KR101093220B1 - Interference coordination apparatus between cells located in the boundary between the cells and interference coordination method for any one of user equipment located in the boundary between the cells - Google Patents

Abstract

The present invention relates to an inter-cell interference coordination apparatus installed in a boundary region of a cell and an inter-cell interference coordination method for a mobile terminal located in a boundary region of a cell. And the base station transmits the frequency and transmission output of the inter-cell interference coordinator through a predetermined link so that the inter-cell interference coordinator can easily adjust inter-cell interference without using complicated algorithms. This is to improve performance.

Mobile terminal, base station, cell, border area, inter-cell interference coordination

Description

Interference coordination apparatus between cells located in the boundary between the cells and interference coordination method for any one of user equipment located in the boundary between the cells}

The present invention relates to an inter-cell interference control technology of a mobile communication system, and more particularly, to an inter-cell interference coordination apparatus installed in a cell boundary region to adjust inter-cell interference, and an inter-cell interference adjustment method for a mobile terminal located in a cell boundary region. will be.

The present invention is derived from the research conducted as part of the IT growth engine technology development project of the Ministry of Knowledge Economy and the Ministry of Information and Communication Research and Development. [Task management number: 2006-S-003-03, Task name: Development of next generation mobile communication service platform] .

Mobile communication systems such as 3G LTE's 3G Generation 3rd Generation Long Term Evolution (LTE) require high data rates of up to several hundred Mbps while moving and stopping. Various techniques have been proposed to satisfy these requirements, and OFDMA transmission technology is one of the core technologies.

OFDMA transmission technology has superior frequency efficiency and ease of implementation in broadband compared to single carrier technology. However, since all cells can use the same frequency, communication performance is degraded due to interference at the cell boundary. .

The methods for solving such communication degradation problems include interference randomization, interference cancellation, interference coordination, and antenna technique.

Among them, the interference coordination method is discussed to be the most effective in solving the communication performance degradation problem. Conventional inter-cell interference coordination method is to exchange the load information message containing the predefined indicators between the base station to determine the state of the neighboring cell and the frequency range causing the interference.

Indicators transmitted through the Load Information Message (IOI: Interference Overload Indicator) and High Interference Indicator (HII) and Relative Narrowband Tx Power (RNTP) Etc.

Since the interference overload indicator (IOI) has exceeded a predetermined threshold of uplink interference measured in its own cell, the base station of the counterpart cell that caused the interference is generated through scheduling such as frequency redistribution. Say a request to reduce. Such interference overload indicator (IOI) is reported as one value per physical resource block (PRB), and the reported values are divided into three classes.

The high interference indicator (HII) has a high probability of causing a serious uplink interference by a specific mobile terminal in its own cell (especially a boundary). To avoid interference. Such a large interference indicator (HII) is reported as one value per physical resource block (PRB) like the interference overload indicator (IOI), but the grade is divided into two stages.

The relative narrowband transmission power (RNTP) is used to report whether or not the downlink transmission output of its cell base station exceeds a predetermined limit, and is used to adjust downlink interference.

In addition to exchanging these indicators as necessary or in advance between base stations, the base station uses various scheduling methods for frequency redistribution in order to minimize interference that may occur between neighboring cells.

Scheduling methods for frequency redistribution can be classified into fractional frequency reuse (FFR), soft frequency reuse (SFR), and partial frequency reuse (PFR).

Fragment Frequency Reuse (FFR) is a method of dividing the total available frequency reuse set into up to three parts and assigning them to cells. In this case, the available frequency set is a set of frequencies in consideration of user interference, which is obtained by subtracting a frequency set Fi that cannot be used in the entire frequency domain.

For example, if the frequency reuse factor (Frequency Reuse Factor) is 3 as shown in Figure 1, Fi can be determined by the following equation.

