KR101820049B1 - Method and Apparatus for Automatically Setting Location ID based on PCI Sniffing of Neighbor Cell in Femto Cell - Google Patents

Abstract

The present invention automatically sets a TAI (Tracking Area Identity) equal to that of a neighboring macro cell in a femtocell based on an LTE (Long Term Evolution: Release 8) The present invention relates to a method and apparatus for managing a femtocell that can reduce a network load due to paging when a mobile station moves while preventing paging for an area update.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a method and an apparatus for automatically setting a location ID of a neighboring cell in a femtocell based on PCI sniffing,

[0001] The present invention relates to a femtocell management method and apparatus, and more particularly, to a femtocell based on a long term evolution (" Release 8 ") based femtocell, The present invention relates to a method and an apparatus for managing a femtocell which can reduce the network load due to paging during movement of a mobile station by preventing paging for a Tracking Area Update (TAU) from occurring during mobile terminal movement.

In addition to an evolved NodeB (eNB), which is a general macro base station defined in 3GPP LTE (Long Term Evolution: Release 8), a femto base HeNB (home evolved NodeB) can be installed and managed in a macro cell area . The macro base station connects the communication of the mobile terminal under the control of the controller (RNC) interworking with the core network (CN). The femto base station operates at a very small / low power level and covers a very small range of femtocell area It is installed indoors in homes, offices and so on. The femto base station is a small cellular base station connected to a broadband router. It is controlled by a femto gateway (G / W) that manages femto base stations and a home evolved management server (HMS) (CN) to enable voice and data communication of 2G as well as 3G. The femto base station can support connection of the terminal in Open Mode (mode in which a registered user terminal can access) or Closed Mode (mode in which all user terminals can access).

In general WCDMA-based mobile communication, as shown in FIG. 1, the location (LA1, LA2 ..) of the mobile station is identified as a location area identity (LAI) value for paging of the mobile station, The mobility is ensured so that communication can be established via a nearby base station and an exchange (MSC / VLR) regardless of the location. On the other hand, in the 3GPP LTE based mobile communication, the location (TA1, TA2, TA3 ..) of the terminal is identified by the TAI (Tracking Area Identity) value for paging of the mobile terminal in the femtocell, The mobility management entity (MME) supports the mobility to connect the call by paging the corresponding terminal through the support of the MME.

However, as shown in FIG. 2, in the 3GPP LTE based mobile communication, when a large number of femtocells are installed in the macro cell area covering the communication of the macro base station, the mobile terminal moves from the macro cell area to the femtocell area, There is a problem that paging for updating the location registration of the mobile terminal occurs. In particular, the coverage of the macro cell is not clear due to the influence of signal attenuation and fading in the TA boundary region. Therefore, when the TAI allocated to each femtocell is different from that of another cell, There is a problem that the load on the network becomes large.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and it is an object of the present invention to provide a method and apparatus for automatically setting a TAI such as an adjacent macro cell in an LTE based femtocell, The present invention provides a method and apparatus for managing a femtocell that can reduce a network load due to paging when a mobile station moves while avoiding paging for a femtocell.

In order to determine the exact location of the femto BS to which the TAI is to be set, the femto BS measures the surrounding macrocells at the time of initial installation, The present invention also provides a method and apparatus for managing a femtocell in which TAI can be accurately set to a femto base station by using position information of the femto base station.

According to another aspect of the present invention, there is provided a method of managing a femtocell, the method comprising the steps of: measuring a femto base station identification information of a neighboring macrocell, Receiving ID, location information, and the base station identification information and requesting a location ID from a macro management server on the network; And the macro management server manages the location ID corresponding to the base station identification information transmitted according to the request as the location ID of the femto cell and transmits the location ID to the femto base station, ID "

The femtocell management method is characterized in that the terminal is prevented from performing location registration update upon movement of a macrocell, a femtocell, or a femtocell on a network in a location registration using a location ID of a base station of the neighbor macrocell .

The base station identification information is PCI (Physical Cell Identity) information, which is a physical identifier of a macro cell, and the location ID is TAI (Tracking Area Identity) information, which is an identifier of a cell region covered by the femto BS.

