JP5982133B2 - Load distribution apparatus, load distribution method, and load distribution program - Google Patents

Description

  The present invention relates to a load distribution apparatus, a load distribution method, and a load distribution program.

In a mobile radio communication system, the load state of a base station changes with time changes in user distribution and traffic generation bias.
Here, the load on the base station is determined by the number of terminals connected to the base station, the usage rate of radio resources, the usage rate of a CPU (Central Processing Unit) in the base station device, or any combination thereof. It is an evaluation index.

The mobile terminal makes a state transition between a communication state (Connected Mode) and a standby state (Idle Mode) in response to the occurrence of user traffic.
The mobile terminal in the communication state is synchronized with the base station for both the downlink signal and the uplink signal, and the mobile terminal switches the connection station (base station to be connected) by handover.
On the other hand, the mobile terminal in the standby state is synchronized with the base station only for the downlink signal, and the mobile terminal switches the standby station (the base station that is on standby) by cell reselection.

  In LTE (Long Term Evolution), load parameters between base stations are adjusted by adjusting setting parameters for handover and cell reselection and changing handover timing (handover timing) and cell reselection timing (cell reselection timing). A technique for realizing dispersion has been studied (for example, see Non-Patent Document 1).

First, referring to FIG. 7 and FIG. 8, a change in handover timing will be described.
FIG. 7 is a diagram illustrating an example of a handover and an implementation condition in LTE.
FIG. 7 shows the first base station (base station # 1), the second base station (base station # 2), the communication area (area # 1) of the base station # 1, and the communication of the base station # 2. An area (area # 2) and mobile terminals 1011-1 and 1011-2 are shown.
Here, the mobile terminal 1011-1 before the movement and the mobile terminal 1011-2 after the movement represent the same mobile terminal and are present at different positions.

Regarding the mobile terminal 1011-1 (mobile terminal 1011-2), the following processing (1) to (5) regarding the handover (HO) from the area # 1 of the base station # 1 to the area # 2 of the base station # 2 Is done.
(1) Base station # 1 designates a transmission condition of a handover request (HO request) to mobile terminal 1011-1.
(2) The mobile terminal 1011-1 transmits the HO request when the specified transmission condition of the HO request is satisfied.
(3) The base station # 1 that has received the HO request issues a handover instruction (HO instruction) to the mobile terminal 1011-2.
(4) Execute handover (HO execution).
(5) The mobile terminal 1011-2 reports completion of handover (HO completion) to the base station # 2.

FIG. 7 shows a graph in which time is plotted on the horizontal axis and power characteristics 1001 of connected cells and power characteristics 1002 of neighboring cells are plotted on the vertical axis.
The connected cell is a cell of a base station (connected base station) to which the mobile terminal is connected, and the adjacent cell has a cell that is adjacent to the connected cell (adjacent base station). Of the cell.
Two cells of the same base station having a plurality of cells may be connected cells and adjacent cells, but here, the cells of different base stations will be described as connected cells and adjacent cells, respectively.

Conditions for the mobile terminal to transmit a handover request include the following <transmission condition (1)> and <transmission condition (2)>.
<Transmission condition (1)>
There is a transmission condition that a power difference (handover margin) between an adjacent base station (adjacent cell) and a connected base station (connected cell) is equal to or greater than a predetermined threshold. Note that a power quality difference that is a difference in power quality values may be used instead of a power difference that is a difference in power values.
<Transmission condition (2)>
There is a transmission condition that the state of <transmission condition (1)> described above is satisfied for a predetermined time (fixed time) or longer.

Here, the handover margin is the result of subtracting (the received power value or received power quality value from the connected base station (connected cell)) from (the received power value or received power quality value from the adjacent base station (adjacent cell)). It is.
If the handover margin threshold is set to a small value, the handover timing is advanced. Conversely, if the handover margin threshold is set to a large value, the handover timing is delayed.

In LTE, handover processing is performed when a base station receives MR (Measurement Report) transmitted from a mobile terminal as a handover request.
A plurality of types with different transmission determination conditions are defined in MR. Here, A3 MR, which is often used for determination of handover processing, will be described.
The A3 MR is transmitted from the mobile terminal to the connected base station when the conditional expression (1) is satisfied for a certain period (TTT: Time To Trigger) or more (see, for example, Non-Patent Document 2).

Here, with respect to Equation (1), s and n are base station IDs representing a connected base station and an adjacent base station, respectively.
M (s, s) and M (s, n) are respectively a power value (RSRP: Reference Signal Received Power) [dBm] or a power quality value (dBm) of the connected base station s and the adjacent base station n observed by the mobile terminal. RSRQ: Reference Signal Received Quality) [dB].

In addition, regarding the expression (1), variables other than the above-described M (s, s) and M (s, n) are system parameters that can be set by the operator.
Specifically, Of (s, s) and Oc (s, s) are an offset value set according to the frequency of the connected base station s and an offset value specific to the connected base station s, respectively.
Similarly, Of (s, n) and Oc (s, n) are respectively an offset value set according to the frequency of the adjacent base station n and an offset value set by the connected base station s for each adjacent base station n ( Cell individual offset value).
Hys (s) and Off _A3 (s) are parameters set for each connected base station s, and are an offset value called hysteresis and an offset value specific to A3 MR, respectively.

By changing the above system parameters, it is possible to change the timing at which the conditional expression (1) is satisfied, that is, the timing for handover from the connected base station s to the adjacent base station n.
When a power difference or power quality difference between the adjacent base station n and the connected base station s is defined as a handover margin (HO margin) as shown in a generalized expression (2) of the conditional expression (1), handover is performed. The handover timing can be advanced by setting a small threshold for the margin, and the handover timing can be delayed by setting a large threshold for the handover margin.

FIG. 8 is a diagram illustrating an example of a state of MLB (Mobility Load Balancing) by handover. FIG. 8 shows an image of load distribution between base stations by changing the handover timing.
FIG. 8 illustrates a first base station (base station # 1) having a high load, a second base station (base station # 2) having a low load, a communication area (area # 1) of the base station # 1, The communication area (area # 2) of the base station # 2 and mobile terminals (mobile terminals 1101, 1102, etc.) are shown.
In the example of FIG. 8, for the mobile terminal 1101 connected to the base station # 1, the handover timing from the base station # 1 to the base station # 2 is advanced. For the mobile terminal 1102 connected to the base station # 2, the handover timing from the base station # 2 to the base station # 1 is delayed. As a result, it is possible to connect the mobile terminal to the base station # 2 having a lower load than the base station # 1 having a higher load, and to reduce the number of mobile terminals connected to the base station # 1, It is possible to reduce the load.

