JP2673947B2 - Mobile communication call channel control system - Google Patents

Description

The present invention relates to a channel control system of a mobile communication system using a small zone system.

[Conventional technology]

Call channel allocation in the small zone system is roughly divided into (1) fixed channel allocation in which channels are fixedly assigned to each zone, and (2) dynamic channel allocation in which usage rights of call channels are exchanged between zones. is there.

 First, the fixed channel arrangement of (1) will be described.

FIG. 6 is a diagram for explaining a fixed channel allocation method in the small zone method, 51 to 57 are wireless zones (also simply referred to as “zones”), 51a to 57a are wireless base stations in each wireless zone, and S1) to (S7) represent the number of wireless facilities provided in each wireless base station.

As shown in the figure, the fixed channel arrangement is a method of fixedly allocating channels to the first to seventh wireless zones 51 to 57 according to the traffic volume in advance,
Each of the radio base stations 51a to 57a is provided with the radio equipment indicated by the number of equipments (S1) to (S7).

However, this fixed channel arrangement cannot flexibly deal with the temporal fluctuation of traffic because the channel allocation is fixed.

 An example is shown in FIG.

FIG. 7 is a diagram showing temporal fluctuations of traffic in each wireless zone, 58 is the number of traffic occurring at each time in each wireless zone, 59 is the peak of the number of traffic occurring in each wireless zone. The points and 60 represent the number of lost channels in each wireless zone.

For example, if the traffic peak point 59 exists in a certain zone and exceeds the number of channels allocated in that zone, the newly originated call cannot connect because the number of lines is insufficient, resulting in call loss. There were drawbacks such as.

However, it is considered physically and economically impossible to reduce the call loss rate to 0% in terms of system design. Therefore, for example, the wireless rate should be assigned within 3% (call loss rate 3%). Design the number of lines.

On the other hand, the dynamic channel arrangement (2) is a method of controlling the wireless channel for call by call.

For the control method and effect in that case, refer to (Jakes J
r., "Microwave Mobile Commu-nications", Chapter 7,
John Wiley & Sons, 1974).
They generally need to manage all channels sequentially because they allocate wireless channels to call by call flexibly between wireless zones, especially when allocation control considers co-channel interference. Control becomes very complicated and the control amount becomes large. Also. There is a drawback that the number of required radio equipments increases considerably compared to the fixed arrangement.

[Problems to be solved by the invention]

In fixed channel allocation, it is not possible to flexibly deal with temporal fluctuations of traffic because the channel allocation to each wireless zone is fixed, and the traffic exceeds the number of channels allocated to that wireless zone. Has
The newly generated call has a drawback that it cannot be connected because the number of lines is insufficient and the call is lost. On the other hand, the dynamic channel arrangement requires a complicated control method and increases the number of required radio equipments.

The present invention has been made in view of the above problems, and in the fixed channel arrangement, when traffic is concentrated in a specific wireless zone, a part of the traffic can be distributedly controlled to other wireless zones in the vicinity. An object is to provide a mobile communication call channel control system.

[Means for Solving the Problems] According to the present invention, the above-mentioned object is achieved by the means described in the claims.

That is, the present invention relates to a mobile communication system in which a wireless zone is configured by a small zone system and a mobile station is equipped with an in-call channel switching function for continuing a call by switching to another call channel during a call. The traffic amount is measured, and it is determined whether the traffic amount exceeds a predetermined threshold value.When the traffic amount exceeds the predetermined threshold value, the mobile station in a call in the wireless zone, At least one of the wireless base stations in the wireless zone adjacent to the wireless zone measures the reception level of the transmission radio wave of the other party, and the reception level is higher than a predetermined level threshold value. In this case, the mobile communication call channel control system is configured to perform channel switching for connecting the mobile station to the base station in the adjacent radio zone.

[Action]

When traffic is concentrated in a certain wireless zone in fixed channel arrangement, the size covered by that wireless zone is changed according to the traffic volume, and it is forcibly forced to another wireless zone where the call can be continued. Switch channels.

〔Example〕

An embodiment of the mobile communication call channel control system of the present invention will be described below.

In this embodiment, the service area is composed of seven wireless zones, and the number S of wireless equipments in each wireless zone is S (= 10).
0) The case of channel is taken as an example.

FIG. 1 is a diagram showing a distribution of mobile stations in a call or seeking a call in each wireless zone at an arbitrary time.

FIG. 1A shows a configuration diagram of a wireless zone, where 1 to
Reference numeral 7 denotes each wireless zone (also simply referred to as “zone”, also indicated by reference numerals “# 1 to # 7”), 1a to 7a denote wireless base stations in each wireless zone, and R denotes a conventional wireless zone # 1 and other wireless zones. The boundary between the wireless zone and the number in parentheses () indicates the number of mobile stations in each area who are talking or requesting a call.

