KR20120001671A - System for managing interference of control channel - Google Patents

Abstract

PURPOSE: A system for managing the interference of a control channel is provided to reduce interference between adjacent cells in an environment where different kind of cell is mixed and to allocate wireless resources to transmit a control channel to a macro terminal with reference to wireless information which is received from a femto base station. CONSTITUTION: A femto base station allocates a radio resource about a control channel(410). The femto base station transmits allocated wireless resource information to a macro base station(420). The femto base station transmits a cell ID to the macro base station(430). Wireless resource information is used for allocating a wireless resource about a control channel of the macro base station. The cell ID is a physical layer cell ID or a global ID.

Description

System for managing interference of control channel {SYSTEM FOR MANAGING INTERFERENCE OF CONTROL CHANNEL}

The following embodiments relate to a system for managing interference of a control channel, and more particularly, to a system for reducing interference of a control channel by transmitting a control channel using different radio resources from a macro base station and a femto base station. will be.

The control channel is not a channel through which user data is transmitted. However, it is a channel through which control information including information on a method for receiving user data is transmitted. Therefore, if an error occurs in the control information transmitted on the control channel, the user's data cannot be transmitted.

In general, control channels are transmitted using low code rates and high transmit power to withstand some degree of inter cell interference. However, this alone may be insufficient. In particular, in a heterogeneous network environment in which different types of cells are mixed, many control channels are not properly received due to interference received from adjacent cells.

One embodiment of the exemplary embodiments provides a method of reducing interference between cells adjacent to each other in an environment in which different types of cells are mixed.

Yet another aspect of exemplary embodiments provides a method in which different kinds of cells transmit control channels using different radio resources.

According to one aspect of the exemplary embodiment, the step of allocating a radio resource for the control channel of the femto base station and transmitting the information of the allocated radio resource to the macro base station, the information of the radio resource is the macro base station Provided is a radio resource allocation method used for allocating radio resources for a control channel of.

According to yet another aspect of an exemplary embodiment, a control channel of a macro base station is allocated by receiving information of radio resources for a control channel of a femto base station and with reference to radio resource information for a control channel of the femto base station. A radio resource allocation method is provided that includes allocating radio resources that can be used.

According to yet another aspect of an exemplary embodiment, receiving a first control channel from a femto base station, transmitting information of a first radio resource received by the first control channel to a macro base station, from the macro base station A method of allocating a radio resource includes receiving information of an allocated second radio resource with reference to information of a first radio resource and receiving a second control channel from the macro base station using the second radio resource. Is provided.

According to one side of the exemplary embodiments, in an environment where different kinds of cells are mixed, interference between adjacent cells is reduced.

According to yet another aspect of the exemplary embodiments, different kinds of cells may transmit a control channel using different radio resources.

1 is a diagram illustrating a configuration of an interference management system according to an exemplary embodiment.
2 is a diagram illustrating the allocation of radio resources in the uplink of the 3GPP LTE system.
Fig. 3 is a diagram illustrating the allocation of radio resources according to yet another exemplary embodiment.
4 is a diagram illustrating a radio resource allocation method according to an exemplary embodiment.
Fig. 5 is a diagram showing a radio resource allocation method according to another exemplary embodiment.
5 is a diagram illustrating a method of receiving a control channel using an allocated radio resource according to an exemplary embodiment.

1 is a diagram illustrating a configuration of an interference management system according to an exemplary embodiment.

An interference management system according to an exemplary embodiment includes macro base stations 110 and 120 and femto base stations 130, 140 and 150. In this specification, the terms macro base station (110, 120) and femto base station (130, 140, 150) is used, but the interference management system according to an exemplary embodiment may include other types of base stations, different types of Interference between base stations can be managed. Therefore, not only the femto base stations 130, 140, 150, but also a pico base station may be included, and a macro base station, a femto base station, and a pico base station may all coexist.

Two macro terminals 160 and 180 are located in the coverage 111 of the first macro base station 110. The femto base station 130, 140 receives the control channel from the femto terminals 132, 142 in the coverages 131, 141.