The macro management server receives the location information and the base station identification information included in the request and updates a location ID of a corresponding macro cell whose location information and base station identification information match in a database with a location ID .

The location information may be GPS position information measured by the femto base station using the GPS module, a physical port number of the femto base station connected to the femto gateway, or a unique location information identifier previously set for the femto base station.

The femtocell management server according to another aspect of the present invention receives the femtocell ID, the location information, and the base station identification information after the femto base station measures the base station identification information of the neighbor macrocell, A location ID request unit for requesting a location ID; And the macro management server manages the location ID corresponding to the base station identification information transmitted according to the request as the location ID of the femto cell and transmits the location ID to the femto base station, ID " as < / RTI >

According to the method and apparatus for managing a femtocell according to the present invention, the same TAI as that of a macro cell adjacent to a femtocell is automatically set, thereby avoiding paging for update of location registration when a mobile station moves between macrocells and femtocells or femtocells, The network load due to the paging of the city can be reduced.

Since the femto base station can accurately set the TAI in the femto base station by using the sniffing-based physical cell identity (PCI) and the location information for measuring and transmitting macrocells around the femto base station, It is possible to effectively prevent the location registration update at the time of movement of the terminal.

1 is a diagram for explaining a service environment of a general macro cell and a femtocell.
2 is a diagram for explaining a location registration update load in a service environment of a general macro cell and a femtocell.
3 is a view for explaining a communication network system according to an embodiment of the present invention.
4 is a diagram for explaining a femto management server according to an embodiment of the present invention.
5 is a flowchart illustrating an operation of a communication network system according to an embodiment of the present invention.
6 is a diagram for explaining location registration in a service environment of a macro cell and a femtocell of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout.

3 is a diagram for explaining a communication network system 100 according to an embodiment of the present invention.

3, a communication network system 100 according to an exemplary embodiment of the present invention includes a core network (CN) 110, a macro management server 120, a femto gateway 130, (HMS) 140, a macro base station (eNB) 150, and a plurality of femto base stations (APs) 170.

The core network 110 is a network of mobile communication providers including mobile communication networks such as WCDMA, WiFi, and WiBro, and wired and wireless Internet. A radio network controller (RNC) (not shown) between the macro base station 150 and the core network 110 performs radio resource management (RRM) according to the scheduling of radio resources in cooperation with the core network 110 ) Function and a handover function for supporting mobility between cells, so that the mobile terminal can support 2G and 3G voice and data communication through the macro base stations 150. [

The macro base stations 150 and the femto base stations 170 are respectively connected to a macro base station covering communication of a macro cell area corresponding to an evolved NodeB (eNB) defined in 3GPP LTE (Long Term Evolution: Release 8) The femto base station may be a femto base station that covers communication of the femtocell region corresponding to the femto cell. The femto base stations 160 operate in a very small size / low power so as to cover a very small range of the femtocell area than the macro cell area. And is connected to the femto gateway 130 that manages the femto base stations 160 and is controlled by the femto gateway 130 and the femto management server 140 to receive the core And enables communication of voice and data of 2G as well as 3G with other mobile terminals in the macro cell area or the femtocell area in cooperation with the network 110. [

Particularly, in the present invention, a mobile terminal capable of receiving a mobile communication service through a core network 110 such as a smart phone, a cellular phone, and a PCS phone (Personal Communications Services phone) In order to reduce the network load due to the paging during the movement of the mobile station, the femto base stations 160 may be located at the same position as the neighboring macrocells in the initial installation, ID (e.g., TAI) can be automatically set.

For example, when a femto base station 160 that is initially installed measures femtocell ID (unique identification information of a femto base station) to transmit after measuring base station identification information (e.g., PCI) of a neighboring macro cell, Upon receiving the identification information (e.g., PCI), the femto management server 140 may request a location ID (e.g., TAI) from the macro management server 120 connected to the core network 110 through the femto gateway 130 . Accordingly, the macro management server 120 transmits a location ID (e.g., TAI) corresponding to the base station identification information (e.g., PCI) according to the request, and the femto management server 140 transmits the base station identification information (E.g., TAI) corresponding to the neighboring macrocell to the corresponding femto BS 160 and transmits the location ID (e.g., TAI) to the femto BS 160 in the same manner as the base station 150 of the neighbor macrocell It can be controlled by transmitting a parameter to set it as a position ID.

