper limit threshold is updated by the first subtractor 137 and the second selector 138 to a value smaller by the upper limit lowering width 1. However, if the value obtained by reducing the upper threshold by the upper limit lowering width 1 becomes smaller than the lower limit of the upper threshold, the upper threshold is updated to the lower limit of the upper threshold.
[0051]
The third selector 139 outputs the output of the first selector 136 based on the values supplied from the first determination unit 132 and the second determination unit 134 and the value of the upper limit threshold variation enable 1 of the setting register 8. One of the value, the output value of the second selector 138, and the upper threshold stored in the setting register 8 is selected. Then, the third selector 139 outputs the selected value as the upper limit threshold.
[0052]
Specifically, when the upper threshold change enable 1 is “1” and the output value of the first determination unit 132 is “1”, the third selector 139 outputs the output of the first selector 136. The value is output as the updated upper threshold. When the upper threshold change enable 1 is “1” and the output value of the second determination unit 134 is “1”, the third selector 139 sets the output value of the second selector 138 to Output as the updated upper threshold. Both the output value of the first determination unit 132 and the output value of the second determination unit 134 do not become “1”.
[0053]
On the other hand, if the upper threshold change enable 1 is “1” and both the output value of the first determination unit 132 and the output value of the second determination unit 134 are “0”, the upper threshold is changed. No control is performed. Therefore, the third selector 139 outputs the upper limit threshold value stored in the setting register 8 as it is. Also, when the upper threshold change enable 1 is “0”, the third selector 139 outputs the upper threshold stored in the setting register 8 as it is. In FIG. 5, the output of the third selector 139, that is, the output of the first upper threshold variation unit 13 is set as the upper threshold (temporary).
[0054]
FIG. 6 is a block diagram illustrating an example of the configuration of the second upper threshold change unit 15. As shown in FIG. 6, the second upper threshold changing unit 15 includes a fourth comparing unit (comparing unit 4) 150, a third determining unit (determining unit 3) 151, and a fifth comparing unit (comparing unit 5). ) 152, a fourth determination unit (determination unit 4) 153, a fourth addition unit (addition unit 4) 154, a fourth selector (selector 4) 155, a second subtraction unit (subtraction unit 2) 156, The fifth selector (selector 5) 157 and the sixth selector (selector 6) 158 are provided.
[0055]
The fourth comparing unit 150 receives the number of valid multipaths from the number of multipaths detecting unit 11, and compares the number of valid multipaths with the upper limit threshold 2 stored in the setting register 8. As a result of the comparison, if the number of effective multipaths is larger than the upper threshold 2, the fourth comparing section 150 outputs “1” to the third determining section 151 for each valid detecting base station (cell). If the number of effective multipaths is equal to or less than the upper threshold 2, the fourth comparing section 150 outputs “0”.
[0056]
The third determination unit 151 fetches the value output from the fourth comparison unit 150 in synchronization with the target base station change timing clock and the clock for each path detection. Then, when all the values received from the fourth comparing unit 150 are “1” for each valid detection base station (cell), the third determination unit 151 sets “6” to the sixth selector 158. Output. The third determination unit 151 outputs “0” when at least one value received from the fourth comparison unit 150 is “0”.
[0057]
The fifth comparing section 152 receives the number of valid multipaths from the multipath number detecting section 11 and compares the number of valid multipaths with the upper limit lowering threshold value 2 stored in the setting register 8. As a result of the comparison, if the number of valid multipaths is smaller than the upper limit lowering threshold 2, the fifth comparing section 152 outputs “1” to the fourth determining section 153 for each valid detecting base station (cell). If the number of effective multipaths is equal to or larger than the upper limit lowering threshold 2, the fifth comparing section 152 outputs “0”.
[0058]
The fourth determination unit 153 fetches the value output from the fifth comparison unit 152 in synchronization with the target base station change timing clock and the clock for each path detection. Then, when all the values received from the fifth comparing unit 152 are “1” for each valid detected base station (cell), the fourth determining unit 153 sets “6” to the sixth selector 158. Output. The fourth determination unit 153 outputs “0” when at least one of the values received from the fifth comparison unit 152 is “0”.
[0059]
The fourth adding unit 154 adds the upper limit increase width 2 supplied from the setting register 8 to the upper limit threshold (provisional) supplied from the first upper threshold changing unit 13, and outputs the result to the fourth selector 155. Output to The fourth selector 155 selects the smaller one of the value supplied from the fourth adder 154 and the upper limit value of the upper limit threshold supplied from the setting register 8, and sets the selected value to the sixth value. Output to selector 158. That is, the upper limit threshold (temporary) is updated to a value larger by the upper limit increase width 2 by the fourth adder 154 and the fourth selector 155. However, if the value obtained by increasing the upper limit threshold (provisional) by the upper limit increase width 2 becomes larger than the upper limit of the upper limit threshold, the upper limit threshold (provisional) is updated to the upper limit value of the upper limit threshold.
