JP2006033894A - Peripheral base station information update method, mobile communication system, mobile station, and base station - Google Patents

Abstract

Information on neighboring base stations notified from a base station to a mobile station is appropriately updated and set.
In a mobile station of a mobile communication system comprising a plurality of base stations that transmit perch channels and peripheral base station information, and the mobile station, the peripheral base station information transmitted by the base station is received and received Based on the base station information, a perch channel transmitted by a neighboring base station is searched and received. Peripheral base station information actually observed during the search / reception step is transmitted to the base station. The base station receives the peripheral base station information transmitted by the mobile station, and updates the peripheral base station information of the base station based on the received peripheral base station information.
[Selection] Figure 9

Description

  The present invention includes a plurality of base stations that transmit a perch channel and neighboring base station information, and a mobile station that receives the neighboring base station information, searches for a perch channel based on the neighboring base station information, and receives the neighboring base station information. The present invention relates to a neighboring base station information update method in a mobile communication system.

  In mobile communication systems such as mobile phones that are currently popular, services are performed by dividing the entire service area into relatively small wireless zones called cells. For example, as shown in FIG. 1, such a system is wireless between a plurality of base stations 111-1 to 111-5 that cover the divided wireless zones and these base stations 111-1 to 111-5. The mobile stations 112-1 to 112-3 are configured to perform communication by setting channels.

  The main access methods between base stations and mobile stations are: Frequency Division Multiple Access (FDMA), Time Division Multiple Access (TDMA), Code Division Multiple Access (Code Division Multiple Access) CDMA). In any system, each base station transmits a channel for enabling the mobile station to identify a base station to be connected. Here, such a channel is called a perch channel. In the FDMA system and the TDMA system, the perch channel of each base station uses a different radio frequency, and the mobile station identifies each base station by the radio frequency. On the other hand, direct spreading (DS) -CDMA performs information transmission by performing secondary modulation in which a conventional information data modulation signal is spread by a spreading code at a high rate, thereby allowing a plurality of users to communicate using the same radio frequency band. It is a method to perform. Each user's communication wave is identified by a spreading code assigned to each user.

  By the way, the radio wave transmitted with a certain transmission power from the base station propagates through the space while being attenuated and reaches the reception point. Because the amount of attenuation received by radio waves increases as the distance between the transmission point and the reception point increases, basically the perch channel transmitted from a distant base station has a weak reception level, and the perch is transmitted from a close base station. The channel is received at a strong reception level. In reality, the magnitude of the propagation loss varies depending not only on the distance but also on the terrain, buildings, and the like, so that the received power of the perch channel from each base station varies greatly as the mobile station moves. In order to receive the signal transmitted from the base station with better quality, it is important that the mobile station constantly monitors the perch channel from each base station and selects the best base station. In the situation where the reception level of the perch channel from each base station constantly fluctuates, the perch is always replaced when it exceeds the required reception level, and the reception level of the perch that has been received so far suddenly decreases and is received. In other words, the reception level of the perch, which was previously unreceivable, suddenly increases and becomes receivable. Even in such a situation, in order to allow the mobile station to follow the best perch channel, in general, in a mobile communication system, information on the perch channel used by neighboring base stations is transferred from the network side to the mobile station. A way to notify is taken. The information on the peripheral base stations is information on a perch radio frequency in an FDMA or TDMA system, and information on a spreading code used in a CDMA system and its phase. In such a method, it is necessary for a system operator to prepare information on surrounding base stations and store the information in each base station in advance. Neighboring base station information is manually determined using the distance on the map, or using software that simulates the actual propagation environment based on topography and building data.

  In the conventional method, it is difficult to accurately predict the actual propagation environment, so there are problems such as that the surrounding base station information prepared in advance is not appropriate, or that changes in buildings and topography cannot be followed quickly. there were. If the neighboring base station information is not appropriate, it will hinder the mobile station's communication handover control and standby cell transition processing, and the mobile communication service will not be able to receive incoming calls. It had the defect of causing serious undesirable problems.

  In view of the above problems, an object of the present invention is to appropriately update and set information on neighboring base stations notified from each base station to a mobile station.

