KR101691662B1 - Method and Apparatus for Assigning Cell Resource of Mobile Communication System - Google Patents

Abstract

The present invention relates to a cell resource allocation method for a wireless communication system that can minimize cell ID collisions by separately assigning a cell ID group of a PCID (Physical Layer Cell Identity) to a macro cell of a wireless communication base station and a small- And a device equipped with the function.
In order to achieve the above object, the present invention provides a method for allocating PCIDs to a plurality of small cell devices located within a macrocell coverage, the method comprising the steps of: allocating a plurality of PCIDs from a minimum value to a maximum value, Assigning a cell ID incrementally from a minimum value of a PCID group to the macro cell and decreasing a cell ID from a maximum value of a PCID group for a small cell device; And allowing the macro cell to operate the cell by increasing the PCID group from the minimum value and allocating the PCID group from the maximum value to the small cell to operate the cell.

Description

[0001] The present invention relates to a cell resource allocation method and apparatus for a wireless communication system,

The present invention relates to a method and apparatus for effectively allocating a physical layer cell identity (PCID) to a cell area for wireless communication, thereby minimizing a cell ID collision between a macro cell and a small- And a method of allocating the same.

2. Description of the Related Art In recent years, as the use of the Internet as a multimedia communication method has been actively developed, demand for using the Internet while using the mobile communication terminal has been greatly increased. As the contents on the Internet provided to the mobile communication terminal are multimedia, The traffic volume has increased significantly as communication traffic has shifted from the center of existing voice traffic to the center of multimedia traffic in the form of data.

Compared with base station-based mobile communication networks, which have been designed mainly for voice service as a main function in accordance with a significant increase in the demand for mobile communication, the next generation mobile communication network is required to secure high capacity, Efforts have been made to resolve this problem.

On the other hand, in a wireless communication system using a cellular mobile communication system, when there are many shadow regions in a base station cell and the geographical condition is poor or the channel state becomes poor due to a difference in distance between the mobile communication terminal and the base station, The communication can not be smoothly performed.

In order to solve this problem, recently, the concept of a pico cell has been proposed for smooth communication service in a radio wave shadow area. In order to solve the service problem in the radio wave area and to provide a high quality data service to more users A femtocell concept has been proposed in which a picocell and a femtocell have a very small cell area compared to a macro cell and a plurality of picocells and femtocells And a long term evolution (LTE) system in which cells are classified using a physical layer cell identity (PCID) (hereinafter referred to as a PCID) is used in consideration of these points.

In this LTE system, 504 PCIDs are used for cell classification, and 504 PCIDs can be fully utilized for operating a macrocell type eNB.

However, in the case of small-scale equipment such as a pico-cell eNB, a home eNB, and a femtocell eNB having a cell area smaller than that of a macro cell, it is possible to install tens of thousands to hundreds of thousands of cells within a single cell coverage. When the equipment and the macro cell eNB share the PCID, there is a possibility of conflict of the PCID, so that the operating system of the system may become unstable, and the performance degradation of the handover becomes extremely severe. have.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a method and apparatus for allocating a cell ID group of a PCID (Physical Layer Cell Identity) ID collision of a wireless communication system, and to provide an apparatus therefor.

It is another object of the present invention to provide a cell ID group for a cell in which a cell ID group of a PCID is separately assigned to a macro cell and a small cell device, And to provide a method and apparatus for allocating cell resources in a wireless communication system.

According to another aspect of the present invention, there is provided a method of allocating PCIDs for cell classification to a plurality of small scale cell devices located within a macro cell coverage, Setting a cell ID from a minimum value of the PCID group to a maximum value of the PCID group from the maximum value of the PCID group for a small cell device; And allocating a PCID group from the minimum value to the macrocell to allow the cell to operate; and allocating a PCID group from the maximum value to the small cell to operate the cell The method of claim 1, further comprising the steps of: The ball.

