JP2000308123A - Mobile communication system and synchronizing method in the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce/remove radio wave interference generated between systems by executing communication in a service area with a time slot which is previously decided and deciding timing by means of a timing deciding means when radio wave interference occurs with the other mobile communication system. SOLUTION: The controller of a system 1 receives a signal transmitted from the radio base station of the other system and transmits the signal for requesting the report of the measured result to respective radio base stations 3 under control. Radio base stations 1, 2, 4 and 5 receiving instruction signals execute communication in a self-service area in instructed timing. The radio base stations 3 receive the signals of the other systems existing at peripheries. When they receive signals transmitted from a radio base station 41, the result is reported to the controller. The self-system can obtain timing information on the time slot of another system by receiving the common control channel of another system.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication system which communicates at a radio frequency using digital signals. Radio interference generated in the system, and radio interference generated between adjacent wireless base stations in the mobile communication system,
Also, the present invention relates to a mobile communication system and a synchronization method in the mobile communication system for removing and removing the communication quality to improve the communication quality.

[0002]

2. Description of the Related Art In mobile communication systems, service areas are expanding as information communication and users (subscribers) are rapidly expanding. To cope with the sudden increase in subscribers,
Effective use of frequency is essential. The technical solution is to digitize the signal format, and there is a method of narrowing the service area of one radio base station and increasing the frequency reuse rate at different places. 1.9 in Japan
The system using the GHz band is PH for public communication.
There is an S system, and as a self-employed system, there is a digital cordless telephone system. By the way, the frequency band used for the PHS system and the digital cordless telephone is the same, the service area is in a densely populated area, or in a large-scale office, and the applied standards are basically the same. Is used. Actually, in the former public communication system, three systems exist in almost the same service area, and at the same time, the service area itself in a specific place is not so large, but the latter system is also in the same area as the former service area. They may share a common area.

[0003] Each of the above systems has a number of radio base stations belonging to each of them, which are scattered in each service area, and each radio base station sends a user (portable type) included in the system. (E.g., owner of a terminal such as a telephone). Each system has a control station for controlling signals transmitted and received by the radio base station belonging to the own system. Through this control station, a mobile radio belonging to the own system can be connected to another mobile radio of the own system or another system. It can communicate with mobile radios.

In anticipation of the future development of mobile communication systems, it is expected that various systems having the same frequency band and basically the same standard will be developed and put into practical use. When a system is operated in an environment where such various systems are mixed, technically, the following problems may occur, and a solution has been demanded.

The following describes the currently known problems and their solutions, taking a digital cordless telephone system as an example.

[0006] With respect to the control channel of the digital cordless telephone system, control is performed so that different timings are provided for each base station (by monitoring interference power). This is not a slot unit, but a super-frame (720 ms)
Among them, the timing of the control channel is distributed. Further, a system in which the other base stations synchronize with the master-base station timing has been put to practical use. (IEICE B-II Vol. J-81-B-II No.
4, 1998, April) On the other hand, regarding the communication channel, since the communication capacity per base station is small, communication is performed by communicating using different frequencies (that is, by avoiding interference on the frequency axis). I have.

In recent years, a system in which a digital code is spread and multiplexed (abbreviated as CDMA) has been widely used in a mobile communication system. One of these systems, CDMA-TDD (Code Division Multiple Access)
In Time Division duplex (time division multiplexing system using CDMA), a common control channel from a radio base station is bursty, and transmission power needs to be increased to obtain the same characteristics. For this reason, in a system such as a cordless telephone system, a common control channel of another system causes interference, and the mobile station cannot receive the signal.

In narrow-band communication, interference can be avoided by using different frequencies as in the conventional example. On the other hand, in a broadband communication such as a CDMA system, the orthogonality of the spreading code can suppress interference and increase the capacity. For this reason, it is impossible to avoid interference to different frequencies, and interference avoidance can be realized by moving to another slot. In particular, in the TDD system, when the timing of the uplink time slot of the adjacent system matches the timing of the downlink time slot of the own system, the power transmitted by the mobile station of the other system causes interference, and the The reception quality may be significantly deteriorated.