In the present invention, the macro management server 120 uses the sniffing base station identification information (e.g., PCI: Physical Cell Identity) and location information received from the femto management server 140, (E.g., TAI) corresponding to the location ID (e.g., 150). The macro management server 120 further compares the location information of the femto base station 160 to prevent ambiguity due to duplication of PCI that can be equally allocated to base stations of other macro cells, The femto base station 160 extracts a location ID (e.g., TAI) corresponding to the base station 150 of the macrocell, The femto management server 140 can effectively prevent the location registration update when the terminal moves between the macro cell and the femtocell or the femtocell.

For this, the femto management server 140 according to an embodiment of the present invention may include a location ID request unit 141, a database 142, and a configuration management unit 143, as shown in FIG.

First, briefly, the location ID request unit 141 receives the femtocell ID of the femto base station 160, which is transmitted from the femto base station 160 after measuring the base station identification information (e.g., PCI) (E.g., PCI) and requests a location ID (e.g., TAI) from the macro management server 120 on the network. The femtocell base station 160 transmits GPS position information (including latitude, longitude, and altitude information) measured by a femto base station 160 using a Global Positioning System (GPS) module to the femto base station 160 The physical port number to which the femto base station 160 is connected, or the unique position information identifier previously set for the femto base station 160, for example.

Here, the base station identification information for the base station 150 of the neighboring macro cell is PCI (Physical Cell Identity) information that is a physical identifier unique to the macro cell. In addition, the location ID requested by the macro management server 120 is TAI (Tracking Area Identity) information, which is an identifier of a cell area covered by the femto BS 160, Is set to the same position ID as the position ID which is the identifier of the cell region to be used.

The setting management unit 143 stores the location ID (e.g., TAI) corresponding to the base station identification information (e.g., PCI) transmitted in response to the request of the location ID request unit 141 in the macro management server 120 The femto base station 160 may manage the femto base station 160 in the database 142 with the femtocell location ID and transmit the corresponding location ID (e.g., TAI) to set the same location ID as the base station 150 of the neighbor macrocell .

When requesting a location ID (e.g., TAI) from the macro management server 120, the location ID request unit 141 transmits a message including the location information of the femto BS 160 and the BS identification information (e.g., PCI) And the macro management server 120 extracts a location ID (e.g., TAI) corresponding to the base station 150 of the corresponding macro cell from a database (not shown) in response to a request from the location ID requesting unit 141 can do. In order to prevent ambiguity due to duplication of PCI that can be equally allocated to base stations of other macrocells, the macro management server 120 transmits base station identification information (e.g., PCI) managed in the database and location information of the femto base station 160 (E.g., TAI) of the corresponding macrocell whose location information coincides with the base station identification information (e.g., PCI) transmitted by the location ID request unit 141 from the location ID list corresponding to the base station identification information (e.g., PCI) and responds to the setting management unit 143 in the form of a message included in a predetermined message.

In this way, the macro management server 120 accurately extracts the location ID (e.g., TAI) corresponding to the base station 150 of the macro cell by accurately dividing the macro cells based on the base station identification information (e.g., PCI) and the location information . Accordingly, the setting management unit 143 correctly sets the same location ID (e.g., TAI) as that of the base station 150 of the macrocell based on the femtocell ID (unique identification information of the femto base station) By transmitting the parameter, the mobile terminal can perform location registration using the same location ID as the location ID (e.g., TAI) of the base station of the neighboring macro cell even in the femtocells within the macro cell. Accordingly, when the mobile terminal moves between the macrocell and the femtocell on the network, or moves between the femtocells, the femto management server 140 regards the femto management server 140 as the same cell area and can control not to perform the location registration update.

Hereinafter, the operation of the communication network system 100 according to an embodiment of the present invention will be described in more detail with reference to the flowchart of FIG.

When the macro base station 150 is installed in a home, an office, or the like in a macro cell area covering communication, the femto base station 160 automatically sets a location ID (e.g., TAI) through the following process.