F _i = frequency set not available in cell i

F _i ∩ F _j ≠ 0

F ₁ ∩ F ₂ ∩ F ₃ = 0

In FIG. 1, the mobile terminal in the center of cell ₁ may use the U ₁ frequency domain except for the F ₁ region (black portion) in the entire frequency domain, and is located at the boundary between cell 1 and cell 2 on the left. In case of a mobile terminal, cell ₂ cannot use the F ₂ region (black portion). Therefore, if you use the U _1-2 region (black portion), which is the intersection of U ₁ and F ₂ , the interference is minimized. Can be.

The soft frequency reuse (SFR) technique and the partial frequency reuse (PFR) technique divide the frequency into the cell when the frequency reuse factor is close to 1 and close to the cell boundary when the frequency reuse factor is greater than 1.

That is, in each cell, the entire frequency domain is divided into cells and boundaries, and the frequency domains for mobile terminals located at the boundary between adjacent cells are arranged to be orthogonal to each other, and the base station has a relatively high output in consideration of mobile terminals located at a distance. To send.

The difference between the soft frequency reuse (SFR) technique and the partial frequency reuse (PFR) technique is that for the soft frequency reuse (SFR) technique, the frequency reuse factor inside the cell may not be 1 (in this case, the frequency allocated for the cell boundary). When the frequency distribution for the cell boundary is used, the fluidity is increased so that the frequency reuse factor can be adjusted to 3 or more.

However, in the case of the partial frequency reuse (PFR) technique, the frequency reuse factor is 1 and the cell boundary is 3, so that the entire frequency domain is distributed in principle. Therefore, the inside of the cell uses all the frequency ranges with low power, and the cell boundary divides the frequency so that the frequency reuse factor with neighboring cells becomes 3, and the output for this frequency range is set high.

In terms of frequency utilization efficiency, soft frequency reuse (SFR) or partial frequency reuse (PFR) is more efficient than fractional frequency reuse (FFR).

However, both the soft frequency reuse (SFR) technique and the partial frequency reuse (PFR) technique are based on the assumption that the mobile terminal at the cell boundary is the main cause of interference to adjacent cells. There is a problem that needs to be separated from the inside.

In particular, in the case of a mobile terminal used in an asynchronous mobile communication system such as 3GPP LTE, which does not use a device such as GPS, this problem becomes larger because there is no separate device indicating an accurate location.

Currently, the most considered method in the asynchronous mobile communication system is cell boundary by comparing Reference Signal Received Power (RSRP) of neighboring cells and currently resident cells in cell selection and handover situations. Is to make a decision about whether or not to make a handover.

However, if the reference signal transmitted from the base station is relatively weak because it is located in the shadow area caused by the obstacles around, this method is likely to be mistaken for being located at the edge of the cell even though it is in the center of the cell. Have.

In addition, as mentioned above, in the conventional inter-cell interference coordination scheme, the frequency must be divided and distributed according to the position of the mobile station, and the mobile station at the cell boundary must be assigned a specific frequency. All mobile stations are allocated all frequencies, but the transmit power must be adjusted to be small so that no interference occurs between mobile terminals at adjacent cells and cell boundaries. Scheduling and output control algorithms are quite complex because of many considerations, such as ensuring that there is no problem in receiving data.

Accordingly, the present inventors have studied a technique for improving communication performance by adjusting interference between cells in an easier manner without using complicated algorithms.

The present invention has been invented under the above-described aspect, and is provided in a cell boundary area which is a main cause of intercell interference, and is installed in a cell boundary area of a cell which can easily adjust intercell interference without using a complicated algorithm. To provide for that purpose.

In addition, according to another aspect of the present invention, an inter-cell interference coordinator is installed in a boundary region of a cell which is a major cause of inter-cell interference, and the base station sets a link (predetermined link frequency and transmission output of the inter-cell interference coordinator). It is an object of the present invention to provide an inter-cell interference coordination method for a mobile terminal located in a boundary region of a cell so that the inter-cell interference can be more easily adjusted by transmitting through a link).

According to an aspect of the present invention for achieving the above object, the inter-cell interference coordination apparatus according to the present invention receives the use frequency from the base station of the cell to which it belongs, based on this located in the boundary region of the cell to which it belongs The inter-cell interference is adjusted by scheduling the mobile stations.

