JP2003259414A - Mobile station and mobile communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To ontain a mobile communication system in which congestion is lessened in the vicinity of cell boundary. <P>SOLUTION: A mobile station 11 detects the strength and frequency of an interference wave to a receiving signal from a base station 21. When the detection results exceed specified threshold levels, strength and frequency of the interference wave are detected over a specified period determined by random numbers. If the strength and frequency of the interference wave exceed the threshold levels even after elapsing the period determined by random numbers, any one of switching the frequency channel or stopping transmission is effected. If the strength and frequency of the interference wave do not reach the threshold levels within the period determined by random numbers, both switching of the frequency channel and stopping of transmission are interrupted to sustain communication with the base station 21. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a mobile station and a mobile communication system mainly for data communication.

[0002]

2. Description of the Related Art In a mobile communication system, for example, as shown in FIG.
In the case of 1, the cell is divided into three cells 31 to 33 and the base stations (access points) 2 are provided in the cells 31 to 33.
1 to 23 are arranged. At this time, cells 31 to 3
3 overlap each other, and communication within the service area is secured in a plane.

When the mobile station communicates, it communicates with the base station having the best communication condition in its service area. In the case of FIG. 11, the mobile station 11 communicates with the base station 21. , Mobile station 12 is in communication with base station 22, and mobile station 13 is in communication with base station 23.

FIG. 12 shows an example of a frame structure of a signal used for communication between a mobile station and a base station. Transmission units are a broadcast phase, a downlink phase, an uplink phase and a random phase. It consists of an access phase. Note that this transmission unit is called a MAC frame, and its time length is 2 ms.

The broadcast phase is M
It is located at the beginning of each AC frame and is composed of a broadcast burst corresponding to CCH in the cellular system. This burst has a preamble at the beginning, as shown in FIG. This preamble can be used for determining the presence of a burst, capturing a reception timing, detecting a frequency offset, estimating a channel, and the like. The preamble has a different format defined depending on the burst to be transmitted.

[0006] The broadcast phase is used by the base station to deliver control information to each mobile station. The initial acquisition of the mobile station is also performed by receiving this broadcast burst.

Further, the downlink phase is a section in which the information channel transmitted from the base station to the mobile station is accommodated, and is composed of a predetermined number of downlink bursts.
Then, the base station determines at what timing information should be transmitted to each mobile station, and schedules the allocation slot. The signal in the broadcast phase informs to which mobile station the information is transmitted at which timing in the MAC frame.

FIG. 14 shows an example of the downlink burst. For example, two OFDs follow the preamble.
M symbols are concatenated. Although the details of this OFDM symbol will be described later, this OFDM symbol is called a "time slot". In FIG. 14, the number of time slots is only two, but it may be increased or decreased depending on the communication capacity or the number of users. Each mobile station is notified in the broadcast phase which number of this time slot is used.

Furthermore, the uplink phase in the MAC frame is a section in which the information channel transmitted from the mobile station to the base station is accommodated, and is composed of a predetermined number of uplink bursts. The uplink burst has the same structure as the downlink burst, as shown in FIG.

By receiving the broadcast phase, the mobile station receives information about the timing of transmission in the MAC frame, and transmits an uplink signal according to this instruction. The random access phase is also used to convey this request when the mobile station first requests a connection from the base station.

FIG. 16 shows the structure of an OFDM symbol. One OFDM symbol has a time length of 3.2 μs, and a guard time of 0.8 μs (or 0.4 μs) is added in front of it to form one OFDM symbol. It is considered as a transmission unit of. And one MAC frame has 500 OFs
Since it is composed of DM symbols, the time length of one MAC frame is 2 ms (= (0.8 μs + 3.2 μs) as described above.
X 500 pieces). Also, the base station and the mobile station transmit and receive frames at intervals of 2 ms.