According to another aspect of the present invention, there is provided a maintenance and control apparatus for a base station, comprising: a plurality of small scale cell equipment located within a macro cell coverage; maintenance and maintenance of a base station for allocating a PCID for cell division; A control unit configured to monitor a PCID allocation state between the small-scale network equipment from the communication unit and the macrocell or the macrocell, A measurement unit for measuring whether a PCID collision occurs in a small cell, a plurality of PCIDs allocated to a predetermined number from a minimum value to a maximum number of PCID groups, and a minimum value of a PCID group And for a small cell device, the cell ID is allocated from the maximum value of the PCID group, And a control unit for controlling the cells to be operated within the range of the PICD group divided by reflecting the measurement result from the measurement unit, And a storage unit for storing and managing assignment information for each home cell.

As described above, according to the present invention, in the wireless communication system, the PCIDs for the macrocells are allocated from the minimum value for each ID group, the small-sized home eNBs, the femtocell eNBs, etc. are allocated from the maximum value of the PCID group , The predetermined intermediate value (INIT) of the PCID can be flexibly increased / decreased by the step (STEP) so that the PCID collision can be eliminated by adjusting the median value at the time of the PCID collision, It is possible to minimize the PCID collision between the small scale cell device and the macro cell and even if the PCID collision occurs, it is possible to quickly remove the collision situation by the increase / decrease operation of the flexible PCID.

1 illustrates a configuration of a wireless communication system to which a cell resource allocation method according to the present invention is applied;
2 is a detailed block diagram of the control apparatus of the base station shown in FIG. 1,
3 is a diagram illustrating a structure of an information frame of a PCID group for segmented allocation of a PCID according to the present invention;
4 is a diagram illustrating an information frame structure showing cell ID allocation states of a macro cell and a small cell device according to a PCID group according to a preferred embodiment of the present invention;
FIG. 5 is a diagram illustrating allocation states of IDs for minimizing signal interference of the alpha / beta / gamma sectors of a macro cell and a small-scale cell equipment according to a preferred embodiment of the present invention.

Hereinafter, the present invention configured as described above will be described in detail with reference to the accompanying drawings.

FIG. 1 is a diagram illustrating a configuration of a wireless communication system to which a cell resource allocation method according to the present invention is applied.

1, a wireless communication system to which the present invention is applied includes a base station 100, a plurality of microcell eNBs (Evolved NodeBs) A1 to An, a plurality of Home Cells ) eNBs B1 to Bn, and a mobile communication terminal 200.

Although the present invention will be described by way of an example of a home cell eNB as a network equipment having the smallest cell coverage, it is also possible to use a small-sized (e.g., PicoCell) eNB or a femtocell eNB including the microcell eNB It is needless to say that the embodiment of the present invention can be equally applied to network equipment.

The base station 100 is constructed to form macrocells having a radius of about 35 Km or less and is capable of performing direct radio communication with the mobile communication terminal 200 located in its own cell coverage or transmitting a plurality of picocell eNBs A1 to An Or wireless communication with the mobile communication terminal 200 through the femtocell eNBs B1 to Bn having the smallest cell coverage.

The plurality of microcell eNBs (A1 to An) are constructed to form microcells each having a radius of about 1 Km or less. The microcell eNBs (A1 to An) can be wirelessly communicated with the mobile communication terminal 200 located in its own cell coverage, Can be handed over.

The plurality of the home cells eNB (B1 to Bn) are constructed so as to respectively form a home cell having a radius of about 25 m. The home cells eNB (B1 to Bn) are connected to the mobile communication terminal 200, Communication, and Internet communication.

Meanwhile, the base station 100, the plurality of microcell eNBs A1 to An, and the plurality of home cells eNBs B1 to Bn each have a hierarchical cellular network structure, which provides a very large coverage The macrocell network can be used to secure wide area coverage and support high-speed mobile users. On the other hand, when the number of users included in a single macro cell greatly increases, It is possible to constitute a micro cell occupying a smaller coverage area than the macro cell in a region where users are dense and to constitute a home cell, a pico cell, and a femtocell which are responsible for a smaller coverage, The capacity that can be provided by a single base station of the base station can be divided and used by a small number of users Is to allow the users to get the data traffic services.

