KR20180001049A - Method and system for controlling cell coverage - Google Patents

Abstract

The present invention relates to a method and a system for controlling a cell coverage on the basis of a normalized power headroom and a path loss. According to an embodiment of the present invention, the system for controlling a cell coverage comprises: a database for storing a report collected through each mobile terminal located in a cell; a sample selection unit for analyzing a plurality of reports stored in the database to select a normalized power headroom sample value and a path loss sample value of the cell; and a coverage adjusting unit for determining whether to adjust the cell coverage on the basis of the selected normalized power headroom sample value and the path loss sample value, and performing a change in an angle of an antenna of a base station for forming the cell when an adjustment of the cell coverage is required.

Description

[0001] The present invention relates to a cell coverage control method and system,

The present invention relates to a technique for controlling cell coverage, and more particularly, to a method and system for controlling cell coverage based on normalized power headroom and pathloss.

In a conventional mobile communication system, a plurality of base stations forming a radio link with a mobile terminal are installed, and such base stations form a certain coverage. The base station forms a downlink coverage used in the downlink and an uplink coverage used in the uplink. The following patent document discloses a base station coverage control apparatus.

In order to improve the quality of the mobile communication service, the service providers monitor the quality of the cell coverage of the base station. However, since it is difficult to precisely motorize the uplink coverage formed by the base station, the mobile communication providers monitor the downlink coverage only and measure the quality of the cell coverage of the base station.

However, the resources used in the downlink of the base station are sufficient, but the resources used in the uplink are in short compared with the downlink resources. On the other hand, uplink signals are frequently generated in the currently installed LTE communication network, and quality improvement for uplink coverage is required.

Korean Patent Publication No. 10-2000-0061282

It is an object of the present invention to provide a cell coverage control method and system for optimizing cell coverage by maintaining a balance between uplink coverage and downlink coverage.

Other objects and advantages of the present invention will become apparent from the following description, and it will be understood by those skilled in the art that the present invention is not limited thereto. It will also be readily apparent that the objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.

According to a first aspect of the present invention, there is provided a system for controlling cell coverage, comprising: a database for storing a report collected through each mobile terminal located in a cell; Analyzing a plurality of reports stored in the database to select a normalized power headroom sample value and a path loss sample value of the cell; And a coverage adjustment unit for determining whether to adjust the coverage of the cell based on the selected normalized power headroom sample value and path loss sample value and for adjusting the angle of the base station antenna forming the cell when adjustment of the cell coverage is required .

According to a second aspect of the present invention, there is provided a method of controlling cell coverage by changing antenna angles in a cell coverage control system, comprising: extracting a plurality of reports stored in a database; analyzing the extracted plurality of reports; Selecting a normalized power headroom sample value and a path loss sample value of the cell; Determining whether the coverage of the cell is adjusted based on the selected normalized power headroom sample value and path loss sample value; And adjusting the angle of the base station antenna forming the cell if the cell coverage needs to be adjusted as a result of the determination.

The present invention is based on the selection of path loss and normalized power headroom values that occur in cell coverage, and the quality of the uplink coverage is determined based on the sampled values to adjust the uplink coverage, thereby maintaining a balance between the uplink coverage and the downlink coverage There are advantages.

In addition, the present invention analyzes a report received from a mobile terminal and performs handover of the mobile terminal when the normalized power headroom of the mobile terminal is less than a threshold value, thereby performing cell load balancing, There is an advantage that the quality of the service can be improved.

Further, by optimizing the cell coverage of the present invention, the quality of the mobile communication service is further improved.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention. And shall not be construed as limited to such matters.
1 is a diagram of a communication system, in accordance with an embodiment of the present invention.
2 is a diagram showing a configuration of a coverage control system according to an embodiment of the present invention.
3 is a diagram illustrating a management table according to an embodiment of the present invention.
4 is a flow diagram illustrating a method for adjusting cell coverage based on normalized power headroom and path loss in a cell coverage system, in accordance with an embodiment of the present invention.
5 is a flowchart illustrating a method for controlling handover of a mobile station based on a normalized power headroom in a cell coverage system according to an embodiment of the present invention.

The foregoing and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, in which: There will be. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram of a communication system, in accordance with an embodiment of the present invention.

As shown in FIG. 1, a communication system according to an embodiment of the present invention includes a coverage control system 200, a plurality of base stations 310 and 320, and a plurality of mobile terminals 110.

