KR20160092391A - Method for Resolving PCI Collision in Mobile Communication System - Google Patents

Abstract

The present invention relates to a method for solving PCI collision in a mobile communication system. The present invention allows redundancy allocation of PCI within the number of PCIs allowable for moving relay nodes (MRN) and solves the PCI collision between the MRNs by detecting and reallocating PCI collision to be allocated on the MRN caused by the concentration or access to the MRNs.

Description

Technical Field [0001] The present invention relates to a PCI collision in mobile communication system,

The present invention relates to a PCI conflict resolution method in a mobile communication system, and more particularly, to a PCI (Physical Cell Identity, Physical Cell Identifier) due to dense or approaching mobile relay nodes (mRN) The present invention relates to a mobile relay node and a method of operating a central node in a mobile communication system for detecting and resolving a collision of a mobile node.

Relay technology is introduced in LTE Rel-10 as a technology that can expand network coverage at low cost. In LTE, a relay node with its own independent cell is called a Type 1 relay node. A base station to which a relay node wirelessly connects via an Un interface is referred to as a donor base station, and a service area provided by a relay node is referred to as a relay cell. The Type 1 relay node has an independent relay cell having its own PCI, and appears as a cell different from the base station cell by the donor base station.

The transmission between the relay node and the donor base station is carried out through the LTE Un radio interface, and the Un interface is also referred to as the backhaul link. The LTE Rel-10 standard describes a wireless protocol for backhaul links. Transmission between the terminal and the relay node is performed through the LTE Uu air interface, and the Uu interface is also referred to as the access link. The wireless protocol of the access link is the same as the base station to terminal communication protocol in LTE. The relay node consists of a base station functional element and a terminal functional element. The terminal functional element operates as a user terminal for a donor base station, and the base station functional element operates as a base station for a terminal connected to a relay node. The terminal functional element operates like a normal user terminal, and the connection procedure of the general user terminal is directly applied to the Un interface to establish a connection between the relay node and the donor base station. This connection procedure is described in 3GPP TR 36.806.

LTE Rel-10 supports only stationary or fixed relay nodes. 3GPP TR 36.836 describes a mobile relay node installed on a vehicle roof such as a train or a bus. A terminal (referred to as a relay terminal) in the vehicle moving in the mobile relay node is wirelessly connected to the mobile relay node, not to the external base station. While the relay terminal is inside the vehicle, the relay terminal does not need to change the serving cell from the mobile relay node to another cell even if the vehicle moves through several base station cells. Instead, the mobile relay node is handed over from the donor base station to the other donor base station.

However, mobility relay node technology introduces new problems not found in cellular systems based on conventional fixed base stations. One of the problems to be solved is PCI management. In the LTE mobile communication system, PCI is a physical layer signal that identifies an LTE cell. PCI is allocated to all LTE cells and consists of a total of 504 different data sequences. The LTE cell transmits its own PCI sequence over the synchronization channel. The UE acquires the cell synchronization using the PCI and identifies the serving cell and the neighboring cells. Generally, in a cellular network using the same frequency band, the number of cells is more than 504, so that PCI is reused between cells which are not so much interfered with each other. However, if two cells using the same PCI are immediately neighboring, the terminal can not separate the signals between the two cells, or recognizes two cells as the same cell, so that the handover can not be performed. Another problem is that if both cells located in the same cell are located in the same cell, a PCI confusion that can not distinguish a target cell from the two cells in the middle cell during handover, Problems can arise. Therefore, it is most important to allocate PCIs so that there is no PCI conflict between neighboring cells or neighboring cells.

The LTE specification allows for 504 different PCIs, but if the network operator divides the entire PCI into several groups, the available number of PCIs is much smaller. For example, a network operator can use a range of PCI values for macro cells, small cells, fixed relay nodes, and home base stations in 504 PCIs.

In the conventional cellular system, the PCI allocation technique is a technique in which a base station is designed in a fixed state. However, there is a high possibility that a mobile relay node moving with its own PCI will collide with a cell identifier of another base station. For example, when a mobile relay node first connects to a network, even if there is no PCI conflict with neighboring cells, there is a high possibility that a mobile relay node moves and a PCI collision with another neighbor cell occurs. In another example, there is a high likelihood of a PCI collision between an area where a vehicle equipped with a mobile relay node is located or a mobile relay node approaching.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a mobile relay node (mRN) The present invention provides a method of operating a mobile relay node and a central node in a mobile communication system for detecting and reassigning a PCI collision allocated to a mobile relay node due to a mobile relay node.

