KR101565247B1 - Cell selection method for handover in mobile communication network - Google Patents

Abstract

A cell selection method for handover in a mobile communications network comprises the following steps: a plurality of mobile terminals receive cell types and remaining power values from a plurality of accessible cells; the mobile terminals transmit the cell types and the remaining power values to a macro-cell base station; a device which controls the handover of the mobile terminals determines candidate cells based on a moving speed of the mobile terminal and a coverage size according to the cell types, and selects a first connection cell for at least one among the mobile terminals from the candidate cells, based on the moving speed and whether the cell of the mobile terminal is changed or not; and the device which controls the handover selects a second connection cell for the remaining mobile terminals, which could not select the first connection cell, among the mobile terminals from all cells accessible by the remaining mobile terminals, based on whether the cell of the mobile terminal is changed or not.

Description

TECHNICAL FIELD [0001] The present invention relates to a cell selection method for handover in a mobile communication network,

The techniques described below relate to cell selection techniques in mobile communication networks.

The cell connected to the mobile terminal may be changed according to the movement of the user using the mobile terminal. The process of changing a cell is called a handover. In order to perform a handover, it is determined whether a particular mobile terminal should be connected through a certain cell. This process is called cell selection.

The 3GPP standard describes that each terminal selects a cell having the highest value based on the signal strength of a reference signal received from a neighboring cell.

Recently, mobile communication networks use cells having various coverage such as macro cells, picocells, femtocells, and the like. There is also a technology that can use a heterogeneous network (HetNet) that is heterogeneous from the conventional mobile communication network. For example, interworking with a Wifi network. Related technology is being actively studied for handover between HetNet.

Korean Patent Publication No. 10-2013-0078188 Korean Patent Publication No. 10-2011-0096456

If the users are simultaneously connected based on the strength of the reference signal of the cell as in the conventional 3GPP standard, efficient cell distribution can not be achieved.

The technique described below is intended to provide a cell selection method of maximizing a terminal accessing the same cell as much as possible based on the moving speed of the mobile terminal or the like.

The solutions to the technical problems described below are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

A cell selection method for handover in a mobile communication network includes receiving a cell type and a residual power value from a plurality of cells accessible by a mobile terminal, transmitting a cell type and a residual power value to a macro cell base station, A macro cell base station or an apparatus for controlling a handover of a mobile station determines a candidate cell based on a moving speed of the mobile station and a size of coverage according to the cell type, And selecting a connected cell for the mobile terminal using the moving speed of the candidate cell and information on the previous connected cell of the mobile terminal.

The candidate cell includes a macrocell and the femtocell if the moving speed is equal to or greater than the upward reference value and the moving speed is less than the upward reference value and equal to or greater than the downward reference value, Macro cells, femtocells, and Wi-Fi cells.

The candidate cell is divided into a wide coverage cell, an intermediate coverage cell and a small coverage cell according to the coverage size order. If the movement speed is equal to or greater than the upper reference value, the candidate cell includes a wide coverage cell. If the movement speed is less than the upper reference value, The candidate cell may include a wide coverage cell and an intermediate coverage cell, and the candidate cell may include a wide coverage cell, a middle coverage cell and a small coverage cell when the traveling speed is less than the downward reference value.

The number of mobile terminals capable of being connected to the candidate cell with a moving speed, the degree to which the plurality of mobile terminals satisfy the Qos condition in the candidate cell, or the number of mobile terminals which can be connected to the candidate cell without changing the cell It is possible to select the connected cell among the candidate cells so that at least one of the candidate cells has the maximum.

A cell selection method for handover in a mobile communication network includes receiving a cell type and a residual power value from a plurality of cells accessible to a plurality of mobile terminals, The apparatus for controlling handover of a mobile terminal determines a candidate cell based on a moving speed of the mobile terminal and a size of coverage according to the cell type, Selecting a first connected cell for at least one of the plurality of mobile terminals, and controlling the handover control apparatus to allow the remaining mobile terminals to access the remaining mobile terminals that fail to select the first connected cell among the plurality of mobile terminals Selecting a second connected cell for the remaining mobile terminals based on whether or not the mobile terminal changes cell among all the cells, Can.