First, the femto base station 160 may measure the signal received from the base station 150 of the neighbor macrocell at the time of initial installation and determine the base station identification information (e.g., PCI) for the base station 150 (S110) . PCI is a physical identifier unique to each base station that is physically easy to grasp.

The femto base station 160 measures the base station identification information (e.g., PCI) of the neighboring macro cell and then transmits the femto base ID , And transmits the information request message (REQ) including the PCI to the femto management server 140 through the femto gateway 130 (S120). The location information of the femto base station 160 includes GPS position information (including information such as latitude, longitude, and altitude) measured by the femto base station 160 using a Global Positioning System (GPS) module, The physical port number of the femto base station 160 when the femto base station 160 is connected to the gateway 130, or the unique position information identifier previously set for the femto base station 160. The reason why the base station identification information (e.g., PCI) of the neighboring macro cell is transmitted together with the location information of the GPS and the like is that even if the location is determined geographically by the GPS module or the like, It is difficult to know due to the irregular nature of wireless coverage due to attenuation.

The femto management server 140 may transmit a response message (RSP) to the femto BS 160 in response to the information request message REQ of the femto BS 160, Transmits the TAI request message including the location information of the femto BS 160 and the base station identification information (e.g., PCI) of the neighboring macro cell included in the information request message (REQ) to the macro management server 120, (E.g., TAI) to the macro management server 120 in step S121. The location ID requested by the macro management server 120 is information of TAI (Tracking Area Identity) which is an identifier of a cell area covered by the femto BS 160 and is an identifier of a cell area covered by the base station 150 of the neighboring macro cell Is set to the same position ID as the position ID.

The macro management server 120 receiving the TAI request message from the location ID requesting unit 141 may extract a location ID (e.g., TAI) corresponding to the base station 150 of the macro cell from the database (not shown) (S130, S131). For example, in order to prevent ambiguity due to PCI duplication, which can be equally allocated to the base stations of other macro cells, the macro management server 120 responds to base station identification information (e.g., PCI) (E.g., PCI) transmitted from the location ID requesting unit 141 from the list of the location IDs of the corresponding macrocells (S130) The location ID (e.g., TAI) may be extracted from the database (S131). The macro management server 120 transmits a location ID (e.g., TAI) corresponding to the detected base station identification information (e.g., PCI) to the femto management server 140 on the network in a predetermined message (S132) .

For example, the database managed by the macro management server 120 includes a list of base station identification information (e.g., PCI), location information of the femto base station 160, and location ID (e.g., TAI) And the macro management server 120 may determine whether the macro information of the macro cell having the corresponding base station identification information (e.g., PCI) is identical to the macro information of the femto base station 160 (E.g., TAI) of the ID of the cell and transmit it to the femto management server 140. In some cases, each location information managed in the database managed by the macro management server 120 may be managed as a range of location values. At this time, the macro management server 120 transmits location information (e.g., GPS (E.g., location information, physical port number, or pre-set unique location information identifier, etc.) may be stored in a range of location values of the ID of the corresponding macrocell managed by the database (e.g., range of GPS location information, The range of the unique position information identifier set in advance, etc.), it may be determined that the position information matches.

The setting management unit 143 of the femto management server 140 that receives the location ID (e.g., TAI) corresponding to the base station identification information (e.g., PCI) of the peripheral macro cell from the macro management server 120 stores the location ID 142) (S133). In this manner, the setting management unit 143 can store and manage the location ID (e.g., TAI) corresponding to each base station of the macrocell to each of a plurality of femto base stations in the database 142. [

Thereafter, the setting management unit 143 transmits a parameter setting message including the corresponding location ID (e.g., TAI) transmitted from the macro management server 120 to the femto BS 160 having the femtocell ID, The femto BS 160 may control the femto BS 160 to set the same location ID (e.g., TAI) as the location ID (e.g., TAI) of the neighbor base macro cell 150 in step S140.

Accordingly, the femto BS 160 receiving the parameter setting message from the setting management unit 143 sets the same location ID (e.g., TAI) as that of the base station 150 of the surrounding macrocell to its own location ID (e.g., TAI) (S150).