Also, in the case of PCI collision detection in the mobile relay nodes, PCI information is broadcast based on D2D (Device-to-Device) multicast or broadcast communication according to the relay of the central node, and when the mobile relay node approaches, PCI interference To provide a method of operating a mobile relay node and a central node in a mobile communication system for resolving PCI conflicts between mobile relay nodes by detecting and reassigning PCI conflicts in advance so that broadcasted PCI information can be received There is.

In accordance with another aspect of the present invention, there is provided a method for processing a PCI conflict between mobile relay nodes in a mobile communication system, the method comprising: Assigning a PCI selected in the PCI subset permitted in the PCI management area to the first mobile relay node by allocating a PCI already allocated to the second mobile relay node to the PCI management area; Requesting D2D broadcasting of the collision information to the first mobile relay node and the second mobile relay node through the base station according to the redundant assignment; And the first mobile relay node and the second mobile relay node broadcast collision PCI information through the D2D broadcast channel and detect collision PCI information of the other of the first mobile relay node and the second mobile relay node, And assigning a new PCI to the corresponding relay node.

Wherein the mobile relay node accesses the macro network via a backhaul link and accesses the user terminal through an access link to transmit to the user terminal a content caching service, a location based advertisement service, a warning message service for the digital multimedia contents of the macro network, And is a node that provides a local service including a proximity SNS (Social Network Service) or a temporary service that provides a service for a predetermined time.

And the first mobile relay node detects and reports collision PCI information of the other party.

In a state where the second mobile relay node first connects to the network in the same PCI management area managed by the same one PCI subset, the first mobile relay node attaches to the network and then transmits the PCI allocation request Can be performed.

Wherein the first mobile relay node performs a PCI allocation request after handing over from a first PCI management area to a second PCI management area accessed by the second mobile relay node, For each of the second PCI management areas, the same PCI values to be used for allocation may be managed in the database.

According to another aspect of the present invention, a central node on a mobile communication network for handling PCI conflict between mobile relay nodes refers to a database according to a PCI allocation request of a first mobile relay node, A PCI allocator for allocating a PCI selected in the set to the first mobile relay node and allocating a PCI already allocated to the second mobile relay node in the PCI management area to the first mobile relay node; And a PCI conflict manager for requesting D2D broadcasting of the collision information to the first mobile relay node and the second mobile relay node through the base station in accordance with the duplicate assignment, and wherein the first mobile relay node and the second mobile relay The node broadcasts the collision PCI information through the D2D broadcast channel, and either the first mobile relay node or the second mobile relay node detects and reports the collision PCI information of the other party, Assign a new PCI to the node.

Wherein the mobile relay node accesses the macro network via a backhaul link and accesses the user terminal through an access link to transmit to the user terminal a content caching service, a location based advertisement service, a warning message service for the digital multimedia contents of the macro network, A local SNS (Social Network Service), or a local service including a temporary service providing a service for a predetermined time.

And the first mobile relay node detects and reports collision PCI information of the other party.

In a state where the second mobile relay node first connects to the network in the same PCI management area managed by the same one PCI subset, the first mobile relay node attaches to the network and then transmits the PCI allocation request Can be performed.

Wherein the first mobile relay node performs a PCI allocation request after handing over from a first PCI management area to a second PCI management area accessed by the second mobile relay node, For each of the second PCI management areas, the same PCI values to be used for allocation may be managed in the database.

According to another aspect of the present invention, there is provided a method of processing a PCI conflict of a mobile relay node in a mobile communication system, the method comprising: performing a PCI allocation request through a backhaul link; Receives a D2D broadcast request from a central node that duplicately allocates the same PCI already allocated to the second mobile relay node according to the PCI allocation request, and multicasts or broadcasts transmission / reception of the first collision PCI information using the D2D radio resource ; Detecting second collision PCI information received from the second mobile relay node according to the broadcast request; And reporting the detection of the second collision PCI information to the central node and reallocating the new PCI allocation to resolve the PCI collision.

Wherein the power for the multicast or broadcast transmission / reception is set to be greater than the power for the backhaul link from the mobile relay node to the base station, and before the PCI interference occurs close to the second mobile relay node, Can be detected.

After attaching to a network of the same PCI management area in a state in which the second mobile relay node first connects to the same PCI management area managed by the same one PCI subset, After the handover to the second PCI management area accessed by the second mobile relay node, the PCI allocation request can be performed.