[0060]
The second subtraction unit 156 subtracts the upper limit reduction width 2 supplied from the setting register 8 from the upper limit threshold (temporary), and outputs the result to the fifth selector 157. The fifth selector 157 selects the larger one of the value supplied from the second subtractor 156 and the lower limit of the upper threshold supplied from the setting register 8, and sets the selected value to the sixth value. Output to selector 158. That is, the upper limit threshold (temporary) is updated to a value smaller by the upper limit lowering width 2 by the second subtractor 156 and the fifth selector 157. However, if the value obtained by reducing the upper threshold (temporary) by the upper limit lowering width 2 becomes smaller than the lower limit of the upper threshold, the upper threshold (temporary) is updated to the lower limit of the upper threshold. .
[0061]
The sixth selector 158 outputs the output of the fourth selector 155 based on the values supplied from the third determination unit 151 and the fourth determination unit 153 and the value of the upper threshold variation enable 2 of the setting register 8, respectively. One of the value, the output value of the fifth selector 157, and the upper threshold (temporary) is selected, and the selected value is output as the upper threshold. The upper threshold value output from the sixth selector 158 is stored in the setting register 8.
[0062]
Specifically, when the upper threshold variation enable 2 is “1” and the output value of the third determination unit 151 is “1”, the sixth selector 158 outputs the output of the fourth selector 155. The value is output as the updated upper threshold. When the upper threshold variation enable 2 is “1” and the output value of the fourth determination unit 153 is “1”, the sixth selector 158 sets the output value of the fifth selector 157 to Output as the updated upper threshold. The output value of the third determination unit 151 and the output value of the fourth determination unit 153 do not both become “1”.
[0063]
On the other hand, if the upper limit threshold variation enable 2 is “1” and both the output value of the third determination unit 151 and the output value of the fourth determination unit 153 are “0”, the upper threshold value is varied. No control is performed. Therefore, the sixth selector 158 outputs the upper limit threshold (provisional) supplied from the first upper threshold change unit 13 as it is as the upper limit threshold. Also, when the upper threshold change enable 2 is “0”, the sixth selector 158 outputs the upper threshold (temporary) as it is as the upper threshold.
[0064]
FIG. 7 is a block diagram illustrating an example of the configuration of the lower threshold change unit 17. As shown in FIG. 7, the lower threshold change unit 17 includes a sixth comparing unit 170, a first counter (counter 1) 171, a seventh comparing unit (comparing unit 7) 172, and a second counter (counter 2). 173, an eighth comparing section (comparing section 8) 174, a third subtracting section (subtracting section 3) 175, a seventh selector (selector 7) 176, and an eighth selector (selector 8) 177. . The lower limit threshold changing unit 17 determines the number of effective multipaths when a path search results in a correlation result having only a small peak of a correlation value that is buried in noise, for example, as shown in FIG. It has a function of lowering the lower threshold in order to increase it.
[0065]
The sixth comparing section 170 receives the sum of the correlation values from the multipath number detecting section 11 and compares the sum of the correlation values with the lower limit threshold stored in the setting register 8. As a result of the comparison, if the sum of the correlation values is smaller than the lower threshold, the sixth comparing section 170 outputs “1” to the first counter 171. The sixth comparing section 170 turns on the path search stop flag. When the path search stop flag is turned on, the path search is stopped, and a new path search is performed. If the sum of the correlation values is equal to or greater than the lower threshold, the sixth comparing unit 170 outputs “0” and turns off the path search stop flag.
[0066]
The first counter 171 receives the output value of the sixth comparing section 170 in synchronization with a clock for each path detection. Then, when receiving the “1”, the first counter 171 increments the count value by one. That is, the first counter 171 counts the number of times the path search stop flag is turned on (the number of times the path search is stopped). The first counter 171 outputs the coefficient value to the seventh comparing section 172. The first counter 171 is reset when the lower threshold variation enable of the setting register 8 is “0”.
[0067]
The seventh comparing section 172 compares the number of times the path search stop flag received from the first counter 171 is turned on with the lower limit lowering threshold value supplied from the setting register 8. As a result of the comparison, if the number of ONs of the path search stop flag is larger than the lower limit lowering threshold, the seventh comparing unit 172 sets “1” to the second counter 173, the eighth selector 177, and the first counter 171. Output. If the number of ONs of the path search stop flag is equal to or smaller than the lower limit lowering threshold, the seventh comparing unit 172 outputs “0”. When the output value of the seventh comparing section 172 becomes “1”, the first counter 171 is cleared.
[0068]
Upon receiving “1” from the seventh comparing section 172, the second counter 173 increments the count value by one. In other words, the second counter 173 counts the number of times that the number of times the path search stop flag is turned on is greater than the number specified by the lower limit lowering threshold. The second counter 173 outputs the coefficient value to the eighth comparing section 174. The second counter 173 is reset when the lower threshold variation enable is “0”.
[0069]
The eighth comparing unit 174 compares the count value of the second counter 173, that is, the number of times that the number of times the path search stop flag is turned on exceeds the lower limit lowering threshold, with the lower limit lowering number supplied from the setting register 8. . As a result of the comparison, if the number of times that the ON number of the path search stop flag exceeds the lower limit lowering threshold is larger than the lower limit lowering number, the eighth comparing unit 174 sets the eighth selector 177 and the second counter 173 to “ 1 "is output. If the number of times that the ON number of the path search stop flag exceeds the lower limit lowering threshold is equal to or less than the lower limit lowering threshold, the eighth comparing unit 174 outputs “0”. When the output value of the eighth comparing section 174 becomes “1”, the second counter 173 is cleared.
