JP4405623B2 - Mobile station standby control method and apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To quickly and efficiently restrict waiting on the side of a mobile station. SOLUTION: This restriction method is employed in a mobile communication system where a base station and a plurality of mobile stations MS are connected by the CDMA system, and the mobile stations are in a standby state for a nearby base station, whose stations being operated synchronously with a prescribed symbol in a perch channel owing to prescribed cell searching. Changing contents of the prescribed symbol or its spread method into those other than the specified ones by the base station allows the mobile stations not to recognize the base station in the case of restricting the waiting on the side of the mobile stations.

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a mobile station standby control method and apparatus therefor, and more particularly, a base station and a plurality of mobile stations connected by a CDMA system, and the mobile station is synchronized with a predetermined symbol in a perch channel. The present invention relates to a mobile station standby control method and apparatus for a mobile communication system that is in a standby state.
[0002]
In this type of mobile communication system, a mobile station finally enters a standby state by synchronizing with a predetermined symbol in the perch channel provided by the nearest base station in the first stage of cell search. If a large number of mobile stations (communication traffic) are concentrated on the mobile station, the communication service capability of the base station may be exceeded. Therefore, it is desired that the mobile station standby regulation control can be performed efficiently.
[0003]
[Prior art]
FIGS. 13 to 17 are diagrams (1) to (5) for explaining the prior art, and FIG. 13 shows a partial configuration of a mobile communication system based on a conventional CDMA system. In the figure, 100 is a public network, 101 is a mobile switching center (MSC), 102 is a base station controller (BSC), 10 is a base station (BS1 to BS3), and MS1 to MS6 are mobile stations.
[0004]
An example of the communication status will be described in detail. MS1 to MS4 are registered in the location of BS2, MS1 to MS3 are in a call, and MS4 is in a standby state via a paging channel or the like. In addition, the MS 5 is moving into the service area (cell) of the BS 2, and the BS 6 is newly powered on in the cell of the BS 2.
[0005]
In this case, the MS 5 captures the nearest BS 2 (perch channel) and synchronizes with the BS 2, further identifies a spreading code (long code) unique to the BS 2, and exchanges necessary information with the BS 2. (Location registration, etc.) is performed, and finally a standby state in which outgoing and incoming calls can be made is established. The same applies to MS6.
[0006]
A perch channel is a physical channel that a mobile station acquires for the first time after power-on (or after entering a cell), and is a reception level measurement target when searching for a base station (a sector if the cell is divided into multiple sectors). Is a channel. Also, this is a one-way channel from the base station to the mobile station. In this system, the first perch channel used for capturing the nearest base station and communicating downlink information is used for the purpose of shortening the long code search time described later. There is a second perch channel to be played.
[0007]
FIG. 14 shows a radio format of the perch channel. In the figure, one radio superframe is composed of a plurality of radio frames 1 to m (for example, m = 64), and one radio frame (for example, 10 ms) is composed of a plurality of radio slots 1 to n (for example, n = 16). Further, regarding the radio slot (625 μs) which is the basic structure of communication, the first perch channel is a pilot symbol (for example, 4 symbols, 8 bits) used as a reference signal for synchronization when the mobile station receives information from the base station. From a data symbol that is transmission information from the base station to the mobile station and a long code mask symbol (for example, 1 symbol, 2 bits = “11”) that is a target of reception level measurement when the mobile station acquires a perch channel The second perch channel is composed of only a long code mask symbol (for example, 1 symbol, 2 bits = “11”) for searching for a group short code.
[0008]
Pilot symbols and data symbols in the first perch channel are double spread by a common short code 1 (one symbol period) common to all base stations and a long code (one frame period) different for each base station. The mask symbol is spread by a common short code 2 (one symbol period) common to all base stations. On the other hand, the long code mask symbol of the second perch channel is spread by a group short code (one symbol period) common to all base stations. FIG. 14 shows pilot timing PT for transmitting pilot symbols, data timing DT for transmitting data symbols, and long code mask timing LMT for transmitting long code mask symbols.