According to another aspect of the present invention, there is provided a mobile relay node of a mobile communication system, the mobile relay node including: a PCI setting unit for performing a PCI allocation request through a backhaul link; Receives a D2D broadcast request from a central node that duplicately allocates the same PCI already allocated to the second mobile relay node according to the PCI allocation request, and multicasts or broadcasts transmission / reception of the first collision PCI information using the D2D radio resource A direct communication control unit; And a collision detecting unit for detecting second collision PCI information received from the second mobile relay node according to the broadcast request, wherein the PCI setting unit reports the detection of the second collision PCI information to the central node, The PCI collision can be resolved by reallocating the allocation.

Wherein the power for the multicast or broadcast transmission and reception is set to be greater than the power for the backhaul link from the mobile relay node to the base station and before the PCI interference occurs close to the second mobile relay node, 2 conflict PCI information can be detected.

After attaching to a network of the same PCI management area in a state in which the second mobile relay node first connects to the same PCI management area managed by the same one PCI subset, After the handover to the second PCI management area to which the second mobile relay node is connected, the PCI setting unit can perform the PCI allocation request.

According to the PCI conflict resolution method in the mobile communication system according to the present invention, the PCI collision allocated to the mobile relay node is detected and reallocated due to the concentration or access of the mobile relay nodes, , It is possible to prevent the occurrence of interference due to the use of the same PCI between the relay cells.

Also, it is possible to solve the PCI shortage problem by permitting PCI redundancy allocation within the allowable PCI number range of the mobile relay nodes (mRN) to enable the service of the mobile relay technology and to prevent the PCI interference from occurring in advance, It is possible to maintain the quality of communication without interruption.

In addition, since it is possible to detect and resolve PCI collision based on D2D (Device-to-Device) multicast or broadcast communication between mobile relay nodes according to the relay of the central node, Implementation is possible with simple hardware or software changes of the mobile relay node.

1 is a view for explaining a central node of a mobile communication system according to an embodiment of the present invention.
FIG. 2 is a diagram for explaining a method of allocating PCI by distinguishing a PCI management area and a PCI subset from a central node according to an embodiment of the present invention.
3 is a flowchart illustrating a procedure for resolving a duplicate PCI conflict in a central node according to an exemplary embodiment of the present invention.
4 is a diagram illustrating a PCI allocation operation after a mobile relay node attaches to a central node according to an embodiment of the present invention.
5 is a diagram illustrating a PCI management operation when a mobile relay node moves from a central node 100 to another PCI management domain according to an embodiment of the present invention.
6 is a specific block diagram of a mobile relay node according to an embodiment of the present invention.
7 is a flowchart illustrating a PCI conflict detection and resolution procedure according to PCI redundancy in a mobile communication system according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same components are denoted by the same reference symbols as possible. In addition, detailed descriptions of known functions and / or configurations are omitted. The following description will focus on the parts necessary for understanding the operation according to various embodiments, and a description of elements that may obscure the gist of the description will be omitted. Also, some of the elements of the drawings may be exaggerated, omitted, or schematically illustrated. The size of each component does not entirely reflect the actual size, and therefore the contents described herein are not limited by the relative sizes or spacings of the components drawn in the respective drawings.

1 is a view for explaining a central node 100 of a mobile communication system according to an embodiment of the present invention.

Referring to FIG. 1, a central node 100 according to an embodiment of the present invention includes a PCI allocator 110, a PCI conflict manager 120, and a PCI information database 130. These components of the central node 100 may be implemented in hardware (e.g., a semiconductor processor), software (e.g., computer program instructions), or a combination thereof.

The central node 100 according to an exemplary embodiment of the present invention may be provided in a donor or a macro base station (hereinafter referred to as a base station) on a core network or may be provided on a core network in a dedicated operation support system (OSS) It can also be built.

The central node 100 divides the mobile communication service areas covered by the base stations into at least one or more PCI management areas and manages them. Here, the PCI management area is a predetermined area for the central node 100 to allocate PCI, and is an area configured to cover at least one base station cell. In addition, the central node 100 classifies the PCI subset to be used for the mobile relay node in the PCI management area among 504 PCI according to the LTE standard, manages the PCI subset in the PCI information database 130, and selects PCI in the corresponding PCI subset To the mobile relay node in the PCI management area. Another PCI subset not used by the mobile relay node is used for PCI allocation for macro base station cells, small cells, fixed relay cells, home base stations, and the like.

The PCI information database 130 stores information necessary for PCI allocation, and PCI management area information, PCI subset information, PCI-related allocation information, and the like are stored in the PCI information storage.