Two macro terminals 160, 180 are adjacent to the femto base station 130, 140. The two macro terminals 160 and 180 transmit control channels to the macro base station 110. The control channel transmitted by the macro terminals 160 and 180 serves as an interference signal to the femto base station 130 or 140. Since the distance between the macro terminals 160 and 180 and the femto base station 130 and 140 is shorter than the distance between the macro terminals 160 and 180 and the macro base station 110, the control channel transmitted by the macro terminals 160 and 180 is reduced. Has a strong interference effect on the femto base station (130, 140).

In addition, the macro terminal 170 located in the coverage 121 of the second macro base station 120 also transmits a control channel to the second macro base station 120. In this case, femto base station 150 receives strong interference from macro terminal 170. Accordingly, the femto base station 150 may not receive a control channel from the femto terminal 152 located in the coverage 151.

In this case, an error may occur in the control information transmitted using the control channel between the femto base station 130, 140, 150 and the femto terminal 131, 141, 151. Therefore, the femto base station 130, 140, 150 can not successfully decode the data of the user transmitted from the femto terminal (131, 141, 151), the efficiency of data transmission is extremely degraded.

2 is a diagram illustrating the allocation of radio resources in the uplink of the 3GPP LTE system. In FIG. 2, the horizontal axis represents time and the vertical axis represents a frequency band.

PUCCH, which is a control channel for transmitting control information among the uplink radio resources 210 of the 3GPP LTE system, is located at both ends 220 and 240 of the frequency band as shown in FIG. In addition, the PUSCH, which is a data channel for transmitting user data, is located in the middle portion 230 of the frequency band.

According to one side, the data transmission system according to an exemplary embodiment reduces the inter-cell interference by differently allocating radio resources used by the macro base station to receive the control channel and radio resources used by the femto base station to receive the control channel. You can.

Fig. 3 is a diagram illustrating the allocation of radio resources according to yet another exemplary embodiment.

Assume that the first femto base station and the second femto base station are located within the coverage of the macro base station and are interfered with by the macro terminal.

According to one side, the first femto base station is a radio resource (311, 313) for receiving the control channel in the frequency band 311 of the highest region and the lowest frequency band 313 of the uplink radio resources (310) Can be used as In addition, the first femto base station may use a radio resource 312 other than the radio resources 311 and 313 for receiving the control channel as a radio resource for transmitting data. In addition, the second femto base station may transmit a control channel using radio resources 321 and 323.

The macro base station may transmit the control channel to the terminal using radio resources not used by the first femto base station or the second femto base station.

According to one side, the macro base station may receive information of radio resources allocated by the femto base station. The macro base station may transmit the control channel to the terminal by using a radio resource other than the radio resource allocated by the femto base station.

4 is a diagram illustrating a radio resource allocation method according to an exemplary embodiment.

In step 410 the femto base station allocates radio resources for the control channel. The femto base station may transmit the radio resource information to the femto terminal located within the coverage of the femto base station, and receive a control channel from the femto terminal using the radio resource.

In step 420, the femto base station transmits the information of the allocated radio resource to the macro base station. According to one side, the femto base station may transmit a cell ID (Cell ID) of the femto base station to the macro base station. When the macro base station receives the information of the radio resource from the plurality of femto base stations, the macro base station may distinguish the radio resource by using the cell identifier.

According to one side, the cell identifier may be a physical layer cell ID or a global ID of the cell.

The macro base station determines an area of a radio resource for which it can transmit a control channel with reference to the radio resource information received from the femto base station. According to one side, the area of the radio resource determined that the macro base station can transmit the control channel may include a radio resource allocated by the femto base station to transmit the control channel.

The femto base station may send the cell identifier to terminals in coverage. If the macro terminal is located within the coverage of the femto base station, the macro terminal may receive the cell identifier of the femto base station. That is, macro terminals transmitting strong interference to the femto base station are terminals that receive a cell identifier from the femto base station.