Next, the change of cell reselection timing will be described.
When reselecting a cell in the same frequency band, when the mobile terminal has passed the RRC_IDLE state for 1 second or more and the conditional expression (3) is satisfied for a certain period (Treatment _RAT ) or more Then, the standby station is changed from the connected base station s to the adjacent base station n (see, for example, Non-Patent Document 3).

Here, Q _{means, s} and Q _{means, n} are _{RSRPs of} the connecting base station s and the adjacent base station n, respectively.
Q _Hyst and Q _Offset are system parameters that can be set by the operator, and are a hysteresis and an offset value, respectively.
By changing these system parameters, it is possible to change the timing at which the conditional expression (3) is satisfied, that is, the timing at which the cell is reselected from the connected base station s to the adjacent base station n.

As shown in Formula (4) obtained by generalizing Formula (3) as a conditional formula, the power difference (Q _{means, n} −Q _{means, s} ) between the adjacent base station n and the connected base station s is determined as a cell reselection margin. If the threshold for cell reselection margin is set small, the cell reselection timing (cell reselection timing) can be advanced, and by setting the threshold for cell reselection margin large, the cell reselection timing can be increased. Can be late.

  Note that the image of load distribution between base stations by changing the cell reselection timing is the same as the image of load distribution by base station by changing the handover timing shown in FIG.

3GPP TS36.300, v9.8.02011-09. 3GPP TS36.331, v9.3.2010-06. 3GPP TS36.304, v9.5.5.0.2010-12. “Load Balancing in Downlink LTE Self-Optimizing Networks”, Vehicular Technology Conference (VTC 2010-Spring), 2010 IEEE 71st. “On Mobility Load Balancing for LTE Systems”, Vehicular Technology Conference Fall (VTC 2010-Fall), 2010 IEEE 72nd. “Design of Distributed and Autonomous Load Balancing for Self-Organization LTE”, Vehicular Technology Conference Fall (VTC 2010-Fall E. 2010 72 E). "Conflict Avidance betbet Mobility Robustness Optimization and Mobility Load Balancing", IEEE Globecom 2010 processings.

  Comparing the load distribution due to the change in handover timing with the load distribution due to the change in cell reselection timing, the change in handover timing for mobile terminals in communication state is more involved in base station load fluctuation in real time. The direct effect is considered large. For this reason, the control method related to load sharing between base stations reported so far is mainly based on a change in handover timing (see, for example, Non-Patent Documents 4, 5, 6, and 7).

However, changing the handover timing may affect the handover performance itself.
Also, in handover optimization (MRO: Mobility Robustness Optimization) being studied in LTE, the same system parameters as in the conditional expression (1) are changed, so that the operation competes with the MLB.
For this reason, there is a problem that the load distribution effect and the handover performance are in a trade-off relationship and the control becomes complicated (for example, refer to Non-Patent Document 7).

On the other hand, load distribution by changing the cell reselection timing does not provide the expected load distribution effect unless the handover timing setting is taken into account, and generates an extra handover to the mobile terminal immediately after transition to the communication state There is a problem of letting you.
Here, as an example, the base station # 1 has a high base station load, and in order to promote the change of the standby station to the base station # 2, the cell reselection timing from the base station # 1 to the base station # 2 is set. Consider the case of speeding up.

FIG. 9 is a diagram illustrating an example of an MLB state by cell reselection.
FIG. 9 illustrates a first base station (base station # 1) having a high load, a second base station (base station # 2) having a low load, a communication area (area # 1) of the base station # 1, The communication area (area # 2) of base station # 2 and mobile terminals (mobile terminals 1201-1, 1201-2, etc.) are shown.
Here, the mobile terminal 1201-1 in the standby state before the state transition and the mobile terminal 1201-2 in the communication state after the state transition represent the same mobile terminal and represent different cases.

FIG. 9 shows an example of a cell reselection timing boundary from the base station # 1 to the base station # 2, and an example of a handover timing boundary from the base station # 2 to the base station # 1.
In the example of FIG. 9, the mobile terminal 1201-1 in the standby state selects connection with the base station # 2, and the mobile terminal 1201-2 immediately after transitioning to the communication state is the base station # 1. Perform a handover to

  Thus, if the cell reselection timing from the base station # 1 to the base station # 2 is set earlier than the handover timing from the base station # 2 to the base station # 1, the base station # 2 is waited in the standby state. The mobile terminal 1201-1 (mobile terminal 1201-2) selected as the receiving station satisfies the handover condition to the base station # 1 as soon as the mobile terminal 1201-1 transitions to the communication state, and is handed over to the base station # 1. That is, the mobile terminal 1201-1 (the mobile terminal 1201-2) is eventually connected to the base station # 1 in the communication state, and is not able to distribute the load to the base station # 2, and the mobile terminal 1201-1. An extra handover occurs immediately after the (mobile terminal 1201-2) transitions to the communication state, thereby degrading the communication performance of the mobile terminal. Such a problem is related to load distribution between base stations due to cell reselection.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a load distribution apparatus, a load distribution method, and a load distribution program capable of effectively distributing loads.

  (1) In order to solve the above-described problem, the load distribution apparatus according to the present invention does not change the handover timing for the mobile terminal in the communication state but changes the cell reselection for the mobile terminal in the standby state. A cell reselection parameter determining unit that determines a parameter related to cell reselection based on the load situation of the cell of the base station with the timing as a change target is provided.

  (2) The present invention provides the load distribution apparatus according to (1) described above, wherein the cell reselection parameter determination unit includes a cell reselection margin from a cell having a high load to a cell having a low load. And / or increasing the threshold for cell reselection margin from a lightly loaded base station cell to a heavily loaded base station cell so that one or both of: It is characterized by determining.

  (3) The present invention provides the load distribution apparatus according to (1) or (2) described above, wherein the cell reselection parameter determination unit is configured such that the cell of the base station having a low load is changed from the cell of the base station having a high load. The cell reselection margin value to the base station cell having a low load to the base station cell having a high load by reversing the sign of the handover margin. Determining a cell reselection margin value from a cell to a high-load base station cell to a handover margin value from a low-load base station cell to a high-load base station cell; Or both.

  (4) The present invention provides the load distribution apparatus according to (1) or (2) described above, wherein the cell reselection parameter determination unit is configured such that the cell of the base station having a low load is changed from the cell of the base station having a high load. Decrease the cell reselection margin to a predetermined multiple of a predetermined step width, and determine the cell reselection margin from the low load base station cell to the high load base station cell. In such a case, the cell reselection margin from the connected cell to the adjacent cell is determined so as to achieve one or both of the predetermined step width and the predetermined step multiple. Less than the handover margin from the cell to the neighboring cell and more than the value obtained by reversing the sign of the handover margin from the neighboring cell to the connected cell , To constrain, characterized in that.