FIG. 17 shows the frequency structure of an OFDM symbol, and 53 subcarriers are distributed at a frequency interval of 312.5 kHz. However, since the subcarrier is not placed in the baseband 0Hz, its occupied frequency band is 1
It becomes 6.5625MHz (= 312.5kHz × 53). In addition, in the OFDM symbol in which information is modulated (indicated by a thick arrow), the pilot subcarrier is 312.5 kHz.
z x (-21), 312.5 kHz x (-7), 312.5 kHz x 7, 312.5 kHz
It is located at the frequency position of × 21. The complex amplitude of the pilot subcarrier has a known value in transmission and reception.

Communication between the base station and the mobile station is performed according to the above MAC frame structure and OFDM symbols. Further, the base station and the mobile station are completely synchronized in a master-slave relationship as in the cellular system, and the transmission / reception timing of the mobile station is entirely managed by the base station.

Then, when the mobile station starts up, it scans the frequency channel and selects the strongest signal.
Receives the broadcast phase transmitted from the base station. Then, since the position of the random access phase can be known by receiving the broadcast phase, the mobile station next transmits a communication request signal to the base station in the random access phase. Then, when the base station accepts the communication request, it transmits the time slot information used by the mobile station for transmitting and receiving information in the broadcast phase.

Therefore, the mobile station knows the time slot destined for itself and the time slot to be transmitted to the base station by receiving the broadcast phase sent from the base station every 2 ms. You can

[0016]

As shown in FIG. 11, the mobile station 11 is located near the boundary between the cell 31 and the cell 32.
And the mobile station 12 communicate with the base stations 21 and 22 using the same frequency channel. Then, at this time, interference occurs between the communication between the mobile station 11 and the base station 21 and the communication between the mobile station 12 and the base station 22, and the interference state becomes as shown in FIG. 18, for example.

That is, since the communication between the mobile station 11 and the base station 21 and the communication between the mobile station 12 and the base station 22 are asynchronous, the positional relationship between the two communication phases is shown in FIG.
It may be as shown in. In this case, the downlink phase from the base station 21 to the mobile station 11 and the base station 22
The same frequency is used in the downlink phase from the mobile station 11 to the mobile station 12.
Since the interference wave received at 2 is relatively weak, the mobile station 1
The influence of interference can be avoided by using directional antennas for 1 and 12.

However, if the mobile station 12 transmits a signal of the uplink phase while the mobile station 11 is receiving the broadcast phase, the mobile station 12 sees the mobile station 12 more than the base station 21 from the viewpoint of the mobile station 11. However, due to their close distance, they will be subject to strong interference. This is also the case when the mobile station 11 transmits a signal in the uplink phase.

If the mobile station receives interference during the reception of the broadcast phase, the mobile station cannot know the time slot to be used by the mobile station and cannot transmit or receive. Then, if the state in which transmission / reception cannot be performed continues for a certain period, the base station side is forcibly disconnected. Also, in the vicinity of the cell boundary, the mobile station 11 or 12 may be forcibly disconnected due to congestion.

In view of such a point, the present invention intends to reduce the forced disconnection due to the congestion near the cell boundary as much as possible.

[0021]

According to the present invention, for example, the strength and frequency of an interference wave with respect to a received signal from a base station is detected, and when the detection result exceeds a predetermined threshold level, the frequency is The mobile station is configured to perform either channel switching or transmission stop. Therefore, there is no transmission on the frequency channel that causes interference, and communication with the base station is restarted.

[0022]

First Embodiment FIG. 1 shows an example of the relationship between a base station and a mobile station. In FIG. 1, base stations 21 to 23 and mobile station 1 are shown.
1 to 13 are in the state described with reference to FIG.

In the present invention, the mobile station 11
2 to 13 are provided with a routine 100 shown in FIG. 2, for example, as a part of the program executed by them. This routine 100 is for reducing forced disconnection due to congestion near cell boundaries, and the details thereof will be described below. However, in FIG. 2, the routine 100 extracts only the portion related to the present invention. Is shown.

That is, when the communication with the base station is started, the routine 100 starts from step 101, and then the communication with the base station is started in step 102. Then, in step 103, the state of the received signal is checked to determine the intensity of the interference wave, the frequency of the interference, and the like. When the interference with the received signal is less than the threshold level, the process of step 103 is continued. Thus, once communication with the mobile station is initiated, interference with the received signal is constantly monitored. Further, when the interference is below the threshold level, no special processing is executed.

