JPH1042341A - Cell selecting method, base station device and mobile station device in cdma mobile communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cell selecting method, a base station device and a mobile station device in a CDMA(code division multiple access) mobile communication system which shortens a cell selective processing time and also can construct a mobile communication system that has base station structural realizability. SOLUTION: A base station which has a GPS antenna 10 and a GPS receiving part 11 and can generate the same reference timing in plural base stations shortens cell selective processing in a mobile station by using the same diffusion code with each base station in a different diffusion code phase for the diffusion processing of a pilot channel. On the other hand, a base station which does not have the antenna 10 or the part 11 and is difficult to have the same reference timing can construct a mobile communication system that has realizability without increasing the scale of a hardware by allocating a different diffusion code to each base station for the diffusion processing of a pilot channel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a cell selection method in a code division multiple access (hereinafter abbreviated as CDMA) type mobile communication system, and to a base station apparatus and a mobile station apparatus.

[0002]

2. Description of the Related Art In a CDMA mobile communication system,
Divide the service area into multiple unit areas, cells,
One base station is provided in each cell, and mobile stations existing in a certain cell in a service area communicate with a base station of the cell via a radio line.

[0003] Each base station constantly transmits a pilot channel, and when a mobile station receives a pilot channel, the individual pilot channel can be identified by some method. For example, in an FDMA system, a different frequency is used for each pilot channel.
In a CDMA system, a mobile station can identify an individual pilot channel by using a different spreading code for each pilot channel.

[0004] A mobile station measures the reception level of a plurality of pilot channels and performs cell selection based on the measured values. Specifically, the mobile station despreads the received signal with multiple spreading codes that can be used as pilot channels,
The reception level is measured, and the spread value corresponding to the measured value is stored. After the measurement of all the spreading codes is completed, despreading and receiving processing of the pilot channel corresponding to the spreading code having the highest reception level are performed, and whether the pilot channel can be decoded without error or the cell obtained from the decoded information is checked. Of the communication, such as whether the communication is permitted, and if so, the cell is determined to be a serving cell. If it is not valid, the reception process of the pilot channel is sequentially performed in descending order of the reception level, and similarly, the validity of the communication is determined, and the cell determined to be valid is set as the serving cell.

[0005] In the above-described cell selection processing, the reception level measurement processing of the pilot channel requires a plurality of times of the spread code period per measurement of one pilot channel. The reason will be described below.

As an example, a case where a matched filter is used in the process of measuring the pilot channel reception level will be described. FIG. 8 shows an output example when a signal spread by a spreading code is input to the matched filter. As shown in FIG. 8, a peak signal is output for each period of the spreading code, and the output level of this peak signal is used as a reception level. In the actual reception level measurement process, the output level is measured over a plurality of cycles at the timing of the peak signal detected in the first cycle to improve the measurement accuracy, and the averaged value is used as the measured value of the reception level. Therefore, measuring the reception level of one spread code requires a time that is a multiple of the spread code period. This is an example of a matched filter, but the matched filter has a relatively large hardware scale,
There is a drawback that power consumption is large, and a sliding correlator that is generally effective in terms of hardware scale and power consumption is frequently used. However, in the case of a sliding correlator, the processing time is further longer than the processing time of the matched filter by a diffusion period, and more processing time is required.

Furthermore, since this processing time is required for the number of spreading codes that can be used as pilot channels, a relatively long time is required for the cell selection processing. For example, after the mobile station is powered on, it can be used. It will take a long time to complete.

In order to prevent this problem, a method of identifying the pilot channel not only by the spreading code but also by making the spreading code phase different for each pilot channel is considered. FIG. 9 shows an output example of a matched filter when the same spreading code is used, the spreading code phase is made different for each pilot channel, and a matched filter is used for the pilot channel reception level measurement processing. This is an example in which the spreading code phase of each pilot channel is shifted by ３ cycle for three pilot channels. As shown in the figure, a peak corresponding to each pilot channel appears apart from the spreading code phase difference for each pilot channel.
Peaks corresponding to one pilot channel appear for each spreading period as in FIG. Since peaks corresponding to a plurality of pilot channels can be detected by measuring one spreading code, reception levels of a plurality of pilot channels can be measured by measuring each peak. Thus, by assigning n different spreading code phase differences with one spreading code to n pilot channels, 1 / in the case where the pilot channel is identified only by the spreading code.
The measurement of the reception level can be performed in the time of n.

However, in order to assign different spreading code phases to a plurality of pilot channels,
It is necessary to assign the same reference timing in all base stations and assign a different spreading code phase difference from the reference timing to each pilot channel based on the reference timing. This is because when a pilot channel is transmitted with an arbitrary spreading code phase for each base station, there is a possibility that a plurality of pilot channels transmit pilot channels with substantially the same spreading code phase. This is because the mobile station cannot identify a plurality of pilot channels transmitted with almost the same spreading code phase, and therefore cannot perform cell selection using these pilot channels.