  (5) In order to solve the above problem, in the load distribution method according to the present invention, the cell reselection parameter determination unit does not change the handover timing for the mobile terminal in the communication state, but moves in the standby state. A parameter related to cell reselection is determined based on a cell load situation of a base station, with a cell reselection timing for a terminal as a change target.

  (6) In order to solve the above-described problem, in the load distribution program according to the present invention, the cell reselection parameter determination unit does not change the handover timing for the mobile terminal in the communication state, but moves in the standby state. A load distribution program for causing a computer to execute a step of determining a parameter related to cell reselection based on a cell load situation of a base station, with a cell reselection timing for a terminal as a change target.

  According to the present invention, it is possible to effectively distribute the load.

It is a block diagram which shows schematic structure of the load distribution apparatus between base stations which concerns on one Embodiment of this invention. It is a figure which shows the example of the hysteresis area | region of a handover. It is a figure for demonstrating the method to determine a cell reselection parameter by the cell reselection parameter determination part which concerns on 1st Embodiment. It is a flowchart figure which shows an example of the process sequence of control in the determination of the cell reselection parameter performed by the cell reselection parameter determination part which concerns on 1st Embodiment. It is a figure for demonstrating the method to determine a cell reselection parameter by the cell reselection parameter determination part which concerns on 2nd Embodiment. It is a flowchart figure which shows an example of the process sequence of control in the determination of the cell reselection parameter performed by the cell reselection parameter determination part which concerns on 2nd Embodiment. It is a figure which shows the example of the handover in LTE, and its implementation conditions. It is a figure which shows the example of the mode of MLB by a hand-over. It is a figure which shows the example of the mode of MLB by cell reselection.

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

[First Embodiment]
In this embodiment, a case where the present invention is applied to a mobile radio communication system is shown.
The mobile radio communication system according to the present embodiment includes a plurality of base stations, a central server that manages the plurality of base stations, a network that connects the plurality of base stations and the central server so that they can communicate with each other, It has a plurality of terminals (for example, mobile terminals) that communicate with each base station by radio in the communication area.
In addition, the mobile radio communication system according to the present embodiment includes an inter-base station load distribution device (an example of a load distribution device) for each of a plurality of base stations.

  Here, in this embodiment, a configuration is shown in which an inter-base station load distribution device is installed for each base station. As another configuration example, an inter-base station load distribution device is installed in a centralized server that manages a plurality of base stations. You can also

Further, in this embodiment, a case where the load is distributed among the base stations based on the load of each base station in units of base stations will be described as an example. However, actually, for example, a cell formed by the base station As a unit, the load is distributed among the cells based on the load for each cell.
As a specific example, in LTE, one base station has three cells.
The load distribution among the cells may be performed not only between cells of different base stations (different cells) but also between different cells of the same base station.

In the following description, it is assumed that one base station corresponds to one cell for convenience of explanation.
That is, for example, when one base station has one (only) cell, or one base station has a plurality of cells but two adjacent base stations that are adjacent to each other (respectively A case will be described as an example in which load distribution is performed between base station cells).

FIG. 1 is a block diagram showing a schematic configuration of an inter-base station load distribution apparatus 1 according to an embodiment of the present invention.
In the present embodiment, two base stations considered to be adjacent to each other will be described as a first base station (base station # 1) and a second base station (base station # 2), respectively.
Further, the description will be made assuming that the inter-base station load distribution apparatus 1 according to the present embodiment is installed in the base station # 1.

  Note that base stations that are considered to be adjacent to each other are determined in advance and set in the system, for example. Examples of base stations that are considered to be adjacent to each other may include not only base stations that are actually adjacent but also base stations that are not actually adjacent but are determined to be adjacent.

The inter-base station load distribution apparatus 1 according to the present embodiment includes an input unit 11, an output unit 12, a storage unit 13, and a cell reselection parameter determination unit 14.
The input unit 11 inputs information from an external device.
The output unit 12 outputs information to an external device.
The storage unit 13 stores various types of information such as a predetermined program used by the cell reselection parameter determination unit 14 and a threshold value used in various types of processing.

The cell reselection parameter determination unit 14 determines a cell reselection parameter based on information input from the input unit 11, and outputs information on the determined cell reselection parameter from the output unit 12.
Specifically, the cell reselection parameter determination unit 14 includes information on the load of the base station # 1, information on the load of the base station # 2, and parameters for handover of the base station # 1 to the base station # 2 (handover parameters ), Handover parameter information of base station # 2 to base station # 1, information of cell reselection parameters of base station # 1 to base station # 2, and cell of base station # 2 to base station # 1 Reselection parameter information is input as input parameter information.
Then, the cell reselection parameter determination unit 14 uses the cell reselection parameter information for the base station # 2 of the base station # 1 as the cell reselection parameter information determined based on the input information, and the base station # 2 And cell reselection parameter information for base station # 1.

Here, the load information of the base station # 1 and the load information of the base station # 2 may be detected by an arbitrary device, for example, may be detected by each of the base stations # 1 and # 2, Or it may be detected by a centralized server. Information on the result of the detection is output to the inter-base station load distribution apparatus 1 from the apparatus that performs such detection.
Alternatively, as another configuration example, the load information of the base station # 1 and the load information of the base station # 2 may be detected by the inter-base station load distribution apparatus of each of the base stations # 1 and # 2. For example, the inter-base station load distribution apparatus 1 may not input information detected by the inter-base station load distribution apparatus 1 from an external apparatus.

Also, handover parameter information for base station # 1 to base station # 2, handover parameter information for base station # 2 to base station # 1, and cell reselection parameter information for base station # 1 to base station # 2 And the cell reselection parameter information of the base station # 2 for the base station # 1 is stored by the base station # 1 and the base station # 2 as an example, and the inter-base station load from the base station # 1 or the base station # 2 It is output to the distribution device 1 and input to the inter-base station load distribution device 1.
As another example, information on handover parameters for base station # 2 of base station # 1 and information on cell reselection parameters for base station # 2 of base station # 1 are stored by base station # 1, and base station # 1 1 to the inter-base station load distribution apparatus 1 and input to the inter-base station load distribution apparatus 1, and information on handover parameters for the base station # 1 of the base station # 2 and the base station of the base station # 2 The information of the cell reselection parameter for # 1 is stored by the base station # 2, is output from the base station # 2 to the inter-base station load distribution apparatus 1, and is input to the inter-base station load distribution apparatus 1.

In addition, the cell reselection parameter information for the base station # 2 of the base station # 1 and the information of the cell reselection parameter for the base station # 1 of the base station # 2 which are information of the determined cell reselection parameters are examples. Are output from the inter-base station load distribution apparatus 1 to the base station # 1 and the base station # 2, and stored by the base station # 1 and the base station # 2.
As another example, information on the cell reselection parameter for the base station # 2 of the base station # 1, which is information on the determined cell reselection parameter, is output from the inter-base station load distribution apparatus 1 to the base station # 1. The cell reselection parameter information for the base station # 1 of the base station # 2 that is stored by the base station # 1 and is the determined cell reselection parameter information is transmitted from the inter-base station load balancer 1 to the base station It is output to # 2 and stored by the base station # 2.