[0070]
The third subtraction unit 175 subtracts the lower limit reduction width supplied from the setting register 8 from the lower threshold, and outputs the result to the seventh selector 176. The seventh selector 176 selects the larger one of the value supplied from the third subtractor 175 and the lower limit value of the lower limit threshold value supplied from the setting register 8, and sets the selected value to the eighth value. Output to selector 177. That is, the third subtractor 175 and the seventh selector 176 update the lower limit threshold to a value smaller by the lower limit reduction width. However, if the value obtained by reducing the lower threshold by the lower limit lowering width is smaller than the lower limit of the lower threshold, the lower threshold is updated to the lower limit of the lower threshold.
[0071]
The eighth selector 177 determines the output value of the seventh selector 176 and the setting register 8 based on the values supplied from the seventh comparing unit 172 and the eighth comparing unit 174 and the value of the lower threshold variation enable signal, respectively. One of the lower limit threshold value and the lower limit initial value stored in. Then, the eighth selector 177 outputs the selected value as a lower threshold. The lower threshold value output from the eighth selector 177 is stored in the setting register 8.
[0072]
Specifically, when the lower threshold variation enable is “1” and the output value of the seventh comparing unit 172 and the output value of the eighth comparing unit 174 are “1” and “0” respectively, The eighth selector 177 outputs the output value of the seventh selector 176 as the updated lower threshold. When the lower threshold variation enable is “1”, the output value of the seventh comparing unit 172 is “0”, or the output value of the seventh comparing unit 172 and the output value of the eighth comparing unit 174 are If the output values are both "1", the control for changing the lower threshold is not performed. Therefore, the eighth selector 177 outputs the lower limit threshold value stored in the setting register 8 as it is.
[0073]
On the other hand, when the lower threshold variation enable is “0”, the eighth selector 177 outputs the lower initial value. That is, when the number of times the path search is stopped because the sum of the correlation values is less than the lower threshold exceeds a predetermined number defined by the lower lower threshold, the lower threshold changing unit 17 sets the lower threshold to the lower threshold. Within a range that does not become smaller than the lower limit of the threshold value, the value is updated to a value smaller by the lower limit reduction amount. However, if the number of updates exceeds a predetermined number defined by the lower limit number of times, further updates cannot be made.
[0074]
As described above, the first upper threshold variation unit 13, the second upper threshold variation unit 15, and the lower threshold variation unit 17 perform the threshold operation by the upper threshold variation enable 1, the upper threshold variation enable 2, and the lower threshold variation enable, respectively. It is controlled whether or not the fluctuation processing is performed. In particular, only one of the first upper threshold variation unit 13 and the second upper threshold variation unit 15 needs to be valid. However, when both the first upper threshold variation unit 13 and the second upper threshold variation unit 15 are enabled, the upper threshold variation enable 1 and the upper threshold variation enable 2 are set to the first upper threshold variation unit 13. Is controlled such that the upper limit threshold (temporary) output from is input to the second upper threshold changing unit 15.
[0075]
Next, the processing performed in the multipath number detection unit 11 will be described. FIG. 8 is a flowchart illustrating an example of the multipath number detection process. When the process is started, first, a value obtained by adding the correlation values sent up to immediately before (in the order of higher correlation values), that is, the sum of the correlation values (cumulative correlation value) is equal to the upper threshold. It is determined whether the number is smaller than the maximum value and whether the rank (path #) of the correlation value sent immediately before is equal to or less than the maximum number of valid multipaths (step S801).
[0076]
The correlation values are sent in descending order. Therefore, for example, if a third-order correlation value (= c) is sent after a first-order correlation value (= a) and a second-order correlation value (= b), In step S801, it is determined whether a value obtained by adding the first-order correlation value, the second-order correlation value, and the third-order correlation value (= a + b + c) is smaller than an upper limit threshold. Also, since the third correlation value has been sent, the number of paths is three. Therefore, it is determined whether or not 3 is equal to or less than the maximum effective multipath number.
[0077]
As a result of the determination in step S801, when the sum of the correlation values is smaller than the upper limit threshold value and the number of paths is equal to or less than the maximum number of valid multipaths (Yes in step S801), the next rank is added to the sum of the correlation values. Are added to obtain a new sum of correlation values, and the number of paths is incremented by 1 (steps S802 and S803). This is repeated until the sum of the correlation values becomes equal to or larger than the upper limit threshold value or until the path # becomes larger than the maximum number of valid multipaths, that is, until the result of step S801 becomes “no”.