  In the present invention, the mobile station acquires base station information of a base station that can be received by the mobile station by receiving signals transmitted from a plurality of base stations, and notifies the base station of the acquired information. It is a summary. As already explained, it is very difficult to accurately predict the actual propagation environment. Base station information observed at the mobile station (for example, the base station and the mobile station communicate with each other by spreading the signal over a wide band using a spreading code higher than the information rate, and the same repetition period as the information symbol period. System that uses a first spreading code group that is common to all base stations and a second spreading code that differs for each base station that has a longer repetition period compared to the information symbol period, and transmits signals in a double spread manner The second spreading code number, or the second spreading code number and the phase information, or the peripheral base station information held in the base station based on the perch channel radio frequency (for example, spreading at a higher speed than the information rate) A base station and a mobile station communicate with each other by spreading a signal over a wide band using a code, and has the same repetition period as an information symbol period and is common to all base stations And a second spreading code number or a second spreading code number in a system in which a signal is transmitted in a double spread using a different second spreading code for each base station having a repetition period longer than the information symbol period, and The phase information (or the radio frequency of the perch channel) is updated so that the actual propagation environment is accurately reflected by the peripheral base station information.

  FIG. 2 is a diagram illustrating an example of a predicted power range of each base station depending on a distance on the map. In the figure, it is determined that it is sufficient to register information on the base stations BS2, BS3, BS4, and BS5 as the neighboring base station information of the base station BS1, and underlined below these symbols. It shows.

  However, in the actual propagation environment, it is assumed that the power range is as shown in FIG. A mobile station attempting to perform a handover from the base station BS1 to the base station BS6 cannot be handed over and is disconnected during a call because information related to the BS6 is not registered in the peripheral base station information of the BS1.

  However, in the present invention, since the actual propagation environment is reflected, it is reported to the base station that a signal from each base station can be received from the mobile station located at the boundary between BS1 and BS6. Acts to enable handover from to BS6 (FIG. 4). 2 to 4, the predicted power range is represented by a circle, and the case where the reality is not a circle has been described as an example. However, this diagram simply means that the prediction and the reality are different. However, the expected range of power need not be a circle.

  Furthermore, if the second spreading code and the phase information are combined and reported to the measurement / base station, a high-speed cell search (based on the base station) is performed using the phase information when searching for a new cell for handover. The search for the perch channel) is performed with low power consumption (FIG. 4). Here, the phase information is information indicating the phase difference between the second spreading code used in the base station and the second spreading code used in the neighboring base station, and the mobile station captures this information and the current information. It is possible to search for neighboring base stations at high speed based on the phase of the second spreading code of the existing base station.

  Also, if the base station is configured to prioritize neighboring base station information according to the number of reports, handover success rate, and number of successful handovers, the perch channel that is expected to be received at a higher probability at the mobile station is given priority. The search can be performed, and the time and power required for the cell search are reduced.

  To achieve the above object, according to the first aspect of the present invention, there is provided a neighboring base station information updating method in a mobile communication system comprising a plurality of base stations that transmit perch channels and neighboring base station information, and a mobile station. In the mobile station, a first reception step for receiving the neighboring base station information transmitted by the base station, and a perch channel transmitted by the neighboring base station based on the neighboring base station information received by the first receiving step. A search / reception step of searching and receiving, and a transmission step of transmitting to the base station the neighboring base station information actually observed in the search / reception step, wherein the mobile station transmits the base station information A second receiving step for receiving neighboring base station information, and the neighboring base station information based on the neighboring base station information received by the second receiving step. And a updating step of updating the Chikyoku information.

  Here, the peripheral base station information may include information regarding the phase of the spreading code used by the peripheral base station.

  Here, the information regarding the phase may be information representing a phase difference between a spreading code used by a base station that transmits the neighboring base station information and a spreading code used by the neighboring base station.

  In the second aspect of the present invention, a mobile communication system comprising a plurality of base stations that transmit perch channels and peripheral base station information, and a mobile station, the mobile station transmits a peripheral base station transmitted by the base station A first receiving means for receiving information; a search / reception means for searching for and receiving a perch channel transmitted by the neighboring base station based on the neighboring base station information received by the first receiving means; and the search / receiving Transmitting means for transmitting neighboring base station information actually observed in the means to the base station, wherein the base station receives second neighboring base station information transmitted by the mobile station, and 2 based on neighboring base station information received by the receiving means, and updating means for updating neighboring base station information of the base station.

  Here, the peripheral base station information may include information regarding the phase of the spreading code used by the peripheral base station.

  Here, the information regarding the phase may be information representing a phase difference between a spreading code used by a base station that transmits the neighboring base station information and a spreading code used by the neighboring base station.