According to another aspect of the present invention, an inter-cell interference coordination method for a mobile station located in a boundary region of a cell according to the present invention determines a frequency used by the base station to be used in the inter-cell interference coordination apparatus located at the boundary of the cell to which it belongs. And transmits it to the inter-cell interference coordination apparatus and, in response to the request for location registration from the mobile terminal determined to be located in the cell boundary region, the inter-cell interference coordination apparatus installed in the cell boundary region processes the position registration for the mobile terminal. The inter-cell interference is adjusted by allocating a frequency within the use frequency.

Accordingly, the present invention provides an inter-cell interference coordinator in a boundary region of a cell which is a major cause of inter-cell interference, and the base station transmits the frequency and transmission output of the inter-cell interference coordinator through a predetermined link. Since the inter-cell interference coordinator can easily adjust inter-cell interference without using complicated algorithms, it has a useful effect of improving communication performance.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce the present invention.

In the following description of the present invention, detailed descriptions of well-known functions or configurations will be omitted if it is determined that the detailed description of the embodiments of the present invention may unnecessarily obscure the gist of the present invention.

Prior to describing the present invention, terms used throughout the specification are defined. These terms are terms defined in consideration of functions in the embodiments of the present invention, and are terms that can be sufficiently modified according to the intention, convention, etc. of the user or operator, and the definitions of these terms are based on the contents throughout the specification of the present invention. Will have to be lowered.

2 is a schematic diagram of an inter-cell interference coordination apparatus installed in a boundary region of a cell according to the present invention. As shown in the figure, the base station is located in the center of the cell, and the inter-cell interference coordination apparatus 100 is disposed in the boundary region of the cell.

The base station in the cell center uses all frequencies to schedule mobile terminals in the cell, and reduces transmission power so as not to affect the interference between the inter-cell interference coordination apparatuses 100 in the cell boundary region.

3 is a block diagram showing a configuration according to an embodiment of an inter-cell interference coordination apparatus installed in a boundary region of a cell according to the present invention. As shown in the figure, the inter-cell interference coordination apparatus 100 installed in the boundary region of the cell according to this embodiment includes a frequency receiver 110 and a scheduling unit 120.

The frequency receiver 110 receives a frequency used from the base station of the cell to which it belongs. The base stations receive the planned system shape information from the network operation center with the highest frequency efficiency and the smallest reuse factor of the cell boundary frequency, and the inter-cell interference coordination apparatus located at the boundary of the cell to which it belongs based on the received system shape information. Determining the use frequency and the transmission output to be used in the transmission, and transmits it to the inter-cell interference coordination apparatus 110 through a predetermined link.

Inter-cell interference coordination apparatus 100 receives the use frequency transmitted from the base station of the cell to which it belongs through the frequency receiver 110. At this time, the frequency used for the inter-cell interference coordination apparatus 100 is determined from the cell boundary frequency value included in the system shape information.

The scheduling unit 120 adjusts the inter-cell interference by scheduling mobile terminals located in the boundary region of the cell to which it belongs based on the use frequency received by the frequency receiving unit 110.

The base station and inter-cell interference coordination apparatus 100 transmits synchronization information for time synchronization and system information for acquiring system information to the mobile terminal, respectively, and the mobile terminal receives them to synchronize time.

System information transmitted from each of the base station and the inter-cell interference coordination apparatus 100 includes identification information for identifying the base station itself and the inter-cell interference coordination apparatus 100 itself.

When time synchronization is performed, each of the base station and inter-cell interference coordination apparatus 100 transmits a reference signal for locating the mobile terminal to the mobile terminal. Receiving this, the mobile station detects its position from the reference signal for identifying the position transmitted from each of the base station and inter-cell interference coordination apparatus of the cell to which it belongs.

At this time, the mobile terminal can determine its position by comparing the strength of the reference signal for determining the position received from each of the base station and inter-cell interference coordination apparatus of the cell to which it belongs. have.