However, when the interference with the received signal exceeds the threshold level, this is detected in step 103, and the process proceeds from step 103 to step 111, in which the period Tw is determined by a random number.
And then in step 112, step 10
Similar to 3, it is determined whether there is interference with the received signal.

In this case, since it is immediately determined that there is interference with the received signal in step 103, it is generally determined that there is interference also in step 112. If there is interference, the process proceeds from step 112 to step 113.
Then, in this step 113, in step 111
It is determined whether or not the period Tw has elapsed since the execution of the above. When the period Tw has not elapsed, the process returns from step 113 to step 112. Therefore, when interference with the received signal is determined in step 103, steps 112 and 113 are repeated thereafter for the period Tw.

If the interference with the received signal becomes less than the threshold level before the period Tw elapses,
This is determined in step 112, and the process returns from step 112 to step 103 to continue the communication with the base station and monitor the interference with the received signal.

However, if the period Tw elapses before the interference with the received signal becomes less than the threshold level, this is discriminated in step 113, and the process proceeds from step 113 to step 114, in which step 1
At 14, it is determined whether or not it is possible to switch to another frequency channel, and when switching is possible,
The process proceeds from step 114 to step 115. In this step 115, the base station is notified that the frequency channel is switched, the frequency channel is switched to an empty channel, and then step 103 is performed.
Return to.

Therefore, when the interference with the received signal exceeds the threshold level, if there is a vacant channel, the frequency channel is switched to the vacant channel after the time Tw determined by the random number, and thereafter, after the switching. Communication is continued on the frequency channel, and interference with the received signal is monitored on the frequency channel after the switching.

However, when the frequency channel cannot be switched in step 114, the process proceeds from step 114 to step 121, and this step 1
In step 21, the transmission of its own station is temporarily stopped, and then in step 122, the state of checking the interference with the received signal is continued as in step 103. At this time, if the signals of the broadcast phase and the downlink phase can be received from the base station, the reception is continued.

Then, when the interference with the received signal becomes less than the threshold level, the process returns from step 122 to step 102, and the communication with the mobile station is restarted.

The interference with the received signal is, for example, as described with reference to FIG. 18, the mobile station 11 and the base station 21.
Between the mobile station 12 and the base station 22, that is, generally between two sets of the mobile station and the base station. Will be performed in each of the two mobile stations.

In this way, according to the above-mentioned mobile station, when the received signal from the base station causes interference at the threshold level or more, the communication is stopped and the communication waits for the period Tw.
After restarting the communication after the waiting period Tw,
Since the waiting period Tw is determined by a random number, it is unlikely that the communication will be restarted at the same time between the two sets of the mobile station and the base station when the communication is restarted. It is possible to reduce the possibility of causing interference. Another feature is that each mobile station performs control to avoid interference in a self-sustaining and distributed manner.

In the above description, the waiting period Tw until the communication is restarted is set by a random number. However, the priority order is set for each mobile station, and the mobile station with a higher priority order has the waiting time Tw.
W can also be set short. Then, the priority order can be determined, for example, according to the fee plan of the user.

Alternatively, the priority can be determined from the moving direction of the mobile station. For example, in FIG.
When the mobile station 11 is stopped and the mobile station 12 is moving toward the base station 21, when either the mobile station 11 or the mobile station 12 has decided to stop transmission, the mobile station 1
The priority of 1 is increased and the transmission of the mobile station 12 is stopped. As a method of identifying the moving direction, each mobile station examines the history of the intensity of the received signal from the base station to estimate the moving direction to determine the priority order, and the GPS method for each mobile station.
There is a method of identifying the moving direction by mounting a receiver or a gyroscope.

Second Embodiment FIG. 3 shows a system configuration when an APC (control station) is used to reduce interference with a received signal of a mobile station. Base stations 21 to 23 and mobile station 11 are shown. 13 to 13 are in the states described in the system (systems in FIGS. 1 and 2), and the base stations 21 to 23 are controlled by the APC 40.