[0009]
FIG. 15 shows a partial configuration of a conventional base station apparatus. In FIG. 15, reference numeral 11 denotes a first perch channel data generation unit for generating transmission data (pilot, data, long code mask) of the first perch channel; Is a second perch channel data generator for generating transmission data (long code mask) for the second perch channel, 13 is a common short code 1 generator, 14 is a common short code 2 generator, 15 is a long code generator, 16 Is a group short code generating unit, 17 to 20 are spreading units (mixers, etc.) for spreading input symbols with code signals, 21 to 24 are spreading switch units for controlling the spreading timing of input symbol code signals, and A is an AND gate. Circuit, O is an OR gate circuit, 25 is a pilot, data and long code mask timing The timing generator for generating grayed signal PT, DT, the LMT, the signal multiplexing unit 26 to the signal multiplexed signals of the respective channels under the CDMA system, 27 transmission unit by radio, 28 is an antenna. In addition, a well-known normal structure is employ | adopted about the other structure which is not shown in figure.
[0010]
Focusing on the spreading method of the first perch channel, only the spreading switch units 21 and 23 are energized in the section of the pilot timing PT and the data timing DT. As a result, the pilot symbol and the data symbol are 2 by the common short code 1 and the long code. Heavily diffused. Further, only the spreading switch unit 22 is energized in the section of the long code mask timing LMT, so that the long code mask symbol is spread only by the common short code 2. On the other hand, focusing on the spreading method of the second perch channel, only the spreading switch unit 24 is energized in the section of the long code mask timing LMT, so that the long code mask symbol is spread only by the group short code.
[0011]
FIG. 16 is a flowchart of a three-stage cell search process in a conventional mobile station, and FIG. 17 is an image diagram of the three-stage cell search. In FIG. 16, the optimal (nearest) base station is found in the first stage of cell search. That is, in step S11, the long code mask symbol of the first perch channel transmitted from each base station is despread with the common short code 2 common to all base stations, and in step S12, the level of each despread result is measured. The timing (base station) having the highest correlation value is selected and held.
[0012]
FIG. 17A shows a processing image of the first stage. BS1 to BS4 operate asynchronously with each other, and transmit a common long code mask symbol at each timing. The mobile station detects each correlation value that shows each peak at each of these timings, but since the mobile station in this example is closest to BS2, the correlation value output (reception power) for BS2 is maximized. Therefore, the mobile station synchronizes the despreading timing with BS2.
[0013]
Returning to FIG. 16, in the second stage of the cell search, work for shortening the search time of the long code is performed. That is, in step S13, the long code mask symbols in the second perch channel are sequentially despread with all the group short codes at the held timing, and each despread result is compared in step S14, and the group with the highest correlation value is obtained. Select and hold a short code.
[0014]
Here, the relationship between the group short code and the long code will be described. If there are 256 types of long codes that can be assigned to the first perch channel of a certain base station, these are LC1 to LC256. Also, assuming that there are 16 types of group short codes that bundle them, these are designated as GSC1 to GSC16. At this time, both codes can be grouped as follows.
[0015]
GSC1 "LC1-LC16"
GSC2 “LC17-LC32”
GSC3 "LC33-LC48"
::
GSC16 "LC241-LC256"
As a result, when GSC2 is detected, for example, by searching for the group short code in the second stage, only the long codes LC17 to LC32 included in GSC2 need to be searched thereafter. Thus, a unique long code for each base station is obtained. The time for searching is 16 + 16 = 32 units, which is shortened to 1/8 compared to searching for 256 units.
[0016]
FIG. 17B shows a second stage processing image. The mobile station sequentially performs despreading by GSC1 to GSC16 in synchronization with BS2, but here, the maximum correlation value is obtained by despreading by GSC2.
[0017]
Returning to FIG. 16, in the third stage of the cell search, an operation for searching for a unique long code for each base station is performed. That is, in step S15, a predetermined received symbol (for example, pilot symbol) is despread in order by all the long codes belonging to the detected group short code, and in step S16, each despread result is compared and the correlation value is highest. Select and hold the long code.
[0018]
FIG. 17C shows a third stage processing image. The mobile station sequentially performs despreading by LC17 to LC32 belonging to GSC2 in synchronization with BS2, and here, the maximum correlation value is obtained by despreading by LC20.
[0019]
Thereafter, the mobile station uses the despread replica obtained by multiplying the common short code 1 and the selected long code LC20 to obtain reception synchronization with the pilot symbol from BS2, and can receive subsequent data symbols. Based on the received information, a procedure such as location registration is performed in BS2 using another logical channel, and finally a standby state in BS2 is entered.