The shaded area in the figure represents the boundary area between the wireless zone # 1 and the adjacent wireless zone.

The figure (b) is a figure which shows the number of call origination channels in each radio zone # 1 to # 7, the number of call failure channels, and the figure (c) is a boundary area between the radio zone # 1 and the peripheral radio zones. It is a figure which shows the number of the mobile stations in.

In the wireless zone # 1, as shown in FIG. 1 (b), the traffic (the number of communication channels) is 130, the number of wireless equipments exceeds S (= 100), and the traffic is concentrated. Among the traffic, 30 channels of traffic exist in the boundary area shown by the shaded area.

In the case of conventional channel switching between wireless zones, channel switching is not executed until the receiving level of the mobile station or base station falls below the switching threshold represented by the receiving level on the wireless zone boundary R. Therefore, in the above example, 30 of the calls that occurred in wireless zone # 1 are lost.

However, according to the present invention, the above call loss should occur.
30 calls, wireless zone # 2 with low traffic around,
It is possible to continue the call by distributing the channels to # 3, # 4, and # 5.

For that purpose, first, of the channels used in the radio zone # 1, the reception level is measured at the radio base stations in the radio zones # 2, # 3, # 4, and # 5 with less traffic in the periphery. Then, the radio network controller makes the radio zone #
Channel switching is forcibly executed by the wireless base stations in 2, # 3, # 4, and # 5.

Hereinafter, the operation of the present invention will be described in more detail.

FIG. 2 shows a control configuration diagram of the present invention. 10 is a mobile station (MSS) in the radio zone # 1, 11 to 17 are radio base stations (MBS #) in the radio zones # 1 to # 7. 1-MBS # 7), 18
Is a radio network controller, L _{1 to} L ₅ are radio base stations (MBS # 1 to MBS # 1 to which currents are transmitted from mobile stations (MSS) in radio zone # 1
This shows the reception level in # 5).

That is, wireless zone # 1 where traffic is concentrated
The current level transmitted from the mobile station (MSS) 10 in the wireless base stations MBS # 2 to # 5 in the wireless zones # 2 to # 5 in which the traffic is not concentrated is measured and the call continues. Confirmation is possible.

FIG. 3 is a diagram for explaining the channel switching direction when the present invention is applied, and FIG. 3 (a) is a wireless zone configuration diagram for explaining the channel switching direction, and the dotted line R is conventional. The boundary line between the wireless zone of and other wireless zones, arrowed lines 20 to 23 indicate the channel switching direction, and the numbers in parentheses () indicate the number of active and outgoing channels in each wireless zone. The other symbols are the same as those in FIG.

In the example of the figure, the channels of the mobile stations of the numbers indicated by the numbers in parentheses () existing in the boundary area of the old wireless zone # 1 indicated by the shaded area are respectively indicated by arrowed lines 20 to 23. It will be switched to the wireless zone of the direction.

FIG. 3 (b) is a diagram showing the number of calling and calling channels in each wireless zone after channel switching, and FIG. 3 (c) is a channel from wireless zone # 1 to another wireless zone. It is a figure which shows the switching number of.

That is, of the 130 channels of calls that existed in the conventional wireless zone # 1 (the area within the boundary R of FIG. 3A), the calls of 30 channels that should be lost are Figure (c)
, The wireless zones # 2 to # 5 are distributed,
Finally, the distribution of mobile stations is as shown in FIG.

When switching channels, wireless zone # 2
When the mobile station tends to move to the wireless zone # 1 where the traffic is concentrated, the channel control is performed so that the channel switching is not performed as much as possible by, for example, lowering the channel switching level. To do.

An example of the channel switching control algorithm described above is shown in FIG.

FIG. 4 is a flow chart showing an example of the control algorithm of the present invention, 30 to 36 are the steps of each process in the control algorithm, and Tr (i) is the traffic volume (i = 1, 2 in the i-th wireless zone). , ......, 7), T _th is a traffic threshold for executing channel switching, and L _i is a wireless zone #.
The reception level of the radio wave transmitted from the mobile station in 1 at the wireless base station in the adjacent i-th wireless zone, L _th is the level threshold at which a call can be made, M _j is in the wireless zone where traffic is concentrated This represents the j-th mobile station existing in (wireless zone # 1 in this example).

 Next, this flowchart will be described.

In step 30, the traffic volume Tr (i) of each wireless zone is measured, and in step 31, it is compared whether or not the traffic volume Tr (i) of each wireless zone exceeds the traffic threshold T _th for channel switching. .

If Tr (i) <T _th (i = 1, 2, ..., 7), it is not necessary to switch channels, and control returns to the start point. If Tr (i)> T _th , the process proceeds to step 32. Then, the switching process is executed.

In step 32, the reception level L _i of the radio wave from the mobile station M _j is measured by the radio base station in the adjacent i-th radio zone, and the reception level L _i and the level threshold L _th with which a call can be made are set. Make a comparison of.

