KR101311408B1 - An interference control apparatus and method regarding femto cell - Google Patents

Abstract

The present invention discloses a femtocell related interference control method and apparatus which can minimize interference between a macro cell and a femtocell and can avoid interference between a femtocell and a femtocell. In the interference control method, a macro control station controls an interference given to a macro cell by a femtocell, and based on user information of the macro cell, a subchannel (frequency resource) based on an amount of interference given to an existing user of the macro cell by the femtocell. Subchannel set generation step of generating a set; and transmitting the subchannel set to a femto control station, wherein the subchannel set generation step calculates an amount of interference given to an existing user of the macro cell, Extracting the subchannels having positive interference to generate the subchannel set. Therefore, since the frequency co-channel method is used, the frequency can be efficiently used, and the interference of the femtocell to the macrocell user can be reduced to the maximum.

Description

Method and apparatus for interference control related to femtocells {AN INTERFERENCE CONTROL APPARATUS AND METHOD REGARDING FEMTO CELL}

The present invention relates to an interference control method and apparatus, and more particularly, to a method and apparatus for controlling interference associated with femtocells in wireless communication.

In general, when the macro cell region and the femtocell are overlapped and disposed in the same region, the macro cell and the femtocell provide communication services using different frequencies to reduce interference generated during communication.

Most femtocell networks use resources in a dedicated channel. The frequency dedicated channel method is a method in which a macrocell and a femtocell allocate respective dedicated channels. Each of the outdoor base station and indoor base station does not have the advantage of no interference because the frequency dedicated channel method is used, but the network capacity is reduced because the entire channel cannot be used. This technique uses the frequency-dedicated channel and has the above disadvantages.

The channel allocation scheme as opposed to the frequency dedicated channel scheme is a frequency co-channel scheme. In the frequency co-channel scheme, a macro cell and a femtocell share the same resource. Frequency can be used efficiently, but there is a disadvantage that interference occurs severely unless resources are carefully allocated.

Conventional technologies for managing interference in a co-channel femtocell network are as follows.

Composes a subchannel set that can calculate and use the interference signal for each subchannel received from the femtocell by itself. That is, a femtocell user creates a subchannel set with little interference. It does not take into account the information of the macro user and does not consider the interference information affecting the macro user. In addition, it is a frequency allocation method that reduces the influence of interference between the macrocell base station and the femtocell base station, and does not consider the interference between femtocells at the same time.

The femtocell itself measures the amount of interference for each subchannel received. Based on this, the femtocell uses the subchannel calculated below a certain threshold. Since it only considers the amount of interference the femtocell receives, it is not possible to determine exactly how much interference the macro user is giving. In addition, it does not consider the interference between femtocells.

Korean public patent KR 10-2009-0004164 ("Resource allocation method and device in communication system", Samsung Electronics Co., Ltd., published on Jan. 12, 2009)

An object of the present invention for solving the above problems is to allow the macro control station to configure the sub-channel set to be used by the femtocell, the femtocell to configure the sub-channel set of sub-channels with minimal interference to the macro user, The present invention provides a femtocell-related interference control method and apparatus capable of avoiding inter-femtocell interference by configuring a modified subchannel set with remaining subchannel sets except for the existing femtocell.

According to the femtocell-related interference control method of the present invention for achieving the above object, in a method for controlling interference that a femtocell gives to a macro cell, the femtocell is an existing user of the macro cell based on user information of the macro cell. A subchannel set generation step of generating a subchannel (frequency resource) set based on the amount of interference given to the subchannel; And transmitting the subchannel set to a femto control station.

The generating of the subchannel set may include calculating an amount of interference given to an existing user of the macro cell when the femtocell uses the subchannel for all subchannels; Arranging the subchannels in order of decreasing magnitude of the interference amount based on the calculated interference amount; And generating the subchannel set based on the sorted order.

The generating of the subchannel set may include generating the subchannel set by calculating an amount of interference given to an existing user of the macro cell and extracting a subchannel having the least amount of interference.