[0020]
Returning to FIG. 13, the MSs 5 and 6 are newly registered in the BS 2 and enter a standby state, and the MSs 5 and 6 can receive and send incoming calls in this standby state. However, BS2 in this case is already providing a call service (call channel) to MS1 to MS3, and MS4 is already in a standby state. Will do. Conventionally, BS2 has received MS5 and MS6 in a new standby state even when standby control is in progress, and has transmitted and received information on standby control (transmission control, etc.) from BS2 using a broadcast channel. In MS4 to MS6, transmission from the own station was regulated.
[0021]
[Problems to be solved by the invention]
However, as described above, even if BS2 is under standby restriction, if MS5, 6 is in a new standby state, MS5, 6 performs a three-step cell search and BS2 in spite of the standby restriction as a result. It is necessary to enter a standby state, and this consumes extra power. In addition, since the MSs 5 and 6 enter the standby state of the BS 2 and are restricted from calling or the like, they are restrained by the BS 2 while in the cell of the BS 2. Further, when viewing the above situation from the BS 2 side, the BS 2 could not perform the quick standby control for the MSs 5 and 6 that have made the standby request after the standby control.
[0022]
The present invention has been made in view of the above-mentioned problems of the prior art, and an object of the present invention is to provide a mobile station standby control method and apparatus capable of quickly and efficiently controlling mobile station standby.
[0023]
[Means for Solving the Problems]
The above problem is solved by the configuration of FIG. In other words, the mobile station standby restriction method of the present invention (1) is such that the base station and a plurality of mobile stations are connected by the CDMA system, and the mobile station is synchronized with a predetermined symbol in the perch channel to the nearest base station. In the mobile station standby control method of the mobile communication system that is in a standby state, the base station uses the predetermined symbol spreading method when performing the mobile station standby control. Spreading method other than pre-defined for your station It is to change to.
[0024]
In the present invention (1), the base station uses a predetermined symbol spreading method when restricting the standby of the mobile station. Spreading method other than pre-defined for your station With the configuration to be changed, the MS5 that has moved into the service area after the standby restriction or the MS6 that is powered on in the service area cannot detect a predetermined symbol at the initial stage of the cell search. It is possible to regulate the waiting state. Moreover, the MSs 5 and 6 do not need to perform a useless cell search, so that the power savings of the MSs 5 and 6 can be achieved. Further, when this situation is viewed from the base station (BS2) side, the new MSs 5 and 6 that are being subjected to standby regulation can be regulated at the initial stage of cell search, so that rapid regulation control can be performed.
[0025]
In addition, since the present invention can be realized without any modification to the existing mobile stations (MS1 to MS6), it can be easily introduced into an existing mobile communication system. Further, the base station can narrow down the standby restriction targets to the mobile stations (MS5, 6) after the standby restriction. On the other hand, since MS1 to MS4 already in a standby state including a call are not subjected to cell search, the respective standby states can be maintained. Accordingly, the base station can provide a fair standby control service that gives preferential treatment.
[0026]
In addition, in the MSs 5 and 6 that are subject to standby regulation, the perch channel of the next nearest BS1, 3 and so on can be seen instead of seeing the perch channel of the nearest BS2, and these are captured and are in a standby state. Can be. Accordingly, the concentration of one cell in the BS 2 can be automatically distributed, and the MSs 5 and 6 are not restricted by the BS 2 and can be made / received via the BSs 1 and 3. That is, communication resources (communication channels etc.) can be used effectively.
[0027]
Preferably, in the present invention (2), in the present invention (1),
The base station includes a first perch channel that includes a first predetermined symbol that the mobile station refers to in the first stage of cell search and a second perch that includes a second predetermined symbol that is referred to in the second stage of cell search. And the first or second predetermined symbol spreading method when the mobile station standby control is performed. Spreading method other than pre-defined for your station Change to
[0028]
By the way, in this type of mobile communication system, after synchronizing with the nearest base station in the first stage of cell search with reference to the first perch channel, a unique long code is searched for each base station and the base station is searched. In some cases, a so-called two-stage cell search method is employed in which communication with the device is possible (transition to a standby state) is possible. In order to shorten the search for the long code, the second perch channel is referred to in the second stage of the cell search, and a group short code for specifying a long code group previously grouped into small groups is searched here. In some cases, a so-called three-step cell search method is employed. The present invention (2) is suitable for application to such a mobile communication system of the three-stage cell search method, and the base station uses the first or second predetermined symbol spreading method. Spreading method other than pre-defined for your station With this configuration, the mobile station can be controlled in standby in the first or second stage of cell search.