  In the third aspect of the present invention, the mobile station includes a receiving unit that receives the neighboring base station information transmitted by the base station, and a perch transmitted by the neighboring base station based on the neighboring base station information received by the receiving unit. Search / reception means for searching for and receiving a channel, and transmission means for transmitting neighboring base station information actually observed by the search / reception means to the base station.

  Here, the peripheral base station information may include information regarding the phase of the spreading code used by the peripheral base station.

  Here, the information regarding the phase may be information representing a phase difference between a spreading code used by a base station that transmits the neighboring base station information and a spreading code used by the neighboring base station.

  In the fourth aspect of the present invention, a plurality of base stations that transmit perch channels and neighboring base station information, and the neighboring base station information are received, and the perch channel is searched based on the neighboring base station information and received. A base station information acquisition method for acquiring base station information of a base station that has transmitted the perch channel from a received perch channel in the mobile station in a mobile communication system including a mobile station And base station information transmitting step for transmitting the base station information acquired in the base station information acquiring step to the base station, and the base station information for receiving the base station information transmitted by the mobile station in the base station A neighboring base that updates the neighboring base station information based on the receiving step and the base station information received by the base station information receiving step And an information update step.

  Here, the perch channel is spread over a wide band using a spreading code higher than the information rate, and the first spreading code group and information common to all base stations having the same repetition period as the information symbol period The base station information is double-spread using a different second spreading code for each base station having a repetition period longer than the symbol period, and the base station information includes the second spreading code number used by the base station and the code It can be configured by phase information.

  Here, the perch channel is spread over a wide band using a spreading code higher than the information rate, and the first spreading code group and information common to all base stations having the same repetition period as the information symbol period The base station information is composed of a second spreading code number used by the base station. The base station information is double-spread using a different second spreading code for each base station having a repetition period longer than the symbol period. Can be.

  Here, the base station information may be composed of a perch channel radio frequency.

  Here, the base station may rearrange the neighboring base station information in the order of base stations included in the base station information received in the base station information receiving step.

  Here, the base station may rearrange the neighboring base station information in the order of base stations having a high handover success rate calculated based on a success or failure result of the handover.

  Here, the base station may rearrange the neighboring base station information in the order of base stations having the highest number of successful handovers.

  Here, the mobile station may search for a perch channel with a high frequency for base stations with high rank and with a low frequency for base stations with low rank.

  Here, the base station may transmit information for the top N stations (N is a predetermined constant) of the neighboring base station information.

  In the fifth aspect of the present invention, a plurality of base stations that transmit perch channels and neighboring base station information and the neighboring base station information are received, and the perch channel is searched based on the neighboring base station information and received. A mobile communication system comprising: a base station information acquisition unit configured to acquire base station information of a base station that has transmitted the perch channel from the perch channel received by the mobile station; and the base station information acquisition Base station information transmitting means for transmitting base station information acquired by the means to the base station, wherein the base station receives base station information transmitted by the mobile station, and the base station Peripheral base station information updating means for updating the peripheral base station information based on the base station information received by the information receiving means.

  Here, the perch channel is spread over a wide band using a spreading code higher than the information rate, and the first spreading code group and information common to all base stations having the same repetition period as the information symbol period The base station information is double-spread using a different second spreading code for each base station having a repetition period longer than the symbol period, and the base station information includes the second spreading code number used by the base station and the code It can be configured by phase information.

  Here, the perch channel is spread over a wide band using a spreading code higher than the information rate, and the first spreading code group and information common to all base stations having the same repetition period as the information symbol period The base station information is composed of a second spreading code number used by the base station. The base station information is double-spread using a different second spreading code for each base station having a repetition period longer than the symbol period. Can be.

  Here, the base station information may be composed of a perch channel radio frequency.

  Here, the base station may rearrange the neighboring base station information in the order of base stations included in a lot of base station information received by the base station information receiving means.

  Here, the base station may rearrange the neighboring base station information in the order of base stations having a high handover success rate calculated based on a success or failure result of the handover.

  Here, the base station may rearrange the neighboring base station information in the order of base stations having the highest number of successful handovers.

  Here, the mobile station may search for a perch channel with a high frequency for base stations with high rank and with a low frequency for base stations with low rank.

  Here, the base station may transmit information for the top N stations (N is a predetermined constant) of the neighboring base station information.

  6th aspect of this invention WHEREIN: The base station information which searches the perch channel which the base station transmitted, and receives the base station information which acquires the base station information of the base station which transmitted this perch channel from the received perch channel An acquisition means and a base station information transmission means for transmitting the base station information acquired by the base station information acquisition means to the base station.