FIG. 10 is a timing chart in the case where different spreading code phase differences with respect to the reference timing are assigned to three pilot channels. As shown in the figure, the same reference timing is used in all base stations, and the spreading code phase difference for the same reference timing is assigned to each pilot channel, so that the spreading code phase of each pilot channel can be made different.

However, in order for a plurality of base stations to have the same reference timing, it is necessary to have extremely complicated timing synchronization means. As to this method, a method of measuring round trip delay and a method of using GPS by performing wireless or wired communication between base stations have been studied and partially realized, but the hardware configuration is complicated. With difficulty. In particular, with the development of mobile communication services in the future, it is considered that more flexibility is required for installing base stations, and miniaturization of base stations is required. Therefore, it is extremely difficult to provide a function having the same reference timing to all base stations in terms of hardware configuration, and it is considered that only a part of the base stations can have this function.

[0012]

As described above, when a different spreading code is used for each pilot channel, there is a problem that the cell selection process takes a long time. When a different spreading code phase is used for each pilot channel, the time for cell selection processing can be reduced,
All base stations must have the same reference timing,
In order for all the base stations to have this function, there is a problem that the hardware configuration of the base station is complicated, and it is difficult to realize the function.

The present invention has been made in view of the above,
It is an object of the present invention to provide a cell selection method, a base station apparatus, and a mobile station apparatus in a CDMA mobile communication system capable of shortening a cell selection processing time and constructing a mobile communication system having a feasible base station configuration. It is in.

[0014]

In order to achieve the above object, according to the present invention, a base station is provided in each of a plurality of cells, and each base station transmits a different pilot channel for each base station. The mobile station is a cell selection method in a CDMA mobile communication system that determines a serving cell based on the reception level of the pilot channel, wherein a plurality of base stations having the same reference timing of the spreading code phase have the same base station. With the spreading code, the pilot channel transmitted with a spreading code phase difference different for each base station with respect to the reference timing is transmitted, and the base station having no reference timing is spread with a different spreading code for each base station. The gist is to transmit the pilot channel at an arbitrary spreading code phase.

According to the first aspect of the present invention, a plurality of base stations having the same reference timing transmit a pilot channel spread by the same spreading code with a different spreading code phase difference for each base station. , The number of spreading codes required as pilot channels can be reduced, the cell selection process at the mobile station can be shortened, and base stations without reference timing can freely set pilot channels spread with different spreading codes for each base station. A base station that has difficulty in having the same reference timing does not need to have the function of having the same reference timing because it transmits at the spread code phase of Can be built.

The present invention according to claim 2 provides the invention according to claim 1.
In the described invention, a mobile station despreads a received signal with one or more spreading codes that can be used for spreading a pilot channel to measure a reception level, and measures the reception level by using a plurality of spreading codes for each spreading code. About the phase,
A plurality of received level measurement values and a spread code and a spread code phase corresponding to each measured value are stored, and the mobile station corresponds to a spread code and a spread code phase corresponding to a maximum received level among the stored received level measured values. Performs despreading and reception processing of the pilot channel to determine whether or not communication in a cell under the base station transmitting the pilot channel is valid, and when valid, the cell is a serving cell, If not valid, the gist is to sequentially determine the validity of the communication in the descending order of the reception level and determine the serving cell.

According to the second aspect of the present invention, the mobile station measures reception levels for a plurality of spreading code phases for each spreading code for one or more spreading codes that can be used for spreading a pilot channel, and The reception level measurement values and the spreading code and the spreading code phase corresponding to each measurement value are stored, and the spreading code and the spreading code phase corresponding to the maximum reception level are subjected to despreading and reception processing of the pilot channel corresponding to the spreading code phase. It is determined whether communication in a cell under the base station transmitting the pilot channel is valid. If the communication is valid, the cell is determined to be a serving cell. The serving cell is determined by similarly determining the validity.

Further, the present invention according to claim 3 provides the invention according to claim 2.
In the invention described above, a mobile station stores the same spreading code and a plurality of spreading codes different for each base station, and for the same spreading code, a spreading code and a spreading code corresponding to reception levels of a plurality of spreading code phases. Storing a phase, and for a spreading code different for each base station, only a spreading code phase having a maximum reception level during one cycle of the spreading code, and a spreading code and a spreading code phase corresponding to the reception level are stored. Make a summary.

According to the third aspect of the present invention, the mobile station stores the same spreading code and a plurality of different spreading codes for each base station. A corresponding spreading code and a spreading code phase are stored, and for a spreading code different for each base station, only the spreading code phase having the maximum reception level during one cycle of the spreading code, the spreading code and the spreading code corresponding to the reception level. Because the phase is stored, unnecessary reception level information for cell selection can be ignored, the required memory capacity can be reduced, and the reception level information that is not actually transmitted as a pilot channel is effectively used for cell communication. To check for gender,
The processing load can be reduced.