When the mobile terminal determines its location and determines that its location is located in the cell boundary region, the mobile terminal requests location registration from the inter-cell interference coordination apparatus 100 installed in the cell boundary region.

Then, the inter-cell interference coordination apparatus 100 schedules the mobile stations located in the boundary region of the cell to which they belong based on the use frequency received by the frequency receiver 110 through the scheduling unit 120 to inter-cell interference. Adjust it.

At this time, the scheduling unit 120 includes a location registration processing unit 121 and a location registration notifying unit 122 and registers the location in response to a request for location registration from a specific mobile terminal located in the boundary region of the cell. The processor 121 processes the location registration for the mobile terminal and assigns a frequency within the frequency used. In addition, the location registration notification unit 122 notifies the base station of the cell to which the location registration itself belongs to notify.

Accordingly, in this manner, the present invention provides the inter-cell interference coordination apparatus 100 in the boundary region of the cell which is the main cause of the inter-cell interference, and the base station links the preset frequency and transmission output of the inter-cell interference coordination apparatus in advance. By transmitting through the link, the inter-cell interference coordination apparatus 100 can easily adjust the inter-cell interference without using a complicated algorithm, thereby improving communication performance.

Meanwhile, according to an additional aspect of the present invention, the inter-cell interference coordination apparatus 100 installed in the boundary region of the cell may further include an information transmitter 130. The information transmitter 130 transmits synchronization information for time synchronization, system information for acquiring system information, and a reference signal for location determination.

That is, in this embodiment, the inter-cell interference coordination apparatus 100 installed in the boundary region of the cell may transmit synchronization information for visual synchronization, system information for acquiring system information, and a reference signal for locating the information. By transmitting to the mobile terminal through the 130) is an embodiment so that the mobile terminal can use this when synchronizing the time and location.

The mobile terminal receives the synchronization information for time synchronization transmitted from each of the base station and the inter-cell interference coordination apparatus 100, and the system information for acquiring system information to synchronize time synchronization.

System information transmitted from each of the base station and the inter-cell interference coordination apparatus 100 includes identification information for identifying the base station itself and the inter-cell interference coordination apparatus 100 itself.

When time synchronization is performed, the mobile station receives reference signals for its own location from each of the base station of the cell to which it belongs and the inter-cell interference coordination apparatus 100, respectively, and the strength of the reference signal for the received location. Compare your location to find out where your location is.

Meanwhile, according to an additional aspect of the present invention, the inter-cell interference coordination apparatus 100 installed in the boundary region of the cell may further include a frequency changing unit 140. The frequency changing unit 140 notifies the mobile station located in the boundary region of the cell according to the request for changing the frequency of use from the base station of the cell to which it belongs, and then changes the frequency of use.

The base station that has received the load information message from the neighboring base station may receive an interference overload indicator (IOI), a large interference indicator (HII), or a relative narrowband transmission output (RNTP) included in the load information message. Based on the indicators and their values, it is determined whether to change the frequency of use of the inter-cell interference coordination apparatus 100 installed in the cell boundary region.

If the base station determines to change the use frequency of the inter-cell interference coordinator 100, the base station requests the inter-cell interference coordinator 100 to change the use frequency, accordingly the inter-cell interference coordinator 100 is a frequency changer ( Through 140, the mobile station located in the boundary region of the cell is notified of the frequency change, and then the frequency used is changed.

Referring to Figure 4 looks at the inter-cell interference coordination procedure through the inter-cell interference coordination apparatus installed in the boundary region of the cell according to the present invention having the above configuration. 4 is a flowchart according to an embodiment of an inter-cell interference coordination method for a mobile station located in a boundary region of a cell.

First, in the use frequency processing step (S210), the base station determines a use frequency to be used by the inter-cell interference coordination apparatus located at the boundary of the cell to which it belongs, and transmits it to the inter-cell interference coordination apparatus.