The techniques described below perform cell selection considering the mobile speed of the terminal, the QoS of the mobile terminal, and / or the number of cell changes of the mobile terminal so that frequent cell changes do not occur throughout the network.

The effects of the techniques described below are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

Figure 1 shows an example for a mobile communication network in which various cells are present.
2 is an example of a flowchart of a cell selection method for handover in a mobile communication network.
3 is another example of a flowchart for a cell selection method for handover in a mobile communication network.

The following description is intended to illustrate and describe specific embodiments in the drawings, since various changes may be made and the embodiments may have various embodiments. However, it should be understood that the following description does not limit the specific embodiments, but includes all changes, equivalents, and alternatives falling within the spirit and scope of the following description.

The terms first, second, A, B, etc., may be used to describe various components, but the components are not limited by the terms, but may be used to distinguish one component from another . For example, without departing from the scope of the following description, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

As used herein, the singular " include "should be understood to include a plurality of representations unless the context clearly dictates otherwise, and the terms" comprises & , Parts or combinations thereof, and does not preclude the presence or addition of one or more other features, integers, steps, components, components, or combinations thereof.

Before describing the drawings in detail, it is to be clarified that the division of constituent parts in this specification is merely a division by main functions of each constituent part. That is, two or more constituent parts to be described below may be combined into one constituent part, or one constituent part may be divided into two or more functions according to functions that are more subdivided. In addition, each of the constituent units described below may additionally perform some or all of the functions of other constituent units in addition to the main functions of the constituent units themselves, and that some of the main functions, And may be carried out in a dedicated manner. Therefore, the existence of each of the components described in the present specification should be interpreted as a function. For this reason, the configuration of the components according to the cell selection method for handover in the mobile communication network, which will be described below, It should be clear that it may be different from the corresponding drawings to the extent that the object of the technology can be achieved.

Also, in performing a method or an operation method, each of the processes constituting the method may take place differently from the stated order unless clearly specified in the context. That is, each process may occur in the same order as described, may be performed substantially concurrently, or may be performed in the opposite order.

1 shows an example for a mobile communication network 100 in which various cells are present. FIG. 1 shows several cells included in one macro cell. The macro cell is an area included in the coverage of the macro cell base station 110. The terminals 50A, 50B, 50C, 50D and 50E shown in FIG. 1 are all present in the macro cell area. That is, all the terminals shown in FIG. 1 can access the core network of the mobile communication network through the macro cell.

However, because the resources of the macro cell are limited, the communication service provider or the user can use other cells included in the macro cell area for smoother service. For example, the pico cell base station 120 controls a pico cell included in a macro cell area. The femtocell base station 130 also controls a femtocell. The picocell and the femtocell may be cells using the same mobile communication scheme as the macro cell, or may be a communication network using a heterogeneous communication scheme. 3G (WCDMA), 4G (LTE), Wi-Fi, and NFC are different types of heterogeneous networks. In general, a macro cell, a picocell, and a femtocell are used as terms for distinguishing sizes of coverage, and it is not necessary to distinguish whether the communication methods of the cells are the same or different. In FIG. 1, a cell shown as a femtocell may be a Wi-Fi cell.

In FIG. 1, arrows on the terminal 50 indicate the moving speed of the terminal. The absence of an arrow is a stop, and the length of the arrow is proportional to the speed of movement. The mobile terminal 50C shown at the bottom right in Fig. 1 has a slow moving speed. Accordingly, even if data communication is performed through the pico cell base station 120, services can be performed without a cell transition for a predetermined time. However, since the mobile terminal 50D has a relatively high speed, if the picocell is selected for handover, the handover can be performed again in a short time. Therefore, if stable service is desired for a certain period of time, the mobile terminal 50D preferably connects to the macrocell.

Since the mobile terminal 50E is located in a femtocell or WiFi cell having a relatively small coverage, the mobile terminal 50E can receive a stable service even if it is connected to a femtocell or a WiFi cell.

The cell selection scheme described below selects a cell having a reasonable coverage based on the moving speed of the mobile station. Further, the mobile station selects the cell in which the QoS and the frequent change of the cell are expected to be small in addition to the moving speed. Briefly, i) a cell in which at least one of the number of terminals that can be connected with a constant movement speed, ii) the QoS value of the mobile terminal, and iii) the number of mobile terminals connected without cell change is selected will be.