  In the seventh aspect of the present invention, a base station that transmits neighboring base station information includes base station information receiving means for receiving base station information transmitted by a mobile station, and base station information received by the base station information receiving means. Peripheral base station information updating means for updating the peripheral base station information based on

  According to the above configuration, it is possible to appropriately update and set information on neighboring base stations notified from each base station to the mobile station.

  If the second spreading code and the phase information are reported together to the measurement / base station, a high-speed cell search can be executed with low power consumption.

  Furthermore, if the base station prioritizes neighboring base station information, the time and power required for cell search can be kept small.

  ADVANTAGE OF THE INVENTION According to this invention, the information of the periphery base station notified to a mobile station from each base station can be updated appropriately and can be set.

  If the second spreading code and the phase information are reported together to the measurement / base station, a high-speed cell search can be executed with low power consumption.

  Furthermore, if the base station prioritizes neighboring base station information, the time and power required for cell search can be kept small.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  The mobile communication system according to the present embodiment receives a perch channel and neighboring base station information, and receives the neighboring base station information, and searches for and receives a perch channel based on the neighboring base station information. Mobile station. The base station according to the present embodiment transmits the perch channel including peripheral base station information, that is, information such as the perch channel of the base stations around the base station.

  The present invention can be applied regardless of the radio access scheme, but the mobile communication system according to the present embodiment uses the CDMA scheme as the radio access scheme. A spreading code used for spreading includes a first spreading code group having a repetition period of an information symbol period and a second spreading code different for each base station having a repetition period longer than the information symbol period. These two types of spreading codes are combined.

  FIG. 5 is a conceptual diagram for explaining a method of using a spreading code in the mobile communication system according to the present embodiment. In the figure, the upper layer indicates a scrambling code layer assigned to each base station in a long cycle, and the lower layer indicates a spreading code layer commonly used for all base stations in a short cycle. A signal transmitted from each base station is identified using a long-period scrambling code assigned to each base station.

  FIG. 6 is a schematic diagram showing the timing relationship of scrambling codes for signals from each base station received by the mobile station according to the present embodiment. The mobile communication system according to the present embodiment is an asynchronous mobile communication system that does not necessarily require synchronization between base stations, and the timing of scrambling codes received at the mobile station varies from base station to base station.

  FIG. 7 is a diagram illustrating a configuration example of a mobile station according to the present embodiment. In the figure, only the configuration of the part related to the present invention is shown. The mobile station according to this embodiment includes a mobile station transmission / reception device 720, a user interface 722, an antenna 724, a base station information report processing circuit 726, a common control circuit 728, a cell search control circuit 730, a base station information acquisition / processing circuit 732, A memory 734 and a bus 736 are provided. The mobile station according to the present embodiment searches for a perch channel transmitted from the base station and receives it to determine a base station for communication or standby.

  The mobile station transceiver 720 is a device for demodulating radio-modulated user information and control signals transmitted from the base station, and encoding and modulating user signals and control signals. The mobile station transmission / reception device 720 is connected to an antenna 724 and a user interface 722, respectively. The common control circuit 728 is a circuit that performs overall control of the mobile station. The cell search control circuit 730 is a circuit that controls the cell search operation while controlling the timing based on the priority of the neighboring base station information. In another circuit, the cell search control circuit 730 stores the cell search result in the memory 734 so that the cell search result can be reused. The base station information acquisition / processing circuit 732 is a circuit that creates scrambling code information and phase information of the base station using the cell search result stored in the memory 734. The base station information report processing circuit 726 is a circuit that instructs the mobile station transmitting / receiving apparatus 720 to transmit the information in order to report the generated base station information to the base station. The common control circuit 728, cell search control circuit 730, base station information acquisition / processing circuit 732, base station information report processing circuit 726, and memory 734 are connected to each other via a bus.