[0009]

As described above, there have been cases where a plurality of systems exist in the same area and their respective service areas overlap. In this case, a large number of wireless base stations of different systems communicate with mobile wireless devices belonging to each system by radio signals for the same service area. As a result, when communication traffic of each system is small, Although there was no problem, when the number of mobile radios included in the system increased and the communication traffic generated from the radio increased, a situation in which radio interference occurred between the systems appeared.

This is a natural phenomenon, because a system using the same frequency band and basically having the same system standard (hereinafter abbreviated as “similar system”) is used in a coexistent state.

However, in the former public communication system, the occurrence of interference is slightly reduced because the system itself has already been partially provided with means for preventing mutual radio interference.
In many cases, no measures are taken to prevent radio wave interference between the former and the latter or between the latter, so that the degree of adverse effects is large.

The system problems and the problems to be solved are as follows.

First, since the common control channel transmits a common control signal to a plurality of users, transmission power control may not be performed unlike other communication channels. Furthermore,
In TDD, it is necessary to increase transmission power in order to perform burst transmission. For example, assuming that the power in the case of continuously transmitting the common control channel is 1, if the transmission is performed only in two time slots / 16 time slots, the transmission is performed eight times (about 9 dB). Become. Such a problem does not occur in a system that performs cell design and determines transmission power as in a cellular system. However, in a self-managed system such as a cordless system, it is impossible to design a cell, and when the time slots of the common control channel have the same timing, interference occurs and a control signal cannot be demodulated. Therefore, it is necessary to shift the timing of the common control channel between different systems.

Therefore, the present invention reduces or eliminates the radio interference generated between the above-mentioned systems and the radio interference generated between adjacent radio base stations in the above-mentioned system, and effectively uses the frequency of the system. To provide a means for improving

First, at the time of system installation, each radio base station responds to an instruction from a control device that supervises control of the system,
Transmit the signal using the common control channel. However, in order to prevent a plurality of wireless base stations from transmitting the common control channel at the same time, the control device designates and executes the wireless base station to be transmitted for each time. In accordance with this designation, each nearby radio base station receives the transmitted signal of the common control channel and notifies the control device of its own radio base station number and reception level. However, when the transmission power of the common control channel transmitted from the radio base station differs for each radio base station, the transmission power level is also included in the signal of the common control channel and transmitted. Each radio base station receiving the signal of the common control channel calculates a reception level at the time of spatial transmission and notifies the control device instead of the reception level.

FIG. 2 is a diagram showing an example of a radio wave reception level between radio base stations in a mobile communication system. The control device can create and store a reception level table between the respective radio base stations as shown in FIG. 2 by sequentially performing the above operation for each of the radio base stations. The details of FIG. 2 will be described later. As described below, this table is used when the control device allocates a communication channel in the same radio channel to be used by the subordinate radio base station, that is, when allocating a certain code in a time slot, when performing a communication channel allocation without interference. used.

Next, each wireless base station under the control of the own system is instructed to receive a common control channel of a wireless base station belonging to another system operating in the vicinity, and the received information is controlled by the own system. Notify the device. As a result, the control device sets the wireless base station of its own system to a wireless base station group (A group) that does not receive radio interference from another system and a radio base station group (B group) that receives radio interference from another system.
Classified as In addition, the control device determines the timing of the common control channel unique to the own system for the radio base station group belonging to the A group, and makes it follow the timing. The radio base station group belonging to the B group does not receive radio interference from other systems, and the timing of a common control channel that does not cause radio interference to the communication of the radio base station belonging to the A group of the own system is determined. Follow this.

The above decision is reported to each of the radio base stations belonging to both the A and B groups. Each radio base station that has received the notification of this information determines the timing of its own radio base station based on this information, and applies the timing when communicating with a mobile radio located in a service area controlled by its own radio base station. .