Hereinafter, a cell selection method for handover in a mobile communication network will be described in detail with reference to the drawings. Hereinafter, the term " mobile communication network " is meant to encompass all networks that manage the connection of a terminal by a certain cell unit using a base station or an AP regardless of the type of communication method such as 4G and 3G.

2 is an example of a flowchart for a cell selection method 200 for handover in a mobile communication network.

A cell selection method (200) for handover in a mobile communication network includes receiving (210) a cell type and a residual power value from a plurality of cells accessible by a mobile terminal, A step 220 of transmitting to the base station 220, a step 230 of determining a candidate cell based on the size of the coverage of the macro cell base station or the mobile terminal, A mobile station that applies a binary integer programming to a cell base station or an apparatus for controlling a handover of the mobile station as a variable with respect to a candidate cell and whether the candidate cell is a cell previously accessed by the mobile station (Step 240).

The cell selection method 200 shown in FIG. 2 selects a candidate cell based on the moving speed of the mobile terminal and selects a mobile terminal to be allocated to the candidate cell.

First, the mobile terminal receives information on a cell type and a residual power value from a plurality of accessible cells (210). Information including a cell type and a residual power value for a specific cell is referred to as cell information. For example, according to 3GPP standards, cell information can be received from a femtocell or the like through CPICH (Common PIlot CHannel), and cell information can be received from a Wi-Fi cell through a beacon signal.

The MS receiving the cell information transmits the cell information to the macro cell BS (220). For example, the mobile terminal can transmit the corresponding cell information to the macro cell base station through a Measurement Report frame or the like. Of course, whether the cell selection method 200 transmits cell information through a signal is not an important factor.

Thereafter, the macro cell performs a process of selecting a cell for the mobile station based on the given information. The macro cell base station may receive the cell selection information through the control unit of the mobile communication core network to perform the handover or the macro cell base station may perform the cell selection. For example, in a 4G mobile communication network, an MME (Mobility Management Entity) generally controls a handover process. However, in the cell selection method 200 shown in FIG. 2, it is not a matter of which mobile communication configuration performs cell selection.

A macro cell base station or an apparatus for controlling handover of a mobile terminal determines a candidate cell based on a moving speed of the mobile terminal (230). As described with reference to FIG. 1, it is preferable that a mobile station having a high moving speed selects a cell having a large coverage.

For example, when the moving speed of the mobile terminal is equal to or greater than the upward reference value, the macrocell can be selected as the candidate cell. If the moving speed of the mobile station is less than the upward reference value and is equal to or higher than the downward reference value, a pico-cell or a femtocell having a smaller coverage than the macrocell may be selected as the candidate cell. If the moving speed is less than the downward reference value, all connectable cells may be selected as candidate cells. The uplink reference value and the downlink reference value corresponding to the threshold value of the moving speed of the mobile terminal may be changed according to the setting of the network system administrator. As a result, the uplink reference value is a reference value for determining whether or not the mobile station moving at a constant rate can maintain the connection in the macrocell for a predetermined reference time, and the downlink reference value is a reference value for a predetermined reference time in the same pico- This is a reference value that determines whether or not the connection can be maintained for a while.

If the moving speed is less than the upward reference value and the moving speed is equal to or greater than the downward reference value, the candidate cell includes the macrocell and the femtocell. If the moving speed is less than the downward reference value The candidate cell may include a macro cell, a femtocell, and a WiFi cell.

Rather than referring to the specific type of candidate cell, the candidate cell may be more preferably divided into a wide coverage cell, a middle coverage cell, and a small coverage cell according to their coverage size order. In this case, if the moving speed is equal to or greater than the upward reference value, the candidate cell includes a wide coverage cell. If the moving speed is less than the upward reference value and is equal to or higher than the downward reference value, the candidate cell includes a wide coverage cell and an intermediate coverage cell, The candidate cell may include a wide coverage cell, a middle coverage cell and a small coverage cell.