[0078]
If the answer is NO in step S801, the counting of the number of paths is terminated, and the sum of the correlation values at that time is output (step S804). Then, the reset signal is set to “0” (step S805). This clears the sum of the correlation values and the count value of the number of passes. In addition, the count value of the number of paths at that time is output as the number of effective multi-paths (step S806), and the process ends. Here, when the upper limit threshold is set to a sufficiently large value, the number of effective multipaths is the value set to the maximum number of effective multipaths. In the process shown in FIG. 8, the number of paths is counted each time the newly sent correlation value is added. However, since the order is sent together with the correlation value, the order sent is added to the path. It may be used as a count value of a number.
[0079]
Next, the processing performed in the first upper threshold variation unit 13 will be described. FIG. 9 is a flowchart illustrating an example of the first upper threshold variation process. When the process is started, first, it is confirmed that the upper threshold change enable 1 is on (step S901). If the upper threshold variation enable 1 is off (step S901: No), the process ends. That is, the upper limit threshold is not updated, but remains as it is.
[0080]
If the upper threshold variation enable 1 is on (step S901: Yes), the processes from step S903 to step S910 described below are repeated for the effective base stations (the first to eighth base stations). (Step S902). In the processing from step S903 to step S910 in the first round, processing is performed for the first base station (cell).
[0081]
The sum of the correlation values is divided by the number of effective multipaths to obtain an average of the correlation values (step S903). It is determined whether or not this average value is greater than the upper threshold 1 (step S904). When the average value of the correlation values is greater than the upper limit raising threshold 1 (step S904: Yes), the first determination result (determination 1 result) is “1” for the base station (cell) to be processed at this time. (Step S905). When the average value of the correlation values is equal to or smaller than the upper threshold 1 (step S904: No), the first determination result is set to “0” (step S906).
[0082]
Next, it is determined whether the average value of the correlation values is smaller than the upper limit lowering threshold 1 (step S907). If the average of the correlation values is smaller than the upper limit lowering threshold 1 (step S907: Yes), the second determination result (determination 2 result) is “1” for the base station (cell) to be processed at this time. (Step S908). When the average value of the correlation values is equal to or more than the upper limit lowering threshold 1 (step S907: No), the second determination result is set to “0” (step S909).
[0083]
Next, the effective base station (cell) is set to the next-ranked base station (cell) (step S910), and the processes of steps S903 to S910 in the second round are performed for the second base station (cell). The same applies to the third and subsequent base stations (cells). When the loop processing up to the eighth base station (cell) is completed (step S911), the first to eighth base stations (cells) It is determined whether or not the determination result of 1 (determination 1 result) is “1” (step S912). As a result, if all of the first determination results are “1” (step S912: Yes), the upper limit threshold is one of a value obtained by adding the upper limit increase width 1 to the upper limit threshold or an upper limit of the upper limit threshold. The value is updated to the smaller value (step S913), and the process ends.
[0084]
On the other hand, if the first determination result is “0” in any one of the first to eighth base stations (cells) (step S912: No), all of the first to eighth base stations For (cell), it is determined whether the second determination result (determination result 2) is “1” (step S914). As a result, if all of the second determination results are “1” (step S914: Yes), the upper limit threshold is set to a value obtained by subtracting the upper limit decrease width 1 from the upper limit threshold or the lower limit value of the upper limit threshold. Is updated to the larger value (step S915), and the process ends. If the second determination result is "0" in any one of the first to eighth base stations (cells) (step S914: No), the upper limit threshold is not updated and the value is used as it is. And ends the processing.
[0085]
Next, the contents of processing performed in the second upper threshold changing unit 15 will be described. FIG. 10 is a flowchart illustrating an example of the second upper threshold variation process. When the process is started, first, it is confirmed that the upper threshold change enable 2 is ON (step S1001). When the upper limit threshold variation enable 2 is off (step S1001: No), the process does not update the upper limit threshold, keeps the same value, and ends the processing.
[0086]
If the upper threshold variation enable 2 is on (step S1001: Yes), the processes from step S1003 to step S1008 described below are repeated for valid base stations (the first to eighth base stations). (Step S1002). In the processing of steps S1003 to S1008 in the first round, processing is performed for the first base station (cell).
[0087]
It is determined whether the number of effective multipaths is greater than the upper limit threshold 2 (step S1003). If the number of effective multipaths is larger than the upper limit raising threshold 2 (step S1003: Yes), the first determination result (determination 1 result) is “1” for the base station (cell) to be processed at this time. (Step S1004). If the number of valid multipaths is equal to or smaller than the upper limit threshold 2 (step S1003: No), the first determination result (determination 1 result) is set to “0” (step S1005).
[0088]
Next, it is determined whether the number of effective multipaths is smaller than the upper limit lowering threshold 2 (step S1006). When the number of effective multipaths is smaller than the upper limit lowering threshold 2 (step S1006: Yes), the second determination result (determination 2 result) is “1” for the base station (cell) to be processed at this time. (Step S1007). If the number of valid multipaths is equal to or larger than the upper limit lowering threshold 2 (step S1006: No), the second determination result (determination 2 result) is set to “0” (step S1008).