For example, in the use frequency processing step (S210), the use frequency may be determined to be used by the inter-cell interference coordination apparatus through a procedure as illustrated in FIG. 5, and may be transmitted to the inter-cell interference coordination apparatus. 5 is a flowchart illustrating an example of a use frequency processing procedure.

In step S211, the base station receives the planned system shape information from the network operation center with the highest frequency efficiency and the smallest reuse factor value of the cell boundary frequency.

Based on the system shape information received by step S211 in step S212, the base station determines a use frequency and transmission output to be used by the inter-cell interference coordination apparatus located at the boundary of the cell to which the base station belongs, and sets a preset link. Notify the inter-cell interference coordination apparatus through the. At this time, the frequency used for the inter-cell interference coordination apparatus is determined from the cell boundary frequency value included in the system shape information.

After determining the use frequency to be used in the inter-cell interference coordination apparatus by the use frequency processing step (S210), the position transmitted by the mobile terminal from each of the base station and inter-cell interference coordination apparatus of the cell to which the mobile terminal belongs in step S220. It finds its position from the reference signal for identification.

For example, in this mobile terminal position detection step (S220), it is possible to determine the position of the mobile terminal through the procedure as shown in FIG. 6 is a flowchart illustrating an example of a mobile terminal location procedure.

The base station and the inter-cell interference coordination apparatus transmit synchronization information for time synchronization and system information for system information acquisition to the mobile terminal, respectively, and the mobile terminal receives them to synchronize time synchronization.

System information transmitted from each of the base station and the inter-cell interference coordination apparatus each includes identification information for identifying the base station itself and the inter-cell interference coordination apparatus itself.

When time synchronization is performed, each of the base station and the inter-cell interference coordination apparatus transmits a reference signal for locating the mobile terminal to the mobile terminal.

Then, in step S221, the mobile station receives a reference signal for location determination from the base station of the cell to which it belongs.

Meanwhile, in step S222, the mobile terminal receives a reference signal for locating the location from the inter-cell interference coordination apparatus of the cell to which the mobile station belongs.

Next, in step S223, the mobile station compares the strengths of the reference signals for determining the location received from each of the base station of the cell to which it belongs and the inter-cell interference coordination apparatus, and determines in which region the location of the mobile station exists.

The location of the mobile terminal is determined by the mobile terminal location detecting step (S220), and if the mobile terminal is located in the cell boundary area by the mobile terminal location detecting step (S220), the mobile terminal is located between the cells installed in the cell boundary area. Request registration of location with interference coordination device.

Then, in the inter-cell interference coordination step (S230), the inter-cell interference coordination apparatus installed in the cell boundary area is located in response to the request for location registration from the mobile terminal determined by the mobile terminal location determination step (S220). The location registration for the mobile station is processed, and the mobile station adjusts the inter-cell interference by allocating a frequency within the use frequency transmitted by the use frequency processing step (S210).

For example, in the inter-cell interference coordination step (S230), the position of the mobile terminal can be determined through a procedure as shown in FIG. 7. 7 is a flowchart illustrating an example of an inter-cell interference coordination procedure of an inter-cell interference coordination apparatus.

In step S231, the inter-cell interference coordination apparatus receives the location registration request from the mobile terminal located in the cell boundary region.

Then, in response to receiving the location registration request in step S231, the inter-cell interference coordination apparatus processes the location registration for the corresponding mobile terminal in step S232, and is transmitted to the mobile terminal by the used frequency processing step (S210). Assign a frequency within the frequency used.

Then, the inter-cell interference coordination apparatus notifies the base station of the cell to which it belongs in step S232 to the base station of the cell to which it belongs, and receives a response to the location registration fact notification from the base station.

Upon receiving the response to the location registration fact notification in step S233, the inter-cell interference coordination apparatus transmits the response to the location registration request to the mobile terminal which requested the location registration in step S234.

Therefore, by the above, the present invention provides an inter-cell interference coordination apparatus in a boundary region of a cell which is a major cause of inter-cell interference, and the base station presets the frequency of use and transmission output of the inter-cell interference coordination apparatus in advance. By passing through, the inter-cell interference coordinator can easily adjust inter-cell interference without using complicated algorithms, thereby improving communication performance.