Then, for example, the routine 200 shown in FIG. 4 is executed in each mobile station. That is,
When starting communication with the base station, the routine 20
0 starts from step 201, then step 20
2 starts communication with the base station. Subsequently, in step 203, the intensity of the interference wave, the frequency of interference, etc. are determined by checking the state of the received signal, and when the interference with the received signal is less than the threshold level, the process of step 203 is continued. Thus, once communication with the mobile station is initiated, interference with the received signal is constantly monitored. Further, when the interference is below the threshold level, no special processing is executed.

However, when the interference with the received signal exceeds the threshold level, this is detected in step 203, and the process proceeds from step 203 to step 211, in which information on the arrival time of the interference wave is provided. collect. In this case, the time of arrival of the interference wave is the same time position in each MAC frame, as is clear from FIGS. 12 and 18,
It can be represented by the number of the time slot in the MAC frame.

Then, the process proceeds to step 212, and in this step 212, the fact that the own station is interfered and the time (time when interference is received) collected in step 211 are transmitted to the corresponding base station. .

On the other hand, each of the base stations executes the routine 300 shown in FIG. 5, for example. That is, when the base station is activated, the routine 300 starts from step 301, then in step 302, the signal from the mobile station and the APC 40 described later is monitored, and when the signal is received, the received signal is received in step 303. By checking, it is determined whether or not the mobile station in the own cell needs to be controlled. If it is not necessary to control the mobile station in the own cell, the process returns to step 302. Thus
The base station normally operates with the mobile station in its own cell and the APC 40
Is monitoring the signal from.

However, when the mobile station receives the interference in step 212 and when the time of the interference is transmitted, it is necessary to control the mobile station in its own cell, and therefore the processing is repeated from step 303 to step 304. In step 304, it is determined whether the signal is from the APC 40 or the mobile station.

When the signal is from the mobile station, the process proceeds from step 304 to step 311. In step 311, it is determined whether or not the frequency channel can be switched to another frequency channel. The process proceeds from step 311 to step 312. In step 312, the mobile station is notified that the frequency channel is to be switched, the frequency channel is switched to an empty channel, and then the process returns to step 302. Therefore, mobile station interference is avoided.

On the other hand, if the frequency channel cannot be switched in step 311, the process proceeds from step 311 to step 321 and this step 32 is executed.
In step 1, the mobile station grasps the information on the interference transmitted at step 212 and the time, and then step 32
In step 2, the information acquired in step 321
Send to C40, then return to step 302. That is, when the base station itself cannot resolve the interference of the mobile station, the base station notifies the APC 40 of this.

Then, in the APC 40, for example, the mobile station which is interfered by the routine 400 shown in FIG. 6 is switched to the adjacent base station. That is, APC4
When 0 is started, the routine 400 starts from step 401, and next, at step 402, the signal from each base station is monitored, and when the signal is received, step 403 is performed.
In the above, the received signal is checked to determine whether the mobile station is causing interference (the fact that the mobile station is causing interference is transmitted in step 322), and when no interference is occurring, The process returns to step 402. Thus, APC 40 is monitoring the mobile station's interference as reported by step 322 from the base station.

However, when interference occurs in the mobile station, the process proceeds from step 403 to step 411,
In this step 411, the base station causing the interference to the mobile station is discriminated, and it is examined whether the mobile station receiving the interference can be switched to the adjacent base station, that is, whether the handover can be performed. Then, when the handover is possible, the processing is from step 412 to step 4
In step 413, the base station is instructed to perform handover, and then in step 4
Return to 02.

If the hand-over is impossible in step 412, the process proceeds from step 412 to step 421, and in step 421,
Information on the time of the interference transmitted at step 322 is taken out, and then at step 422, a base station adjacent to the base station including the mobile station having the interference is searched. Then, in step 423, step 422
The interference information such as the time of the interference and the request for the transmission restriction transmitted from the mobile station is transmitted to the base station (generally a plurality of base stations) searched by, and then the process returns to step 402.

Thus, upon receiving the interference report from the base station, the APC 40 instructs the base station to perform the handover in step 413 or transmits the interference information to the adjacent base station in step 423.