The femtocell related interference control method may include checking whether a femtocell exists in a network; And receiving location information of the femtocell from the femtocell based on the presence.

In order to achieve the above object, an apparatus for controlling femtocell-related interference according to an embodiment of the present invention is an apparatus for controlling interference given to a macro cell by a femtocell, wherein the femtocell is an existing user of the macro cell based on user information of the macro cell. A subchannel set generator for generating a subchannel (frequency resource) set based on the amount of interference given to the subchannel; And a transmitter for transmitting the subchannel set to the femto control station.

The subchannel set generation unit includes: an interference amount calculation unit for calculating an amount of interference given to an existing user of the macro cell when the femtocell uses the subchannel for all subchannels; An alignment unit to align the subchannels in order of decreasing magnitude of the interference amount based on the calculated interference amount; And a set generator configured to generate the subchannel set based on the sorted order.

The subchannel set generator may generate the subchannel set by extracting a subchannel having the least amount of interference by calculating an amount of interference given to an existing user of the macro cell.

The femtocell related interference control device may include: a femtocell identification unit for confirming whether or not the femtocell exists in a network; And a location information receiver configured to receive location information of the femtocell from the femtocell based on the presence.

The femtocell related interference control method of the present invention for achieving the above object is a method for controlling the interference that the second femtocell to the first femtocell at the femto control station, based on the user information of the first femtocell Generating a modified subchannel set by excluding a subchannel used by the first femtocell user from a subchannel (frequency resource) set received from a control station; And a subchannel allocating step of allocating the second femtocell with a subchannel that gives the least amount of interference to the existing macro user in the modified subchannel set.

The generating of the modified subchannel set may include generating the modified subchannel set in consideration of the amount of interference between the first and second femtocells based on the subchannel set.

The generating of the modified subchannel set includes excluding a subchannel used by the first femtocell user from the subchannel set; Aligning the subchannel sets in the order of the smallest amount of interference between the first and second femtocells; And generating the modified subchannel set based on the sorted subchannel set.

The generating of the modified subchannel set may include calculating an amount of interference between the first and second femtocells based on the amount of interference that the second femtocell gives to the first femtocell user.

The subchannel allocating step may include allocating the subchannel to the second femtocell based on the amount of interference that the second femtocell gives to an existing user of the macro cell.

The femtocell related interference control apparatus of the present invention for achieving the above object is a device for controlling the interference that the second femtocell to the first femtocell in the femto control station, based on the user information of the first femtocell macro A modified subchannel set generation unit for generating a modified subchannel set by excluding a subchannel used by the first femtocell user from a subchannel (frequency resource) set received from a control station; And a subchannel allocator for allocating the second femtocell to a second channel having the least amount of interference in the modified macrochannel set.

The modified subchannel set generator may generate the modified subchannel set in consideration of the amount of interference between the first and second femtocells based on the subchannel set.

The modified subchannel set generation unit excluding a subchannel used by the first femtocell user from the subchannel set; An alignment unit for aligning the subchannel sets in the order of a small amount of interference between the first and second femtocells; And a set generator configured to generate the modified subchannel set based on the sorted subchannel set.

The modified subchannel set generator may calculate the amount of interference between the first and second femtocells based on the amount of interference that the second femtocell gives to the first femtocell user.

The subchannel allocator may allocate the subchannel to the second femtocell based on the amount of interference that the second femtocell gives to an existing user of the macro cell.

In order to achieve the above object, a femtocell related interference control method of the present invention provides a method for controlling interference caused by a second femtocell to a first femtocell and a macro cell, wherein the macro control station is configured to perform the control based on user information of the macro cell. A subchannel set generation step of generating a subchannel set having the least amount of interference by calculating an amount of interference that a second femtocell gives to an existing user of the macro cell; Generating, by the femto control station, a subchannel set modified by excluding a subchannel used by a first femtocell user from the subchannel set based on the user information of the first femtocell; And a subchannel allocating step of the femto control station allocating a subchannel which gives the least amount of interference to an existing user of the macro cell in the modified subchannel set to the second femtocell.