The PCI allocator 110 allocates the PCI in response to the PCI allocation request of the mobile relay node. The PCI allocator 110 refers to the PCI information database 130 and selects an allowable PCI according to the reuse factor in the PCI subset managed for the PCI management area, and allocates the PCI to the mobile relay node requesting PCI allocation. If there is insufficient PCI value to be assigned to the mobile relay nodes in the PCI management area without any redundancy, the PCI allocator 110 may reallocate the PCIs assigned to the other mobile relay nodes according to the reuse factor to allocate the redundant PCI .

The PCI conflict management unit 120 requests the serving base stations DeNB to D2D broadcast collision PCI information to two or more mobile relay nodes using the same PCI.

2 is a diagram for explaining a method of allocating PCI by distinguishing a PCI management area and a PCI subset from the central node 100 according to an embodiment of the present invention.

2 (a), the PCI allocator 110 manages one PCI subset for the mobile relay nodes belonging to the PCI management areas a, b, and c, and reuses the PCI reuse factor = 1 It is possible to assign PCI to mobile relay nodes. That is, in this case, the same PCI can be reused once by using the same PCI in the PCI management area a or b, respectively.

Alternatively, as shown in FIG. 2B, the PCI allocator 110 manages the PCI sub-sets A, B, and C for the mobile relay nodes belonging to the PCI management areas a, b, and c, To the relay nodes. That is, in this case, each of the PCI sub-sets A, B, and C can have the same PCI, and the same PCI can be reused up to three times using the PCI management areas a, b, or c respectively.

The PCI allocator 110 may select and allocate the PCI in the PCI subset allowed to the mobile relay node entering the PCI management area. However, if the mobile relay node has more mobile relay nodes than the PCI number allowed in the PCI management area, or if the mobile relay node moves to another PCI management area, the PCI allowed in other PCI management areas may become insufficient. In this case, the PCI allocator 110 can allocate a PCI already used by another mobile relay node to the mobile relay node according to a request of a mobile relay node entering or attaching to the PCI management area (1)).

At this time, the PCI collision managing unit 120 may request to broadcast collision PCI information to two mobile relay nodes using the same PCI through the serving base stations (DeNB). Accordingly, two mobile relay nodes using the same PCI receive this and broadcast the collision PCI information through the D2D communication channel (see (2) in FIG. 3), and receive the collided PCI information of the broadcasted party as they approach each other The mobile relay node that detects the PCI collision reports the collision to the central node 100 (see (3) in FIG. 3). Accordingly, the PCI allocator 110 allocates a new PCI to the corresponding mobile relay node to control the reconfiguration of the relay cell, thereby resolving the PCI conflict (see (4) in FIG. 3).

In the PCI allocation and conflict resolution process, when a mobile relay node is already connected to the PCI management area, another mobile relay node connects to the same PCI management area and requests PCI assignment to the central node 100 through the base station (See FIG. 4), and may also be initiated by movement between two PCI management zones, i.e., handover, where the mobile relay node uses the same PCI subset (see FIG. 5).

4 is a diagram illustrating a PCI allocation operation after a mobile relay node attaches to a central node 100 according to an embodiment of the present invention. In FIG. 4, the base station cells A and B correspond to the cells belonging to the same PCI management area managed by the central node 100 in the same manner as in FIG. 2A or FIG.

The central node 100 transmits information such as the PCI subset information allowed for the mobile relay node, the assignment of each PCI value, and the cell global identifier (CGI) in use in the management target PCI management areas to the PCI information And can be managed in the database 130.

4, the terminal unit of the mobile relay node RN_x (see 520 in FIG. 5) can be attached to the base station cell A as a terminal (11). After attaching, the RN_x base station (see 510 in FIG. 5) accesses the central node 100 through the base station cell A and requests the setup information necessary for the RN (Relay Node) operation (12). The message for this request also includes a PCI allocation request that includes the PCI value in use (e.g., 10). The central assigning unit 110 of the central node 100 inquires the PCI management table of the database 130 and selects a PCI which is not used in the corresponding PCI subset 13 and sends it to the RN_x through the serving base station cell A ). At this time, the PCI allocation unit 110 may select at least one PCI.