Further, it is assumed that during operation of the system maintained in the above-described state, a certain radio base station suddenly receives radio wave interference from a nearby radio base station of another system. This is probably due to changes in the shape of the terrain and features, such as the construction of new buildings around the radio base station and the widening of roads, and thus changes in the state of radio wave propagation. . The control device receiving this report changes the timing of the common control channel for the radio base station. The method of change is to determine the timing so as not to cause radio wave interference from other systems and not to cause radio wave interference to the communication of any of the radio base stations included in the own system, transmit this to the above radio base station, To be applied when communicating with

The operation when the above-described means is applied to a system will be described.

It is assumed that a call is originated from a mobile radio located in a service area of a radio base station under the control of the control unit. The radio base station which has received the call signal transmits a request signal for allocating a communication channel to be communicated with the mobile radio to the control device. At this time, the control device determines whether a communication channel can be assigned to the wireless base station. When making this determination, do not interfere with other communications that are in progress at the same time.On the other hand, do not interfere with other communications for new communications, and do not interfere with other systems. To maintain good communication and
Improving frequency usage is the maximum requirement for communication control.

That is, in a mobile communication system using time-division multiplexed digital signals, a call signal is transmitted using a control channel from one mobile radio located in a service area of a radio base station to which the system belongs. I will come. The wireless base station receiving this transmits this information to the control device. The control device that has received this signal transmits the radio channel in use by this radio base station and the nearby radio base stations, the usage status of the speech channel in each time slot in the radio channel, and the stored data of FIG. Using the table, it is determined whether or not there is a communication channel that does not cause interference. In addition, the A and B groups which indicate the influence of interference with other systems described above may also be considered in some cases.

As a result, if it is possible to recognize that there is a communication channel in which interference is not likely to occur, a call is made.

In the above-described execution, the possibility of occurrence of radio interference between radio base stations in the own system and the possibility of occurrence of radio interference from another system is clearly eliminated. In addition, radio interference from another system newly generated during the operation of the system due to any cause is immediately taken, so that the mutual interference can be minimized in the mutual systems.

[0025]

According to the first aspect of the present invention, there is provided a mobile communication system, wherein timing information of a time slot of another mobile communication system having a service area near a service area of the own mobile communication system is provided. And a timing for determining a timing of a time slot of the own mobile communication system for reducing or eliminating radio wave interference with the other mobile communication system based on the timing information received by the receiving device. When the own mobile communication system performs communication in a service area by a predetermined time slot and radio wave interference occurs with the other mobile communication system, the timing determination unit The timing is determined, and the service timing of the mobile communication system is determined based on the timing. And performing communication within the store.

According to a second aspect of the present invention, there is provided a mobile communication system, comprising: receiving means for receiving time slot timing information of another mobile communication system having a service area near a service area of the mobile communication system. ,
Based on the timing information received by the receiving means,
Reduce the radio interference with the other mobile communication system,
Or a timing determining means for determining a timing of a time slot of the own mobile communication system to be removed, wherein the timing is determined by the timing determining means prior to the start of service, and the service area of the own mobile communication system is determined by the timing. It is characterized by performing communication within.

According to a third aspect of the present invention, there is provided a mobile communication system, comprising: receiving means for receiving time slot timing information of another mobile communication system having a service area near a service area of the mobile communication system. ,
Based on the timing information received by the receiving means,
Reduce the radio interference with the other mobile communication system,
Or a timing determining means for determining the timing of the time slot of the own mobile communication system to be removed, and during the service, when radio wave interference occurs with the other mobile communication system, the timing determining means The timing is determined, and the communication is performed within the service area of the mobile communication system based on the determined timing.

According to a fourth aspect of the present invention, in the mobile communication system according to any one of the first to third aspects, the timing information of the time slot of the other mobile communication system is common to the other mobile communication system. Timing information of a control channel is included, and the timing determining means determines a timing shifted from a timing of a common control channel of the another mobile communication system, and the own mobile communication system performs common control in a service area according to the determined timing. Transmitting a channel.

According to a fifth aspect of the present invention, in the mobile communication system according to any one of the first to fourth aspects, the mobile communication system includes one or more radio base stations, and a service area of the radio base stations is gathered to perform self-mobile communication. A service area of the system is formed.