The base stations 310 and 320 include one or more antennas as a base station transceiver subsystem (BTS), a NodeB, an evolved NodeB (e-NodeB), and a femto base station, and form cell coverage using the at least one antenna . Each of the base stations 310 and 320 may form one or more cells having a constant frequency band. That is, the same base station 310 may have a plurality of antennas, and a plurality of cells may be formed through each antenna. In addition, each cell formed through the base station 310 has unique identification information (i.e., PCI: Physical Cell Identity).

In this case, the angles of the antennas included in the base stations 310 and 320 may be controlled by the coverage control system 200. For example, Lt; / RTI >

The base stations 310 and 320 form an uplink or a downlink with a mobile terminal 110 located in a cell coverage. The base stations 310 and 320 form uplink coverage for the uplink and downlink coverage for the downlink. The downlink (forward link) refers to the communication link from the base station to the terminal, and the uplink (reverse link) refers to the communication link from the terminal to the base station

In particular, the base stations 310 and 320 may instruct the mobile terminal 110 to transmit a report and receive a report including a power headroom from the mobile terminal 110. In another embodiment, the base stations 310, 320 may receive reports from the mobile terminal 110 that include power headroom, normalized power headroom, and path loss. The power headroom, the normalized power headroom, and the path loss may be recorded in a MAC Control Element included in the MAC layer. Here, the power headroom may be referred to as residual power, surplus power, or the like as a difference between the maximum transmission power (P _CMAX ) set in the UE and the PUSCH (Physical Uplink Shared CHannel). In addition, the normalized power headroom is a value calculated by fixing the number of resource blocks to a preset value.

The normalized power headroom and path loss may be recorded in an extended data field in an existing MAC control element. The base stations 310 and 320 transmit the report to the coverage control system 200 when the report is received from the mobile terminal 110. When requesting the report to the mobile terminal 110, the base stations 310 and 320 may set the parameters for the power headroom calculation and provide the parameter to the mobile terminal 110.

The mobile terminal 110 transmits data to the base stations 310 and 320 in an uplink communication with the base stations 310 and 320 or receives data from the base stations 310 and 320 by downlink communication with the base stations 310 and 320 . When a report is requested from the base stations 310 and 320, the mobile terminal 110 uses parameters provided from the base stations 310 and 320 to calculate a power headroom PH (Power Headroom), and transmits the report including the power headroom to the base stations 310 and 320.

The mobile terminal 110 calculates power headroom using Equation (1) below.

PH (i): Power Headroom

P _CMAX : maximum power of mobile terminal

M _PUSCH (i): number of resource blocks allocated to a subframe

_{O_} P _PUSCH (j): parameter which consists of the sum _{O_NOMINAL_} P _PUSCH (j) of the serving cell

α (j): path loss compensation factor

PL: Downlink path loss calculated in the mobile terminal

이다. 여기서, K_s는 각 서빙셀 c에 대하여 상위계층에서 deltaMCS-Enabled으로 제공되는 파라미터이며 1.25 또는 0이다. DELTA _TF (i) is a parameter for reflecting the influence of a modulation coding scheme (MCS)

to be. Here, K _s is a parameter provided as deltaMCS-Enabled in the upper layer for each serving cell c and is 1.25 or 0. [

f (i): the correction value of the mobile terminal defined in response to the scheduling

Using Equation (1), when the mobile terminal calculates the power headroom, the power headroom is changed by the resource block. That is, even if the mobile terminal 110 is located in the same area, the power headroom varies depending on the number of resource blocks in use. Therefore, a normalized power headroom is required to understand the state of uplink coverage based on the power headroom.

The normalized power headroom fixes a predetermined number of resource blocks and calculates a normalized power headroom in the mobile terminal 110 or the coverage control system 200. The normalized power headroom is utilized for controlling the uplink coverage do.

That is, in the coverage control system 200, the state of the upward coverage is grasped by using the normalized power headroom.

Equation (2) below is a mathematical expression for calculating a normalized power headroom (Normailized PH) used when there is one resource block.

The mobile terminal 110 calculates the normalized power headroom by fixing the number of resource blocks to one, and then transmits a report including the normalized power headroom, path loss, and power headroom to the base stations 310 and 320 . That is, the mobile terminal 110 may additionally record the path loss and the normalized power headroom in the report, and transmit the report.