  FIG. 8 is a diagram for explaining a structure example of a perch channel according to the present embodiment. The cell search operation controlled by the cell search control circuit 730 will be described below. The perch channel is used when the mobile station synchronizes with the system when the power is turned on to acquire system information, or when the mobile station detects that it has moved to another base station during standby or communication. Each base station transmits at least one perch channel at a temporally constant transmission power. The perch channel is spread over a wide band using a spreading code that is faster than the information rate. The perch channel is double spread with a spreading code that has a repetition period equal to the symbol period and that is commonly specified in all base stations, and a scrambling code that is different for each base station. The scrambling code used for spreading the perch channel is masked at regular intervals, and the masked section is spread only by the spreading code without being spread by the scrambling code. This part is called a mask symbol. The spreading code used for the perch channel is common to all base stations. When the mobile station uses this common spreading code as a spreading code replica and correlates with a matched filter, the correlation peak occurs at the reception timing of the spreading code spreading section of the received signal, regardless of which scrambling code is used. Can be detected. By storing each time according to the timing of the mask symbol from the correlation peak, the timing synchronization of the scrambling code is established. Subsequently, the scrambling code number for spreading the received signal may be identified. This is done by using the spreading code multiplied by the spreading code and the scrambling code as a replica code, detecting the correlation at the already obtained timing, and determining the threshold value, so that the received perch is scrambled. It can be determined whether or not a ring code is used. By repeating this process for possible scrambling codes, the scrambling code used by the received perch can be identified. For details on the cell search method, see Higuchi, Sawahashi, Adachi, “Fast Cell Search Algorithm in Inter-Cell Asynchronous DS-CDMA Mobile Radio,” IEICE Trans. Commun., Vol. E81-B, No. 7, July 1998. It has been explained in detail. Eventually, base station information can be acquired by such an operation. That is, it is possible to acquire the scrambling code number and phase information of the perch channel that can be received by the mobile station. FIG. 9 shows an image in which the mobile station acquires base station information, reports to the base station to which the mobile station is connected, and updates the information in the base station.

  In this embodiment, the base station information is composed of the second spreading code number used by the base station and the phase information of the code. By using the phase information, a high-speed cell search can be executed with low power consumption. However, the base station information can be configured only by the second spreading code number used by the base station. Further, it is possible to configure the base station information with the radio frequency of the perch channel by using the FDMA method or the TDMA method as the wireless access method.

  The mobile station transmits base station information to the base station. When the base station information of BS6 is newly obtained as in the example of FIG. 4, the base station information of BS6 is transmitted to BS1, for example. Furthermore, the base station information of BS1 can be transmitted to BS6. The transmission of the base station information to the BS 6 may be performed directly by the mobile station or may be performed via the BS 1. The base station that has received the base station information transmitted by the mobile station updates the neighboring base station information based on the base station information.

  The base station can prioritize neighboring base station information.

  FIG. 10 is a diagram illustrating an example of state transition when ranking is performed according to the number of reports. The base station notifies (transmits) neighboring base station information to the in-zone mobile station at regular intervals. When the base station information report is received from the mobile station, the base station information is extracted and the number of reports for each base station is updated. Then, the neighboring base station information is rearranged in the order of the number of reports, that is, in the order of base stations included in the base station information.

  FIG. 11 is a diagram showing an example of state transition when ranking is performed according to the handover success rate or the number of handover successes. The base station notifies (transmits) neighboring base station information to the in-zone mobile station at regular intervals. When the base station information report is received from the mobile station, the base station information is extracted and the number of reports for each base station is updated. Further, when a handover occurs, the handover destination and the result are acquired, and the neighboring base station information is rearranged. At this time, the success or failure result of the handover can be acquired to calculate the success rate of the handover, and the neighboring base station information can be rearranged in the order of the base stations having the highest handover success rate. Further, the number of successful handovers can be acquired, and the neighboring base station information can be rearranged in the order of base stations with the highest number of successful handovers.

  When the base station information is ranked, the base station can transmit information for the top N stations (N is a predetermined constant) of the peripheral base station information.

  On the other hand, in the mobile station, when peripheral base station information with a rank is received, a perch channel search is performed with a high frequency for a base station with a high rank and with a low frequency for a base station with a low rank. Can be.

  FIG. 12 is a diagram illustrating an example of a rank table used when prioritizing individual base stations based on neighboring base station information notified from the base station and changing the search frequency of the perch channel. The perch search frequency of each base station is determined using the neighboring base station information acquired from the base station and the correspondence table prepared in advance in the mobile station. That is, for the base stations ranked by the neighboring base station information, the perch channel of the base station is searched at the search cycle corresponding to the rank in the correspondence table.

  In FIG. 12, the search frequency is described as different for each priority, but this is not necessarily a necessary condition. For example, the priority is divided into the first half and the second half, and the thing belonging to the first half has a high frequency. Various other methods are conceivable, such as applying one frequency of 1 and applying a low frequency to those belonging to the latter half. Whatever method is used, the same effect can be obtained as long as the frequency for a base station with high priority is set high and the frequency for a base station with low priority is set low. Further, the relationship between the priority order and the frequency has been described in advance as if it was determined in advance and stored in the mobile station, but this is not a necessary condition for applying the present invention. In addition, for example, various methods such as a method of periodically notifying this information from the base station and a method determined by the user can be considered, but the same effect can be obtained regardless of which method is used.