Then, in the base station which is the transmission destination of step 413 or 423 among the base stations, the process proceeds from step 302 to step 304 to step 304. In this case, since it is the signal from the APC 40, further, The process proceeds to step 331, and in this step 331, the signal transmitted in step 413 or 423 is discriminated.

Then, the transmitted signal is step 4
In the case of the signal of 13, the processing proceeds from step 331 to step 332, and in this step 332.
Handover is instructed to the mobile station causing the interference, and then the process returns to step 302.

When the signal transmitted in step 331 is the signal obtained in step 423, the process proceeds from step 331 to step 341, and in this step 341, the time slot of that time is used from the time of interference. The mobile station in question is searched, and then in step 342, it is examined whether the frequency channel used by the mobile station in the search result can be switched. Then, when the switching is possible, the processing is step 342.
To step 312, the frequency channel is switched, and then the process returns to step 302.

When it is impossible to switch the frequency channel in step 342, the process proceeds from step 342 to step 343, and in this step 343.
In step 3, the corresponding mobile station is instructed to stop transmission, and then the process returns to step 302. When it is determined from the time information transmitted in step 423 that there is no mobile station using the time slot at that time, the information transmitted in step 423 is ignored.

In this way, when the mobile station reports to the base station that the mobile station is receiving interference, the base station performs step 312,
Since 332 or 343 is executed, interference can be avoided.

For example, in the case of FIG. 3, when the mobile station 11 receives the interference, the information is transmitted via the base station 21 to the A
It is transmitted to the PC 40. However, in many cases, mobile station 1
Since there is mutual interference between the mobile station 1 and the mobile station 12, the interference information and time information are transmitted from both mobile stations 11 and 12 to the APC 40. At this time, the APC 40 randomly determines the priority order of the mobile station 11 and the mobile station 12,
A mobile station with a low priority is instructed to switch frequency channels or stop transmission. The method of deciding the priority can be the method described in.

Third Embodiment FIG. 7 is a system of FIG. 7 (systems of FIGS. 3 to 6) in which cells 31 to 33 are further divided into, for example, three sectors to reduce interference. This is the case. The base stations 21 to 23 and the mobile stations 11 to 13
However, while in the state described by the system of
The base stations 21 to 23 are controlled by the APC 40.

Then, the routine 200 is executed in each of the mobile stations 11 to 13. Also, the base station 2
In steps 1 to 23, the routine 300 shown in FIG. 8 is executed. However, the routine 300 shown in FIG. 8 has step 351 added to the routine 300 shown in FIG.

That is, in step 304, when the signal received in step 302 is a signal from the mobile station (a signal indicating that there is interference and the time of the interference, etc.), the process proceeds from step 304 to step 3.
Proceeding to step 51, in step 351, the sector in which the mobile station reporting the interference is located is determined, and then the processing advances to step 311.

Then, in step 311, if the frequency channel cannot be switched, the process proceeds from step 311 to step 321.
In step 21, the mobile station grasps the information on the interference transmitted in step 212 and the time, and then step 3
In 22, the information acquired in step 321 and
The information of the sector grasped in step 351 and the APC
40 and then return to step 302. That is, when the base station alone cannot resolve the interference of the mobile station by itself, the base station notifies the APC 40 of this and also notifies the sector in which the mobile station is located.

On the other hand, the APC 40 executes the routine 400 shown in FIG. However, the routine 400 shown in FIG. 9 differs from the routine 400 shown in FIG. 6 in steps 421 and subsequent steps. That is, when the hand-over is impossible in step 412, the process proceeds from step 412 to step 421, and in this step 421, the information on the time of the interference transmitted by step 322 is taken out. Run.

In this step 451, the information of the sector in which the mobile station is located is extracted from the information transmitted in step 322, and then in step 452, the base station adjacent to the base station including the interfered mobile station. To search. Then, in step 453, among the base stations (generally a plurality of base stations) of the search result of step 452, the base station in the direction of the sector in which the mobile station causing the interference is transmitted from the mobile station. The interference information such as the time of coming interference and the request for transmission restriction is transmitted, and then the process returns to step 402.

Thus, when the APC 40 receives the interference report from the base station, the APC 40 instructs the base station to perform the handover in step 413 or, in step 453, the adjacent base station in the direction in which the mobile station is located. Send the interference information to.