On the other hand, according to an additional aspect of the present invention, the inter-cell interference adjustment method for the mobile terminal located in the boundary region of the cell may further include a frequency changing step (S240).

In the frequency changing step (S240), the inter-cell interference coordination apparatus notifies the frequency change to the mobile stations located in the boundary region of the cell to which the cell belongs, in response to a request for changing the frequency of use from the base station of the cell to which the cell belongs. Change the frequency.

The base station that has received the load information message from the neighboring base station may receive an interference overload indicator (IOI), a large interference indicator (HII), or a relative narrowband transmission output (RNTP) included in the load information message. Based on the indicators and their values, it is determined whether to change the frequency of use of the inter-cell interference coordination apparatus installed in the cell boundary region.

If the base station determines to change the frequency of use of the inter-cell interference coordinator, the base station requests the inter-cell interference coordinator to change the frequency of use, whereby the inter-cell interference coordinator changes the frequency to mobile terminals located in the boundary region of the cell. After notifying, change the use frequency.

For example, in this frequency changing step S240, the use frequency can be changed through the procedure as shown in FIG. 8 is a flowchart illustrating an example of a use frequency change procedure.

When the base station receives the load information message from the neighboring base station (S241) determines to change the use frequency therefrom (S242), the base station makes a request for use frequency change to the inter-cell interference coordination apparatus (S243).

Then, the inter-cell interference coordinator notifies the mobile station located in the boundary region of the cell to which it belongs in response to the request for changing the frequency of use from the base station of the cell to which it belongs, and then changes the frequency of use (S244). do.

As described above, the present invention provides an easy and accurate way for the mobile terminal to compare the strength of the reference signal transmitted from the inter-cell interference coordination apparatus and the base station by providing the inter-cell interference coordination apparatus in the boundary region of the cell which is the main cause of the inter-cell interference. A base station transmits a frequency used by an inter-cell interference coordinator through a preset link, and schedules terminals located in a cell boundary region based on the frequency used by the inter-cell interference coordinator. Since the scheduler can reduce the burden of directly allocating a frequency for each of the mobile terminals and adjusts the output, thereby improving communication performance, the above-described object of the present invention can be achieved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. .

The present invention can be industrially used in the inter-cell interference control technology of the mobile communication system and its application technology.

1 is a diagram illustrating an example of a frequency set determination method that cannot be used in a cell;

2 is a schematic diagram of an inter-cell interference coordination apparatus installed in a boundary region of a cell according to the present invention;

3 is a block diagram showing a configuration according to an embodiment of an inter-cell interference coordination apparatus installed in a boundary region of a cell according to the present invention.

4 is a flowchart according to an embodiment of an inter-cell interference coordination method for a mobile station located in a boundary region of a cell;

5 is a flowchart illustrating an example of a used frequency processing procedure;

6 is a flowchart illustrating an example of a mobile terminal location procedure;

7 is a flowchart illustrating an example of an inter-cell interference coordination procedure of an inter-cell interference coordination apparatus;

8 is a flowchart illustrating an example of a use frequency change procedure;

<Explanation of symbols for the main parts of the drawings>

100: inter-cell interference adjusting device 110: frequency receiver

120: scheduling unit 121: location registration processing unit

122: location registration notification unit 130: information transmission unit

140: frequency change unit

Claims (9)