  Here, in this embodiment, information of handover margin (# 1 → # 2) is used as information of handover parameters for base station # 2 of base station # 1, and handover of base station # 2 to base station # 1 is performed. Information on the handover margin (# 2 → # 1) is used as parameter information, and information on the cell reselection margin (# 1 → # 2) is used as information on the cell reselection parameter for the base station # 2 of the base station # 1. Information is used, and information on cell reselection margin (# 2 → # 1) is used as information on cell reselection parameters for base station # 1 of base station # 2.

Here, the handover margin (# 1 → # 2) represents the handover margin from the base station # 1 to the base station # 2.
The handover margin (# 2 → # 1) represents the handover margin from the base station # 2 to the base station # 1.
The cell reselection margin (# 1 → # 2) represents a cell reselection margin from the base station # 1 to the base station # 2.
The cell reselection margin (# 2 → # 1) represents a cell reselection margin from the base station # 2 to the base station # 1.

  In the present embodiment, information processed by the inter-base station load distribution apparatus 1 (cell reselection parameter determination unit 14 or the like) is represented by handover margin (# 1 → # 2), handover margin (# 2 → # 1). The cell reselection margin (# 1 → # 2) and the cell reselection margin (# 2 → # 1) will be described, and these indicate the set values used as the respective threshold values. The same applies to the equations (5) to (10).

With reference to FIG. 2 to FIG. 4, processing for determining a cell reselection parameter by the cell reselection parameter determination unit 14 according to the present embodiment will be described.
As an overview, the cell reselection parameter determination unit 14 according to the present embodiment is a method for realizing load balancing between base stations, and is a timing of standby station switching (cell reselection) of a mobile terminal in a standby state. Cell reselection so as to change the cell reselection timing of the mobile terminal according to the load status of the base station, with the timing of connection station switching (handover) of the mobile terminal in communication state as a constraint condition Determine the parameters. Thereby, in this embodiment, load distribution between base stations is implement | achieved, without degrading the performance of the handover of the mobile terminal in communication state.

First, the range in which the cell reselection timing that is limited by the handover timing can be changed will be described with reference to FIG.
FIG. 2 is a diagram illustrating an example of a hysteresis region of handover.
In FIG. 2, the horizontal axis represents the position of the mobile terminal between the base station # 1 and the base station # 2, and the vertical axis represents the received power level from the base station # 1 as the received power level from the base station. A graph showing a power characteristic 101 and a received power characteristic 102 from the base station # 2 is shown. Thereby, the received power level of the mobile terminal existing between the base station # 1 and the base station # 2 is schematically shown.

FIG. 2 also shows the handover margin (HO margin) from the base station # 2 to the base station # 1, the handover point P1 from the base station # 2 to the base station # 1, and the base station # 1 to the base station # 2. And a handover point P2 from the base station # 1 to the base station # 2.
Further, the region between the handover point P1 from the base station # 2 to the base station # 1 and the handover point P2 from the base station # 1 to the base station # 2 is a hysteresis region. In this hysteresis region, the mobile terminal can be connected to either the base station # 1 or the base station # 2. In this hysteresis region, when the mobile terminal is connected to one of the base stations # 1 and # 2, the mobile terminal previously connected until the handover point to the other base station is exceeded. Continue to connect to one base station.

  When handover timing is set between the base station # 1 and the base station # 2 as shown in FIG. 2, handover between base stations does not occur in the area indicated as the hysteresis area in FIG. The mobile terminal continues to connect to the base station connected earlier. The base station selected by the mobile terminal in the standby state and the base station to which the mobile terminal is connected after transition to the communication state are the same.

For this reason, by changing the cell reselection timing within the hysteresis region, the connected base station in the communication state of the mobile terminal can be switched according to the standby station in the standby state of the mobile terminal, and load balancing between base stations can be performed. Can be realized.
When cell reselection timing is set beyond the hysteresis region, a handover occurs immediately after the mobile terminal transitions from the standby state to the communication state, and the mobile terminal is different from the standby station in the standby state. Connect to the base station. As a result, it is considered that load distribution to the expected base station cannot be realized.

  In summary, the constraint conditions for the cell reselection parameters are expressed by the conditional expressions (5) and (6).

  The cell reselection parameter determination unit 14 according to the present embodiment uses the load information of the base station # 1 and the base station # 2, the information of each handover parameter and each cell reselection parameter as input information, and is a conditional expression. The cell reselection parameter is determined so as to change the cell reselection parameter within a range that satisfies the constraint conditions represented by Expression (5) and Expression (6).

Next, a method for determining a cell reselection parameter by the cell reselection parameter determination unit 14 according to the present embodiment (first embodiment) will be described with reference to FIG.
FIG. 3 is a diagram for explaining a method of determining a cell reselection parameter by the cell reselection parameter determination unit 14 according to the present embodiment.
FIG. 3 is a graph similar to that shown in FIG. 2, and further shows cell reselection margin (# 1 → # 2) and cell reselection when the load on base station # 1 is larger than the load on base station # 2. The set point P11 of the selection margin (# 2 → # 1) and the cell reselection margin (# 1 → # 2) and the cell reselection margin (# when the load on the base station # 2 is larger than the load on the base station # 1 The setting point P12 of 2 → # 1) is shown.

  Specifically, the cell reselection parameter determination unit 14 according to the present embodiment determines the magnitude relationship between the load of the base station # 1 and the load of the base station # 2, and the load of the base station # 1 is determined by the base station # 1. If it is determined that the load is larger than 2, the cell reselection parameter from the base station # 1 to the base station # 2 and the base station # 2 as shown in the equations (7) and (8) The parameter for cell reselection to base station # 1 is set according to the parameter for handover from base station # 2 to base station # 1.

  Conversely, the cell reselection parameter determination unit 14 according to the present embodiment determines the magnitude relationship between the load of the base station # 1 and the load of the base station # 2, and the load of the base station # 2 is determined by the base station # 1. When it is determined that the load is larger than the load, as shown in the equations (9) and (10), the cell reselection parameter from the base station # 2 to the base station # 1 and the base station # 1 to the base station The parameter for cell reselection to # 2 is set according to the parameter for handover from base station # 1 to base station # 2.