If L _i <L _th , the mobile station M _j cannot communicate with the i-th radio base station, and the process proceeds to step 36, and the mobile station M _j operates to measure the reception level of another mobile station that can communicate. To do.

If L _i > L _th , the process proceeds to step 34 and step 34
In (1), one of the wireless base stations satisfying the condition of L _i > L _th is selected and the channel is switched, and in step 35, the switching threshold of the wireless zone in which the channel is switched is lowered.

By performing the control as described above, it is possible to distribute the traffic in the wireless zone where the traffic is concentrated to other wireless zones in the vicinity, so that it is possible to carry a large amount of traffic at the same time.

Further, if all channels are to be connected by a dynamic arrangement that allows the usage right of the call channel to be connected, in this example, the maximum number of wireless equipments is 130 in the wireless zone # 1, but in the present invention, 100 channels are required. It is possible to keep the number of radio equipment to a minimum so that it can be done.

Further, with respect to the co-channel interference problem, in the present invention, if the channel switching location is assumed to be about 1/2 of the zone radius at the maximum, the reduction of the co-channel interference distance is hardly a problem, so Even if control is performed, the co-channel interference degradation increment is negligible and can be ignored.

FIG. 5 is a diagram for explaining the switching threshold and the channel switching, where R is the boundary line between the conventional wireless zone # 1 and other wireless zones, and the dotted line R'is the reduced wireless zone due to the increased channel switching threshold. It represents the boundary line.

That is, the present invention is equivalent to performing channel switching inside the reduced radio zone boundary R ', and the traffic generated between the reduced radio zone boundary R'and the original border R. , Or for the traffic of a mobile station that has moved to this area from another location, channel switching is performed to a peripheral wireless base station.

Therefore, in a radio base station in which traffic is concentrated, as shown in the figure, the switching threshold is increased by a certain value and channel switching is performed, whereby the traffic volume can be effectively distributed.

Further, it is more effective if the wireless base stations in the surrounding wireless zones are configured to lower the channel switching threshold value by a certain value.

〔The invention's effect〕

As explained above, in contrast to the fixed channel allocation method, which conventionally could not flexibly cope with temporal fluctuations in traffic, the traffic concentrated in a specific zone in time is processed with a minimum number of radio equipment. In addition, since the channel arrangement is fixed, there is no need to perform channel control for accommodating the right to use the communication channel between wireless zones for each call that occurs, so traffic control can be performed with extremely simple control. There is an advantage that management can be performed.

[Brief description of the drawings]

FIG. 1 is a diagram showing distribution of mobile stations in each wireless zone during a call and seeking a call at an arbitrary time, FIG. 2 is a control configuration diagram of the present invention, and FIG. 3 is a case where the present invention is applied. FIG. 4 is a flow chart showing an example of a control algorithm of the present invention, FIG. 5 is a diagram explaining a channel switching threshold value and channel switching, and FIG. 6 is a fixation in a small zone system. A diagram illustrating a channel allocation method,
FIG. 7 is a diagram showing temporal changes in traffic in each wireless zone. 1 to 7 ... wireless zones (# 1 to # 7), 1a to 7a ... wireless base stations in each wireless zone, 10 ... mobile stations (MSS) in wireless zone # 1, 11 to 17 ... Radio base stations (MBS # 1 to MBS # 7) in each radio zone, 18 ... Radio circuit control station, 20-23 ... Channel switching direction, 30-36 ... Steps of each process in control algorithm, R: boundary line between a conventional wireless zone and another wireless zone, R ': wireless zone boundary line reduced by increasing the channel switching threshold, L _{1 to} L ₅ : movement within wireless zone # 1 Each radio base station (MBS of the radio wave transmitted from the station (MSS)
Reception level at # 1 to # 5)

Front page continued (72) Inventor Kenji Imamura 1-6, Uchisaiwaicho, Chiyoda-ku, Tokyo Nippon Telegraph and Telephone Corporation (72) Hidetaka Tomita 1-6, Uchisaiwaicho, Chiyoda-ku, Tokyo Nippon Telegraph and Telephone Corporation In-house (56) References JP-A-58-111443 (JP, A)

Claims (1)

(57) [Claims] 1. A mobile communication system having a wireless zone configured by a small zone system and having a channel switching function during a call, in which a mobile station continues a call by switching to another call channel during a call, the traffic of the wireless zone. The traffic volume is measured, and it is determined whether the traffic volume exceeds a predetermined threshold value.When the traffic volume exceeds the predetermined threshold value, the mobile station that is talking in the wireless zone and the wireless Between wireless base stations in the wireless zone adjacent to the zone, at least one of them measures the reception level of the transmission radio wave of the other party, and the reception level is higher than a predetermined level threshold value. At this time, a mobile communication speech channel control system characterized by performing channel switching for connecting the mobile station to a base station in the adjacent radio zone.