[0029]
Also, the mobile station standby restriction method of the present invention (3) is such that the base station and a plurality of mobile stations are connected by the CDMA system, and the mobile station is synchronized with a predetermined symbol in the perch channel at the nearest base station. In the mobile station standby control method of the mobile communication system that is in a standby state, the base station sets the content of the predetermined symbol when the mobile station standby control is performed. Contents other than those specified for your station It is to change to.
[0030]
In the present invention (3), when the base station regulates the standby of the mobile station, the content of the predetermined symbol is displayed. Contents other than those specified for your station With this simple configuration, the mobile station can no longer detect a predetermined symbol by its own cell search, and thus it is possible to restrict the new mobile station from entering the standby state.
[0031]
Preferably, in the present invention (4), in the present invention (3), the base station includes a first perch channel including a first predetermined symbol that the mobile station refers to in a first stage of cell search, and a cell. A second perch channel including a second predetermined symbol to be referred to in the second stage of the search, and the contents of the first or second predetermined symbol when the mobile station waits are restricted. Contents other than those specified for your station Change to
[0032]
In the present invention (4), the contents of the first or second predetermined symbol are Contents other than those specified for your station With this configuration, the mobile station can be controlled in standby in the first or second stage of cell search.
[0033]
In the base station apparatus of the present invention (5), the base station and a plurality of mobile stations are connected by the CDMA system, and the mobile station is in a standby state at the nearest base station synchronized with a predetermined symbol in the perch channel. In the base station apparatus of the mobile communication system, a data generation unit for generating transmission data of the perch channel, a spreading unit in which one or more for spreading the transmission data are cascode-connected, and spreading for each spreading unit A code generation unit that generates a code, and a spreading control unit that controls the timing at which the spreading code is added to each spreading unit. Predefined for your station In addition to spreading with a spreading code, the prescribed symbols are spread when the mobile station standby is restricted. code The Spread codes other than those previously determined for the station It is to change to.
[0034]
In the base station apparatus of the present invention (6), the base station and a plurality of mobile stations are connected by the CDMA system, and the mobile station is in a standby state at the nearest base station synchronized with a predetermined symbol in the perch channel. In the base station apparatus of the mobile communication system, a data generation unit for generating transmission data of the perch channel, a spreading unit in which one or more for spreading the transmission data are cascode-connected, and spreading for each spreading unit A code generation unit that generates a code, and a spreading control unit that controls the timing at which the spreading code is added to each spreading unit. Predefined for your station The content of the predetermined symbol is used when the mobile station is restricted in standby. Contents other than those previously determined for the station It is to change to.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a plurality of preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that the same reference numerals denote the same or corresponding parts throughout the drawings.
[0036]
FIG. 2 is a diagram showing a partial configuration of the base station apparatus according to the first embodiment, and shows a case where the spreading method of the long code mask symbol in the first perch channel is changed. In the figure, 21 to 23 are diffusion switch units according to the first embodiment, 21a to 23a are selectors (SEL), and 31 is a diffusion switch control unit. Other configurations may be the same as those described in FIG.
[0037]
The spreading switch control unit 31 selects each of the selection control signals S1 to S3 (= 0/1) of the selectors 21a to 23a according to a standby restriction signal (= 0/1) sent from a main control unit (not shown) of the base station apparatus 10. ) Is output. The selectors 21a to 23a receive the signal 0 and the long code mask timing signal LMT. When the selection control signal S = 0, the input signal 0 is selected and output, and when the selection control signal S = 1, the input is performed. The long code mask timing signal LMT is output.
[0038]
By the way, the long code mask symbol (= “11”) in the first perch channel of the base station 10 is normally spread only by the common short code 2. In this case, the mobile station uses the long code mask by the common short code 2. Symbols can be despread properly. However, if the long code mask symbol is spread by a spreading code other than the common short code 2, the mobile station can no longer properly despread the long code mask symbol. Accordingly, it is effective to spread the long code mask symbol with a spreading code other than the common short code 2 in order to hide the base station in the first stage of cell search in the mobile station.
[0039]
As a simple method for realizing this, it is conceivable that the long code mask symbol of the first perch channel is spread by another specific short code not used in the system, instead of the common short code 2. However, in this case, it is necessary to assign a specific short code that is the entire system to be unused. In the first embodiment, the specific short code is used by utilizing a configuration in which the spread of the first perch channel data can be spread up to three times by the spreading units 17 to 19 using each existing code. The object can be achieved with a simple configuration and control.