4, if all of the PCIs (e.g., PCI = 1 to 10) are in use, the PCI allocator 110 selects the PCI value 10 being used by the other mobile RN_y and transmits the selected PCI value 10 through the serving base station cell A . If another mobile relay node allocates a PCI that is already being used, the PCI collision managing unit 120 transmits collision PCI information to two mobile relay nodes RN_x and RN_y using the same PCI through the serving base stations of cells A and B You can ask them to broadcast (15, 16). Accordingly, RN_x and RN_y are set to use the D2D broadcast channel of the backhaul link, broadcast collision PCI information through the D2D broadcast channel, and set to receive the colliding PCI information of the two mobile relay nodes, that is, The base station cell A instructs the terminal unit of the RN_x (refer to 520 in FIG. 5) to broadcast the collision PCI information through the D2D broadcasting channel at the request of the central node 100 and receives the collision PCI information broadcasted by the other mobile relay node RN_y . Similarly, base station cell B can also point to the same setting for RN_y.

D2D broadcasting can be transmitted / received by multicast or broadcast communication by allocating time frequency resources shared by all mobile relay nodes transmitting and receiving collision PCI information. Also, the identifier for D2D broadcasting is set to the same group ID shared by all mobile relay nodes transmitting and receiving collision PCI information, so that mobile relay nodes transmitting and receiving collision PCI information through the D2D broadcasting channel are able to access neighbor And can transmit / receive multicast or broadcast broadcast information of the mobile relay node. The PCI information broadcasted by the mobile relay node can broadcast the collision PCI information of the mobile relay node together with the PCI information received from the neighboring mobile relay node together. Thus, the mobile relay node (e.g., RN_x) may not only be a neighboring mobile relay node (e.g., RN_y) but also a PCI of another mobile relay node (e.g., RN_z) not requested to broadcast collision PCI information from the central node 100 Information may be received (Multi-tier).

5 is a diagram illustrating a PCI management operation when a mobile relay node moves from a central node 100 to another PCI management domain according to an embodiment of the present invention. In FIG. 5, the PCI management areas a and b represent managed areas of the central node 100 using the same PCI subset.

In FIG. 5, the mobile relay node RN_x using the PCI value 10 moves between the PCI management areas by handing over from the base station cell A in the PCI management area a to the base station cell B in the PCI management area b (21).

After the RN_x completes the handover to the target base station cell B, the RN_x base station (see 510 in FIG. 5) requests a PCI allocation by transmitting a message including the PCI value (for example, 10) (22). The central allocating unit 110 of the central node 100 inquires the PCI management table of the database 130 to check whether or not the PCI of the RN_x is redundantly used. If the RN_x uses the PCI , It is checked whether or not there is an unused PCI, and the PCI value is selected and assigned to the RN_x (23).

If another mobile relay node (e.g., RN_z) is using a PCI value (e.g., 10) in use by the RN_x as shown in FIG. 4 and all of the PCIs including the RN_x are already in use, Use can be allowed.

4, when the other mobile relay node allocates a PCI that is already in use, the PCI collision managing unit 120 performs two movements using the same PCI through the target base station of the B cell and the serving base stations of the adjacent C cell It may request to broadcast conflict PCI information to the relay node RN_x and the movement RN_z (24, 25). Accordingly, RN_x and RN_z are set to use the D2D broadcast channel of the backhaul link to broadcast the collision PCI information through the D2D broadcast channel and set to receive the colliding PCI information of the two mobile relay nodes, RN_z can detect and avoid the interference due to the PCI collision by transmitting and receiving the D2D broadcast of the collision PCI value.

6, a mobile relay node 500 according to an embodiment of the present invention may be configured to detect and prevent interference due to PCI collision.

Referring to FIG. 6, a mobile relay node 500 according to an embodiment of the present invention includes a base station unit 510 corresponding to a base station functional element and a terminal unit 520 corresponding to a terminal functional element.

The base station unit 510 includes a PCI setting unit 513 including an access link transmission unit 511, an access link reception unit 512, a PCI setting control unit 514 and a conflict resolution unit 515, and a storage unit 516 . These components of the base station 510 may be implemented in hardware (e.g., a semiconductor processor), software (e.g., computer program instructions), or a combination thereof.

The terminal unit 520 includes a PCI collision processor 523 including a backhaul link transmitter 521, a backhaul link receiver 522, a direct communication controller 524 and a collision detector 525, a direct communication transmitter 526, And a direct communication receiving unit 527. These components of the terminal unit 520 may be implemented in hardware (e.g., a semiconductor processor), software (e.g., computer program instructions), or a combination thereof.