Meanwhile, the mobile terminal 110 can perform a handover to the neighboring cell upon receiving a handover instruction.

The coverage control system 200 controls the cell coverage of the base stations 310 and 320 and controls the handover of the mobile terminal 110. In particular, the coverage control system 200 analyzes the accumulated report to determine whether to change the antenna angle of the cell.

2 is a diagram showing a configuration of a coverage control system according to an embodiment of the present invention.

2, a coverage control system 200 according to an exemplary embodiment of the present invention includes a database 210, a data collection unit 220, a sample selection unit 230, a coverage adjustment unit 240, (250), which may be implemented in hardware or software, or a combination of hardware and software.

The data collection unit 220, the sample selection unit 230, the coverage adjustment unit 240, and the handover control unit 250 may include a memory and one or more processors, And may be implemented in the form of a program executed by the one or more processors. In addition, the coverage control system 200 may be implemented integrally with the base stations 310 and 320.

The database 210 is a storage device such as a storage device, a network-attached storage device, a storage device including a cloud computing system, and the like. The database 210 stores reports sent from a plurality of mobile terminals 110 by cell. In addition, the database 210 stores a management table to which path loss, normalized power headroom, and antenna angle are mapped. The management table may be stored in the database 210 in a plurality of ways depending on the antenna model or use.

3 is a diagram illustrating a management table according to an embodiment of the present invention.

Referring to FIG. 3, a path loss 31, a normalized power headroom 32, and an antenna change angle 33 are mapped and recorded in the management table.

The range of the path loss is recorded in the path loss 31, the range of the normalized power headroom is recorded in the normalized power headroom 32, and the direction of the antenna angle to be changed is recorded in the antenna change angle 33 . According to the management table of FIG. 3, the cell coverage determined to be equal to or greater than the A1 value and less than the A2 value, the normalized power headroom exceeding the B1 value and less than B2, have.

When the antenna angle is increased, the upward coverage is enlarged, and when the antenna angle is lowered, the upward coverage is reduced. In addition, the pathloss and normalized power headroom mapped to the antenna elevation angle indicate that the resources of the uplink coverage are sufficient, indicating that uplink coverage can be extended. Also, the path loss and the normalized power headroom mapped to the antenna fall angle indicate that the resources of the uplink coverage are insufficient, thereby indicating that downlink coverage needs to be reduced.

The data collection unit 220 receives the report of the mobile terminal 110 from the base stations 310 and 320 and stores the report in the database 210. The data collecting unit 220 may identify the cell identification information in which the report is generated, map the report to the cell identification information, store the report in the database 210, and store the report in the database 210 .

Data acquisition unit 220, a parameter (i. E., M _PUSCH (i), P _{O_ PUSCH} (j) for the case that does not include the normalized power headroom and the path loss to the report, the calculation of the normalized power headroom, α (j), Δ _TF (i), obtaining f (i)), and the reports and the parameters can be stored together in the database 210.

The sample selection unit 230 extracts a report included in the database 210 when the analysis period arrives and selects a normalized power headroom sample value and a path loss sample value for each cell. In one embodiment, the sample selection unit 230 classifies and extracts the reports included in the database 210 by cell, calculates the average of the normalized power headroom and path loss included in the extracted report, The average value of the room can be selected as the normalized power headroom sample value and the path loss average value can be selected as the path loss sample value to select the sample value of each cell. In another embodiment, the sample selection unit 230 classifies and extracts the reports included in the database 210, and then calculates a path loss having the largest value among the path loss included in the report and the normalized power headroom as the path loss The normalized power headroom with the largest value and selected as the sample value can be selected as the normalized power headroom sample value.

When the normalized power headroom and the path loss are not recorded in the report, the sample selection unit 230 sets the parameters mapped with the report to a mathematical expression (for example, Equation 2) for calculating the normalized power headroom You can calculate the normalized power headroom by substituting it, and you can check the path loss by inverting the power headroom included in the report.