Therefore, when handover or frequency channel switching is not possible, the routine 300
In step 343, the base station adjacent in the direction in which the mobile station is present instructs the interfering mobile station to stop transmission.

Thus, when the mobile station reports to the base station that it is receiving interference, the base station performs a handover,
Since the frequency channel is switched or the transmission of the mobile station giving the interference is stopped, the interference can be avoided.

Fourth Embodiment In the system shown in FIG. 10, as in the system of or, the base stations 21 to 23 and the mobile stations 11 to 13 are used.
However, the base stations 21 to 23 are controlled by the APC 40 while being in the state described in the system. In addition, in this system, the mobile stations 11 to 13
Receives a radio wave from a navigation satellite, for example, a GPS satellite, with a GPS receiver to grasp position information.

When interference occurs, the mobile station notifies the base station of the position information of its own station. The base station sends this position information to the APC 40 when the channel cannot be switched.
To transmit. Based on the position information of this mobile station, the APC 40 transmits interference information such as time information and position information to a base station handling the mobile station which is considered to cause interference.

In the case of FIG. 10, when the mobile station 11 and the mobile station 12 interfere with each other, the mobile station 11 transmits the interference information, the time information and the position information to the base station 21. Then, when the frequency channel cannot be switched, the base station 21 notifies the APC 40 of the time information and the position information. As a result, APC40
Searches the base station closest to the mobile station 11, that is, the base station 22 in the case of FIG. 10, from the position information of the mobile station 11, and transmits the interference information and the time information to this base station. Then, thereafter, the same processing as that of the system is executed.

[List of Abbreviations Used in this Specification] APC: Access Point Controller CCH: Common Control Channel GPS: Global Positioning System MAC: Message Authentication Code OFDM: Orthogonal Frequency Division Multiplex
ng

[0067]

According to the present invention, when interference occurs between mobile stations, the transmission of mobile stations having a lower priority is limited, so that the congestion state can be avoided, and the entire system can be prevented. Throughput can be improved.

Further, by using the position information of the mobile station, the control information from the APC to the base station can be limited to only the necessary base station, and the amount of information transmission between the APC and the base station can be reduced. You can Furthermore, by limiting the transmission of the mobile station in the direction in which there is a possibility of handover, it is possible to deal with the handover without the forced disconnection.

[Brief description of drawings]

FIG. 1 is a system diagram showing one form of a system according to the present invention.

FIG. 2 is a flowchart showing one form of processing contents of a mobile station.

FIG. 3 is a system diagram showing another form of the system according to the present invention.

FIG. 4 is a flowchart showing another mode of processing contents of a mobile station.

FIG. 5 is a flowchart showing an example of processing contents of a base station.

FIG. 6 is a flowchart showing one form of processing contents of APC.

FIG. 7 is a system diagram showing another mode of the system according to the present invention.

FIG. 8 is a flowchart showing another mode of processing contents of the base station.

FIG. 9 is a flowchart showing another mode of the processing content of APC.

FIG. 10 is a system diagram showing another form of the system according to the present invention.

FIG. 11 is a system diagram for explaining the present invention.

FIG. 12 is a diagram for explaining a signal format.

FIG. 13 is a diagram for explaining a signal format.

FIG. 14 is a diagram for explaining a signal format.

FIG. 15 is a diagram for explaining a signal format.

FIG. 16 is a diagram for explaining a signal format.

FIG. 17 is a diagram for explaining a signal format.

FIG. 18 is a diagram for explaining a signal format.