According to a sixth aspect of the present invention, in the mobile communication system according to the fifth aspect, the timing determining means is configured to perform the radio interference based on information on radio interference between radio base stations in the mobile communication system. The timing of the time slot of the own mobile communication system for reducing or eliminating the above is also determined.

According to a seventh aspect of the present invention, in the mobile communication system according to the fifth or sixth aspect, when there are a plurality of the radio base stations, each of the radio base stations uses the other mobile communication system. The timing information of a time slot is received, and the timing determining means determines the timing of the time slot for each of the radio base stations.

The invention according to claim 8 is a mobile communication system including a plurality of radio base stations, wherein the radio interference is reduced or eliminated based on information on radio interference between the radio base stations. The wireless base station further comprises timing determining means for determining the timing of each time slot, by the timing determined by the timing determining means,
The communication is performed within the service area.

According to a ninth aspect of the present invention, in the mobile communication system according to the eighth aspect, information of radio interference between the radio base stations is transmitted and received between the radio base stations using a common control channel. In this case, the reception level of the radio wave is obtained.

According to a tenth aspect of the present invention, there is provided a synchronization method in a mobile communication system, comprising receiving timing information of a time slot of another mobile communication system having a service area near a service area of the mobile communication system. When radio communication occurs between the mobile communication system and the other mobile communication system when the mobile communication system performs communication within a service area using a predetermined time slot, the mobile communication system performs the other communication based on the received timing information. To reduce the radio interference between the mobile communication system, or to determine the timing of the time slot of the mobile communication system to be eliminated, by the determined timing, to perform communication within the service area of the mobile communication system. Features.

The invention according to claim 11 is a synchronization method in a mobile communication system, wherein prior to the start of a service, a time slot of another mobile communication system having a service area near a service area of the own mobile communication system. Receiving the timing information, based on the received timing information, to reduce the radio wave interference with the other mobile communication system, or determine the timing of the time slot of the own mobile communication system to remove, the determined It is characterized in that communication is performed within the service area of the mobile communication system according to timing.

According to a twelfth aspect of the present invention, there is provided a synchronization method in a mobile communication system, wherein a timing of a time slot of another mobile communication system having a service area near a service area of the own mobile communication system during a service. Receiving information, if radio wave interference occurs with the other mobile communication system, based on the received timing information, reduce or eliminate radio wave interference with the other mobile communication system The timing of the time slot of the own mobile communication system is determined, and communication is performed within the service area of the own mobile communication system at the determined timing.

According to a thirteenth aspect of the present invention, there is provided a synchronization method in a mobile communication system including a plurality of radio base stations, wherein the radio interference is reduced based on radio interference information between the radio base stations, Alternatively, the timing of each time slot of the radio base station to be removed is determined, and communication is performed within a service area according to the determined timing.

According to the above configuration, radio interference can be reduced as much as possible in the mobile communication system, the subscriber capacity can be increased as a system, and a service of good communication quality can be provided to the user. .

[0039]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS.

FIG. 1 is a diagram showing a configuration example of a mobile communication system including a plurality of radio base stations (for example, a digital cordless telephone system for business use). In this case, four radio base stations 71 to 74 are shown, and these are PBX
The lines are concentrated to the control device 70 having the equal control function. Each wireless base station has service areas 171 to 174, and the service areas are gathered to form a service area of the system. Numerals 81 to 88 in the figure denote mobile wireless devices (mobile phone (data) devices, mobile terminals). The mobile radio can freely move to the service areas 171 to 174 of other radio base stations while communicating within the service areas 171 to 174.