The macro terminals transmit the cell identifier received from the femto base station to the macro base station. The macro base station may receive a cell identifier of a femto base station adjacent to each macro terminal from a plurality of macro terminals in the coverage area. The macro base station may determine a femto base station adjacent to each macro terminal.

The macro base station may select a radio resource different from the radio resources of the femto base station adjacent to the macro terminal and allocate a control channel. That is, a radio resource for transmitting a control channel to a specific macro terminal is different from a radio resource for transmitting a control channel by a femto base station adjacent to the specific macro terminal.

Let's explain with reference to FIG. The first femto base station 130 transmits information of the first radio resource used by the first femto base station 130 to receive a control channel from the first femto terminal 132 to the macro base station 110. In addition, the second femto base station 140 transmits information of the second radio resource used by the second femto base station 140 to receive a control channel from the second femto terminal 142 to the macro base station 110.

The macro base station 110 allocates a radio resource that the macro base station 110 can use to receive a control channel from the macro terminals 160 and 180 by using the information of the first radio resource and the information of the second radio resource. . In this case, the radio resources that the macro base station 110 can use to receive the control channel from the macro terminals 160 and 180 may include a first radio resource and a second radio resource.

The first macro terminal 180 adjacent to the first femto base station 130 receives the cell identifier of the first femto base station 130 from the first femto base station 130, and sends the received cell identifier to the macro base station 110. send. In addition, the second macro terminal 160 transmits the cell identifier of the second femto base station 140 to the macro base station 110.

The macro base station 110 may allocate a second radio resource different from the first radio resource as a radio resource for receiving a control channel from the first macro terminal 180 adjacent to the first femto base station 130. Even when the first macro terminal 180 transmits a control channel using the second radio resource, the first femto base station 130 minimizes the influence of interference received from the first macro terminal.

The macro base station 110 may allocate a first radio resource different from the second radio resource as a radio resource for receiving a control channel from the second macro terminal 160 adjacent to the second femto base station 140. Even when the second macro terminal 160 transmits a control channel using the first radio resource, the second femto base station 140 minimizes the influence of interference received from the first macro terminal.

According to one side in step 410, the femto base station may allocate radio resources according to its cell identifier. If the femto base station determines the radio resource according to the cell identifier, the femto base station does not need to transmit the radio resource information to the macro base station, it can transmit only the cell identifier.

In addition, if the femto base station determines the radio resources according to the cell identifier, the radio resources allocated to each femto base station do not overlap each other, it is possible to efficiently use the radio resources.

Fig. 5 is a diagram showing a radio resource allocation method according to another exemplary embodiment.

In step 510 the macro base station receives the information of the radio resource from the femto base station. The radio resource information may include information about a frequency band and a time interval of the radio resource used by the femto base station to receive a control channel from the femto terminal.

In step 520 the macro base station receives the cell identifier of the femto base station. According to one side, the cell identifier may be a physical layer cell ID or a global ID of a cell to which the femto base station belongs. In addition, the radio resource received in step 510 may be allocated according to the cell identifier of the femto base station. If the femto base station determines the radio resource according to the cell identifier, since the radio resources allocated to each femto base station do not overlap each other, it is possible to efficiently use the radio resource. In addition, each macro terminal may receive only a cell identifier in step 520 without receiving information on a radio resource in step 510.

In step 530 the macro base station determines the area of the radio resource to which the macro base station can be assigned a control channel. The radio resource to which the control channel can be allocated means a radio resource through which the macro base station can receive a control channel from the macro terminal. According to one side, the macro base station may determine a radio resource to which the control channel of the macro base station can be allocated with reference to the radio resource of each femto base station.

In step 540, the macro base station re-receives information of a radio resource of the femto base station or a cell identifier of the femto base station from the macro terminal adjacent to the femto base station. The macro base station can know the radio resource or cell identifier of the femto base station receiving the strong interference signal from the macro terminal.

In step 550, the macro base station selects a radio resource capable of receiving a control channel from the macro terminal among the radio resources to which the control channel of the macro base station can be allocated by referring to the information of the re-received radio resource or the re-received cell identifier. Assign.