The number of mobile terminals having a moving speed and being connectable to a candidate cell in the step of selecting 240, the degree to which a plurality of mobile terminals satisfy a QoS condition in a candidate cell, or a case where a plurality of mobile terminals are connected to a candidate cell It is possible to select the connection cell among the candidate cells so as to have at least one of the connectable numbers at the maximum.

Hereinafter, a process of selecting a specific cell and a connection cell for a mobile terminal after selecting a candidate cell will be described. A process 240 for selecting a connection cell for a mobile terminal is, in other words, a process for selecting a mobile terminal to be assigned to a specific candidate cell.

The step 240 of selecting a connection cell for the mobile terminal corresponds to stepwise optimization according to binary integer programming. We will define some variables and functions for equations for binary integer programming.

는 이동 단말 i가 접속 가능한 모든 셀에서 셀 T가 선택되었음을 의미하는 지시 함수(indicator fuction)이다.

Is an indicator function indicating that the cell T is selected in all cells to which the mobile terminal i is connectable.

For convenience of explanation, it is assumed that there are three kinds of candidate cells. Three types are macro cell, femtocell and WiFi cell according to their coverage order. Of course, other types of cells may be candidate cells, and there may be three or more types of candidate cells. Assuming that the candidate cell is a macro cell, a femtocell, and a Wi-Fi cell,

이다.

은 매크로셀 원소이다.

는 펨토셀 요소이다. 펨토셀은 L개 존재하며, j = {1,...,L}의 값을 갖는다.

는 와이파이셀 요소이다. 와이파이셀은 P개 존재하며 k = {1,...,P}의 값을 갖는다.

to be.

Is a macro cell element.

Is a femtocell element. There are L femtocells, and j = {1, ..., L}.

Is a Wi-Fi cell element. There are P WiFi cells and k = {1, ..., P}.

The speed of the mobile terminal is detected by a conventional mobile communication network system using a technique of detecting the location information or speed of the mobile terminal. For example, GPS or a plurality of base stations may be used to estimate the position and the speed.

The access cell selection for the mobile terminal basically maximizes the number of mobile terminals connected to the corresponding cell.

2, candidate cells are classified into three groups according to the moving speed of the mobile terminal.

(1) First group: If the moving speed is equal to or higher than the upward reference value, the candidate cell is a macro cell, and in step 240 to select, a terminal to be connected to the macro cell may be selected so that the macro cell satisfies the following equation (1).

은 매크로셀 집합, M은 매크로셀,

은 이동 단말 i가 매크로셀에 연결됨을 나타내는 지시 함수,

는 이동 단말 i가 최종적으로 매크로셀에 연결됨을 나타내는 지시 함수,

는 이동 단말 i의 속도,

는 이동 단말 i의 QoS 등급,

은 이동 단말 i가 이전에도 매크로셀에 연결되었는지 여부를 나타내는 지시 함수,

는 0~1 사이의 값을 갖는 가중치,

는 0~1 사이의 값을 갖는 가중치이다.

는 예컨대 8개의 등급을 갖는 것으로 구분될 수도 있고, 다른 종류의 등급을 가질 수도 있다.
Where i is the ordinal number of the mobile terminal,

A macro cell set, M a macro cell,

Is an indicating function indicating that the mobile terminal i is connected to the macro cell,

Is an instruction function indicating that the mobile terminal i is finally connected to the macro cell,

The speed of the mobile terminal i,

The QoS level of the mobile terminal i,

Is an instruction function indicating whether or not the mobile terminal i has been connected to the macro cell before,

Is a weight having a value between 0 and 1,

Is a weight having a value between 0 and 1.

For example, eight grades, or may have different grades.

Equation (1) should satisfy the following equations (2) to (4).

은 이동 단말 i에 대해 매크로셀에 할당된 파워값,

은 매크로셀의 잔여 파워값이다. 상기 수학식 2는 매크로셀 M이 갖고 있는 잔여 파워값 범위 내에서 단말을 할당하도록 제한한다.

The power value assigned to the macro cell for the mobile terminal i,

Is the residual power value of the macro cell. Equation (2) limits the assignment of the terminals within the range of the residual power value of the macrocell M.

는 이동 단말 i가 연결 가능할 셀의 집합이다. 상기 수학식 3은 어떤 이동 단말도 하나의 셀에 연결되도록 제한한다.