[0089]
Next, the effective base station (cell) is set to the next-ranked base station (cell), and the processes of steps S1003 to S1008 in the second round are performed for the second base station (cell). The same applies to the third and subsequent base stations (cells). When the loop processing up to the eighth base station (cell) is completed (step S1009), the first to eighth base stations (cells) It is determined whether or not the determination result of 1 (determination 1 result) is “1” (step S1010). As a result, if all of the first determination results are “1” (step S1010: Yes), the upper limit threshold is one of the value obtained by adding the upper limit increase width 2 to the upper limit threshold or the upper limit of the upper limit threshold. The value is updated to the smaller value (step S1011), and the process ends.
[0090]
On the other hand, if the first determination result is “0” in any one of the first to eighth base stations (cells) (Step S1010: No), all of the first to eighth base stations For (cell), it is determined whether the second determination result (determination 2 result) is “1” (step S1012). As a result, if all the second determination results are “1” (step S1012: Yes), the upper limit threshold is set to a value obtained by subtracting the upper limit decrease width 2 from the upper limit threshold or the lower limit of the upper limit threshold. Is updated to the larger value (step S1013), and the process ends. If the second determination result is “0” in any one of the first to eighth base stations (cells) (step S1012: No), the upper limit threshold is not updated and the value is used as it is. And ends the processing.
[0091]
Next, the processing performed in the lower threshold change unit 17 will be described. FIG. 11 is a flowchart illustrating an example of the lower threshold change processing. When the process is started, first, it is confirmed that the lower threshold variation enable is on (step S1101).
[0092]
If the lower threshold variation enable is on (step S1101: Yes), it is determined whether the sum of the correlation values is smaller than the lower threshold (step S1102). If the sum of the correlation values is smaller than the lower threshold (step S1102: YES), it is determined that all paths are noise, and the path search stop flag is turned on (step S1103). When the path search stop flag is turned on, a path search end request has been issued, and the path search stops. Then, the first count value (counter 1) obtained by counting the number of times the path search stop flag is turned on is incremented by 1 (step S1104). If the sum of the correlation values is equal to or greater than the lower threshold (step S1102: NO), the path search stop flag remains off and the first count value remains unchanged.
[0093]
Next, it is determined whether or not the first count value is larger than the lower limit lowering threshold (step S1105). If the first count value is larger than the lower limit lowering threshold (step S1105: Yes), the second number that counts the number of times that the path search stop flag is turned on more than the number specified by the lower limit lowering threshold is used. The count value (counter 2) is incremented by 1 (step S1106). When the first count value is equal to or less than the lower limit lowering threshold value (step S1105: No), the second count value remains unchanged.
[0094]
Next, it is determined whether or not the second count value is greater than the lower limit number of times (step S1107). If the second count value is larger than the lower limit lowering count (step S1107: Yes), the lower limit threshold value is not updated and is kept as it is (step S1108), and the process ends. When the second count value is equal to or less than the lower limit number of times (step S1107: No), the lower limit threshold is set to a value obtained by subtracting the lower limit lower limit from the lower limit threshold, or the lower limit of the lower limit threshold, whichever is larger. The value is updated to the other value (step S1109), and the process ends.
[0095]
If the lower threshold change enable is OFF in step S1101 (step S1101: No), the lower threshold is updated to the initial value of the lower threshold. Then, the first count value and the second count value (counter 1/2) are reset (step S1110), and the process ends.
[0096]
FIG. 12 is a diagram illustrating how to assign fingers according to the present embodiment. Here, there are two valid base stations, and the upper limit threshold value, that is, the upper limit of the sum of correlation values is 300. Further, for the first base station, the path powers of the paths having the first, second, third and fourth ranks, that is, the correlation values are 100, 90, 85 and 70, respectively. Regarding the second base station, the path powers (correlation values) of the paths having the first, second, third, fourth and fifth ranks are 95, 80, 65, 50 and 30, respectively.
[0097]
In this case, for the first base station, the sum of the correlation values (path power) of the first to third paths is 275 (= 100 + 90 + 85). When the correlation value of the fourth path is further added, the sum of the correlation values is 345 (= 275 + 70), which is larger than the upper limit threshold value of 300. Therefore, the effective paths of the first base station are three paths, the path having the first place, the path having the second place, and the path having the third place. These three passes are assigned to three fingers. With respect to the first base station, a path having a fourth or higher path rank is invalid.
[0098]
For the second base station, the sum of the correlation values of the first to fourth paths is 290 (= 95 + 80 + 65 + 50). When the correlation value of the fifth path is added to this, the sum of the correlation values becomes 320 (= 290 + 30), which is larger than the upper limit threshold value of 300. Therefore, the effective paths of the second base station are four paths: the first path, the second path, the third path, and the fourth path. These four paths are assigned to four fingers. With respect to the second base station, a path having a fifth or higher path rank becomes invalid.
[0099]
In the example shown in FIG. 12, the effective number of multipaths for the first base station and the second base station is seven. Since the number of fingers is 8, one finger to which a valid path is not assigned remains. That is, seven of the eight fingers are active, and the remaining one is not active.