[0040]
FIG. 3 is a diagram for explaining a control method of the diffusion switch control unit 31 according to the first embodiment. There are the following eight diffusion methods including non-diffusion as a combination of three diffusion methods capable of diffusion. In the figure, spreading method (0) is non-diffusion, spreading method (1) is spreading only by long code, spreading method (2) is spreading only by common short code 2, spreading method (3) is common short code 2 and long code. Double spreading by code, and so on. The spreading method (7) is triple spreading by common short code 1, common short code 2 and long code. The spreading method (2) is a regular spreading method in the communication system, and in the first embodiment, the first stage of cell search in the mobile station can be effectively prevented by adopting other spreading methods. . Here, the case of the diffusion methods (3), (6) and (0) will be described more specifically.
[0041]
FIG. 4 is a diagram for explaining the spreading method (3) in the first embodiment, and shows a case where the long code mask symbol of the first perch channel is double spread by the common short code 2 and the long code. Referring to FIG. 2, in this case, the diffusion switch control unit 31 selects the selection control signals S1 = 0, S2 = 1, S3 = for the selectors 21a to 23a when the input standby restriction signal = 0 (non-regulation). 0 {Diffusion method (2)} is output. In this case, the outputs of the selectors 21a to 23a are the signal 0, the long code mask timing signal LMT, and the signal 0, respectively, whereby the long code mask symbol is spread only by the common short code 2.
[0042]
Further, when the input standby regulation signal = 1 (regulation), the diffusion switch control unit 31 outputs each selection control signal S1 = 0, S2 = 1, S3 = 1 {diffusion method (3)}. In this case, the outputs of the selectors 21a to 23a are the signal 0, the long code mask timing signal LMT, and the long code mask timing signal LMT, respectively, whereby the long code mask symbol is double spread by the common short code 2 and the long code. . Referring to FIG. 4, spreading by the long code is also turned ON in the section of the long code mask timing LMT.
[0043]
FIG. 5 is a diagram for explaining the spreading method (6) in the first embodiment, and shows a case where the long code mask symbol of the first perch channel is double spread by the common short code 1 and the common short code 2. . Referring to FIG. 2, the long code mask symbol in the standby restriction signal = 0 (non-regulation) is spread only by the common short code 2 as described above. The diffusion switch control unit 31 outputs the selection control signals S1 = 1, S2 = 1, and S3 = 0 when the input standby restriction signal = 1 (restriction). In this case, the outputs of the selectors 21a to 23a are the long code mask timing signal LMT, the long code mask timing signal LMT, and the signal 0, respectively, whereby the long code mask symbol is double spread by the common short code 1 and the common short code 2. Is done. Referring to FIG. 5, the spreading by the common short code 1 is also turned ON in the section of the long code mask timing LMT.
[0044]
FIG. 6 is a diagram for explaining the spreading method (0) in the first embodiment, and shows a case where a long code mask symbol of the first perch channel is transmitted without spreading. Referring to FIG. 2, the long code mask symbol in the standby restriction signal = 0 (non-regulation) is spread only by the common short code 2 as described above. The diffusion switch control unit 31 outputs the selection control signals S1 = 0, S2 = 0, and S3 = 0 when the input standby restriction signal = 1 (restriction). In this case, the outputs of the selectors 21a to 23a are a signal 0, a signal 0, and a signal 0, respectively, whereby the long code mask symbol is output without spreading. Referring to FIG. 6, the spreading by the common short code 2 is also turned OFF in the section of the long code mask timing LMT.
[0045]
FIG. 7 is an image diagram of standby restriction control according to the first embodiment. When BS2 adopts any one of the spreading methods (0), (1), (3) to (7) at the time of the standby regulation, it newly enters the service area of BS2 or newly enters the service area Since the spreading method and the despreading method of the long code mask symbol in the first perch channel are different from those of the mobile stations (MS5 and MS6) that are powered on, the mobile station appropriately reverses this long code mask symbol. Cannot spread. Therefore, the MS2 and the MS2 cannot see the BS2 from the first stage of the cell search, and thus the BS2 can efficiently control the standby of the MS5 and the MS6. Incidentally, the MSs 5 and 6 in this case capture BSs 1 and 3 having the next highest received power.