Is a set of cells to which mobile terminal i can connect. Equation (3) limits any mobile terminal to be connected to one cell.

은 이동 단말 i가 이전에 매크로셀에 연결되었음을 나타내는 지시 함수이다. 상기 수학식 4는 이동 단말은 되도록 이전에 접속했던 셀에 접속하도록 한다. 수학식 1에서

을 통해 기존에 선택된 셀에 이동 단말이 유지하면 부가 점수를 부여한다고 할 수 있다.

는 가능하다면 이전에 접속했던 셀을 선택하면 1의 값을 갖고 이전에 접속했던 셀과 다른 셀에 접속하게 되면 0의 값을 갖는다.

Is an indicator function indicating that mobile terminal i is previously connected to a macro cell. In Equation (4), the mobile terminal accesses a cell that has been previously connected. In Equation (1)

It can be said that additional points are given when the mobile terminal maintains a cell selected in the past.

If it is possible to select a previously connected cell, it will have a value of 1 and it will have a value of 0 if it connects to a cell that is different from the previous cell.

(2) Group 2: The candidate cell includes the macrocell and the femtocell when the movement speed is less than the upward reference value and the downward reference value, and the candidate cell includes the macrocell and the femtocell in the selection step 240 And selects a terminal to be connected.

은 매크로셀 집합,

는 펨토셀 j의 집합, M은 매크로셀, F_j는 펨토셀 j,

은 이동 단말 i가 셀 T에 연결됨을 나타내는 지시 함수,

는 이동 단말 i가 최종적으로 매크로셀 또는 펨토셀에 연결됨을 나타내는 지시 함수,

는 이동 단말 i의 속도,

는 이동 단말 i의 QoS 등급,

은 이동 단말 i가 이전에 셀 T에 연결되었는지 여부를 나타내는 지시 함수,

는 0~1 사이의 값을 갖는 가중치,

는 0~1 사이의 값을 갖는 가중치이다. 상기 수학식 5는 아래의 수학식 6 내지 수학식 10의 조건을 만족해야 한다.
Where i is the ordinal number of the mobile terminal,

Macro cell set,

F is a set of femtocells j, M is a macro cell, F _j is a femtocell j,

Is an indication function indicating that mobile terminal i is connected to cell T,

An indicator function indicating that the mobile terminal i is finally connected to a macro cell or a femtocell,

The speed of the mobile terminal i,

The QoS level of the mobile terminal i,

Is an indication function indicating whether mobile terminal i has previously been connected to cell T,

Is a weight having a value between 0 and 1,

Is a weight having a value between 0 and 1. Equation (5) should satisfy the following equations (6) to (10).

은 이동 단말 i에 대해 셀 T에 할당된 파워값,

은 셀 T의 잔여 파워값이다. 여기서 T는 매크로셀 M이다.

Is the power value assigned to cell T for mobile terminal i,

Is the residual power value of the cell T. Where T is the macrocell M.

은 이동 단말 i에 대해 셀 T에 할당된 파워값,

은 셀 T의 잔여 파워값이다. 여기서 T는 펨토셀 F_j이다. 상기 수학식 6 내지 수학식 7은 매크로셀 및 펨토셀이 보유하고 있는 잔여 파워값 범위 내에서 이동 단말을 할당하게 한다.

Is the power value assigned to cell T for mobile terminal i,

Is the residual power value of the cell T. Where T is the femtocell F _j . Equations (6) to (7) allow the mobile terminal to be allocated within the residual power value range held by the macrocell and the femtocell.

는 이동 단말 i가 연결 가능할 셀의 집합이다. 수학식 8은 이동 단말이 하나의 셀에 접속하도록 제한한다.

Is a set of cells to which mobile terminal i can connect. Equation (8) limits the mobile terminal to connect to one cell.

은 이동 단말 i가 이전에 셀 T에 연결되었음을 나타내는 지시 함수이다. 여기서 T는 매크로셀 M이다.

Is an indicator function indicating that mobile terminal i has previously been connected to cell T. Where T is the macrocell M.

은 이동 단말 i가 이전에 셀 T에 연결되었음을 나타내는 지시 함수이다. 여기서 T는 펨토셀 F_j이다. 상기 수학식 9 내지 수학식 10은 이동 단말이 되도록 이전에 접속했던 셀에 접속하도록 제한하는 것이다. 수학식 4에서 설명한 내용과 동일하다.