FIG. 2 is a diagram showing an example of the reception level of radio waves between radio base stations in a mobile communication system as described above. That is, each radio base station 1 to use for communication
For each of the five radio channels, each of the radio base stations 1 to 5 has a control device that comprehensively controls each of the radio base stations 1 to 5 in advance.
It reports the possibility of occurrence of interference between wireless base stations and information on the measurement results of the amount of interference. Here, the transmission power is assumed to be known, but the transmission power and the reception level may be reported together. The number in each column in the figure indicates the magnitude of the amount of interference, and the larger the numerical value, the greater the amount of interference. A blank column means that the interference amount could not be measured at all, and indicates that there is no interference relationship. It should be noted that, for example, the difference between the measured value of the interference amount at the time of transmission of the radio base station 1 and the reception of the radio base station 4 and the measurement value at the time of transmission of the radio base station 4 and the reception of the radio base station 1 is caused by a change in the state of the transmission path. This is because a measurement error occurs due to the above. The same is true for the case of transmission of the radio base station 5 and the reception of the radio base station 1, but there is an interference relationship. However, this indicates that no interference has occurred in the wireless base station 5 because the distance between the wireless base station 1 and the wireless base station 5 is long.

FIG. 3 is a diagram showing an image of a frame configuration example used in a mobile communication system using digital signals that have been time-division multiplexed. The horizontal axis represents the time axis, and one frame has 16 time slots. The vertical axis represents codes or frequencies. This figure shows an example in which the number of codes or frequencies in the vertical axis direction is 8, and eight communication channels are multiplexed.

FIG. 4 is a diagram showing an example of the arrangement of radio base stations in a digital cordless telephone system for a plurality of offices. In the figure, four systems, systems 1, 2, 3 and 4, are shown. The system 1 includes wireless base stations 1 to 5,
The service area of each wireless base station is indicated by 101 to 105. The system 2 comprises radio base stations 21 and 22, and the service area of each radio base station is 121 and 12
This is indicated by 2. The system 3 includes radio base stations 41 and 42, and the service area of each radio base station is indicated by 141 and 142. The system 4 is a wireless base station 6
1 and 62, and the service area of each radio base station is indicated by 161, 162a and 162b. The system 1 is central to the following description.

In the system 1, five ellipses indicate the service areas of the respective radio base stations 1 to 5 installed in the respective central portions. Each of the wireless base stations 1 to 5 is indicated by a rectangle. In FIG. 4, the overlap of the ellipses indicates that the service areas overlap, but in the overlapped area, the radio signals transmitted from the radio base stations 1 to 5 that control the area may show interference. It is shown that. Although not shown, a large number of mobile radios exist in the service area of the system, and are in a communication or standby state. Also,
Although not shown in the figure, the system includes a control device that controls the radio base stations, and is connected to each radio base station by a transmission line. The result of FIG. 2 described above can be considered as a measurement example in the case where the radio base station arrangement is as shown in FIG.

FIG. 4 shows systems 2, 3 and 4 as other systems of the system 1. Of these, system 2 (wireless base stations 21 and 22 are indicated by diamonds)
There is no overlap between the service areas of the system 1 and the system 1.
On the other hand, the service area of the wireless base station 41 of the system 3 (illustrated as a base pentagon) partially overlaps with the service area of the wireless base station 3 of the system 1, and there is a possibility that interference may occur. Is shown. In addition, the radio base station 62 of the system 4 (illustrated by a hexagon) does not overlap the service area with the radio base station 4 of the system 1 conventionally.
Since the radio wave propagation state around the radio base station has changed, the service area of the radio base station 62 has changed from the ellipse 162a indicated by the solid line to the ellipse 162b indicated by the dashed line, resulting in an overlap with the service area 104 of the radio base station 4. Indicates that interference may occur. The number of wireless base stations in the illustrated system 1 is 5, and the number of wireless base stations in the nearby systems 2, 3, and 4 is 2, respectively. There are actually many more, but they are omitted for simplicity.

Hereinafter, FIGS. 5 to 7 will be described.

FIG. 5 is a flowchart for obtaining a radio wave reception level between radio base stations in a mobile communication system.

Hereinafter, a case where the procedure shown in FIG. 5 is applied to the system 1 shown in FIG. 4 will be described as an example. It is assumed that the control device (not shown) of the system 1 and the radio base stations 1, 2, 3, 4, and 5 have started operation but have not yet actually performed system operation. The control device transmits a signal to a subordinate radio base station 1 to 5 at a specified transmission power level using a common control channel at an assigned time timing, and transmits a signal from a nearby radio base station. A signal requesting measurement of the reception level of the received signal is sent (S10). Each of the radio base stations 1 to 5 receiving the signal from the control device transmits the signal on the common control channel at the given time timing, and measures the reception level of the signal transmitted from the peripheral radio base station. Execute (S20). The signal transmitted from each radio base station includes the ID (identification information) of its own radio base station at the request of the control device, and also includes the transmission power level of the common control channel.