The access link transmitter 511 and the access link receiver 512 support a wireless interface (e.g., LTE Uu air interface) with the user terminal UE and transmit information to the terminal UE via the access link radio channel Or receive from the UE (UE). Here, the UE may be connected to the mobile relay node 500 (e.g., a mobile node) through an access link radio channel using a communication method such as WiFi, 3GPP, Bluetooth, ZigBee, NFC, ), A content caching service, a location-based advertisement service, a warning message, a proximity SNS (Social Network Service), a temporary service for providing a service for a predetermined time, etc. for the digital multimedia contents held in the content server on the macro network A local service can be provided.

Here, the user terminal UE includes all the electronic devices that are served through the macro base station DeNB or the mobile relay node 500. For example, the user terminal UE may be a mobile terminal such as a smart phone, a tablet PC, an iPad, a PDA, a PMP, or a wired or wireless Internet such as a wired Internet, a WiFi, , A service for digital multimedia contents supported by a server of a macro network through a mobile communication network (e.g., WCDMA, LTE, etc.), and the like.

The PCI setting control unit 514 processes the request for PCI allocation in cooperation with the central node 100 and controls the reconfiguration and operation of the allocated PCI by controlling the access link transceivers 511 and 512. The collision resolution unit 515 controls the PCI setting control unit 514 to request the PCI allocation again when the collision detection unit 525 detects a PCI collision and the PCI setting control unit 514 interlocks with the central node 100, .

The storage unit 516 stores and manages parameters necessary for the overall operation of the mobile relay node 500. For example, the configuration information of the current relay cell such as the allocated PCI, CGI, and the like is stored and managed.

The backhaul link transmission unit 521 and the backhaul link reception unit 522 support a wireless interface (e.g., LTE Un air interface) with the macro / donor base station DeNB and transmit information via the backhaul link radio channel to the base station DeNB Or receive it from the base station DeNB. Here, it is possible to access the macro network by using a backhaul link radio channel using wired / wireless Internet (e.g., wired Internet, WiFi, WiBro, etc.), mobile communication network (e.g., WCDMA, LTE,

The direct communication control unit 524 controls the direct communication transmitting unit 526 and the receiving unit 527 according to the request for the collision PCI information broadcast of the central node 100 so that the direct communication transmitting unit 526 and the receiving unit 527 transmit the collision PCI information And controls to broadcast and receive through a broadcast channel.

The direct communication transmitting unit 526 and the receiving unit 527 transmit collision PCI information and the like to other neighboring mobile relay nodes through a direct communication (D2D) radio channel supporting a backhaul link connection, respectively, through a multicast or broadcast communication scheme .

The collision detecting unit 525 detects a PCI collision based on the PCI information received by the direct communication receiving unit 527 and the PCI information of the mobile relay node 500.

Hereinafter, the PCI conflict detection and resolution procedure according to the PCI redundancy use in the mobile communication system according to an embodiment of the present invention will be described in detail with reference to the flowchart of FIG.

7, the mobile relay node RN_x is connected to the network through the DeNB_A serving cell using the PCI value 10 (41).

At this time, the mobile relay node RN_y can access the DeNB_B cell (or DeNB_A cell) in the same PCI management area as the RN_x (42). As shown in FIG. 4, DeNB_A and DeNB_B may be base stations of the same PCI management area managed by one PCI subset.

Alternatively, the mobile relay node RN_y may allocate PCI = 10 in another PCI management area (for example, the PCI management area a in FIG. 5) and use a PCI management area (for example, the PCI management area b in FIG. 5) (42). 5, DeNB_A may be the base station of the PCI management area a using the first PCI subset, DeNB_B may be the base station of the PCI management area b using the second PCI subset, and the first PCI subset And the second PCI subset consists of the same PCI values to be used for allocation.

After the RN_y is attached to the DeNB_B cell as a backhaul link or handed over from the other PCI management area to the PCI management area to which the target DeNB_B cell belongs (42), the RN_y is transmitted to the central node 100 (For example, 10), and requests a PCI (43).

The central allocating unit 110 of the central node 100 inquires the PCI management table of the database 130 to select an unused PCI in the corresponding PCI subset 44 and to drop it to the RN_y through the serving DeNB_B cell 45, . At this time, the PCI allocation unit 110 may select at least one PCI.

However, if all PCIs (e.g., PCI = 1 to 10 in FIG. 4 and 5) are in use, the PCI allocator 110 may select a PCI value 10 in use by another RN_x and drop it through the serving DeNB_B cell have. However, when another mobile relay node allocates a PCI that is already in use, the PCI collision managing unit 120 may request 46, 47 to broadcast the conflict PCI information to the serving base stations DeNB_A and DeNB_B. Accordingly, the serving base stations DeNB_A and DeNB_B request the two mobile relay nodes RN_x and RN_y using the same PCI to transmit and receive collision PCI information through the D2D broadcast channel, respectively (48 and 49).