Is an indicator function indicating that mobile terminal i has previously been connected to cell T. Where T is the femtocell F _j . Equation (9) to Equation (10) restricts access to a cell that has been previously connected to become a mobile terminal. Equation 4 is the same as described above.

(3) Third group: If the moving speed is less than the downward reference value, the candidate cell includes a macro cell, a femtocell, and a WiFi cell. In step 240, the candidate cell is connected to a candidate cell And selects a terminal to be used.

은 매크로셀 집합,

는 펨토셀 j의 집합,

는 와이파이셀 k의 집합, M은 매크로셀, F_j는 펨토셀 j, W_k는 와이파이 셀 k,

은 이동 단말 i가 셀 T에 연결됨을 나타내는 지시 함수,

는 이동 단말 i가 최종적으로 매크로셀, 펨토셀 또는 와이파이셀에 연결됨을 나타내는 지시 함수,

는 이동 단말 i의 QoS 등급,

은 이동 단말 i가 이전에 셀 T에 연결되었는지 여부를 나타내는 지시 함수,

는 0~1 사이의 값을 갖는 가중치,

는 0~1 사이의 값을 갖는 가중치이다. 상기 수학식 11은 아래의 수학식 12 내지 수학식 19의 조건을 만족해야 한다.
Where i is the ordinal number of the mobile terminal,

Macro cell set,

A set of femtocells j,

M is a macro cell, F _j is a femtocell j, W _k is a Wi-Fi cell k,

Is an indication function indicating that mobile terminal i is connected to cell T,

An indicator function indicating that the mobile terminal i is finally connected to a macro cell, a femtocell or a Wi-Fi cell,

The QoS level of the mobile terminal i,

Is an indication function indicating whether mobile terminal i has previously been connected to cell T,

Is a weight having a value between 0 and 1,

Is a weight having a value between 0 and 1. The above Equation (11) should satisfy the following Equations (12) to (19).

은 이동 단말 i에 대해 셀 T에 할당된 파워값,

은 셀 T의 잔여 파워값이다. 순서대로 T는 매크로셀 M, 펨토셀F_j 및 와이파이셀 W_k이다. 상기 수학식 12 내지 수학식 14는 매크로셀, 펨토셀 및 와이파이셀이 갖고 있는 잔여 파워값 범위 내에서 이동 단말을 할당하게 한다.
In the equations (12) to (14)

Is the power value assigned to cell T for mobile terminal i,

Is the residual power value of the cell T. T is the macrocell M, the femtocell F _j, and the Wi-Fi cell W _{k, in} that order. Equations (12) to (14) allow mobile terminals to be allocated within a residual power value range of a macro cell, a femtocell, and a Wi-Fi cell.

는 이동 단말 i가 연결 가능할 셀의 집합이다. 수삭식 15는 이동 단말이 하나의 셀에 접속하게 제한한다.

Is a set of cells to which mobile terminal i can connect. The recursion formula 15 restricts the mobile terminal to connect to one cell.

이동 단말 i가 이전에 셀 T에 연결되었음을 나타내는 지시 함수이다. 상기 수학식 16 내지 수학식 18은 이동 단말이 되도록 이전에 접속한 셀에 접속하도록 유도하는 조건이다. 전술한 수학식 4에 대응된다.
In the equations (16) to (18)

Is an indicator function indicating that mobile terminal i has previously been connected to cell T. The above Equations (16) to (18) are conditions for inducing the mobile terminal to connect to a previously connected cell. Corresponds to Equation (4).

3 is another example of a flowchart for a cell selection method 300 for handover in a mobile communication network. The cell selection method 300 for handover in the mobile communication network shown in FIG. 3 is similar to the method of FIG. However, the cell selection method 200 of FIG. 2 fundamentally divides the candidate cells into three groups according to the moving speed of the mobile terminal, and the cell selection method 300 of FIG. 3 corresponds to the method of FIG. 2 So that the cell can be selected for all the mobile terminals including the mobile terminal.

Each step of FIG. 3 is basically the same as that shown in FIG. I would like to give additional explanation only about what can be distinguished.