According to the femtocell-related interference control method and apparatus according to the present invention, since the frequency co-channel method is used, the frequency can be efficiently used, and the femtocell can reduce the interference to the macrocell user to the maximum.

In addition, according to the femtocell-related interference control method and apparatus according to the present invention, since the femto control station determines the frequency resource allocation of the femtocell has the effect of reducing the interference effect between femtocell base stations.

Furthermore, according to the femtocell related interference control method and apparatus according to the present invention, it is possible to increase the throughput of the overall network and also to reduce the probability of transmission failure.

1 is a diagram illustrating a network system for conceptually explaining a femtocell related interference control method according to an embodiment of the present invention;
2 is a flowchart schematically illustrating a femtocell related interference control method according to an embodiment of the present invention;
3 is a detailed flowchart illustrating a subchannel set generation step of a femtocell related interference control method according to an embodiment of the present invention;
4 is a block diagram schematically showing a femtocell related interference control apparatus according to an embodiment of the present invention;
5 is a detailed block diagram illustrating in detail a subchannel generator of a femtocell related interference control apparatus according to an embodiment of the present invention;
6 is a flowchart schematically illustrating a femtocell related interference control method according to another embodiment of the present invention;
7 is a detailed flowchart illustrating a modified subchannel set generation step of a femtocell related interference control method according to another embodiment of the present invention;
8 is a block diagram schematically showing a femtocell related interference control device according to another embodiment of the present invention;
9 is a detailed block diagram illustrating in detail a modified subchannel set generation unit of a femtocell related interference control device according to another embodiment of the present invention;
10 is a flowchart illustrating a femtocell related interference control method according to another embodiment of the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail.

It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

When a component is referred to as being "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but it may be understood that other components may be present in between. Should be. On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the relevant art and are to be interpreted in an ideal or overly formal sense unless explicitly defined in the present application Do not.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In order to facilitate the understanding of the present invention, the same reference numerals are used for the same constituent elements in the drawings and redundant explanations for the same constituent elements are omitted.

1 is a diagram illustrating a network system for conceptually explaining a femtocell related interference control method according to an embodiment of the present invention. As shown in FIG. 1, a network system to which a femtocell related interference control method according to an embodiment of the present invention is applied includes a macro base station 110, a macro cell user 112, a macro network 114, and a macro control station ( 120, a femto base station 130, a femtocell user 132, a femto network 134, and a femto control station 140.

According to an embodiment of the present invention, it is assumed that the macro cell and the femtocell area are in the same channel method using the same frequency resources. Referring to FIG. 1, the macro cell user 112 is provided with a communication service in the macro network 114 through the macro base station 110. In this case, when the femtocell user 132 enters the network 114, the femto base station 130 may interfere with the existing macro user 112. Because the femto network 134 is the macro network 114, Because it is included in the frequency interference between each other may occur.

To prevent this, control of the frequency resource in the macro network 114 is performed by the macro control station 120, and control of the frequency resource in the femto network 134 is performed by the femto control station 130. The control stations 120 and 140 both know the user information of the network to which they belong, that is, the user's location, channel status, and subchannels (frequency resources) used. Therefore, when the femtocell user 132 uses the subchannel, the control stations 120 and 140 calculate how much interference to the existing macrocell users 112 and based on the calculated amount of interference. By assigning a frequency with less interference to the femtocell user 132, it is possible to minimize the interference associated with the femtocell user 132.

In addition, the interference between the femtocell users 132 as well as the interference between the macrocell user 112 and the femtocell user 132 should be controlled. The former interference can be controlled by the macro control station 120, the latter interference can be controlled by the femto control station 140. Detailed description of the latter and the latter interference control will be described later.