Next, with reference to FIG. 4, an example of a control processing procedure in the determination of the cell reselection parameter performed by the cell reselection parameter determination unit 14 according to the present embodiment will be described.
FIG. 4 is a flowchart illustrating an example of a control processing procedure in determining a cell reselection parameter performed by the cell reselection parameter determination unit 14 according to the present embodiment.
A series of processes shown in FIG. 4 (the process of step S1 to the process of step S4) are executed by the cell reselection parameter determination unit 14 at a certain cycle (for example, 1 hour), for example. Various cycles may be used as the fixed cycle.

In the example of FIG. 4, a predetermined threshold A is provided for the load in order to determine whether or not the base station is under high load, and in order to determine whether or not the base station is under low load. A predetermined threshold B is provided for the load.
Here, various values may be used as the thresholds A and B. For example, they are set in advance and stored in the storage unit 13 of the inter-base station load distribution apparatus 1. As an example, the threshold A is made larger than the threshold B, such that the threshold A is a value such as 60% of the maximum load, and the threshold B is a value such as 40% of the maximum load.

  Various values may be used as the load value of the base station. For example, the number of terminals connected to the base station, the usage rate of radio resources in the base station, and the usage rate of the CPU in the base station device Or a value of an evaluation index determined by any combination of two or more of these values can be used.

First, the cell reselection parameter determination unit 14 determines whether or not the first condition is satisfied for the load of the base station # 1 and the load of the base station # 2 (step S1).
Here, the first condition is expressed by Expression (11), and is set in advance, for example.

As a result of the determination in step S1, the cell reselection parameter determination unit 14 determines that the first condition is satisfied for the load of the base station # 1 and the load of the base station # 2, and the base station # The cell reselection timing is set from 1 to the base station # 2, and the cell reselection timing is set from the base station # 2 to the base station # 1 (step S2).
Specifically, in the process of step S2, the cell reselection parameter determination unit 14 sets the set value of the cell reselection timing from the base station # 1 to the base station # 2, as shown in Expression (7). Set according to the set value of the handover timing from the base station # 2 to the base station # 1.
In the process of step S2, the cell reselection parameter determination unit 14 sets the set value of the cell reselection timing from the base station # 2 to the base station # 1 as shown in the equation (8). 2. Set according to the set value of the handover timing from 2 to base station # 1.
After performing the process of step S2, the cell reselection parameter determination unit 14 ends the process of this flowchart.

  Here, in the present embodiment, in the process of step S2, the cell reselection parameter determination unit 14 sets the cell reselection timing from the base station # 1 to the base station # 2, and the base station # 2 Although the configuration for setting the cell reselection timing to the station # 1 has been described, for example, a configuration in which only one of these settings is set instead of the configuration in which both of these settings are performed may be used.

On the other hand, if the cell reselection parameter determination unit 14 determines that the first condition is not satisfied for the load of the base station # 1 and the load of the base station # 2 as a result of the determination in the process of step S1, It is determined whether or not the second condition is satisfied for the load of the base station # 1 and the load of the base station # 2 (step S3).
Here, the second condition is expressed by Expression (12), and is set in advance, for example.

As a result of the determination in the process of step S3, when the cell reselection parameter determination unit 14 determines that the second condition is satisfied for the load of the base station # 1 and the load of the base station # 2, the base station # The cell reselection timing is set from 2 to the base station # 1, and the cell reselection timing is set from the base station # 1 to the base station # 2 (step S4).
Specifically, in the process of step S4, the cell reselection parameter determination unit 14 sets the set value of the cell reselection timing from the base station # 2 to the base station # 1, as shown in Expression (9). Set according to the set value of the handover timing from the base station # 1 to the base station # 2.
In the process of step S4, the cell reselection parameter determination unit 14 sets the cell reselection timing set value from the base station # 1 to the base station # 2 as shown in the equation (10). Set according to the set value of the handover timing from 1 to base station # 2.
After performing the process of step S4, the cell reselection parameter determination unit 14 ends the process of this flowchart.

  Here, in the process of step S4, the cell reselection parameter determination unit 14 sets the cell reselection timing from the base station # 2 to the base station # 1, and also sets the cell reselection timing from the base station # 1 to the base station # 2. Although the configuration in which the cell reselection timing is set is described, for example, a configuration in which only one of these settings is set instead of the configuration in which both the settings are performed may be used.

  On the other hand, as a result of the determination in the process of step S3, the cell reselection parameter determination unit 14 determines that the second condition is not satisfied with respect to the load of the base station # 1 and the load of the base station # 2, The process of this flowchart is complete | finished.

  As described above, in the present embodiment, mobile radio that performs processing (in this embodiment, handover processing and cell reselection processing) to switch the mobile terminal connected to the base station according to the load status of the base station. In the inter-base station load distribution apparatus 1 in the communication system, the handover timing for the mobile terminal in the communication state is not changed, and the cell reselection timing (only) for the mobile terminal in the standby state is changed. The cell reselection parameter determination unit 14 determines a parameter related to cell reselection (cell reselection parameter) based on the load status of the base station.

  In the present embodiment, in the inter-base station load distribution apparatus 1, the cell reselection parameter determination unit 14 decreases the threshold for the cell reselection margin from the base station with a high load to the base station with a low load, It is determined that both increasing the threshold for cell reselection margin from a low base station to a heavily loaded base station is realized. As another configuration example, a configuration in which only one of these two is realized may be used.

  In the present embodiment, in the inter-base station load distribution apparatus 1, the value of the cell reselection margin from the base station having a high load to the base station having a low load is set as the handover margin from the base station having a low load to the base station having a high load. The value of the cell reselection margin from the base station with a low load to the base station with a high load is set to the value obtained by reversing the positive / negative sign of Do both to determine the margin value. Note that, as another configuration example, a configuration in which only one of these two is executed may be used.

As described above, the cell reselection parameter determination unit 1 in the inter-base station load distribution apparatus 1 according to the present embodiment changes the cell reselection timing of the mobile terminal in the standby state, thereby changing the mobile terminal in the communication state. Load distribution between base stations can be realized without degrading the performance of handover. Furthermore, the cell reselection parameter determination unit 1 in the inter-base station load distribution apparatus 1 according to the present embodiment limits the change range of the cell reselection timing according to the handover timing set for the mobile terminal in communication state. By doing so, it is possible to maximize the load distribution effect between base stations without causing extra handover.
As described above, in the mobile radio communication system according to the present embodiment, the load distribution among the base stations is distributed by dynamically switching the connection station and the standby station of the mobile terminal according to the load situation of the base station. Can be realized effectively.

[Second Embodiment]
Compared to the first embodiment, the configuration and operation of the mobile radio communication system according to this embodiment is such that cell reselection is performed by the cell reselection parameter determination unit 14 of the inter-base station load distribution apparatus 1 in the mobile radio communication system. It is the same except that the method for determining the parameter is different.
For this reason, in the present embodiment, differences from the first embodiment will be mainly described in detail. In the present embodiment, the same reference numerals as those shown in FIG. 1 according to the first embodiment are used.