In the inter-cell interference adjusting device provided in the boundary region of the cell, A frequency receiver for receiving a use frequency from a base station of a cell to which the cell belongs; A scheduling unit configured to adjust inter-cell interference by scheduling mobile terminals located in a boundary region of a cell to which the cell belongs, based on the used frequency received by the frequency receiver; Inter-cell interference coordination apparatus is provided in the boundary region of the cell comprising a. The method of claim 1, Inter-cell interference coordination apparatus is installed in the boundary region of the cell: An information transmitter configured to transmit synchronization information for time synchronization, system information for acquiring system information, and a reference signal for location determination; Inter-cell interference coordination apparatus further comprises a boundary region of the cell. The method of claim 1, Inter-cell interference coordination apparatus is installed in the boundary region of the cell: A frequency changing unit for notifying a frequency change to mobile stations located in a boundary region of a cell according to a request for changing a use frequency from a base station of a cell to which the cell belongs; Inter-cell interference coordination apparatus further comprises a boundary region of the cell. The method according to any one of claims 1 to 3, The scheduling unit: A location registration processing unit for processing location registration for the mobile terminal according to a location registration request from a specific mobile terminal located in the boundary region of the cell and allocating a frequency within the use frequency; A location registration notifying unit for notifying a base station of a cell to which the location registration process is performed by the location registration processing unit; Inter-cell interference coordination apparatus is installed in the boundary region of the cell comprising a. A use frequency processing step of the base station determining a use frequency to be used by the inter-cell interference coordination apparatus located at the boundary of the cell to which the base station belongs, and transmitting the same to the inter-cell interference coordination apparatus; A mobile terminal location step of identifying, by the mobile terminal, its location from a reference signal for identifying the location transmitted from each of the base station and inter-cell interference coordination apparatus of the cell to which the mobile station belongs; In accordance with the location registration request from the mobile terminal determined to be located in the cell boundary region by the mobile terminal location determining step, the inter-cell interference coordination device installed in the cell boundary region processes the location registration for the mobile terminal and moves the mobile terminal. An inter-cell interference adjustment step of adjusting inter-cell interference by allocating a frequency within a use frequency transmitted by the use frequency processing step to a terminal; Inter-cell interference coordination method for a mobile station located in the boundary region of the cell, characterized in that comprising a. The method of claim 5, The use frequency processing step is: Receiving, by the base station, system configuration information from the network operation center; Determining, by the base station, a frequency used for the inter-cell interference coordination apparatus located at the boundary of the cell to which the base station belongs, based on the system shape information received by the step, and notifying the inter-cell interference coordination apparatus; Inter-cell interference coordination method for a mobile station located in the boundary region of the cell comprising a. The method of claim 5, The positioning step of the mobile terminal is: Receiving, by the mobile terminal, a reference signal for positioning from the base station of the cell to which the mobile station belongs; Receiving, by the mobile terminal, a reference signal for locating a position from the inter-cell interference coordination apparatus of the cell to which the mobile station belongs; Comparing, by the mobile terminal, the strength of a reference signal for identifying a location received from each of the base station and inter-cell interference coordination apparatus of the cell to which the mobile station belongs, to determine in which region the location of the mobile station exists; Inter-cell interference coordination method for a mobile station located in the boundary region of the cell comprising a. The method of claim 5, The inter-cell interference coordination step is: Receiving, by the inter-cell interference coordination apparatus, a location registration request from a mobile terminal located in a cell boundary region; In response to receiving the location registration request according to the above step, the inter-cell interference coordination apparatus processing the location registration for the corresponding mobile terminal and allocating a frequency within the used frequency transmitted by the used frequency processing step to the corresponding mobile terminal; Receiving, by the inter-cell interference coordination apparatus, the base station of the cell to which the cell belongs to the base station, and receiving a response to the notification of the location registration from the base station; Transmitting a response to the location registration request to the mobile terminal requesting the location registration by the inter-cell interference coordination apparatus upon receiving the response to the location registration fact notification by the above step; Inter-cell interference coordination method for a mobile station located in the boundary region of the cell comprising a. The method according to any one of claims 5 to 8, An inter-cell interference coordination method for a mobile station located in the boundary region of the cell includes: The inter-cell interference coordination apparatus notifies the mobile station located in the boundary region of the cell to which the cell belongs to the frequency change request from the base station of the cell to which the cell belongs, and then changes the frequency to change the frequency used. ; The inter-cell interference adjustment method for a mobile station located in the boundary region of the cell further comprising.

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