[0100]
According to the above-described embodiment, if the reception state is good, the upper threshold value increases and the number of effective multipaths decreases.If the reception state is bad, the lower threshold value decreases and the effective multipath number decreases. Therefore, the number of effective multipaths can be increased or decreased according to the reception state. Therefore, when the number of valid base stations is small and the reception state is good, the number of active fingers is reduced by reducing the number of valid multipaths, and power consumption can be reduced. Further, when the number of valid base stations is small and the reception state is poor, the number of valid multipaths increases, so that the reception quality can be improved.
[0101]
Note that, as shown in FIG. 14, a plurality of multipath detection modules may be arranged and n-layered. In that case, the configuration from the matched filter unit 2 to the peak detection unit 6 via the power conversion unit 3, the first addition unit 4, and the integration RAM 5 is arranged in n columns in parallel, and processing is performed in parallel. Just fine.
[0102]
Further, there is provided a data organizing unit 10 for time-division multiplexing and outputting data obtained from the n peak detecting units 6. For example, as shown in FIG. 15, the data reduction unit 10 obtains the correlation values of the first base station and the third base station obtained in the first column and the correlation values of the third base station in the second column. The correlation value of the second base station and the correlation value of the fourth base station are time-division multiplexed, and the output data to the result register 7 is converted to the correlation value of the first base station and the correlation value of the second base station. , The correlation value of the third base station and the correlation value of the fourth base station. By doing so, the processing in the multipath detection module is speeded up.
[0103]
In the above, the present invention is not limited to the above-described embodiment, but can be variously modified. For example, the chip synchronization acquisition method may be replaced with a sliding correlator method instead of the matched filter method. Further, the above-described multipath number detection function, first upper threshold variation function, second upper threshold variation function, and lower threshold variation function may all be realized by hardware, or some or all may be implemented by software. May be realized.
[0104]
(Supplementary Note 1) A synchronization holding device for detecting effective multipath timing based on a correlation value obtained by a path search for each sample for each of a plurality of base stations to which wireless connection is possible,
Integrating means for adding the correlation values in order from the top to obtain the sum of the correlation values;
Determining means for determining the number of effective multipaths with the path timing corresponding to the correlation value added so far as an effective path when the sum of the correlation values is larger than a preset upper limit threshold;
A synchronization maintaining device in a W-CDMA communication system, comprising:
[0105]
(Supplementary Note 2) The deciding means, before the sum of the correlation values becomes larger than the upper limit threshold value, sets the number of valid paths corresponding to the correlation values added up to that time to a predetermined maximum valid multipath 2. The synchronization maintaining apparatus in the W-CDMA communication system according to claim 1, further comprising means for determining the maximum number of effective multipaths as the number of effective multipaths when the number reaches the number.
[0106]
(Supplementary note 3) The supplementary note 1 or, further comprising upper limit threshold updating means for updating an upper limit threshold based on an average value of correlation values when the number of effective multipaths is determined by the determining means. 3. A synchronization maintaining device in the W-CDMA communication system according to 2.
[0107]
(Supplementary note 4) When the number of effective multipaths for each effective base station determined by the determining means is greater than an arbitrary upper limit increase threshold value set for all effective base stations, the upper limit is increased. 3. The synchronization maintaining device in the W-CDMA communication system according to claim 1 or 2, further comprising a threshold updating unit.
[0108]
(Supplementary Note 5) When the number of effective multipaths for each effective base station determined by the determining means is less than a predetermined upper limit lowering threshold for all the effective base stations, the upper limit for lowering the upper limit threshold 3. The synchronization maintaining device in the W-CDMA communication system according to claim 1 or 2, further comprising a threshold updating unit.
[0109]
(Supplementary Note 6) The number of times that the sum of the correlation values when the number of effective multipaths is determined by the determination means becomes smaller than an arbitrary lower threshold set in advance is equal to an arbitrary lower threshold set in advance. 3. The W-CDMA communication system according to claim 1, further comprising: a lower threshold updating unit that lowers a lower threshold when the threshold is larger than the threshold.
[0110]
(Supplementary Note 7) In detecting effective multipath timing based on a correlation value obtained by a path search for each sample for each of a plurality of base stations that can be wirelessly connected,
An integration step of adding the correlation values in order from the top to obtain the sum of the correlation values,
When the sum of the correlation values is larger than a predetermined upper limit threshold, the number of effective multipaths is determined by using the path timing corresponding to the correlation value added up to that time as an effective path, or Before the sum of the values becomes larger than the upper limit threshold, when the number of effective paths corresponding to the correlation value added so far reaches an arbitrary preset maximum effective multipath number, the maximum effective multipath number is reached. A determining step of determining the number of paths as the number of effective multi-paths,
A synchronization maintaining method in a W-CDMA communication system.
[0111]
(Supplementary note 8) The supplementary note 7, further comprising an upper limit threshold updating step of updating an upper limit threshold based on an average value of the correlation values when the number of effective multipaths is determined in the determining step. In the W-CDMA communication system.