According to a fourth aspect of the present invention, in the first aspect of the invention, when the spreading code period is X chips,
When using N types of spreading code phase differences different for each base station with respect to the reference timing, values of the respective spreading code phase differences with respect to the reference timing are set to 0, X / N, 2X /
N, 3X / N,..., (N-1) X / N.

According to the fourth aspect of the present invention, when N types of spread code phase differences different for each base station are used, the values of the respective spread code phase differences with respect to the reference timing are set to 0, X
/ N, 2X / N, 3X / N, ..., (N-1) X / N
Therefore, it is possible to avoid a problem that a plurality of pilot channels having a small spread code phase difference cannot be received without error.

Further, the present invention described in claim 5 is based on claim 1.
In the described invention, when N kinds of the spreading code phase differences different for each base station are used for the reference timing, the N kinds of spreading code phase differences are transmitted to N base stations arranged in a geographically integrated range. The gist of the present invention is to arrange the spread code phase differences and to use the basic layout patterns geographically repeatedly to arrange the spread code phase differences.

According to the fifth aspect of the present invention, when N types of spreading code phase differences that differ for each base station are used, N
Each type of spreading code phase difference is arranged in each of N base stations arranged in a geographically coherent range, and these are set as a basic arrangement pattern of the spreading code phase difference. To place the difference,
The same spreading code phase difference is not used in a short distance, and a plurality of pilot channels having the same spreading code phase difference interfere with each other at the reception of the mobile station, and are prevented from being erroneously received by the mobile station. be able to.

Further, the present invention described in claim 6 provides the invention according to claim 1.
In the described invention, when N kinds of spreading codes different for each base station are used, the N kinds of spreading codes are respectively arranged in N base stations arranged in a geographically coherent range, and these are assigned to the spreading codes. The gist is that a basic arrangement pattern is used, and the basic arrangement pattern is geographically repeated to arrange a spreading code.

According to the sixth aspect of the present invention, when different N types of spreading codes are used for each base station, the N types of spreading codes are respectively assigned to N base stations arranged in a geographical range. This is set as a basic arrangement pattern of a spreading code, and the basic arrangement pattern is geographically repeated to arrange the spreading code. It is possible to prevent a plurality of pilot channels having the same spreading code from interfering with each other and being erroneously received by the mobile station.

According to a seventh aspect of the present invention, a base station is provided in each of a plurality of cells, each base station transmits a different pilot channel for each base station, and a mobile station determines a pilot channel based on the reception level of the pilot channel. CD to determine the serving cell
In the MA mobile communication system, the base station apparatus has a base station apparatus having a reference timing of the same spreading code phase and a base station apparatus not having the reference timing, and the base station apparatus does not have the reference timing of the same spreading code phase. A plurality of base station devices having timings transmit the pilot channels spread with the same spreading code by a spreading code phase difference different for each base station with respect to the reference timing, and the base station device not having the reference timings However, the gist of the present invention is to transmit the pilot channel spread with a different spreading code for each base station at an arbitrary spreading code phase.

According to the present invention, a plurality of base stations having the same reference timing transmit a pilot channel spread with the same spreading code and a different spreading code phase difference for each base station. , The number of spreading codes required as pilot channels can be reduced, the cell selection process at the mobile station can be shortened, and base stations without reference timing can freely set pilot channels spread with different spreading codes for each base station. A base station that has difficulty in having the same reference timing does not need to have the function of having the same reference timing because it transmits at the spread code phase of Can be built.

The present invention according to claim 8 provides the present invention according to claim 7.
In the described invention, a base station is provided in each of a plurality of cells, each base station transmits a different pilot channel for each base station, and a mobile station determines a serving cell based on the reception level of the pilot channel. In a CDMA mobile communication system, a mobile station device measures a reception level after despreading for a plurality of spreading code phases for a plurality of spreading codes which can be used for spreading a pilot channel, for each of a plurality of spreading codes, Storage means for storing a plurality of reception level measurement values measured by the measurement means and a spreading code and a spreading code phase corresponding to each measurement value; a spreading code corresponding to the maximum reception level among the stored reception level measurement values; Performs despreading and reception processing of the pilot channel corresponding to the spreading code phase, and It is determined whether or not communication in a cell under the base station to be transmitted is valid. If the communication is valid, the cell is determined to be a serving cell. The gist of the present invention is to include a serving cell determination unit that determines a serving cell in the same manner.

According to the present invention as set forth in claim 8, the mobile station measures reception levels for a plurality of spreading code phases for each spreading code for one or more spreading codes that can be used for spreading a pilot channel. The reception level measurement values and the spreading code and the spreading code phase corresponding to each measurement value are stored, and the spreading code and the spreading code phase corresponding to the maximum reception level are subjected to despreading and reception processing of the pilot channel corresponding to the spreading code phase. It is determined whether communication in a cell under the base station transmitting the pilot channel is valid. If the communication is valid, the cell is determined to be a serving cell. The serving cell is determined by similarly determining the validity.