A cell selection method (300) for handover in a mobile communication network includes receiving (310) a cell type and a residual power value from a plurality of cells accessible by a plurality of mobile terminals, (320) a value to the macro cell base station.

In step 330, it is determined whether the moving speed of the mobile terminal is equal to or greater than a reference value. The reference value in step 330 corresponds to the downward reference value in FIG. That is, if the number is equal to or greater than the downward reference value, different candidate cells are selected according to the moving speed. The process 340 for determining a candidate cell according to the movement speed and the cell type corresponds to a process of selecting either the first group or the second group described in FIG. 2 as a candidate cell.

Cells of the first group (macrocell) or the second group (macrocell and femtocell) may not be selected according to the binary integer programming described above for a mobile terminal having a constant movement speed. Therefore, it is determined whether or not the first connection cell is selected (350). If it is determined that the first connection cell is not selected, the mobile station having the moving speed higher than the downward reference value is also checked for the third group (macro cell, femtocell and Wi- (360).

If the moving speed of the mobile terminal is lower than the downward reference value, the cell may be directly selected for the third group (360).

The specific process of selecting cells in the first group, the second group, and the third group is the same as that described in FIG.

In the step 350 of selecting the first connected cell, the handover control unit determines whether the number of candidate cells remaining connected to the candidate cell among the mobile terminals having the moving speed, the number of QoS Values and the number of cells to which the connecting cell of the mobile terminal does not change is maximized.

In the step 360 of selecting the second connection state, the handover control unit determines the sum of the QoS values for the plurality of mobile terminals and the number of the mobile terminals to be connected, The second connected cell can be selected.

After the cell selection method 200, 300 for handover in the mobile communication network, the handover will be performed.

It should be noted that the present embodiment and the drawings attached hereto are only a part of the technical idea included in the above-described technology, and those skilled in the art will readily understand the technical ideas included in the above- It is to be understood that both variations and specific embodiments which can be deduced are included in the scope of the above-mentioned technical scope.

50: mobile terminal 100: mobile communication network
110: macro cell base station 120: pico cell base station
130: femtocell base station

Claims (12)

Receiving a cell type and a residual power value from a plurality of cells accessible by the mobile terminal;
Transmitting the cell type and the residual power value to the macro cell base station;
Determining a candidate cell based on a moving speed of the mobile station and a size of a coverage according to the cell type, the apparatus controlling the handover of the macro cell base station or the mobile station; And
Wherein the macro cell base station or the apparatus for controlling the handover of the mobile terminal is capable of controlling the number of mobile terminals each having a moving speed and capable of being connected to the candidate cell, the degree to which the plurality of mobile terminals satisfy the QoS condition in the candidate cell And selecting the connection cell among the candidate cells so that the plurality of mobile terminals have at least one of the numbers connectable to the candidate cell without changing the cell to a maximum. The method according to claim 1,
Wherein the cell type is at least one of a macro cell, a femtocell, a picocell, and a Wi-Fi cell according to a coverage size. The method according to claim 1,
In the determining step
The candidate cell includes the macrocell and the femtocell when the moving speed is equal to or greater than the upward reference value and the moving speed is less than the upward reference value and equal to or greater than the downward reference value, Wherein the candidate cell is a mobile communication network including the macrocell, the femtocell, and the Wi-Fi cell. The method according to claim 1,
The candidate cell is divided into a wide coverage cell, an intermediate coverage cell, and a small coverage cell according to a coverage size order,
Wherein the candidate cell includes the wide coverage cell when the movement speed is equal to or greater than the upward reference value and the candidate cell includes the wide coverage cell and the middle coverage cell when the movement speed is less than the upward reference value and equal to or greater than the downward reference value Wherein the candidate cell comprises the wide area coverage cell, the middle area coverage cell and the small area coverage cell when the movement speed is less than the downward reference value. delete The method according to claim 1,
Wherein the candidate cell is a macro cell when the movement speed is equal to or greater than an upward reference value and the cell for handover in a mobile communication network selecting a terminal to be connected to the macro cell such that the macro cell satisfies the following equation How to choose.