[0046]
Although the case where the diffusion switch units 21 to 23 include the selectors 21a to 23a has been described in the first embodiment, the present invention is not limited to this. For example, when realizing the diffusion method (3), only the diffusion switch unit 23 is provided with the selector 23a, and the other diffusion switch units 21 and 22 can use the fixed diffusion switch units 21 and 22 shown in FIG. . The same applies when other diffusion methods are realized.
[0047]
FIG. 8 is a diagram showing a partial configuration of the base station apparatus according to the second embodiment, and shows a case where the spreading method of the long code mask symbol in the second perch channel is changed. In the figure, 24 is a diffusion switch unit according to the second embodiment, 24a is a selector (SEL), and 31 is a diffusion switch control unit according to the second embodiment. Other configurations may be the same as those described in FIG.
[0048]
In addition to the above, the second stage of cell search in the mobile station can be effectively prevented by changing the spreading method of the long code mask symbol in the second perch channel. As a method for realizing this, the long code mask symbol of the second perch channel may be diffused by another specific short code that is not used in this communication system, instead of the normal group short code. However, in this case, it is necessary to disable a specific short code that is the entire system. In the second embodiment, a long code mask symbol of the second perch channel is configured to be spread by the spreading unit 20 using an existing group short code, and a specific short code is not used. The objective can be achieved with simple configuration and control.
[0049]
FIG. 9 is a diagram for explaining a method of spreading a long code mask symbol in the second embodiment, and shows a case where a long code mask symbol at the time of standby restriction is transmitted without spreading. Referring to FIG. 8, the diffusion switch control unit 31 in this case outputs the selection control signal S4 = 1 of the selector 24a when the input standby restriction signal = 0 (non-regulation). Therefore, the output of the selector 24a is the long code mask timing signal LMT, whereby the long code mask symbol is spread only by the group short code. The diffusion switch control unit 31 outputs the selection control signal S4 = 0 when the input standby restriction signal = 1 (restriction). In this case, the output of the selector 24a is a signal 0, which makes the long code mask symbol non-spread. Referring to FIG. 9, the spreading by the group short code is also turned off in the section of the long code mask timing LMT.
[0050]
FIG. 10 is an image diagram of standby restriction control according to the second embodiment. If BS2 turns off spreading with the group short code at the time of the standby restriction, MS5 and 6 of the new entrant group can catch BS2 in the first stage of cell search, but further in the second stage, the long code of the second perch channel Even if the mask symbols are despread with all the group shot codes GSL1 to GSL16, a correlation value higher than required cannot be obtained, and therefore the second stage of the cell search cannot be achieved. In this way, BS2 can efficiently control standby of MS5 and MS6 of the new standby participation group under standby control.
[0051]
Incidentally, the MSs 5 and 6 in this case can be substantially in standby in the second stage of the cell search, and when the BS 2 cancels the standby restriction, the second and third stages of the cell search are achieved. Finally, it will be in a standby state. Alternatively, it is possible to change the cell search software of the mobile station. In this case, the MSs 5 and 6 return to the first stage without waiting in the second stage of the cell search, and change other BS1, BS3, etc. It is also possible to capture.
[0052]
FIG. 11 is a diagram illustrating a partial configuration of the base station apparatus according to the third embodiment, and illustrates a case where the content of the long code mask symbol (usually “11”) in the first or second perch channel is changed. Yes. In addition to the above, the first or second stage of cell search in the mobile station can be effectively prevented by changing the content “11” of the long code mask symbol in the first or second perch channel.
[0053]
In the figure, 31 is a spreading switch controller according to the third embodiment, 32 and 33 are data converters for changing the contents of long code mask symbols, and E is an EX-OR circuit. Other configurations may be the same as those described in FIG.
[0054]
In order to block the first stage of cell search in the mobile station, the content of the long code mask symbol in the first perch channel is changed. Specifically, the diffusion switch control unit 31 outputs the selection control signal S5 = 0 of the selector 32a when the standby restriction signal = 0 (non-regulation) from the main control unit (not shown). In this case, the selector 32a selectively outputs the signal 0, whereby the long code mask symbol output from the EX-OR circuit E1 is "11", which is the same as the input symbol. The diffusion switch control unit 31 outputs the selection control signal S5 = 1 when the standby control signal = 1 (control) from the main control unit. In this case, the selector 32a outputs the long code mask timing signal LMT, whereby the long code mask symbol output from the EX-OR circuit E1 becomes "00", which is the logically inverted input symbol. In order to block the second stage of cell search in the mobile station, the content of the long code mask symbol in the second perch channel is changed. Since the operation is the same as described above, description thereof is omitted.