In this process, cell ID collision occurs when the PCID for 504 cell classification held by the single base station 100 is shared with a small-sized network device such as a home cell. In the present invention, this is minimized.

That is, in the base station 100, 504 PCIDs are formed into 168 PCID groups and are allocated to the macrocells of the corresponding base station 100 from the minimum value of the PCID group, while decreasing from the maximum value of the PCID group And allocates the PCID to each of the small-sized home cell eNBs (B1 to Bn) so that the collision of the cell IDs is minimized.

Next, a detailed configuration of the control apparatus of the base station shown in Fig. 1 is shown.

The maintenance and control apparatus of the base station includes a communication unit 10, a measurement unit 20, a control unit 30, and a storage unit 40.

The communication unit 10 performs wireless communication with the mobile communication terminal 200, the micro cell eNBs A1 to An and the home cell eNBs B1 to Bn for voice signal communication, data communication, internet communication, And performs communication for allocation of the PCID.

The measurement unit 20 is for measuring whether or not the cell ID collides with the cell ID allocated to the macro cell by monitoring the allocation state of the PCID with the home cell eNBs B1 to Bn through the communication unit 10, PCID collision occurs from the corresponding macro cell or the home cell and provides the measurement result to the control unit 30. [

The controller 30 sets 504 PCIDs for cell classification to 168 PCID groups, incrementally allocates the macrocells of the base station from the minimum value, and sets the maximum number of PCID groups for the home cell eNB And the predetermined intermediate PCID group position is designated as an intermediate value INIT so that the intermediate value of the intermediate value of the intermediate value PCID is determined according to the measurement result of the PCID collision from the measurement unit 20, (I.e., when the PCID collides with the macro cell) or decreases (i.e., when the PCID collides with the home cell) by a predetermined step (STEP).

The storage unit 40 stores and manages allocation information for a macro cell and a home cell of a PCID that is dynamically allocated by the controller 30.

3, the control unit 30 sets 0, 1, and 2 as the unit group N _ID (2) as the entire PCID (N _ID ^cell ) of 0 to 503 (504) and it forms a PCID group (N _ID (1)) of 0-167 (168) groups the respective unit groups (N _ID (2)).

In this state, the control unit 30 starts counting from the first "0 ", which is the minimum value (MIN) for the macro cell, 1) (for example, 0 to 120), and for the home cell, the PCID group is decrementally allocated starting from the "167" Is allocated to the intermediate value INIT so that the home cell can be allocated from the 167th to the previous (e.g., 121st) of the maximum intermediate value INIT.

Accordingly, the control unit 30 controls the macro cell to operate the assigned cell using the PCID group from the minimum value MIN to the intermediate value INIT determined by the intermediate value INIT Quot; 167 "for the home cell and operates the assigned cell using the PCID group from the maximum value MAX to the intermediate value INIT.

If it is determined from the measurement result of the measurement unit 20 that the collision of the PCID occurs in the macrocell, the control unit 30 determines the intermediate value INIT from the initial set PCID position in STEP ) (In this case, the step value is set to "1") to increase the number of PCIDs in the macrocell.

On the other hand, if it is recognized that PCID collision occurs in the home cell, the controller 30 decreases the intermediate value INIT by a predetermined step from the initial PCID setting position, and stores the number of PCIDs in the home cell The collision of the cell ID is eliminated.

As shown in FIG. 5, the alpha / beta / gamma (alpha / beta / gamma) sectors commonly present in the macrocell and the home cell minimize interference due to the signal phase of the reference signal is each using a 0/1/2 _ID contained in the N (2) to.