On the other hand, the sample selection unit 230 performs report filtering when the power headroom repeatedly transmitted or normalized to the same mobile terminal 110 is out of the specified range among the extracted reports, and analyzes the report Can be excluded. The sample selection unit 230 selects one of the plurality of reports for a specific cell

If the number of reports in which the same path loss value is recorded is less than or equal to a preset threshold number, it can be determined that the report is invalid and the report can be excluded from the analysis. The sample selection unit 230 groups a plurality of reports for a specific cell into reports having the same path loss value, counts the number of reports belonging to each group by group, And if there is a group, it can be determined that the report belonging to the group is an invalid report, and the report of the group can be excluded from the analysis target. In addition, the sample selection unit 230 groups a plurality of reports for a specific cell into reports having the same normalized power headroom value, counts the number of reports belonging to each group by group, It is judged that the report belonging to the group is an invalid report, and the report of the group can be excluded from the analysis target.

The coverage adjustment unit 240 determines whether or not the cell coverage needs to be adjusted and performs a function of enlarging or reducing the cell coverage of the base station. That is, the coverage adjustment unit 240 checks the normalized power headroom sample value and the path loss sample value selected by the sample selection unit 230, and calculates the antenna change angle corresponding to the normalized power headroom sample value and the path loss sample value And confirms it in the management table of the database 210. The coverage adjustment unit 240 starts a procedure for changing the base station antenna that is responsible for the cell, corresponding to the antenna change angle determined in the management table. If the antenna change angle determined in the management table is "no change", the coverage adjustment unit 240 does not change the angle of the base station antenna that is responsible for the cell. Also, when the antenna change angle confirmed in the management table is ascertained at the rising angle, the coverage adjustment unit 240 determines that the resources are sufficient for the upward coverage of the corresponding cell, and increases the antenna angle for the cell to increase the upward coverage do. When the antenna change angle confirmed in the management table is ascertained as the falling angle, the coverage adjustment unit 240 determines that the resources are insufficient for the upward coverage of the corresponding cell, so that the angle of the antenna responsible for the cell is lowered so that the upward coverage is reduced .

When the antenna of the cell is a remotely controllable antenna, the coverage adjusting unit 240 remotely controls the antenna to change the antenna angle to a change angle determined in the management table. In addition, when the antenna of the base station is a remote controllable antenna, the coverage adjusting unit 240 provides information to the operator or the base station controller indicating that the antenna angle is required to be changed.

The handover control unit 250 monitors the report collected by the data collection unit 220 and determines a handover of the mobile terminal 110 that generated the report. Specifically, the handover control unit 250 checks the normalized power headroom based on the report collected by the data collection unit 220. If the normalized power headroom is not recorded in the report, the handover control unit 250 calculates a parameter mapped to the report in the data collection unit 220 according to a formula (for example, equation 2) to identify the normalized power headroom. The handover control unit 250 determines whether the normalized power headroom is below a predetermined threshold or not, and if the normalized power headroom is below a predetermined threshold, the handover controller 250 proceeds with the handover of the mobile terminal 110. At this time, the handover controller 250 checks neighboring cells detected by the mobile terminal 110 (i.e., cells surrounding the serving cell), checks the latest normalized power headroom average value for the neighboring cells, A cell having the highest average value among the power headroom average values may be determined as a target cell and a message instructing handover to the target cell may be transmitted to the mobile terminal 110.

4 is a flow diagram illustrating a method for adjusting cell coverage based on normalized power headroom and path loss in a cell coverage system, in accordance with an embodiment of the present invention.

In the description with reference to FIGS. 4 and 5, it is assumed that the normalized power headroom and the path loss are recorded in the report prepared by the mobile terminal.

Referring to FIG. 4, the sample selection unit 230 monitors whether or not a predetermined analysis period has arrived, and when an analysis period comes (S401), the sample selection unit 230 extracts a plurality of reports for a specific cell from the database 210 S403).

Next, the sample selection unit 230 analyzes the normalized power headroom and path loss included in each of the extracted reports, and calculates a sample value of the normalized power headroom and a sample value of path loss (S405). In one embodiment, the sample selection unit 230 calculates the average of the normalized power headroom and the path loss included in the extracted report, selects the normalized power headroom average value as the normalized power headroom sample value, Path loss sample value. As another example, the sample selection unit 230 may select the path loss having the largest value among the path loss included in the extracted reports and the normalized power headroom as the path loss sample value, The room can be selected as the normalized power headroom sample value.