[0055]
In the third embodiment, the case where the content of the long code mask symbol in the first or second perch channel is changed from normal “11” to “00” has been described, but the present invention is not limited to this. For example, the content of the long code mask symbol may be changed to “10”, “01”, or the like. In addition, in the modification method, the content of the long code mask symbol stored in the first / second perch channel data generation units 11 and 12 is directly changed by the main control unit or the like instead of providing the data conversion units 32 and 33. May be rewritten.
[0056]
FIG. 12 shows a partial configuration of the mobile communication system according to each of the above embodiments. In the figure, BS1 to BS3 are base stations according to the above-described embodiments, and other configurations and operation states of MS1 to MS6 may be the same as those described in FIG. According to each of the above embodiments, the MS 5 that has entered the cell after the restriction on the standby of the BS 2 cannot find the BS 2 by being blocked from the first or second stage of the cell search. It becomes a standby state. Further, the MS 6 that is turned on in the cell of the BS 2 cannot find the BS 2 for the same reason as described above, and instead enters, for example, a standby state in the adjacent BS 3.
[0057]
Such standby restriction control can be realized by the above simple configuration and control applied to the base station, and there is no need to add any change to the existing mobile station. Further, as a result of the cell search being blocked at the initial stage of the cell search, the power consumed by the useless cell search can be greatly reduced. Further, in this case, the MSs 5 and 6 can capture the adjacent BSs 1 and 3 and the like, thereby making effective use of limited communication resources (call channels and the like) along with distribution of communication traffic. In addition, BS2 does not register the positions of BSs 5 and 6 subject to standby regulation, and has no knowledge about the existence of these BSs 5 and 6. That is, the BS 2 in this case only needs to manage the MS1 to MS4 that are already in the standby state, and therefore, MS management when the standby control of the BS2 is restricted becomes simpler than before.
[0058]
The following application examples can also be easily realized. That is, in this case, BS1 and BS3 are existing (operating) base stations, MS5 and MS6 are existing mobile stations, BS2 is a newly established (testing) base station, and MS1 to MS4 test BS2 and the like. Mobile station. Further, the BS 2 is not always visible from the MSs 5 and 6 regardless of the presence / absence of the standby regulation, but is always visible from the MS 1 to the MS 4. Since BS2 cannot be seen from MS5 and 6 in this case, each connects to BS1 and 3 according to usual. On the other hand, since BS2 can be seen from MS1 to MS4, each connects to BS2 in accordance with usual. With this simple configuration and control, the newly installed BS 2 can be fully tested before its operation. In particular, when a new service is provided by BS2, the present invention exhibits a great effect.
[0059]
In each of the above-described embodiments, the application example to the three-step cell search method as described in the prior art has been described. However, the present invention is not limited to this. The present invention uses, for example, the first stage of cell search to synchronize with a specific (nearest) base station using symbols and spreading codes common to the system, and uses the obtained synchronization timing in the second stage. The present invention can also be applied to a communication system that employs a so-called two-stage cell search method for searching for a long code unique to the base station.
[0060]
Moreover, although several embodiment suitable for the said this invention was described, it cannot be overemphasized that the structure of each part, control, and various changes can be performed within the range which does not deviate from this invention.
[0061]
【The invention's effect】
As described above, according to the present invention, with respect to the mobile stations of the new standby participation group, by a simple method of making the base stations under standby control invisible, without making any changes to the existing mobile stations, Mobile station standby regulation can be performed quickly and efficiently. At the same time, it is possible to save power in the mobile station and to wait for distribution to other base stations, which greatly contributes to effective use of resources (communication channels, etc.) in the mobile communication system.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating the principle of the present invention.
FIG. 2 is a diagram showing a partial configuration of a base station apparatus according to the first embodiment.
FIG. 3 is a diagram illustrating a control method of a diffusion switch control unit 31 according to the first embodiment.
FIG. 4 is a diagram illustrating a diffusion method (3) in the first embodiment.
FIG. 5 is a diagram illustrating a diffusion method (6) in the first embodiment.