Next, the control device requests all of the subordinate radio base stations 1 to 5 to transmit the above measurement result at the reception level to the control device at the assigned time timing (S30). Each of the radio base stations 1 to 5 receiving this instruction transmits each reception level to the control device at the given time timing (S40). The control device that has received these reception levels from the radio base stations 1 to 5 creates and stores the reception levels between the respective radio base stations (S50).

The measured values shown in FIG. 2 can be obtained by the above-described process, and the control device can start system operations such as outgoing and incoming calls using the measured values. That is, it is possible to determine the timing of the time slot of each radio base station to reduce or eliminate radio interference between the radio base stations in the system based on the acquired reception levels between the radio base stations.

Next, the influence of signals transmitted from the radio base stations of the other systems 2 to 4 existing in the vicinity of the system 1 on its own system will be investigated.

FIG. 6 is a flowchart showing a system operation for optimizing system operation when a plurality of mobile communication systems are mixed. The control device of the system 1 and the radio base stations 1 to 5 have already started operation, but before the start of service (communication within the service area). Such a situation may be a case where the system 1 is newly installed or a case where the power of the system 1 is turned on. It is also assumed that all of the peripheral systems 2 to 4 have started service operations.

The control device of the system 1 receives a signal transmitted from a radio base station of another system to each subordinate radio base station and transmits a signal requesting to report the measurement result (S210). Each of the subordinate radio base stations 1 to 5 receiving this signal tries to receive a signal transmitted from a radio base station of another system (S220). As a result, the radio base stations 1, 2, 4 and 5 could not receive the signal (S230), and report this result to the control device at the designated time (S240). This is probably because, as already described with reference to FIG. 4, there is no overlap in the service area with other systems. The control device that has received a report from the radio base stations 1, 2, 4, and 5 that the signal of the other system could not be received creates a timing unique to the own system, transmits the timing to each radio base station, and receives the given timing. Request to use timing (S
260). As the timing unique to the own system, the timing of the time slot of each wireless base station for reducing or eliminating radio interference between the wireless base stations in the system is determined based on the reception level between the wireless base stations in the system. It can be determined in advance and used.

Radio base stations 1, 2, and 4 receiving the instruction signal
In steps 5 and 5, communication is performed within the service area at the designated timing (S270). More specifically, for example, the own server is used using the timing of the designated common control channel.
Sends a signal to the service area.

Next, as a result of the wireless base station 3 trying to receive signals of other systems existing in the vicinity (S220), the signal transmitted from the wireless base station 41 is received (S2).
30), and reports this result to the control device (S250).
This is because the service area of the wireless base station 41 of the other system 3 overlaps with the wireless base station 3 of the own system as already described with reference to FIG. Interference occurs between the wireless base station 3 of the own system and the wireless base station 41 of the other system 3.

By receiving, for example, a common control channel of another system, the own system can acquire timing information of a time slot of another system (information such as timing of a common control channel of another system).

The control device that has received the report from the wireless base station 3 determines the timing at which no interference occurs with other systems and no interference occurs with other wireless base stations of its own system. It transmits to the station 3 and requests to use the instructed timing (S260). For example, by shifting the timing of the common control channel, it is possible to avoid the occurrence of interference. When there is no timing at which no interference occurs, it is preferable to select a timing at which the interference becomes small.

The wireless base station 3 that has received the instruction signal performs communication within its own service area at the instructed timing (S280). Specifically, for example, a signal is transmitted to the own service area using the designated timing of the common control channel.

As a result of the above-described initial adjustment, it is possible to provide a timing at which interference does not occur not only within the own system but also with another system, so that the system can be operated smoothly.

Next, a case will be described in which the radio base station 4 of the own system detects the occurrence of interference from the other system 4 while the system 1 is operating a service, and the control unit receives this notification. Will be described.