The sample selection unit 230 groups the extracted plurality of reports into reports having the same path loss value, counts the number of reports belonging to each group by group, and sets the number of reports having a predetermined number of thresholds or less If the group exists, it is determined that the report belonging to the group is an invalid report, and the report of the group can be excluded from the analysis. In addition, the sample selection unit 230 groups the extracted plurality of reports into reports having the same normalized power headroom value, counts the number of reports belonging to each group by group, and outputs a report with a preset threshold number or less It is judged that the report belonging to the group is not valid and the report of the group can be excluded from the analysis target.

When the sample selection unit 230 finishes selecting a sample value, the coverage adjustment unit 240 determines whether the normalized power headroom sample value belongs to a preset normal range or not. When the normalized power headroom sample value is out of the predetermined range, the coverage adjustment unit 240 determines that a failure has occurred in the corresponding cell and outputs cell check information to induce the manager or the staff member to proceed with the cell check (S413).

On the other hand, if the normalized power headroom sample value includes a preset normal range, the coverage adjustment unit 240 may adjust the antenna change angle corresponding to the normalized power headroom sample value and the path loss sample value to the database 210 In the management table (S409).

Subsequently, the coverage adjusting unit 240 changes the antenna of the base station in charge of the corresponding cell in accordance with the antenna change angle confirmed in the management table (S411). At this time, the coverage adjustment unit 240 maintains the antenna angle as it is confirmed in the management table that the antenna change angle is not changed. On the other hand, if the coverage adjustment unit 240 confirms that the antenna change angle is changed in the management table, the procedure proceeds to the step of adjusting the cell coverage by changing the antenna angle.

If the antenna change angle determined in the management table is "no change", the coverage adjustment unit 240 does not change the angle of the base station antenna that is responsible for the cell. Also, when the antenna change angle confirmed in the management table is ascertained at the rising angle, the coverage adjustment unit 240 determines that the resources are sufficient for the upward coverage of the corresponding cell, and increases the antenna angle for the cell to increase the upward coverage do. When the antenna change angle confirmed in the management table is ascertained as the falling angle, the coverage adjustment unit 240 determines that the resources are insufficient for the upward coverage of the corresponding cell, so that the angle of the antenna responsible for the cell is lowered so that the upward coverage is reduced .

The coverage adjustment unit 240 remotely changes the angle of the antenna to the change angle when the antenna responsible for the cell is a remotely controllable antenna. In addition, when the antenna of the base station is a remote controllable antenna, the coverage adjusting unit 240 provides information to the operator or the base station controller indicating that the antenna angle is required to be changed.

5 is a flowchart illustrating a method for controlling handover of a mobile station based on a normalized power headroom in a cell coverage system according to an embodiment of the present invention.

5, the data collection unit 220 receives the report generated by the mobile terminal 110 from the base stations 310 and 320 and stores the received report in the database 210 (S501).

Then, the handover control unit 250 checks the normalized power headroom included in the report on which the report is collected (S503). Then, the handover control unit 250 determines whether the normalized power headroom is equal to or less than a preset threshold value (i.e., the handover threshold value), and if the normalized power headroom is below the threshold value, It is determined that a problem occurs in forming uplinks with the base stations 310 and 320 and handover of the mobile terminal 110 is determined (S505). Next, the handover control unit 250 checks neighboring cells located in the vicinity of the mobile terminal 110, and checks the average normalized power headroom for each neighboring cell (S507, S509). At this time, the handover controller 250 requests the measurement of the neighboring cell from the mobile terminal 110 and receives one or more neighbor cell identification information (i.e., PCI) measured by the mobile terminal 110 from the mobile terminal 110 (E.g., a normalized power headroom average value of a neighbor cell recently calculated by the sample selector) for this neighboring cell.

Next, the handover control unit 250 selects a cell having the highest average value among the power headroom average values as a target cell (S511), and transmits a message instructing handover to the target cell to the mobile terminal 110 The handover of the terminal 110 is induced (S513). Accordingly, the mobile terminal 110 performs handover from the current cell to the target cell, and receives the mobile communication service through the target cell.

As described above, the cell coverage control system 200 according to the embodiment of the present invention confirms the path loss occurring in the cell coverage and the sampled values of the normalized power headroom, and determines the quality of the uplink coverage based on the sampled values By balancing uplink coverage, we maintain a balance between uplink coverage and downlink coverage. The cell coverage control system 200 according to an exemplary embodiment of the present invention analyzes a report received from the mobile terminal 110 and determines whether the normalized power headroom of the mobile terminal 110 is less than a threshold value, The cell load balancing can be performed and the quality of service provided to the mobile terminal 110 can be improved.