FIG. 6 is a diagram for explaining a diffusion method (0) in the first embodiment.
FIG. 7 is an image diagram of standby restriction control according to the first embodiment.
FIG. 8 is a diagram illustrating a partial configuration of a base station apparatus according to a second embodiment.
FIG. 9 is a diagram for explaining a long code mask symbol spreading method according to the second embodiment;
FIG. 10 is an image diagram of standby restriction control according to the second embodiment.
FIG. 11 is a diagram illustrating a partial configuration of a base station apparatus according to a third embodiment.
FIG. 12 is a diagram showing a partial configuration of a mobile communication system according to an embodiment.
FIG. 13 is a diagram (1) for explaining the prior art.
FIG. 14 is a diagram (2) for explaining the prior art.
FIG. 15 is a diagram (3) for explaining the prior art.
FIG. 16 is a diagram (4) for explaining the prior art.
FIG. 17 is a diagram (5) for explaining the prior art.
[Explanation of symbols]
10 Base station (BS)
11 First perch channel data generator
12 Second perch channel data generator
13 Common short code 1 generator
14 Common short code 2 generator
15 Long code generator
16 Group short code generator
17-20 Diffusion part
21-24 Diffusion switch
21a-24a Selector (SEL)
25 Timing generator
26 Signal multiplexer
27 Transmitter
28 Antenna
31 Diffusion switch controller
32, 33 Data converter
100 public network
101 Mobile Switching Center (MSC)
102 Base station controller (BSC)
A AND gate circuit
E EX-OR circuit
O OR gate circuit
MS mobile station

Claims (6)

In a mobile station standby control method of a mobile communication system in which a base station and a plurality of mobile stations are connected by a CDMA system, and the mobile station is in a standby state at the nearest base station synchronized with a predetermined symbol in the perch channel ,
The base station changes the spreading method of the predetermined symbol to a spreading method other than that determined in advance for the base station when the base station regulates the standby of the mobile station. The base station includes a first perch channel that includes a first predetermined symbol that the mobile station refers to in the first stage of cell search and a second perch that includes a second predetermined symbol that is referred to in the second stage of cell search. 2. The method according to claim 1, further comprising changing a spreading method of the first or second predetermined symbol to a spreading method other than that previously determined for the own station when the mobile station is subjected to standby control. The mobile station standby control method described. In a mobile station standby control method of a mobile communication system in which a base station and a plurality of mobile stations are connected by a CDMA system, and the mobile station is in a standby state at the nearest base station synchronized with a predetermined symbol in the perch channel ,
A base station standby control method, wherein the base station changes the content of the predetermined symbol to a content other than that previously determined for the local station when the mobile station standby control is performed. The base station includes a first perch channel that includes a first predetermined symbol that the mobile station refers to in the first stage of cell search and a second perch that includes a second predetermined symbol that is referred to in the second stage of cell search. The content of the first or second predetermined symbol is changed to a content other than that determined in advance for the mobile station when the mobile station is subjected to standby control. Mobile station standby control method. In a base station apparatus of a mobile communication system in which a base station and a plurality of mobile stations are connected by a CDMA system, and the mobile station is in a standby state at the nearest base station synchronized with a predetermined symbol in the perch channel,
A data generation unit for generating transmission data of the perch channel;
A spreading unit in which one or more for spreading the transmission data are cascode-connected,
A code generator for generating a spreading code for each spreading unit;
A spreading control unit that controls the timing of adding a spreading code for each spreading unit;
The diffusion control unit is normally defined for the advance own spreading code of said predetermined symbols when well as spread with a spreading code determined for previously own station to a predetermined symbol, the standby regulation of the mobile station A base station apparatus that changes to a spreading code other than the above . In a base station apparatus of a mobile communication system in which a base station and a plurality of mobile stations are connected by a CDMA system, and the mobile station is in a standby state at the nearest base station synchronized with a predetermined symbol in the perch channel,
A data generation unit for generating transmission data of the perch channel;
A spreading unit in which one or more for spreading the transmission data are cascode-connected,
A code generator for generating a spreading code for each spreading unit;
A spreading control unit that controls the timing of adding a spreading code for each spreading unit;
The data generation unit normally generates a predetermined symbol with contents determined in advance for the own station, and when restricting waiting of a mobile station, the data generating unit is configured so that the contents of the predetermined symbol are not determined in advance for the own station. The base station apparatus is characterized by being changed to the content of

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