[0112]
(Supplementary Note 9) For all effective base stations, when the number of effective multipaths for each effective base station determined in the determining step is larger than a predetermined upper limit raising threshold, the upper limit threshold is increased, On the other hand, for all effective base stations, when the number of effective multipaths for each effective base station determined by the determining means is smaller than a predetermined upper limit lowering threshold, the upper limit threshold updating for lowering the upper limit threshold is performed. The method for maintaining synchronization in a W-CDMA communication system according to claim 7, further comprising the step of:
[0113]
(Supplementary Note 10) The number of times that the sum of the correlation values when the number of effective multipaths is determined in the determination step becomes smaller than a predetermined lower limit threshold is set to a predetermined lower limit lowering threshold 8. The synchronization maintaining method in the W-CDMA communication system according to claim 7, further comprising a lower threshold updating step of lowering the lower threshold when the threshold is larger than the threshold.
[0114]
(Supplementary Note 11) The upper limit threshold updating means increases the upper limit threshold when the average value of the correlation values for all the effective base stations becomes larger than an arbitrary upper limit increase threshold set in advance. The synchronization maintaining device in the W-CDMA communication system according to supplementary note 3, characterized by comprising means.
[0115]
(Supplementary note 12) The upper limit threshold updating unit decreases the upper limit threshold when the average value of the correlation values for all the effective base stations becomes smaller than an arbitrary upper limit lowering threshold set in advance. The synchronization maintaining device in the W-CDMA communication system according to supplementary note 3, characterized by comprising means.
[0116]
(Supplementary note 13) The synchronization holding device in the W-CDMA communication system according to any one of Supplementary notes 3 to 5, further comprising a unit that invalidates updating of an upper limit threshold by the upper limit threshold updating unit. .
[0117]
(Supplementary Note 14) The apparatus further includes means for limiting a change range of the upper limit threshold value by the upper limit threshold update unit based on a predetermined upper limit increase width and a predetermined upper limit decrease width. 6. A synchronization holding device in a W-CDMA communication system according to any one of Supplementary Notes 3 to 5.
[0118]
(Supplementary note 15) The synchronization in the W-CDMA communication system according to Supplementary note 14, wherein the upper limit threshold updating unit includes means for updating the upper limit threshold to an upper limit of an arbitrary preset upper limit threshold. Holding device.
[0119]
(Supplementary note 16) The synchronization in the W-CDMA communication method according to Supplementary note 14, wherein the upper limit threshold updating unit includes means for updating the upper limit threshold to a lower limit of an arbitrary preset upper limit threshold. Holding device.
[0120]
(Supplementary Note 17) When the sum of the correlation values when the number of effective multipaths is determined by the determination unit is smaller than a predetermined lower limit threshold, stop the path search that issues a path search end request. 3. The synchronization maintaining device in the W-CDMA communication system according to claim 1 or 2, further comprising means.
[0121]
(Supplementary note 18) The synchronization holding device in the W-CDMA communication method according to supplementary note 6, further comprising: means for invalidating the update of the lower limit threshold by the lower limit threshold updating means.
[0122]
(Supplementary note 19) The W-CDMA communication according to Supplementary note 6, further comprising: means for limiting the number of times the lower limit threshold is updated by the lower limit threshold updating means to a predetermined lower limit lowering number. Synchronous holding device in the scheme.
[0123]
(Supplementary Note 20) Means for outputting a result of despreading based on the received data, means for outputting data converted to power based on the result of despreading, and outputting a correlation result obtained by adding one frame of the data converted to power. Means, and a plurality of multipath detection modules comprising means for performing peak detection of a correlation value based on the correlation result,
Means for time-division multiplexing and outputting the output data of each multipath detection module,
20. The synchronization maintaining device in the W-CDMA communication system according to any one of supplementary notes 1 to 6 and 11 to 19, characterized by comprising:
[0124]
(Supplementary note 21) The synchronization holding device in the W-CDMA communication system according to any one of Supplementary notes 1 to 6 and 11 to 20, characterized by being configured by hardware.
[0125]
(Supplementary note 22) The synchronization holding device in the W-CDMA communication system according to any one of Supplementary notes 1 to 6 and 11 to 20, wherein at least a part thereof is realized by software processing.
[0126]
【The invention's effect】
According to the present invention, when the reception state is good, by increasing the upper limit threshold, the number of valid multipaths is reduced, and when the reception state is bad, by lowering the lower limit threshold, the effective multipath is reduced. Since the number increases, the number of effective multipaths can be increased or decreased according to the reception state.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating an example of a multipath detection module of a synchronization holding device according to the present invention.
FIG. 2 is a diagram showing input / output signals of a threshold controller constituting the multipath detection module.
FIG. 3 is a block diagram illustrating a schematic configuration of a threshold controller.
FIG. 4 is a block diagram illustrating an example of a configuration of a multipath number detection unit included in the threshold controller unit.
FIG. 5 is a block diagram illustrating an example of a configuration of a first upper threshold variation unit included in the threshold controller.
FIG. 6 is a block diagram illustrating an example of a configuration of a second upper limit threshold changing unit included in the threshold controller unit.
FIG. 7 is a block diagram illustrating an example of a configuration of a lower limit threshold changing unit included in the threshold controller unit.
FIG. 8 is a flowchart illustrating an example of a multipath number detection process in the method of the present invention.