While the specification contains many features, such features should not be construed as limiting the scope of the invention or the scope of the claims. In addition, the features described in the individual embodiments herein may be combined and implemented in a single embodiment. Conversely, various features described in the singular < Desc / Clms Page number 5 > embodiments herein may be implemented in various embodiments individually or in combination as appropriate.

Although the operations have been described in a particular order in the figures, it should be understood that such operations are performed in a particular order as shown, or that all described operations are performed to obtain a sequence of sequential orders, or a desired result . In certain circumstances, multitasking and parallel processing may be advantageous. It should also be understood that the division of various system components in the above embodiments does not require such distinction in all embodiments. The above-described program components and systems can generally be implemented as a single software product or as a package in multiple software products.

The method of the present invention as described above can be implemented by a program and stored in a computer-readable recording medium (CD-ROM, RAM, ROM, floppy disk, hard disk, magneto optical disk, etc.). Such a process can be easily carried out by those skilled in the art and will not be described in detail.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. The present invention is not limited to the drawings.

110: mobile terminal 200: coverage control system
210: database 220: data collection unit
230: sample selection unit 240: coverage adjustment unit
250: handover control unit 310, 320:

Claims (12)

A system for controlling cell coverage,
A database for storing a report collected through each mobile terminal located in a cell;
Analyzing a plurality of reports stored in the database to select a normalized power headroom sample value and a path loss sample value of the cell; And
Determining whether to adjust the coverage of the cell based on the selected normalized power headroom sample value and path loss sample value and proceeding to change the angle of the base station antenna forming the cell when adjustment of cell coverage is required; A coverage control system comprising: The method according to claim 1,
The above-
Wherein the controller determines an antenna change angle corresponding to the normalized power headroom sample value and the path loss sample value and proceeds to change the angle of the base station antenna to match the antenna change angle. 3. The method of claim 2,
The above-
Wherein the base station antenna is remotely controlled to change the angle. 4. The method according to any one of claims 1 to 3,
Wherein the normalized power headroom is fixed in a predetermined number of resource blocks. 4. The method according to any one of claims 1 to 3,
The sample-
Determining a normalized power headroom and a path loss for each report and selecting an average value of the power headroom as the power headroom sample value and selecting the determined path loss average value as the path loss sample value, Coverage control system. 4. The method according to any one of claims 1 to 3,
The sample-
A normalized power headroom and a path loss for each report are checked and a power headroom having a largest value among the identified power headroom is selected as the power headroom sample value and a path having the largest value among the determined path losses And the loss is selected as the path loss sample value. 4. The method according to any one of claims 1 to 3,
A handover decision unit for confirming a normalized power headroom based on the report and generating a handover of the specific mobile terminal if the determined normalized power headroom is less than a preset threshold value when a report generated by a specific mobile terminal is received; Further comprising the step of: 8. The method of claim 7,
Wherein the handover determination unit comprises:
Determining a neighboring cell having a highest power headroom average value among neighboring cells as a target cell and proceeding with a handover to the target cell by checking a neighboring cell around a serving cell in which the specific mobile terminal is located, system. A method of controlling cell coverage by changing antenna angles in a cell coverage control system,
Extracting a plurality of reports stored in a database and analyzing the extracted plurality of reports to select a normalized power headroom sample value and a path loss sample value of the cell;
Determining whether the coverage of the cell is adjusted based on the selected normalized power headroom sample value and path loss sample value; And
And when the cell coverage needs to be adjusted as a result of the determination, changing the angle of the base station antenna forming the cell is performed. 10. The method of claim 9,
The step of changing the angle includes:
Determining an antenna change angle corresponding to the normalized power headroom sample value and the path loss sample value and proceeding to change the angle of the base station antenna to match the antenna change angle. 11. The method according to claim 9 or 10,
Confirming the normalized power headroom based on the report when the report generated by the specific mobile terminal is received; And
And proceeding with handover of the mobile station if the normalized power headroom is less than a preset threshold value. 12. The method of claim 11,
The step of performing the handover includes:
Determining a neighboring cell having a highest power headroom average value among neighboring cells as a target cell and proceeding with handover to the target cell by checking a neighboring cell around the serving cell in which the specific mobile terminal is located, Control method.

Images