According to one side, the macro base station may allocate a radio resource different from the femto base station adjacent to the macro terminal as a radio resource for receiving a control channel from the macro terminal.

6 is a diagram illustrating a method for receiving a control channel using allocated radio resources according to an exemplary embodiment.

In step 610, the macro terminal receives the first control channel from the femto base station. According to one side, the macro terminal may compare the signal strength of the first control channel with a threshold. When the signal strength of the first control channel is greater than the threshold, the macro terminal may determine that the macro terminal is adjacent to the femto base station, and that the macro terminal may influence strong femto base station.

In operation 610, the macro terminal may receive a first control channel using a first radio resource from a femto base station. In this case, the macro terminal may transmit the information of the first radio resource to the macro base station.

In step 630, the macro terminal transmits the cell identifier of the cell to which the femto base station belongs to the macro base station. According to one side, the cell identifier may be a physical layer cell ID or a global ID of the cell.

According to one side, the first radio resource may be allocated according to the cell identifier of the femto base station. In this case,

In step 640, the macro terminal receives information of the second radio resource from the macro base station. According to one side, the second radio resource is a radio resource allocated with reference to the information of the first radio resource. For example, the second radio resource may be allocated to be different from the first radio resource.

In step 650, the macro terminal transmits a second control channel to the macro base station using the second radio resource.

110, 120: macro base station
111, 121: coverage of the macro base station
130, 140, 150: femto base station
131, 141, 151: coverage of femto base station
132, 142, and 152: femto terminals connected to the femto base station
160, 170, 180: Macro terminal connected to the macro base station

Claims (15)

Allocating radio resources for the control channel of the femto base station; And
Transmitting a cell identifier (Cell ID) of a cell to which the femto base station belongs to the macro base station
Including,
The radio resource information is used for allocating radio resources for a control channel of the macro base station. The method of claim 1,
Transmitting the information on the allocated radio resource to the macro base station
Radio resource allocation method further comprising. The method of claim 2,
The cell identifier is a physical layer cell ID or a global ID of the cell. The method of claim 2, wherein allocating the radio resource comprises:
And a method of allocating the radio resource according to the cell identifier. The method of claim 1,
The radio resource allocation method for the control channel of the macro base station is different from the radio resource for the control channel of the femto base station. Receiving a cell identifier (Cell ID) of a cell to which the femto base station belongs; And
Allocating a radio resource to which a control channel of a macro base station can be allocated by referring to information of a radio resource for a control channel of the femto base station;
Radio resource allocation method comprising a. The method of claim 6,
Receiving information of a radio resource for a control channel of the femto base station;
Radio resource allocation method comprising a. The method of claim 7, wherein
The cell identifier is a physical layer cell ID or a global ID of the cell. The method of claim 7, wherein
The radio resource allocation method for the control channel of the femto base station is allocated according to the cell identifier. The method of claim 6,
Receiving information of a radio resource of the femto base station or a cell identifier of a cell to which the femto base station belongs from a macro terminal connected to the macro base station; And
Allocating a radio resource capable of receiving a control channel from the macro terminal among radio resources to which a control channel of the macro base station can be allocated by referring to the information of the received radio resource;
Radio resource allocation method further comprising. The method of claim 10,
Allocating a radio resource capable of receiving a control channel from the macro terminal may include assigning the radio resource such that a radio resource capable of receiving a control channel from the macro terminal is different from a radio resource of the femto base station. Way. Receiving a first control channel from a femto base station;
Transmitting a cell identifier of a cell to which the femto base station belongs to the macro base station
Receiving information of the allocated second radio resource with reference to the information of the first radio resource from the macro base station;
Transmitting a second control channel from the macro base station using the second radio resource
Control channel transmission method comprising a. The method of claim 12,
And wherein the second radio resource is allocated to be different from the first radio resource. The method of claim 12,
Transmitting information of a first radio resource from which the first control channel is received to a macro base station;
Control channel transmission method further comprising. The method of claim 14,
And the first radio resource is allocated according to the cell identifier.

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