  In the present embodiment, information processed by the inter-base station load distribution apparatus 1 (cell reselection parameter determination unit 14 or the like) is represented by handover margin (# 1 → # 2), handover margin (# 2 → # 1). The cell reselection margin (# 1 → # 2) and the cell reselection margin (# 2 → # 1) will be described, and these indicate the set values used as the respective threshold values. The same applies to the equations (13) to (16).

With reference to FIG. 5 to FIG. 6, processing for determining a cell reselection parameter by the cell reselection parameter determination unit 14 according to the present embodiment will be described.
As in the case of the first embodiment, the cell reselection parameter determination unit 14 according to this embodiment includes the load information of the base station # 1 and the base station # 2, the respective handover parameters, and the respective cell reselection parameters. Using the information as input information, the cell reselection parameter is determined so that the cell reselection parameter is changed within a range that satisfies the constraint conditions indicated by the conditional expressions (5) and (6).

A method for determining a cell reselection parameter by the cell reselection parameter determination unit 14 according to the present embodiment (second embodiment) will be described with reference to FIG.
FIG. 5 is a diagram for explaining a method of determining a cell reselection parameter by the cell reselection parameter determination unit 14 according to the present embodiment.
FIG. 5 is a graph similar to that shown in FIG. 2 and further shows the current cell reselection margin setting point P21.

When the load on the base station # 1 is larger than the load on the base station # 2, the cell reselection margin (# 1 → # 2) is decreased by n steps, and the cell reselection margin (# 2 → # 1) is n steps. increase. However, if the value of the changed cell reselection margin does not satisfy the expressions (5) and (6), the limit value is set to satisfy the expressions (5) and (6).
Further, when the load on the base station # 2 is larger than the load on the base station # 1, the cell reselection margin (# 1 → # 2) is increased by n steps, and the cell reselection margin (# 2 → # 1) is increased by n steps. Decrease. However, if the value of the changed cell reselection margin does not satisfy the expressions (5) and (6), the limit value is set to satisfy the expressions (5) and (6).
Here, n is an arbitrary natural number.

  Specifically, the cell reselection parameter determination unit 14 according to the present embodiment determines the magnitude relationship between the load of the base station # 1 and the load of the base station # 2, and the load of the base station # 1 is determined by the base station # 1. If it is determined that the load is larger than 2, the cell reselection parameter from the base station # 1 to the base station # 2 and the base station # 2 as shown in the equations (13) and (14) Set the cell reselection parameters for base station # 1.

Here, Expression (13) indicates that the value of the cell reselection margin (# 1 → # 2) is a value obtained by subtracting (n × step width) from the current value. Further, when the value of the result of the subtraction is smaller than the handover margin (# 2 → # 1), the expression (13) sets the value of the cell reselection margin (# 1 → # 2) to the handover margin (# 2 → # 1).
Expression (14) indicates that the value of the cell reselection margin (# 2 → # 1) is a value obtained by adding (n × step width) to the current value. Further, when the value of the result of the addition is larger than the handover margin (# 2 → # 1), the expression (14) sets the value of the cell reselection margin (# 2 → # 1) to the handover margin (# 2 → # 1).
In addition, in Formula (13) and Formula (14), * represents multiplication (x).

  Conversely, the cell reselection parameter determination unit 14 according to the present embodiment determines the magnitude relationship between the load of the base station # 1 and the load of the base station # 2, and the load of the base station # 2 is determined by the base station # 1. If it is determined that the load is larger than the load, as shown in the equations (15) and (16), the cell reselection parameter from the base station # 2 to the base station # 1 and the base station # 1 to the base station Set the parameter for cell reselection to # 2.

Here, Expression (15) indicates that the value of the cell reselection margin (# 2 → # 1) is set to a value obtained by subtracting (n × step width) from the current value. Further, when the value of the result of the subtraction is smaller than the handover margin (# 1 → # 2), the expression (15) indicates that the value of the cell reselection margin (# 2 → # 1) is −the handover margin (# 1 → # 2).
Expression (16) indicates that the value of the cell reselection margin (# 1 → # 2) is a value obtained by adding (n × step width) to the current value. Further, in the equation (16), when the value of the result of the addition is larger than the handover margin (# 1 → # 2), the value of the cell reselection margin (# 1 → # 2) is changed to the handover margin (# 1 → # 2). # 2).
In addition, in Formula (15) and Formula (16), * represents multiplication (x).

In the present embodiment, the value of n is the same and the value of the step width is the same in Equation (13), Equation (14), Equation (15), and Equation (16). In each of these expressions, a different n value may be used, or a different step width value may be used.
Various values may be used for the value of n and the value of the step width.

Next, with reference to FIG. 6, an example of a control processing procedure in determining a cell reselection parameter performed by the cell reselection parameter determination unit 14 according to the present embodiment will be described.
FIG. 6 is a flowchart illustrating an example of a control processing procedure in determining a cell reselection parameter performed by the cell reselection parameter determination unit 14 according to the present embodiment.
A series of processes shown in FIG. 6 (the process of step S11 to the process of step S14) are executed by the cell reselection parameter determination unit 14 at a predetermined cycle (for example, 1 hour), for example. Various cycles may be used as the fixed cycle.

In the example of FIG. 6, a predetermined threshold A is provided for the load in order to determine whether the base station is under a high load, and in order to determine whether the base station is under a low load. A predetermined threshold B is provided for the load.
Here, various values may be used as the thresholds A and B. For example, they are set in advance and stored in the storage unit 13 of the inter-base station load distribution apparatus 1. As an example, the threshold A is made larger than the threshold B, such that the threshold A is a value such as 60% of the maximum load, and the threshold B is a value such as 40% of the maximum load.

  Various values may be used as the load value of the base station. For example, the number of terminals connected to the base station, the usage rate of radio resources in the base station, and the usage rate of the CPU in the base station device Or a value of an evaluation index determined by any combination of two or more of these values can be used.

First, the cell reselection parameter determination unit 14 determines whether or not the first condition is satisfied for the load of the base station # 1 and the load of the base station # 2 (step S11).
Here, the first condition is expressed by Expression (11), and is set in advance, for example.

As a result of the determination in step S11, the cell reselection parameter determination unit 14 determines that the first condition is satisfied for the load of the base station # 1 and the load of the base station # 2, and the base station # The cell reselection timing is set from 1 to the base station # 2, and the cell reselection timing is set from the base station # 2 to the base station # 1 (step S12).
Specifically, in the process of step S12, the cell reselection parameter determination unit 14 sets the set value of the cell reselection timing from the base station # 1 to the base station # 2, as shown in Expression (13). Setting the handover timing from base station # 2 to base station # 1 as a constraint, the timing is set to be advanced by n steps.
Further, in the process of step S12, the cell reselection parameter determination unit 14 sets the set value of the cell reselection timing from the base station # 2 to the base station # 1 as shown in the equation (14). With the setting value of the handover timing from 2 to base station # 1 as a restriction, the timing is set to be delayed by n steps.
After performing the process of step S12, the cell reselection parameter determination unit 14 ends the process of this flowchart.