Further, the present invention described in claim 9 provides the present invention in claim 8.
In the invention described, the mobile station device is configured to store the same spreading code and a plurality of spreading codes different for each base station, and for the same spreading code,
A spreading code and a spreading code phase corresponding to the reception levels of a plurality of spreading code phases are stored. For a spreading code different for each base station, only a spreading code phase having a maximum reception level during one cycle of the spreading code is stored. It is essential to have a storage means for storing a spread code and a spread code phase corresponding to the reception level.

According to the ninth aspect of the present invention, the mobile station stores the same spreading code and a plurality of different spreading codes for each base station. A corresponding spreading code and a spreading code phase are stored, and for a spreading code different for each base station, only the spreading code phase having the maximum reception level during one cycle of the spreading code, the spreading code and the spreading code corresponding to the reception level. Because the phase is stored, unnecessary reception level information for cell selection can be ignored, the required memory capacity can be reduced, and the reception level information that is not actually transmitted as a pilot channel is effectively used for cell communication. To check for gender,
The processing load can be reduced.

[0032]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a CDM according to an embodiment of the present invention.
FIG. 2 is a block diagram illustrating a configuration of a base station apparatus that implements a cell selection method in a mobile communication system A. The base station apparatus shown in FIG. 1 includes a GPS antenna 10, a GPS receiving unit 11 for receiving a GPS received signal, a reference timing generating unit 12 for generating a reference timing used in the base station, and a reference timing and a control unit. Spread modulation section 1 that generates a pilot channel based on the coded signal of the control signal from the coding section with the spread code and the spread code phase thus obtained.
3, a radio section 14 for amplifying a pilot channel, an antenna 15 for transmitting a pilot channel, a memory 16 for storing a pilot channel spreading code used in a base station and a value of a spreading code phase difference with respect to a reference timing, It comprises a control unit 17 for controlling the entire station, and a coding unit 18 for coding a control signal to be transmitted on a pilot channel generated from the control unit 17.

Here, there are two types of base stations in the present invention, one is a base station that can have the same reference timing in a plurality of base stations, and the other is a base station that does not have the same reference timing. It is. A base station that can have the same reference timing has the configuration of FIG.
It has a function of generating the same reference timing using the S antenna 10 and the GPS receiving unit 11. Here, although the GPS is used in FIG. 1, another configuration may be adopted to generate the same reference timing. For example, a round trip delay measuring device or the like may be used instead of the GPS antenna 10 and the GPS receiving unit 11. Base stations that do not have the same reference timing have a configuration excluding the GPS antenna 10 and the GPS receiving unit 11 in FIG. 1, and other configurations are the same as those in FIG. 1.

FIG. 2 is a timing chart until the pilot channel is spread in the base stations having the same reference timing. The GPS signal, the reference timing signal and the pilot signals of the base stations 1, 2, 3 corresponding to the GPS signal and the reference timing signal in time. 2 shows a spreading code for spreading a channel. Hereinafter, a method of transmitting a pilot channel will be described with reference to FIG.

The reference timing generator 12 generates a reference timing signal having a spread code cycle by multiplying the cycle of the GPS signal from the GPS receiver 11 by b / a. FIG. 2 shows a case where the reference timing signal is generated by halving the cycle of the GPS signal. Reference timing generator 12
The reference timing signal generated in step (1) is supplied to the spread modulator 13. Further, the control unit 17 of the base station reads the spreading code for the pilot channel and the value of the spreading code phase difference with respect to the reference timing from the memory 16 and notifies the spreading modulation unit 13 of these values. The spreading modulator 13 performs a spreading process on the pilot channel according to the notified spreading code and the spreading code phase difference. In a plurality of base stations having the same reference timing, the spreading codes stored in the memory 16 are the same, but the spreading code phase difference with respect to the reference timing differs for each base station. As a result, the spreading modulator 13 of each base station spreads the pilot channel with the same spreading code and different spreading code phases as shown in FIG. FIG. 2 shows three base stations as an example, and shows a case where the spreading code phase differences with respect to the reference timings of the base stations 1, 2, and 3 are 0, P ₁ , and P ₂ , respectively.

In a base station having no identical reference timing, the reference timing generator 13 generates a reference timing signal at an arbitrary spread code cycle interval and supplies it to the spread modulator 13. In base stations that do not have the same reference timing, the pilot channel is identified using a spreading code, and the spreading code phase becomes unnecessary. Therefore, the memory 16
Stores only the spreading code, and the control unit 17
Only the spread code read from 6 is supplied to the spread modulator 13. The spreading modulator 13 spreads the pilot channel with a spreading code specified by the controller 17 with a phase difference of 0 with respect to the reference timing.