It is a figure which shows the example of a mobile communication system. It is a figure which shows the example of the influence range of each base station estimated by the distance etc. on a map. It is a figure which shows the example of the influence range of each actual base station. It is a figure for demonstrating the handover at the time of applying this invention with respect to the example of the influence range of each actual base station. It is a conceptual diagram for demonstrating the usage method of the spreading code of the mobile communication system which concerns on embodiment of this invention. It is a schematic diagram which shows the timing relationship of a scrambling code | cord | chord about the signal from each base station received in the mobile station which concerns on embodiment of this invention. It is a figure which shows the structural example of the mobile station which concerns on embodiment of this invention. It is a figure for demonstrating the structural example of the perch channel which concerns on embodiment of this invention. It is a figure which shows the image which a mobile station acquires the information of a base station, reports to the base station to which the own station is connected, and updates information in a base station. It is a figure which shows the example of a state transition in the case of ranking according to the number of reports. It is a figure which shows the example of a state transition in the case of ranking according to a handover success rate or the number of successful handovers. It is a figure which shows the example of the order | rank table | surface used when prioritizing each base station based on the periphery base station information notified from the base station, and changing the search frequency of a perch channel.

Explanation of symbols

111-1 to 111-5, BS1 to BS6 Base station 112-1 to 112-3 Mobile station 720 Mobile station transceiver 722 User interface 724 Antenna 726 Base station information report processing circuit 728 Common control circuit 730 Cell search control circuit 732 Base Station information acquisition / processing circuit 734 Memory 736 Bus

Claims (9)

A peripheral base station information update method in a mobile communication system comprising a plurality of base stations for transmitting perch channels and peripheral base station information, and a mobile station,
In the mobile station,
A first receiving step of receiving neighboring base station information transmitted by the base station;
A search / reception step for searching for and receiving a perch channel transmitted by the neighboring base station based on the neighboring base station information received by the first receiving step;
Transmitting the neighboring base station information actually observed in the searching and receiving step to the base station,
In the base station,
A second receiving step of receiving neighboring base station information transmitted by the mobile station;
A neighboring base station information updating method, comprising: an updating step of updating neighboring base station information of the base station based on the neighboring base station information received in the second receiving step.   2. The neighboring base station information updating method according to claim 1, wherein the neighboring base station information includes information related to a phase of a spreading code used by the neighboring base station. .   3. The neighboring base station information updating method according to claim 2, wherein the information on the phase is a phase difference between a spreading code used by a base station that transmits the neighboring base station information and a spreading code used by the neighboring base station. A neighboring base station information update method, characterized in that A mobile communication system comprising a plurality of base stations that transmit perch channels and neighboring base station information, and a mobile station,
The mobile station
First receiving means for receiving neighboring base station information transmitted by the base station;
Search / reception means for searching for and receiving a perch channel transmitted by a neighboring base station based on neighboring base station information received by the first receiving means;
Transmission means for transmitting the base station information actually observed in the search / reception means to the base station,
The base station
Second receiving means for receiving neighboring base station information transmitted by the mobile station;
A mobile communication system, comprising: update means for updating neighboring base station information of the base station based on neighboring base station information received by the second receiving means.   5. The mobile communication system according to claim 4, wherein the peripheral base station information includes information related to a phase of a spreading code used by the peripheral base station.   6. The mobile communication system according to claim 5, wherein the information on the phase is information representing a phase difference between a spreading code used by a base station that transmits the neighboring base station information and a spreading code used by the neighboring base station. A mobile communication system characterized by the above. A mobile station,
Receiving means for receiving neighboring base station information transmitted by the base station;
Search and reception means for searching for and receiving the perch channel transmitted by the peripheral base station based on the peripheral base station information received by the receiving means;
A mobile station comprising: transmission means for transmitting neighboring base station information actually observed by the search / reception means to the base station.   8. The mobile station according to claim 7, wherein the peripheral base station information includes information related to a phase of a spreading code used by the peripheral base station.   9. The mobile station according to claim 8, wherein the information on the phase is information indicating a phase difference between a spreading code used by a base station that transmits the neighboring base station information and a spreading code used by the neighboring base station. A mobile station characterized by being.

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