Accordingly, the mobile terminal can perform location registration using the same location ID as the location ID (e.g., TAI) of the base station of the surrounding macrocell even in the femtocells within the macrocell. Accordingly, when the mobile terminal moves between the macrocell and the femtocell on the network, or moves between the femtocells, the femto management server 140 regards the femto management server 140 as the same cell area and can control not to perform the location registration update.

As described above, in the present invention, the macro management server 120 accurately divides macro cells based on the base station identification information (e.g., PCI) and the location information and outputs the location ID (e.g., TAI) corresponding to the base station 150 of the macro cell, The femto management server 140 extracts the same location ID (e.g., TAI) as that of the base station 150 of the macrocell based on the femtocell ID (unique identification information of the femto base station) Can be controlled to be set automatically. Accordingly, the femto BS 160 can automatically and accurately set the same TAI as that of the macro cell adjacent to the femtocell, thereby avoiding paging for update of the location registration when moving the terminal between the macro cell and the femtocell or the femtocell, The network load due to the paging of the network can be reduced.

The functions used in the femto gateway, the femtocell management server, the macro management server, and the method according to an embodiment of the present invention described above can be implemented as computer-readable codes on a computer-readable recording medium Do. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. Examples of the computer-readable recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, a hard disk, a removable storage device, And the like. It should also be noted that the computer-readable recording medium may be distributed over a networked computer system and stored and executed in a computer readable code form in a distributed manner.

While the invention has been shown and described with reference to certain preferred 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. This is possible. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

The macro management server 120
The femto gateway 130,
The femto management server 140,
The location ID request unit 141,
In the database 142,
The setting management unit 143,

Claims (7)

In the femto management server, after the femto base station measures the base station identification information of the neighboring macrocell, in response to a request including the femtocell ID, the location information, and the base station identification information transmitted by the femto base station, Requesting a location ID; And
The femto management server manages the location ID corresponding to the base station identification information transmitted by the macro management server according to the request of the location ID with the location ID of the femto cell, ID of the neighboring macro cell to be set as the same position ID as the base station of the neighboring macro cell,
The macro management server searches for a location ID of the macro cell corresponding to the location information and the base station identification information included in the request of the location ID as the location ID corresponding to the base station identification information Femtocell management method. The method according to claim 1,
Wherein the location registration is performed using a location ID of a base station of the neighboring macro cell when the mobile station moves between macrocells and femtocells or moves between femtocells on a network. The method according to claim 1,
Wherein the base station identification information is PCI (Physical Cell Identity) information that is a physical identifier of a macro cell. The method according to claim 1,
Wherein the location ID is tracking area identity (TAI) information that is an identifier of a cell area covered by the femto base station. The method according to claim 1,
The macro management server receives the location information and the base station identification information included in the request for the location ID and updates the location ID of the corresponding macro cell whose location information and base station identification information match in the database to the base station identification information And searching for the femtocell as a corresponding location ID. In the femto management server, after the femto base station measures the base station identification information of the neighboring macrocell, in response to a request including the femtocell ID, the location information, and the base station identification information transmitted by the femto base station, Requesting a location ID; And
The femto management server manages the location ID corresponding to the base station identification information transmitted by the macro management server according to the request of the location ID with the location ID of the femto cell, So as to set the same location ID as the base station of the neighboring macro cell,
The femto base station determines whether the femto base station is located at a location including the GPS position information measured by the femto base station using the GPS module, the physical port number of the femto base station connected to the femto gateway, And the location ID corresponding to the base station identification information is determined using the location information. A location ID request unit for receiving a femtocell ID, location information, and the base station identification information transmitted from the femto base station after measuring the base station identification information of the neighboring macro cell, and requesting the macro management server on the network for the location ID; And
A location ID corresponding to the base station identification information transmitted from the macro management server in response to the request of the location ID is managed as a location ID of the femto cell and the location ID is transmitted to the femto base station, As the location ID,
The macro management server searches for a location ID of the macro cell corresponding to the location information and the base station identification information included in the request of the location ID as the location ID corresponding to the base station identification information Femtocell management server.

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