Next, the reception processing of the pilot channel in the mobile station will be described. FIG. 3 is a block diagram showing a configuration of the mobile station. The mobile station detects an antenna 30, a radio section 31 for amplifying a received signal, a matched filter 32 for despreading the received signal with a pilot channel spreading code and outputting a despread signal, and a peak in the output of the matched filter 32. A level measuring unit 33 that measures a phase difference between the peak and the mobile station reference timing, and measures a peak reception level. The component in the despread signal corresponding to the phase difference with respect to the mobile station reference timing specified by the control unit is determined. A despread signal component extractor 34 to be extracted, a demodulator / decoder 35 for demodulating and decoding the components extracted by the despread signal component extractor 34, and measurement of reception levels of all spread codes and pilot channels that can be used as pilot channels. A memory 36 for storing the results, a control unit 37 for controlling the entire mobile station, Generating a spreading code, spreading code generating unit 38 supplies to the matched filter 32, and a mobile station reference timing generation unit 39 for generating a reference timing of the spread code period in the mobile station.

In the mobile station, at the start of the cell selection processing, the control unit 37 reads one of the pilot channel spreading codes from the memory 36, and the spreading code generating unit 38
To be specified. The spreading code generator 38 generates the designated spreading code and supplies it to the matched filter 32. Matched filter 32 despreads the received signal received via antenna 30 and radio section 31 with the supplied spreading code, and outputs a despread signal. The level measurement unit 33 searches for a peak in the despread signal, measures the phase difference between the occurrence timing of the peak with respect to the mobile station reference timing, and the reception level of the peak, and notifies the control unit 37 of it. As a method of searching for a peak, when the reception level continuously exceeds a predetermined threshold value, the timing at which the maximum reception level is reached during that period may be set as the peak timing. In the measurement of the peak reception level, the reception level at the same peak timing may be averaged over a plurality of spreading periods, and the average value may be notified to the control unit 37 as the reception level measurement value.

FIG. 4 shows a despread signal output from the matched filter 32 when the mobile station shown in FIG. 3 receives pilot channels from three base stations 1, 2 and 3 having the same reference timing shown in FIG. Show output. Peaks corresponding to the three pilot channels appear in the despread signal, and peaks appear at different phases according to the spreading code phase differences 0, P ₁ , and P ₂ assigned to the respective base stations.
In FIG. 4, the phase difference between the timing of each peak notified by the level measurement unit 33 of the mobile station to the control unit 37 and the mobile station reference timing is as follows for each peak corresponding to the pilot channels of the base stations 1, 2, and 3. D ₁ ,
D ₂ and D ₃ . Here, in practice, the distance between the mobile station and each base station differs for each base station, and the radio wave propagation delay time differs for each base station, so the phase difference between the peaks corresponding to the pilot channels of each base station is: It does not exactly match the spreading code phase difference assigned to each base station. However, in the processing of the mobile station, the spreading code phase differences 0, P ₁ , and P ₂ assigned to each base station have no meaning, and if the processing is performed using the phase differences D ₁ , D ₂ , and D ₃ with respect to the mobile station reference timing. No problem for good.

The control section 37 stores the reception level of the peak and the phase difference between the mobile station reference timing and the mobile station reference timing notified from the level measurement section 33 in the memory 36 in association with the spreading code.

Next, the control unit 37 reads another spreading code that can be used as a pilot channel from the memory 36, performs the same processing as the above-described processing, and determines the peak reception level and the mobile station reference timing for the spreading code. Is stored in the memory 36 in association with the spreading code. This is performed for all spreading codes that can be used as pilot channels.

After the measurement is completed for all the pilot channel spreading codes, the control unit 37 selects one or a plurality of reception level measurement values stored in the memory 36.
The largest one is selected, and the phase difference between the spreading code corresponding to the largest reception level and the mobile station reference timing is read.
The control unit 37 notifies the spread code generation unit 38 of the read spread code, and the spread code generation unit 38 generates the notified spread code and supplies it to the matched filter 32.
The matched filter 32 despreads the received signal with the supplied spreading code and outputs a despread signal. Further, the control unit 3
7 notifies the despread signal component extraction unit 34 of the phase difference from the read mobile station reference timing. The despread signal component extractor 34 extracts a phase difference component from the mobile station reference timing notified from the despread signal, and outputs the extracted component to the demodulator / decoder 35. The demodulation / decoding unit 35 demodulates and decodes the extracted signal, and supplies the decoded control signal to the control unit 37. The control unit 37 determines the validity of the communication based on the content of the decoded control signal, such as whether there is no error in the control signal or whether communication with the base station that transmitted this pilot channel is permitted. When determining that the communication is valid, the control unit 37 determines that a cell under the control of the base station transmitting the pilot channel is a serving cell. If it is determined that the communication with the base station is not valid due to an error in the control signal or the communication with the base station that transmitted this pilot channel is not permitted, it is stored in the memory 36. For a pilot channel having the next highest reception level, similar communication validity determination processing is performed. When the validity is determined, the cell is determined to be a serving cell, and the cell selection processing ends.