  Here, in the present embodiment, in the process of step S12, the cell reselection parameter determination unit 14 sets the cell reselection timing from the base station # 1 to the base station # 2, and the base station # 2 Although the configuration for setting the cell reselection timing to the station # 1 has been described, for example, a configuration in which only one of these settings is set instead of the configuration in which both of these settings are performed may be used.

On the other hand, when the cell reselection parameter determination unit 14 determines that the first condition is not satisfied for the load of the base station # 1 and the load of the base station # 2, as a result of the determination in the process of step S11, It is determined whether or not the second condition is satisfied for the load of the base station # 1 and the load of the base station # 2 (step S13).
Here, the second condition is expressed by Expression (12), and is set in advance, for example.

As a result of the determination in step S13, the cell reselection parameter determination unit 14 determines that the second condition is satisfied for the load of the base station # 1 and the load of the base station # 2, and the base station # The cell reselection timing is set from 2 to the base station # 1, and the cell reselection timing is set from the base station # 1 to the base station # 2 (step S14).
Specifically, in the process of step S14, the cell reselection parameter determination unit 14 sets the set value of the cell reselection timing from the base station # 2 to the base station # 1, as shown in Expression (15). Setting the setting value of the handover timing from the base station # 1 to the base station # 2 as a restriction, the timing is set to be advanced by n steps.
Further, in the processing of step S14, the cell reselection parameter determination unit 14 sets the set value of the cell reselection timing from the base station # 1 to the base station # 2 as shown in the equation (16). With the setting value of the handover timing from 1 to base station # 2 as a restriction, the timing is set to be delayed by n steps.
After performing the process of step S14, the cell reselection parameter determination unit 14 ends the process of this flowchart.

  Here, in the present embodiment, in the process of step S14, the cell reselection parameter determination unit 14 sets the cell reselection timing from the base station # 2 to the base station # 1, and from the base station # 1 to the base station # 1. Although the configuration for setting the cell reselection timing to the station # 2 has been described, for example, a configuration in which only one of these settings is set instead of the configuration in which both of these settings are performed may be used.

  On the other hand, as a result of the determination in the process of step S13, the cell reselection parameter determination unit 14 determines that the second condition is not satisfied for the load of the base station # 1 and the load of the base station # 2, The process of this flowchart is complete | finished.

  As described above, in the present embodiment, mobile radio that performs processing (in this embodiment, handover processing and cell reselection processing) to switch the mobile terminal connected to the base station according to the load status of the base station. In the inter-base station load distribution apparatus 1 in the communication system, the handover timing for the mobile terminal in the communication state is not changed, and the cell reselection timing (only) for the mobile terminal in the standby state is changed. The cell reselection parameter determination unit 14 determines a parameter related to cell reselection (cell reselection parameter) based on the load status of the base station.

  In the present embodiment, in the inter-base station load distribution apparatus 1, the cell reselection parameter determination unit 14 decreases the threshold for the cell reselection margin from the base station with a high load to the base station with a low load, It is determined that both increasing the threshold for cell reselection margin from a low base station to a heavily loaded base station is realized. As another configuration example, a configuration in which only one of these two is realized may be used.

In the present embodiment, in the inter-base station load distribution apparatus 1, the cell reselection parameter determination unit 14 predetermines a cell reselection margin from a base station with a high load to a base station with a low load with a predetermined step width. Both by a predetermined multiple, and by increasing a cell reselection margin from a lightly loaded base station to a heavily loaded base station by a predetermined multiple of a predetermined step width. Decide to be realized. In this case, the cell reselection parameter determination unit 14 sets the cell reselection margin from the connected base station to the adjacent base station to be equal to or less than the handover margin from the connected base station to the adjacent base station, and the adjacent base station. To a value that is greater than or equal to the value obtained by reversing the sign of the handover margin from the base station to the connected base station. As another configuration example, a configuration in which only one of these two is realized may be used.
Here, arbitrary values may be used as the respective step widths and the respective multiples as described above.

As described above, the cell reselection parameter determination unit 1 in the inter-base station load distribution apparatus 1 according to the present embodiment changes the cell reselection timing of the mobile terminal in the standby state, thereby changing the mobile terminal in the communication state. Load distribution between base stations can be realized without degrading the performance of handover. Furthermore, the cell reselection parameter determination unit 1 in the inter-base station load distribution apparatus 1 according to the present embodiment limits the change range of the cell reselection timing according to the handover timing set for the mobile terminal in communication state. By doing so, it is possible to maximize the load distribution effect between base stations without causing extra handover.
As described above, in the mobile radio communication system according to the present embodiment, the load distribution among the base stations is distributed by dynamically switching the connection station and the standby station of the mobile terminal according to the load situation of the base station. Can be realized effectively.

[Configuration example of the above embodiment]
Regarding the above embodiment, the base station has a plurality of cells, and clarified that handover and cell reselection are performed separately for each cell in a communication area <Configuration Example 1> to <Configuration Example 4>. Indicates.
The technical contents of these configuration examples are the same as those described in the above embodiment.
As a connected cell and an adjacent cell, for example, not only when a cell of a different base station is used as a connected cell and an adjacent cell, but also when a different cell of the same base station is used as a connected cell and an adjacent cell Good.

<Configuration example 1>
Based on the load status of the cell (for each cell) of the base station, with the cell reselection timing targeted for the mobile terminal in the standby state as the change target, without changing the handover timing for the mobile terminal in the communication state, A load distribution apparatus comprising a cell reselection parameter determination unit that determines a parameter related to cell reselection.

<Configuration example 2>
The cell reselection parameter determination unit reduces a threshold for a cell reselection margin from a cell of a base station having a high load to a cell of a base station having a low load, and a base having a high load from a cell of a base station having a low load. A load distribution apparatus according to <Configuration Example 1>, characterized in that the threshold for the cell reselection margin to the cell of the station is increased and one or both of the thresholds are determined. It is.
Here, the cell of the base station with a high load and the cell of the base station with a low load may be, for example, cells of different base stations or different cells of the same base station.
It also reduces the threshold for cell reselection margins from a base station cell with a high load to a base station cell with a low load, and a cell re-selection from a base station cell with a low load to a base station cell with a high load. For example, an aspect in which only one of predetermined ones is realized as an aspect in which one or both of the threshold for the selection margin is increased and that is realized is used. Well, or an aspect that allows both to be realized may be used.