Accordingly, RN_x and RN_y are set to use the D2D broadcast channel of the backhaul link, broadcast collision PCI information through the D2D broadcast channel, and set to receive the colliding PCI information of the two mobile relay nodes, that is, The base station cell A instructs the communication control unit 524 to directly transmit the collision PCI information through the D2D broadcast channel and to receive the collision PCI information broadcasted by the counterpart mobile relay node RN_y at the request of the central node 100. [ Similarly, base station cell B can also point to the same setting for RN_y. D2D broadcasting can be transmitted / received by multicast or broadcast communication by allocating time frequency resources shared by all mobile relay nodes transmitting and receiving collision PCI information.

The direct communication control unit 524 controls the direct communication transmitting unit 526 and the receiving unit 527 to broadcast and receive the collision PCI information through the broadcasting channel. However, if RN_x and RN_y are not close enough, the collision detecting unit 525 Does not receive conflict PCI information contained in the D2D multicast or broadcast signal (50, 51). Here, the D2D broadcast is broadcast through some of the uplink radio resources for the backhaul link, and the D2D broadcast transmission power is set to be larger than the transmission power for the backhaul link to the base station of the mobile relay node, Close to be detected before PCI interference occurs.

RN_x and RN_y are close to each other and the receiving unit 527 of the RN_y receives the D2D multicast or broadcast signal 52 and the collision detecting unit 525 of the RN_y receives the collision PCI information Etc.), the conflict resolution unit 515 controls the PCI setting control unit 514 to request the PCI allocation again (53).

Accordingly, the PCI setting control unit 514 of the RN_y reports the collision to the central node 100 and requests the PCI allocation again (54). Accordingly, the PCI allocator 110 of the central node 100 allocates a new PCI (e.g., PCI = 10) to the corresponding mobile relay node RN_y (55) to reconfigure the relay cell, thereby resolving the PCI conflict (56 ).

The above components and their functions for performing the method for resolving the PCI conflict in the central node 100 and the mobile relay node 500 of the mobile communication system according to an embodiment of the present invention may be implemented in hardware, Or a combination thereof. Furthermore, the above-described elements, functions, and the like according to an exemplary embodiment of the present invention may be embodied as computer-readable codes on a computer- or processor-readable recording medium when executed by one or more computers or processors. It is possible to do. The processor-readable recording medium includes all kinds of recording apparatuses in which data that can be read by the processor is stored. Examples of the recording medium readable by the processor include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like, and also a carrier wave such as transmission over the Internet. In addition, the processor readable recording medium may be distributed over networked computer systems so that code readable by the processor in a distributed manner can be stored and executed.

As described above, the present invention has been described with reference to particular embodiments, such as specific elements, and specific embodiments and drawings. However, it should be understood that the present invention is not limited to the above- Those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the essential characteristics of the invention. Therefore, the spirit of the present invention should not be construed as being limited to the embodiments described, and all technical ideas which are equivalent to or equivalent to the claims of the present invention are included in the scope of the present invention .

The central node 100,
The PCI allocation unit 110
The PCI conflict management unit 120
PCI information database 130,
The mobile relay node 500,
The base station 510,
The PCI setting control unit 514,
The conflict resolution unit 515
The terminal unit 520,
The direct communication control unit 524
The collision detection unit 525
The direct communication transmission unit 526
The direct communication receiver 527

Claims (16)