As described above, as a base station configuration, a base station having the same reference timing and transmitting a pilot channel using the same spreading code and a different spreading code phase does not have the same reference timing. Even when base stations transmitting pilot channels using different spreading codes are mixed, the mobile station can identify individual pilot channels using both the spreading code and the spreading code phase, so that cell selection is Can be performed normally.

Next, another embodiment will be described. As a system, the base station having the same reference timing previously limits the same spreading code used for the pilot channel, and all mobile stations store the same spreading code in the memory 36, and All different spreading codes for each base station that can be used by a base station having no reference timing are also stored in the memory 36.

For the same spreading code, the mobile station determines the spread code phase difference between the reception level and the mobile station reference timing for all peaks exceeding a predetermined threshold value in the same manner as in the above embodiment. Stored in memory. Regarding other spreading codes for pilot channels different between base stations, only the peak having the highest receiving level among peaks appearing within one cycle of the spreading code for each spreading code, its reception level and spreading code and The spreading code phase difference with respect to the mobile station reference timing is stored.

FIG. 5 shows an output example of a despread signal of a plurality of pilot channel spreading codes. In this figure, the spreading code 1 is the same spreading code, and the other spreading codes 2 and 3 are different spreading codes.

FIG. 6 shows a spread code phase difference and a reception level between the spread code for each pilot channel stored in the memory and the mobile station reference timing in the present embodiment corresponding to the despread signal of each spread code of FIG. It is a table showing correspondence. Here, the spreading code number in the table is a number for identifying the spreading code. In an actual case, the content stored in the memory is not the 1,0 pattern of the spreading code itself, but may be such an identification number. Also, here, the spreading code numbers 1, 2, and 3 correspond to the spreading codes 1, 2, and 3, respectively, of FIG. Regarding the spreading code 1 in FIG. 5, the spreading code, the spreading code phase difference, and the reception level are stored for all the peaks in the table in FIG. However, although a plurality of peaks are seen in different spreading codes 2 and 3, only the spreading codes 2 and 3 having the maximum reception level are stored in the memory in a table in the memory.

The effect of this embodiment will be described. In the same spreading code, since the base station having the same reference timing transmits a pilot channel with a different spreading code phase difference from the reference timing, the mobile station selects the reception level of a plurality of spreading code phases in a cell. Need to be taken into account. On the other hand, with different spreading codes, only one base station transmits the pilot channel with one spreading code, so that only one peak should appear in the despread signal. However, a peak may appear when the correlation with a noise component or another spreading code is high. Since this is not the peak of the pilot channel that is actually being transmitted, there is no need to store it in the memory in the cell selection process. Since the reception level of such a peak is less likely to be higher than the peak corresponding to the pilot channel transmitting the spreading code, only the peak having the maximum reception level is stored as in the present embodiment. Then, unnecessary peaks in cell selection can be ignored, and the required memory capacity can be reduced. In addition, since it is unnecessary to check the validity of cell communication for peaks that are not actually transmitted as pilot channels, the processing load can be reduced.

Another embodiment will be described. Base stations having the same timing have different spreading code phase differences, and this spreading code phase difference is a phase difference obtained by equally dividing one cycle of the spreading code. That is, when N spreading code phases are prepared with one spreading code, the N spreading code phase differences with respect to the reference timing are set to 0, X
/ N, 2X / N, 3X / N, ..., (N-1) X / N
And This effect will be described. If the spreading code phases are prepared non-uniformly, there may be a plurality of pilot channels with a small difference between the spreading code phases. Further, when the distance between the base station and the mobile station is different for each base station, and the radio wave propagation delay is different for each base station, a plurality of pilot channels having a small difference in spreading code phase are received by the mobile station with almost the same phase. Can happen. When a plurality of pilot channels are received by the mobile station with almost the same phase, the mobile station cannot receive them separately, and the signals of each other interfere with each other, so that the pilot channel cannot be received without error. However, there is a possibility that these cells cannot be selected. Therefore, by uniformly setting the spreading code phase difference as in the present embodiment, a plurality of pilot channels having a small spreading code phase difference does not exist, and the above problem can be avoided.

Another embodiment will be described. When using N kinds of the spread code phase differences different for each base station with respect to the reference timing, the N kinds of spread code phase differences are arranged in N base stations arranged in a geographically integrated range, respectively. The basic arrangement pattern of the spread code phase difference is used, and the basic arrangement pattern is geographically repeated to arrange the spread code phase difference. FIG. 7 shows a case where seven spreading code phase differences with respect to the reference timing are arranged in each cell in consideration of the present embodiment. Seven spreading code phase differences are arranged for seven cells in a hexagon, and
The arrangement pattern of the spread code phase differences C1 to C7 is used as a basic pattern, and the basic pattern is repeatedly arranged in a planar manner. As a result, base stations using the same spreading code phase difference are arranged at equal distances for all spreading code phase differences, so that the same spreading code phase difference is not used at short distances. In addition, it is possible to prevent a plurality of pilot channels having the same spread code phase difference from interfering with each other in reception by the mobile station and from being erroneously received by the mobile station.