FIG. 9 is a flowchart showing an example of a first upper threshold variation process in the method of the present invention.
FIG. 10 is a flowchart showing an example of a second upper threshold variation process in the method of the present invention.
FIG. 11 is a flowchart showing an example of a lower threshold change process in the method of the present invention.
FIG. 12 is a diagram illustrating how to assign fingers according to the present invention.
FIG. 13 is a graph showing an example of a correlation result that requires a change in the lower threshold.
FIG. 14 is a block diagram illustrating an example in which a multipath detection module of the synchronization holding device according to the present invention is multiplexed.
FIG. 15 is a diagram illustrating data processing contents in a data reduction unit included in a multiplexed multipath detection module.
FIG. 16 is a timing chart for explaining a path search.
FIG. 17 is a graph showing an example of a correlation result obtained by a path search.
FIG. 18 is a diagram illustrating a conventional method of assigning fingers to path search results.
FIG. 19 is a diagram illustrating a conventional method of allocating fingers to path search results.
FIG. 20 is a diagram illustrating a conventional method of assigning fingers to path search results.
[Explanation of symbols]
2 Means for outputting despread result (matched filter unit)
3. Means for outputting power-converted data (power conversion unit)
4, 5 Means for outputting a correlation result (first adder, integration RAM)
6. Means for peak detection of correlation values (peak detector)
10 Time-division multiplexed output means (data reduction unit)
110, 111 integrating means (second adding unit, holding unit)
112, 113 determining means (first comparing unit, output unit)
13 Upper threshold updating means (first upper threshold changing unit)
15 Upper threshold updating means (second upper threshold varying unit)
17 Lower threshold updating means (lower threshold changing unit)

Claims (10)

A synchronization holding device that detects effective multipath timing based on a correlation value obtained by a path search for each sample for each of a plurality of wirelessly connectable base stations,
Integrating means for adding the correlation values in order from the top to obtain the sum of the correlation values;
Determining means for determining the number of effective multipaths with the path timing corresponding to the correlation value added so far as an effective path when the sum of the correlation values is larger than a preset upper limit threshold;
A synchronization maintaining device in a W-CDMA communication system, comprising: The determining means, before the sum of the correlation values becomes larger than the upper limit threshold value, the number of valid paths corresponding to the correlation values added so far has reached an arbitrary preset maximum valid multipath number 2. The apparatus according to claim 1, further comprising means for determining the maximum number of effective multipaths as the number of effective multipaths. 3. The apparatus according to claim 1, further comprising an upper limit threshold updating unit that updates an upper threshold based on an average value of correlation values when the number of effective multipaths is determined by the determining unit. 4. In the W-CDMA communication system. For all effective base stations, when the number of effective multipaths for each effective base station determined by the determining means is larger than a predetermined upper limit raising threshold, the upper limit threshold updating means for raising the upper threshold is changed. The synchronization maintaining apparatus according to claim 1 or 2, further comprising: For all effective base stations, when the number of effective multipaths for each effective base station determined by the determining means is smaller than a predetermined upper limit lowering threshold, an upper limit threshold updating means for lowering the upper limit threshold is provided. The synchronization maintaining apparatus according to claim 1 or 2, further comprising: The number of times the total sum of the correlation values when the number of effective multipaths is determined by the determining means becomes smaller than a predetermined lower threshold of an arbitrary lower limit is larger than an arbitrary lower threshold of a predetermined lower limit. 3. The synchronization holding apparatus according to claim 1, further comprising a lower threshold updating unit that lowers a lower threshold. In detecting a valid multipath timing based on a correlation value obtained by a path search for each sample for each of a plurality of base stations capable of wireless connection,
An integration step of adding the correlation values in order from the top to obtain the sum of the correlation values,
When the sum of the correlation values is larger than a predetermined upper limit threshold, the number of effective multipaths is determined by using the path timing corresponding to the correlation value added up to that time as an effective path, or Before the sum of the values becomes larger than the upper limit threshold, when the number of effective paths corresponding to the correlation value added so far reaches an arbitrary preset maximum effective multipath number, the maximum effective multipath number is reached. A determining step of determining the number of paths as the number of effective multi-paths,
A synchronization maintaining method in a W-CDMA communication system. 8. The method according to claim 7, further comprising: an upper threshold updating step of updating an upper threshold based on an average value of correlation values when the number of effective multipaths is determined by the determining step. 9. A method for maintaining synchronization in a CDMA communication system. For all effective base stations, when the number of effective multipaths for each effective base station determined by the determining step is larger than a predetermined upper limit increase threshold, the upper limit threshold is increased, while For the effective base station, when the number of effective multipaths for each effective base station determined by the determining means is smaller than a preset upper limit lowering threshold, an upper limit threshold updating step of lowering the upper threshold, The method for maintaining synchronization in a W-CDMA communication system according to claim 7, comprising: The number of times the total sum of the correlation values when the number of effective multipaths is determined by the determination step is smaller than a predetermined lower threshold of any lower limit is larger than the predetermined lower threshold of the lower limit. 8. The method according to claim 7, further comprising a lower threshold updating step of lowering the lower threshold.

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