A method for processing a PCI conflict between mobile relay nodes in a mobile communication system,
Allocating a PCI already allocated to the second mobile relay node to the PCI management area by allocating a PCI selected in the PCI subset allowed in the PCI management area by referring to the database according to the PCI allocation request of the first mobile relay node, 1 to a mobile relay node;
Requesting D2D broadcasting of the collision information to the first mobile relay node and the second mobile relay node through the base station according to the redundant assignment; And
The first mobile relay node and the second mobile relay node broadcast collision PCI information through the D2D broadcast channel and detect and report collision PCI information of the other of the first mobile relay node and the second mobile relay node Assigning a new PCI to the relay node
The method comprising the steps of: detecting a PCI conflict in a mobile communication system; The method according to claim 1,
The mobile relay node comprising:
A location-based advertisement service, a warning message service, a proximity social network service (SNS) service for the digital multimedia contents of the macro network to the user terminal by accessing the macro network through a backhaul link, ), Or a node providing a local service including a temporary service providing a service for a predetermined time period. The method according to claim 1,
And the first mobile relay node detects and reports collision PCI information of the other party. The method according to claim 1,
In a state where the second mobile relay node first connects to the network in the same PCI management area managed by the same one PCI subset, the first mobile relay node attaches to the network and then transmits the PCI allocation request The method comprising the steps of: The method according to claim 1,
Wherein the first mobile relay node performs a PCI allocation request after handing over from a first PCI management area to a second PCI management area accessed by the second mobile relay node, Wherein the same PCI values to be used for allocation are managed for each of the second PCI management areas. A central node on a mobile communication network for handling PCI conflict between mobile relay nodes,
Allocating a PCI already allocated to the second mobile relay node to the PCI management area by allocating a PCI selected in the PCI subset allowed in the PCI management area by referring to the database according to the PCI allocation request of the first mobile relay node, 1 < / RTI > relay relay node; And
And a PCI conflict manager for requesting D2D broadcasting of the collision information to the first mobile relay node and the second mobile relay node through the base station according to the redundant assignment,
Wherein the first mobile relay node and the second mobile relay node broadcast collision PCI information through the D2D broadcast channel and any one of the first mobile relay node and the second mobile relay node detects collision PCI information of the other mobile relay node And the PCI assigning unit assigns a new PCI to the corresponding relay node. The method according to claim 6,
The mobile relay node comprising:
A location-based advertisement service, a warning message service, a proximity social network service (SNS) service for the digital multimedia contents of the macro network to the user terminal by accessing the macro network via a backhaul link, ), Or a node providing a local service including a temporary service providing a service for a predetermined period of time. The method according to claim 6,
And the first mobile relay node detects and reports collision PCI information of the other party. The method according to claim 6,
In a state where the second mobile relay node first connects to the network in the same PCI management area managed by the same one PCI subset, the first mobile relay node attaches to the network and then transmits the PCI allocation request To the central node. The method according to claim 6,
Wherein the first mobile relay node performs a PCI allocation request after handing over from a first PCI management area to a second PCI management area accessed by the second mobile relay node, Wherein the same PCI values to be used for allocation are managed for each of the second PCI management areas. A method for processing a PCI conflict of a mobile relay node in a mobile communication system,
Performing a PCI allocation request over a backhaul link;
Receives a D2D broadcast request from a central node that duplicately allocates the same PCI already allocated to the second mobile relay node according to the PCI allocation request, and multicasts or broadcasts transmission / reception of the first collision PCI information using the D2D radio resource ;
Detecting second collision PCI information received from the second mobile relay node according to the broadcast request; And
Reporting the detection of the second conflict PCI information to the central node and reassigning the new PCI allocation to resolve the PCI conflict
The method comprising the steps of: 12. The method of claim 11,
Wherein the power for the multicast or broadcast transmission / reception is set to be greater than the power for the backhaul link from the mobile relay node to the base station, and before the PCI interference occurs close to the second mobile relay node, And detecting a PCI conflict of the mobile relay node. 12. The method of claim 11,
After attaching to a network of the same PCI management area in a state in which the second mobile relay node first connects to the same PCI management area managed by the same one PCI subset, The second mobile relay node performs handover to a second PCI management area connected to the second mobile relay node, and then the PCI allocation request is performed. A mobile relay node of a mobile communication system,
A PCI setting unit for performing a PCI allocation request through a backhaul link;
Receives a D2D broadcast request from a central node that duplicately allocates the same PCI already allocated to the second mobile relay node according to the PCI allocation request, and multicasts or broadcasts transmission / reception of the first collision PCI information using the D2D radio resource A direct communication control unit; And
And a collision detector for detecting second collision PCI information received from the second mobile relay node according to the broadcast request,
Wherein the PCI configuration unit reports the detection of the second collision PCI information to the central node and reassigns the new PCI allocation to resolve the PCI collision. 15. The method of claim 14,
Wherein the power for the multicast or broadcast transmission and reception is set to be greater than the power for the backhaul link from the mobile relay node to the base station and before the PCI interference occurs close to the second mobile relay node, 2 < / RTI > conflict PCI information. 15. The method of claim 14,
After attaching to a network of the same PCI management area in a state that the second mobile relay node first connects to the same PCI management area managed by the same one PCI subset,
After handing over from the first PCI management area to the second PCI management area accessed by the second mobile relay node,
Wherein the PCI configuration unit performs the PCI allocation request.

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