As still another embodiment, N different spreading codes among base stations used in base stations not having the same reference timing are arranged in a geographically coherent range as in the previous embodiment. N base stations, each of which is used as a basic arrangement pattern of a spreading code, and the basic arrangement pattern is geographically repeated to arrange a spreading code. It is possible to prevent the pilot channels from interfering with each other and being erroneously received by the mobile station.

[0053]

As described above, according to the present invention,
Since a plurality of base stations having the same reference timing transmit pilot channels spread with the same spreading code and different spreading code phase differences for each base station, that is, base stations having the same reference timing in a plurality of base stations Then
Since a different spreading code phase is used for each base station with the same spreading code for the pilot channel spreading process, the cell selection process at the mobile station can be shortened compared to a case where different spreading codes are used for all base stations, and the pilot The number of spreading codes required as a channel can be reduced. Further, since a base station having no reference timing, that is, a base station having difficulty having the same reference timing transmits a pilot channel spread with a different spreading code for each base station at an arbitrary spreading code phase, Since different spreading codes are assigned to base stations for channel spreading processing, a feasible mobile communication system can be constructed without increasing the hardware scale for base stations having the same reference timing. Can be.

Further, according to the present invention, a base station having the same reference timing and transmitting a pilot channel using the same spreading code and a different spreading code phase does not have the same reference timing. Even in the case where base stations transmitting pilot channels using different spreading codes are mixed, the mobile station can identify individual pilot channels using both the spreading code and the spreading code phase, so that cell selection can be performed. Can be performed normally.

Further, according to the present invention, the mobile station stores the same spreading code and a plurality of spreading codes different for each base station, and for the same spreading code, the spreading code corresponding to the reception level of the plurality of spreading code phases. And the spreading code phase, and for the spreading code different for each base station,
Only the spreading code phase having the maximum receiving level during one cycle of the spreading code stores the spreading code and the spreading code phase corresponding to that receiving level, so that unnecessary receiving level information for cell selection can be ignored, and a required memory can be stored. The capacity can be reduced, and it is possible to eliminate the needlessly to check the validity of cell communication for reception level information that is not actually transmitted as a pilot channel, thereby reducing the processing load.

According to the present invention, when N types of spreading code phase differences different for each base station are used, the values of the spreading code phase differences with respect to the reference timing are 0, X / N, 2X / N,
3X / N,..., (N−1) X / N, that is, the phase difference obtained by dividing the spreading code phase difference assigned to the base stations having the same reference timing by one period of the spreading code at equal intervals Therefore, it is possible to avoid a problem that a plurality of pilot channels having a small spread code phase difference cannot be received without error.

According to the present invention, when N types of spreading code phase differences or spreading codes are used for different base stations, the N types of spreading code phase differences or spreading codes are arranged in a geographically integrated range. N base stations, respectively, and these are used as spreading code phase differences or spreading code basic layout patterns, and the basic layout pattern is geographically repeated to place spreading code phase differences or spreading codes. The same spreading code phase difference or spreading code is not used, and a plurality of pilot channels having the same spreading code phase difference or spreading code interfere with each other at the mobile station reception and are erroneously received by the mobile station. Can be prevented.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a base station apparatus that performs a cell selection method in a CDMA mobile communication system according to an embodiment of the present invention.

FIG. 2 is a timing chart showing waveforms of respective signals until a pilot channel is spread in base stations having the same reference timing in the embodiment of FIG. 1;

FIG. 3 is a block diagram illustrating a configuration of a mobile station device used in the embodiment of FIG.

4 is a waveform diagram showing an output of a despread signal when the mobile station of FIG. 3 receives pilot channels from three base stations having the same reference timing of FIG. 2;

FIG. 5 is a waveform diagram showing an output example of a despread signal of a plurality of pilot channel spreading codes according to another embodiment of the present invention.

6 shows the correspondence between the spreading code phase difference and the reception level between each pilot channel spreading code stored in the memory and the mobile station reference timing in the present embodiment corresponding to the despread signal of each spreading code of FIG. It is a table.

FIG. 7 is a diagram showing a spread code phase difference arrangement pattern according to still another embodiment of the present invention.

FIG. 8 is a waveform diagram showing an output example when a signal spread by a spreading code is input to a matched filter.

FIG. 9 is a waveform diagram showing an output example of a matched filter when the same spreading code is used, the spreading code phase is made different for each pilot channel, and a matched filter is used for the pilot channel reception level measurement processing.

FIG. 10 is a timing chart when different spreading code phase differences with respect to a reference timing are assigned to three pilot channels.