(The formula

,

And

Where i is an ordinal number for the mobile terminal,

A macro cell set, M a macro cell,

Is an indicating function indicating that the mobile terminal i is connected to the macro cell,

Is an instruction function indicating that the mobile terminal i is finally connected to the macro cell,

The speed of the mobile terminal i,

The QoS level of the mobile terminal i,

Is an instruction function indicating whether or not the mobile terminal i has been connected to the macro cell before,

Is a weight having a value between 0 and 1,

Is a weight having a value between 0 and 1,

The power value assigned to the macro cell for the mobile terminal i,

Is the residual power value of the macrocell,

A set of cells to which the mobile terminal i can connect,

Is an indication function indicating that mobile terminal i is previously connected to a macro cell) The method according to claim 1,
Wherein the candidate cell includes a macro cell and a femtocell when the moving speed is less than the upward reference value and is equal to or greater than the downward reference value, and in the selecting step, selecting a terminal accessing the candidate cell so that the candidate cell satisfies the following equation: Method for cell selection for handover in a communication network.

(The formula

,

,

,

And

Where i is an ordinal number for the mobile terminal,

Macro cell set,

F is a set of femtocells j, M is a macro cell, F _j is a femtocell j,

Is an indication function indicating that mobile terminal i is connected to cell T,

An indicator function indicating that the mobile terminal i is finally connected to a macro cell or a femtocell,

The speed of the mobile terminal i,

The QoS level of the mobile terminal i,

Is an indication function indicating whether mobile terminal i has previously been connected to cell T,

Is a weight having a value between 0 and 1,

Is a weight having a value between 0 and 1,

Is the power value assigned to cell T for mobile terminal i,

Is the residual power value of the cell T,

A set of cells to which the mobile terminal i can connect,

Is an indication function indicating that mobile terminal i is previously connected to cell T) The method according to claim 1,
Wherein the candidate cell includes a macro cell, a femtocell, and a Wi-Fi cell when the movement speed is less than a downward reference value, and the mobile station selects a terminal to access the candidate cell so that the candidate cell satisfies the following equation A cell selection method for handover in a network.

(The formula

,

,

,

,

,

And

Where i is an ordinal number for the mobile terminal,

Macro cell set,

A set of femtocells j,

M is a macro cell, F _j is a femtocell j, W _k is a Wi-Fi cell k,

Is an indication function indicating that mobile terminal i is connected to cell T,

An indicator function indicating that the mobile terminal i is finally connected to a macro cell, a femtocell or a Wi-Fi cell,

The QoS level of the mobile terminal i,

Is an indication function indicating whether mobile terminal i has previously been connected to cell T,

Is a weight having a value between 0 and 1,

Is a weight having a value between 0 and 1,

Is the power value assigned to cell T for mobile terminal i,

Is the residual power value of the cell T,

A set of cells to which the mobile terminal i can connect,

Is an indication function indicating that mobile terminal i is previously connected to cell T) Receiving a cell type and a residual power value from a plurality of cells accessible to a plurality of mobile terminals;
The plurality of mobile terminals transmitting the cell type and the residual power value to a macro cell base station;
Wherein the apparatus for controlling handover of the mobile station determines a candidate cell based on a moving speed of the mobile station and a size of coverage according to the cell type, Selecting a first connected cell among the candidate cells so as to maximize the number of cells to be connected and the number of cells to which the connected cells of the mobile terminal do not change; And
Wherein the apparatus for controlling handover controls, for a remaining mobile terminal that has failed to select the first connected cell among the plurality of mobile terminals, Selecting a second connected cell for a mobile terminal in a mobile communication network. delete 10. The method of claim 9,
In the step of selecting the first connection cell
Wherein the apparatus for controlling handover includes a number of the candidate cells remaining connected to the candidate cell among the mobile terminals having the moving speed, a sum of QoS values for the plurality of mobile terminals in the candidate cell, And selecting the first connected cell so as to maximize the number of unconnected cells of the mobile terminal. 10. The method of claim 9,
In the step of selecting the second connection state
The apparatus for controlling handover selects a second connected cell for the remaining mobile terminals so that the sum of the QoS values for the plurality of mobile terminals and the number of unchanged cells connected to the mobile terminal are maximized Method for cell selection for handover in a communication network.

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