<Configuration example 3>
The cell reselection parameter determination unit determines a cell reselection margin value from a base station cell having a high load to a base station cell having a low load from a cell having a low load to a cell having a high load. The value of the cell reselection margin from the low-load base station cell to the high-load base station cell to the base-station cell with a low load. The load described in <Configuration Example 1> or <Configuration Example 2>, wherein one or both of determining a handover margin value to a cell of a base station having a high load from A dispersion device.
Here, the cell of the base station with a high load and the cell of the base station with a low load may be, for example, cells of different base stations or different cells of the same base station.
Also, the cell reselection margin value from the base station cell having a high load to the base station cell having a low load is set to the positive / negative sign of the handover margin from the base station cell having a low load to the base station cell having a high load. And the cell reselection margin value from the base station cell with a low load to the base station cell with a high load is set to the value of the base station with a high load from the base station cell with a low load. As a mode of executing one or both of determining the value of the handover margin to the cell, for example, a mode of executing only any one of predetermined may be used, or both A mode of performing the above may be used.

<Configuration example 4>
The cell reselection parameter determination unit reduces a cell reselection margin from a cell with a high load to a cell with a low load by a predetermined multiple of a predetermined step width, One or both of increasing a cell reselection margin from a low base station cell to a high load base station cell by a predetermined multiple of a predetermined step width In this case, the cell reselection margin from the connected cell to the adjacent cell is equal to or less than the handover margin from the connected cell to the adjacent cell and the handover margin from the adjacent cell to the connected cell. The load distribution device according to <Configuration Example 1> or <Configuration Example 2>, wherein the load is limited to a value that is greater than or equal to a value obtained by reversing the positive and negative signs. It is.
Here, the cell of the base station with a high load and the cell of the base station with a low load may be, for example, cells of different base stations or different cells of the same base station.
Similarly, the connected cell and the adjacent cell may be, for example, cells of different base stations or different cells of the same base station.
In addition, the cell reselection margin from the high load base station cell to the low load base station cell is reduced by a predetermined multiple of a predetermined step width, and the low load base station cell As an aspect in which one or both of increasing a cell reselection margin to a cell of a high load base station by a predetermined multiple of a predetermined step width is realized, for example, A mode in which only one of predetermined ones is realized may be used, or a mode in which both are realized may be used.

[Summary of the above embodiments]
As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, the concrete structure is not restricted to this embodiment, The design change etc. of the range which does not deviate from the summary of this invention are included.

  Further, a program for realizing the function of each device according to each embodiment described above (for example, the function of the inter-base station load distribution device 1 or the like) is recorded on a computer-readable recording medium, and this recording medium Processing may be performed by causing the computer system to read and execute the program recorded in the above.

The “computer system” mentioned here may include an operating system (OS) and hardware such as peripheral devices.
The “computer-readable recording medium” means a flexible disk, a magneto-optical disk, a ROM (Read Only Memory), a writable nonvolatile memory such as a flash memory, a portable medium such as a DVD (Digital Versatile Disk), A storage device such as a hard disk built in a computer system.

Further, the “computer-readable recording medium” refers to a volatile memory (for example, DRAM (DRAM) inside a computer system that becomes a server or a client when a program is transmitted through a network such as the Internet or a communication line such as a telephone line. Dynamic Random Access Memory)) that holds a program for a certain period of time is also included.
The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting a program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line.
Further, the above program may be for realizing a part of the functions described above.
Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.

DESCRIPTION OF SYMBOLS 1 ... Inter-base-station load distribution apparatus, 11 ... Input part, 12 ... Output part, 13 ... Memory | storage part, 14 ... Cell reselection parameter determination part, 101, 102 ... Characteristic, P1, P2, P11, P12, P21 ... Point , 1001, 1002 ... characteristics, 1011-1, 1011-2, 1101, 1102, 1201-1, 1201-2 ... mobile terminal,

Claims (5)

Based on the cell load status of the base station, the cell reselection timing is targeted for the cell reselection timing for the mobile terminal in the standby state without changing the handover timing for the mobile terminal in the communication state. includes a cell reselection parameter determining section for determining a parameter related,
The cell reselection parameter determination unit determines a cell reselection margin value from a base station cell having a high load to a base station cell having a low load from a cell having a low load to a cell having a high load. The value of the cell reselection margin from the low-load base station cell to the high-load base station cell to the base-station cell with a low load. Determining one or both of determining a handover margin value from a cell to a heavily loaded base station cell,
A load balancer. Based on the cell load status of the base station, the cell reselection timing is targeted for the cell reselection timing for the mobile terminal in the standby state without changing the handover timing for the mobile terminal in the communication state. A cell reselection parameter determination unit for determining parameters relating to
The cell reselection parameter determination unit determines whether the base station has a low load from a base station cell having a high load.
The cell reselection margin to the cell is determined with a predetermined step width.
Multiples and cells from a base station cell with a low load to a base station cell with a high load
Increase reselection margin by a predetermined multiple of a predetermined step width
And, in this case, the connection
Cell reselection margin from the connected cell to the adjacent cell
And the margin of handover from the neighboring cell to the connected cell
Restrict to more than the value obtained by reversing the sign of the sign.
A load balancer. The cell reselection parameter determination unit reduces a threshold for a cell reselection margin from a cell of a base station having a high load to a cell of a base station having a low load, and a base having a high load from a cell of a base station having a low load. Determining that one or both of increasing a threshold for cell reselection margin to the cell of the station is realized;
The load distribution apparatus according to claim 1 or 2 , wherein The cell reselection parameter determination unit does not change the handover timing for the mobile terminal in the communication state, but changes the cell reselection timing for the mobile terminal in the standby state to change the cell load of the base station. Based on the situation, determine the parameters for cell reselection ,
The cell reselection parameter determination unit determines a cell reselection margin value from a base station cell having a high load to a base station cell having a low load from a cell having a low load to a cell having a high load. The value of the cell reselection margin from the low-load base station cell to the high-load base station cell to the base-station cell with a low load. Determining one or both of determining a handover margin value from a cell to a heavily loaded base station cell,
A load balancing method characterized by the above. The cell reselection parameter determination unit does not change the handover timing for the mobile terminal in the communication state, but changes the cell reselection timing for the mobile terminal in the standby state to change the cell load of the base station. A load balancing program for causing a computer to execute a step of determining parameters related to cell reselection based on a situation ,
The cell reselection parameter determination unit determines a cell reselection margin value from a base station cell having a high load to a base station cell having a low load from a cell having a low load to a cell having a high load. The value of the cell reselection margin from the low-load base station cell to the high-load base station cell to the base-station cell with a low load. Determining one or both of determining a handover margin value from a cell to a heavily loaded base station cell,
A load balancing program characterized by that .

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