[Explanation of symbols]

11-13 ... Mobile stations, 21-23 ... Base stations, 31-33
... cell, 40 ... APC

Claims (11)

[Claims] 1. The strength and frequency of an interference wave with respect to a received signal from a base station is detected, and when the detection result exceeds a predetermined threshold level, either frequency channel switching or transmission stop is performed. A mobile station that is supposed to perform. 2. The mobile station according to claim 1, wherein when the detection result exceeds a predetermined threshold level, the intensity and frequency of the interference wave are detected for a predetermined period determined by a random number, Even when the period determined by the random number has elapsed, when the intensity and frequency of the interference wave exceeds the threshold level, either one of the switching of the frequency channel and the stop of the transmission is executed, When the strength and frequency of the interference wave do not reach the threshold level within the period determined by the random number, both the switching of the frequency channel and the stop of the transmission are stopped and the base station A mobile station that attempts to continue communication. 3. The mobile station according to claim 1, wherein when the detection result exceeds a predetermined threshold level, the strength and frequency of the interference wave are detected over a fixed period that differs depending on the mobile station, If the intensity and frequency of the interference wave exceeds the threshold level even after the fixed period has elapsed, either the frequency channel is switched or the transmission is stopped, and the fixed When the strength and frequency of the interference wave does not reach the threshold level within the period of,
A mobile station which stops both the switching of the frequency channel and the stop of the transmission and continues communication with the base station. 4. A mobile station comprising: a plurality of mobile stations; a plurality of base stations for communicating with the mobile stations; and an APC that controls the base stations, wherein the mobile stations receive signals from the base stations. When the strength and frequency of the interference wave with respect to the threshold level exceeds the threshold level, the information about the interference is notified to the base station to which the mobile station is connected, and among the base stations, the information about the interference is notified. The transmitted base station sends the information to the APC, the APC sends information about the interference to all of the base stations, and the base station receives information about the interference from the information about the interference transmitted from the APC. When the base station giving the interference is found and the base station giving the interference can be found, it is possible to perform handover, frequency channel switching, and transmission stop to the base station. A mobile communication system adapted to execute a shift. 5. The mobile communication system according to claim 4, wherein the APC has geographical information of the base station, and the mobile station that has received the interference transmits the information about the interference through the base station. Then, based on the geographical information, the information about the interference is transmitted only to the base stations near the base station communicating with the base station receiving the interference among the base stations. Mobile communication system. 6. The mobile communication system according to claim 4, wherein the area covered by the base station is divided into a plurality of sectors, and the APC includes geographical information of the base station and a direction of a sector antenna. And when the information regarding the interference is transmitted from the mobile station that has received the interference through the base station, based on the information about the geographical information and the direction of the sector antenna, Among the base stations, a mobile communication system adapted to transmit the information on the interference only to a base station in the directivity direction of a sector antenna facing the mobile station receiving the interference. 7. The mobile communication system according to claim 4, wherein the mobile station has at least one of a GPS receiver and a gyroscope, and the mobile station has information on its own position and information on the interference. To the base station, and among the base stations, the base station that has received the information on the interference transmits the information to the APC, and the APC gives interference from the position information of the mobile station. A mobile communication system that searches for a base station in which a mobile station exists and transmits the information about the interference to the base station of the search result. 8. The mobile station according to claim 1, further comprising a GPS receiver, a gyroscope, a device for analyzing intensity history information of a received signal from a base station, or a combination thereof. Until the frequency channel is switched or the transmission is stopped in accordance with the information of the moving direction of the own station, the geographical information of the currently communicating base station, and the geographical information of the adjacent base station. A mobile station that decides the time. 9. The mobile communication system according to claim 4, claim 5, claim 6, or claim 7, wherein the mobile station is a GPS receiver, a gyroscope, and strength history information of received signals from a base station. Or a combination of these, the mobile station transmits information on the moving direction of its own station to the base station, and outputs information on the moving direction of the own station among the base stations. The receiving base station sends the information to the APC, and the APC determines the geographical information of the base station and the sector antenna when determining the priority for a plurality of interfering mobile stations. A mobile communication system adapted to determine the priority of the mobile station according to the pointing direction. 10. The mobile communication system according to claim 4, claim 5, claim 6, or claim 7, wherein the APC is configured to notify the mobile station in accordance with information regarding interference transmitted from the base station. A mobile communication system in which priorities are determined at random when the priorities are determined. 11. The mobile communication system according to claim 4, claim 5, claim 6, or claim 7, wherein the APC is configured to notify the mobile station in accordance with information regarding interference transmitted from the base station. A mobile communication system adapted to determine priorities according to information uniquely determined by the mobile station.