In addition, when the specific home cell eNB among the home cells eNB (B1 to Bn) is Omni type, the cell ID is randomly allocated among the remaining N _IDs (2).

While specific embodiments of the invention have been described and shown above, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Such modified embodiments should not be understood individually from the technical idea and viewpoint of the present invention, but should be regarded as belonging to the claims attached hereto.

10: communication unit, 20: measuring unit,
30: control unit, 40: storage unit,
100: base station, 200: mobile communication terminal,
A1 to An: Microcell eNB, B1 to Bn: Home cell eNB.

Claims (10)

A method for allocating a plurality of small cell devices and a physical layer cell identity (PCID) for cell classification within a macro cell coverage,
A first step of setting a plurality of PCIDs into a plurality of PCID groups having a maximum value from a minimum value that is constantly bound to a specific number;
A second step of allocating a cell ID incrementally from the minimum value of the PCID group to the macro cell and decreasingly assigning a cell ID from the maximum value of the PCID group to the small cell device; And
And a third step of allowing the macro cell to operate the cell by increasing the PCID group from the minimum value and allocating the PCID group in a decreasing manner from the maximum value for the small cell to operate the cell Wherein the cell resource allocation method comprises: The method according to claim 1,
In the second step, an intermediate PCID group position is set as an intermediate value among all the PCID groups, and when the PCID collision occurs in the macrocell, the intermediate value is increased by a predetermined number of steps, or PCID And decreasing the intermediate value by a predetermined number of steps at the time of a collision. 3. The method of claim 2,
Wherein the macrocell operates the assigned cell using the PCID group from the minimum value to less than the median value determined by the median value in the third step, Wherein the cell allocation unit allocates the allocated cells to the cell resource allocating unit. The method according to claim 1,
Wherein the number of the PCIDs is 504, and the PCID group has 168 groups ranging from 0, which is the minimum value, to 167, which is the maximum value, . The method according to claim 1,
Wherein the small cell equipment is any one of a home cell eNB (evolved NodeB), a microcell eNB, a pico cell eNB, and a femtocell eNB. A method for allocating cell resources in a system. An apparatus for allocating a plurality of small scale cell devices located within a macro cell coverage and a physical layer cell identity (PCID) for cell classification,
A communication unit for performing wireless communication with the small scale cell equipment and performing communication for allocating a PCID;
A measurement unit for monitoring a PCID allocation status from the communication unit to a small-scale network equipment and measuring whether a PCID collision occurs in the macro cell or the small cell;
A plurality of PCIDs are set to a plurality of PCID groups having a maximum value from a minimum value that is constantly bundled in a specific number, cell IDs are assigned incrementally from the minimum value of the PCID group for macrocells, A control unit that allocates cell IDs in a decreasing manner from the maximum value of the PCID group and controls the cells to operate within the range of the PCID groups that are divided by reflecting the measurement result from the measurement unit; And
And a storage unit for storing and managing assignment information for each macro cell and each home cell of a PCID that is dynamically allocated by the control unit. The method according to claim 6,
Wherein the control unit designates an intermediate PCID group position among the entire PCID groups as an intermediate value and increases the intermediate value by a predetermined number of steps when a PCID collision occurs in the macrocell according to a measurement result from the measurement unit, And controls to reduce the intermediate value by a predetermined number of steps in case of a PCID collision in the small cell. 8. The method of claim 7,
Wherein the controller operates the assigned cell using the PCID group from the minimum value to a value less than the intermediate value determined by the intermediate value, and calculates the PCID from the maximum value to the intermediate value, Wherein the cell allocation unit allocates the cells allocated to the plurality of cells to the plurality of cells. The method according to claim 6,
Wherein the number of the PCIDs is 504, and the PCID group has 168 groups ranging from 0, which is the minimum value, to 167, which is the maximum value, . The method according to claim 6,
Wherein the small-scale cell equipment is any one of a home cell eNB, a microcell eNB, a picocell eNB, and a femtocell eNB.

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