FIG. 7 is a flowchart showing a system operation for re-adjusting the optimization of the system operation when the radio wave propagation state changes during the operation (in service) of a plurality of mobile communication systems. In addition to the control device of the system 1, the radio base station 4, a large number of mobile radios in the service area including the radio base stations 1, 2, 3 and 5, and the systems 2, 3 and 4 operate and service (service area). Communication) has started.

During operation of the system, each radio base station monitors a signal transmitted from a radio base station of another system. At that time, the wireless base station may be able to receive a signal that could not be received so far, and may be interfered with by a wireless base station of another system.

In the example shown in FIG. 4, the radio base station 4 can receive a signal from the radio base station 62 of the system 4 which has not been able to receive the signal until now, and receives interference from the radio base station 62. Consider the case. In that case, the radio base station 4 changes the timing of the time slot,
A signal requesting that a timing that does not cause interference with another system be given is transmitted (S510). As described above, the cause is as follows.
Conventionally, the service area of the radio base station 4 does not overlap with the radio base station 4 of the system 1, but the radio wave propagation state around the radio base station has changed.
This is because, as a result of the change of the service area from the ellipse 162a indicated by the solid line to the ellipse 162b indicated by the dashed line, the radio base station 4 overlaps the service area, causing interference.

In the control device receiving this signal, no interference occurs with the signal of the radio base station 62 of the system 4,
Further, a timing at which no interference occurs with another wireless base station of the own system is transmitted to the wireless base station 4, and a request is made to use the designated timing (S520). The wireless base station 4 receiving this instruction signal performs communication within its own service area at the instructed timing. Specifically, for example, a signal is transmitted to the own service area using the designated timing of the common control channel (S530). As a result, the timing is set such that interference does not occur not only within the own system but also with other systems. Thereafter, each system performs good system operation with good communication quality, and the frequency is effective as a whole system. The utilization rate will be improved.

In the present embodiment, a method in which a radio base station measures interference power from another radio base station has been described. However, a mobile radio measures interference power from a radio base station and reports it to a control device. In this case, the same effect can be obtained.

[0066]

According to the present invention, in order to cope with the needs for wireless use which will increase more and more in the future, more effective use of frequencies is required. It is thought that the possibility that systems having the wireless standard of the above are mixed in the same service area is increased.

The present invention shows various technical methods capable of reducing radio interference as much as possible even if a plurality of such systems coexist in the same service area. This makes it possible to provide a service with good communication quality to the user, so that the effect of the present invention is extremely large.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a configuration example of a mobile communication system including a plurality of wireless base stations.

FIG. 2 is a diagram illustrating an example of a reception level of a radio wave between wireless base stations in a mobile communication system.

FIG. 3 is a diagram showing an image of a frame configuration example used in a mobile communication system using a time-division multiplexed digital signal.

FIG. 4 is a diagram showing an example of a wireless base station arrangement of a digital cordless telephone system for a plurality of offices.

FIG. 5 is a flowchart for obtaining a reception level of a radio wave between radio base stations in a mobile communication system.

FIG. 6 is a flowchart showing a system operation for optimizing system operation when a plurality of mobile communication systems are mixed.

FIG. 7 is a flowchart illustrating a system operation for re-adjusting optimization of system operation when a radio wave propagation state changes during operation of a plurality of mobile communication systems.

[Explanation of symbols]

1-5, 21, 22, 41, 42, 61, 62, 71-
74 Radio base station 70 Controller 81-88 Mobile radio 101-105, 121, 122, 141, 142, 1
61, 162a, 162b, 171-174 Service area of radio base station

Claims (13)