[Explanation of symbols]

 Reference Signs List 10 GPS antenna 11 GPS receiving unit 12 Reference timing generation unit 13 Spread modulation unit 16, 36 Memory 17, 37 Control unit 32 Matched filter 33 Level measurement unit 34 Despread signal component extraction unit 38 Spread code generation unit 39 Mobile station reference timing generation Department

Claims (9)

[Claims] 1. A base station is provided in each of a plurality of cells,
Each base station transmits a different pilot channel for each base station, and the mobile station is a cell selection method in a CDMA mobile communication system that determines a serving cell based on the reception level of the pilot channel. A plurality of base stations having the same reference timing, transmit the pilot channels spread with the same spreading code with a different spreading code phase difference for each base station with respect to the reference timing, and the base station having no reference timing Transmitting the pilot channel spread with a different spreading code for each base station at an arbitrary spreading code phase.
A cell selection method in an MA mobile communication system. 2. A mobile station despreads a received signal with one or a plurality of spreading codes that can be used for spreading a pilot channel and measures a reception level. The measurement of the reception level is performed by using a plurality of spreading codes for each spreading code. The mobile station stores a plurality of received level measurement values and a spread code and a spread code phase corresponding to each of the measured values, and the mobile station transmits a spread code and a spread code corresponding to the maximum received level among the stored received level measured values. It performs despreading and reception processing of a pilot channel corresponding to the code phase, determines whether communication in a cell under the base station transmitting the pilot channel is valid, and if it is valid, leaves the cell. 2. The serving cell is determined, and if not valid, the validity of communication is similarly determined in the descending order of the reception level to determine the serving cell. Cell selection method in a CDMA mobile communication system. 3. A mobile station stores the same spreading code and a plurality of spreading codes different for each of the base stations, and for the same spreading code, a spreading code and a spreading code corresponding to reception levels of a plurality of spreading code phases. For a spreading code different for each base station, only a spreading code phase having a maximum reception level during one cycle of the spreading code, and a spreading code and a spreading code phase corresponding to the reception level are stored. 3. The cell selection method in a CDMA mobile communication system according to claim 2, wherein: 4. When the spreading code period is X chips,
When using N types of spreading code phase differences different for each base station with respect to the reference timing, values of the respective spreading code phase differences with respect to the reference timing are set to 0, X / N, 2X /
2. The cell selection method in a CDMA mobile communication system according to claim 1, wherein N, 3X / N,..., (N-1) X / N. 5. When using N types of spreading code phase differences that differ for each base station with respect to the reference timing, the N types of spreading code phase differences are transmitted to N base stations arranged in a geographically integrated range. 2. The cell in the CDMA mobile communication system according to claim 1, wherein the spread code phase difference is geographically repeated and the spread code phase difference is geographically repeated, and the spread code phase difference is geographically repeated. Selection method. 6. When using N types of spreading codes different for each base station, the N types of spreading codes are respectively arranged in N base stations arranged in a geographically integrated range,
2. The cell selection method in a CDMA mobile communication system according to claim 1, wherein this is set as a basic arrangement pattern of the spreading code, and the basic arrangement pattern is geographically repeated to arrange the spreading code. 7. A base station is provided in each of the plurality of cells,
In a CDMA mobile communication system in which each base station transmits a different pilot channel for each base station and the mobile station determines a serving cell based on the reception level of the pilot channel, the base station apparatus has the same spreading code phase. A base station device having a reference timing and a base station device not having the reference timing, wherein the plurality of base station devices having the same reference timing of the same spreading code phase have the same spreading code, Transmitting the pilot channel spread with a different spreading code phase difference for each base station with respect to a reference timing, the base station apparatus having no reference timing transmits the pilot channel spread with a different spreading code for each base station. A base station apparatus in a CDMA mobile communication system transmitting at an arbitrary spreading code phase 8. A base station is provided in each of the plurality of cells,
Each base station transmits a different pilot channel for each base station, and the mobile station determines a serving cell based on the reception level of the pilot channel. In the CDMA mobile communication system, the mobile station device uses the pilot channel for spreading. Measuring means for measuring reception levels after despreading for a plurality of spreading codes for a plurality of spreading codes for each of a plurality of spreading codes, and a plurality of reception level measurement values measured by the measurement means and corresponding to each measurement value Storage means for storing a spreading code and a spreading code phase to perform a despreading and receiving process of a pilot channel corresponding to a spreading code and a spreading code phase corresponding to a maximum reception level among the stored reception level measurement values, Judge whether communication in a cell under the base station transmitting the pilot channel is valid or not. If the cell is valid, the cell is determined to be a serving cell. If the cell is not valid, the serving cell determining means for determining the serving cell by sequentially determining the validity of the communication in the order of increasing reception level is provided. The mobile station device in the CDMA mobile communication system according to claim 7, wherein: 9. The mobile station apparatus according to claim 1, wherein the mobile station device stores the same spreading code and a plurality of spreading codes different for each base station, and the same spreading code corresponds to a reception level of a plurality of spreading code phases. For the spreading code different for each base station, only the spreading code phase having the maximum receiving level during one cycle of the spreading code is stored in the spreading code and the spreading code corresponding to the receiving level. 9. The mobile station apparatus in a CDMA mobile communication system according to claim 8, further comprising storage means for storing a phase.