[Claims] 1. A mobile communication system, comprising: receiving means for receiving timing information of a time slot of another mobile communication system having a service area near a service area of a mobile communication system; Based on the timing information,
Reduce the radio interference with the other mobile communication system,
Or a timing determining means for determining a timing of a time slot of the own mobile communication system to be removed, and when the own mobile communication system performs communication within a service area by a predetermined time slot, the communication with the other mobile communication system is performed. When radio wave interference occurs between the timing, the timing is determined by the timing determining means,
A mobile communication system wherein communication is performed within a service area of the mobile communication system at the timing. 2. A mobile communication system, comprising: receiving means for receiving timing information of a time slot of another mobile communication system having a service area near a service area of the mobile communication system; Based on the timing information,
Reduce the radio interference with the other mobile communication system,
Or a timing determining means for determining a timing of a time slot of the own mobile communication system to be removed, wherein the timing is determined by the timing determining means prior to the start of service, and the service area of the own mobile communication system is determined by the timing. A mobile communication system for performing communication within a mobile communication system. 3. A mobile communication system, comprising: receiving means for receiving timing information of a time slot of another mobile communication system having a service area near a service area of the mobile communication system; Based on the timing information,
Reduce the radio interference with the other mobile communication system,
Or a timing determining means for determining the timing of the time slot of the own mobile communication system to be removed, and during the service, when radio wave interference occurs with the other mobile communication system, the timing determining means A mobile communication system comprising: determining the timing; and performing communication within a service area of the mobile communication system based on the determined timing. 4. The mobile communication system according to claim 1, wherein the timing information of the time slot of the another mobile communication system includes timing information of a common control channel of the other mobile communication system. Wherein the timing determining means determines a timing shifted from the timing of the common control channel of the another mobile communication system, and the own mobile communication system transmits the common control channel within the service area according to the determined timing. Mobile communication system. 5. The mobile communication system according to claim 1, comprising one or more radio base stations,
A mobile communication system, wherein a service area of the mobile communication system is formed by gathering service areas of the radio base stations. 6. The mobile communication system according to claim 5, wherein said timing determination means also reduces or eliminates the radio interference based on information on radio interference between radio base stations in the mobile communication system. A mobile communication system characterized in that it determines the timing of a time slot of its own mobile communication system. 7. The mobile communication system according to claim 5, wherein when there are a plurality of said radio base stations, each of said radio base stations receives timing information of a time slot of said another mobile communication system. The timing determining means determines the timing of a time slot for each of the radio base stations. 8. A mobile communication system including a plurality of radio base stations, wherein each of the radio base stations reduces or removes the radio interference based on information on radio interference between the radio base stations. A mobile communication system comprising timing determination means for determining a timing of a time slot, and performing communication within a service area according to the timing determined by the timing determination means. 9. The mobile communication system according to claim 8, wherein the information on the radio wave interference between the radio base stations is a radio wave reception level when a signal is transmitted and received between the radio base stations using a common control channel. A mobile communication system, characterized in that: 10. A synchronization method in a mobile communication system, comprising: receiving timing information of a time slot of another mobile communication system having a service area near a service area of the mobile communication system; When radio wave interference occurs with the other mobile communication system when performing communication within the service area by the determined time slot,
Based on the received timing information, the timing of a time slot of the own mobile communication system to reduce or eliminate radio wave interference with the other mobile communication system is determined. A synchronization method in a mobile communication system, characterized in that communication is performed within a service area. 11. A synchronization method in a mobile communication system, comprising: prior to starting a service, receiving timing information of a time slot of another mobile communication system having a service area near a service area of the mobile communication system; Based on the received timing information, the timing of a time slot of the own mobile communication system to reduce or eliminate radio wave interference with the other mobile communication system is determined. A synchronization method in a mobile communication system, characterized in that communication is performed within a service area. 12. A synchronization method in a mobile communication system, comprising: receiving, during a service, timing information of a time slot of another mobile communication system having a service area near a service area of the mobile communication system; When radio interference occurs with the mobile communication system, the time of the own mobile communication system for reducing or eliminating radio interference with the other mobile communication system based on the received timing information. A synchronization method in a mobile communication system, comprising: determining a slot timing; and performing communication within a service area of the mobile communication system based on the determined timing. 13. A synchronization method in a mobile communication system including a plurality of radio base stations, wherein the radio base station reduces or eliminates radio interference based on information on radio interference between the radio base stations. Determining a timing of each time slot, and performing communication within a service area based on the determined timing.