2 is a flowchart schematically illustrating a femtocell related interference control method according to an embodiment of the present invention. As shown in FIG. 2, the femtocell related interference control method according to an embodiment of the present invention provides the amount of interference that the femtocell user 132 gives to the macrocell user 112 based on the information of the macrocell user 112. The method may include generating a subchannel set based on the 210 and transmitting the subchannel set to the femto control station 140.

Referring to FIG. 2, first, the macro control station 120 checks whether a femtocell user 132 exists in the network 114. If the femtocell user 132 exists in the network 114, it should find a resource to be allocated to the femtocell user 132. At this time, when the femtocell user 132 enters the network 114, the femtocell base station 130 transmits its own location information to the macro control station 120. The macro control station 120 recognizes that the femtocell user 132 is present in its network 114 and searches for a subchannel (frequency resource) to allocate.

In the subchannel set generation step 210, since the macro control station 120 has macrocell user 112 information, when the femtocell user 132 enters the network 114 based on the user information, A subchannel set is generated based on the amount of interference that the femtocell gives to the macrocell user 112. As described above, the macro control station 120 grasps information (location, channel state, subchannel to be used) of the macro cell user 112. Accordingly, the macro control station 120 may calculate how much sub-channel can cause interference to existing macro users. Therefore, the subchannel set giving a small amount of interference to the existing macrocell user 112 is generated based on the calculated amount of interference.

3 is a detailed flowchart illustrating a subchannel set generation step 210 of a femtocell related interference control method according to an embodiment of the present invention. As shown in FIG. 3, the subchannel set generation step 210 according to an embodiment of the present invention provides interference to the macrocell user 112 when the femtocell user 132 uses subchannels for all subchannels. Calculating the amount 310, arranging the subchannels in the order of the least amount of interference amount based on the calculated amount of interference 320, and generating the subchannel set based on the sorted order 330. It may include.

Referring to FIG. 3, first, in the interference amount calculation step 310, it is assumed that the femtocell user 132 enters the network 114 for all subchannels. The amount of interference received by the macrocell user 112 in the hypothesized situation is calculated for all the subchannels. Since the macro control station 120 knows all the user-related information existing in its network 114, the existing user generated when the femtocell user 132 enters all subchannels in the interference amount calculation step 310. The amount of interference can be calculated. Here, the calculation of the amount of interference may be calculated by estimating the power of the interference channel and the interference signal when the femtocell user 132 enters. However, the present invention is not limited thereto, and various interference calculation methods may be used.

Next, in the sorting step 320, the interference amount is sorted in ascending order according to the interference amount calculated in the interference amount calculating step 310. That is, the subchannels allocated in the highest order are the subchannels where the existing macrocell user 112 receives the least interference by the entry of the femtocell user 132.

In the set generation step 330, the macro control station 120 generates a subchannel set to be assigned to the femtocell user 132 based on the sorted order in the sorting step 320. Preferably, since the order in which the amount of interference is lower is arranged in the higher order, the subchannel set may be generated such that the subchannels assigned to the higher order become priorities. In addition, since the amount of interference estimated through the sorted order can be identified, the subchannel set can be generated by discarding a subchannel that gives an amount of interference above a specific value by setting a specific value as a threshold. In addition, when there is an element related to channel allocation other than the amount of interference when generating the subchannel set, the subchannel set may be generated in consideration of this.

2, after performing the subchannel set generation step 210, the subchannel set is transmitted to the femto control station 140 in the transmission step 220. This is because the femto control station 140 receives the subchannel set and transmits the first channel to the femto control station 140 because the femtocell user 132 does not allocate the subchannels and makes some modifications to allocate the subchannels.

4 is a block diagram schematically illustrating a femtocell related interference control apparatus 400 according to an embodiment of the present invention. As shown in FIG. 4, the femtocell related interference control apparatus 400 may include a subchannel set generator 410 and a transmitter 420.

As described above, the macro control station 120 checks whether a femtocell user 132 exists in the network 114. At this time, when the femtocell user 132 is turned on in the network 114, the femtocell user 132 transmits its own location information to the macro control station 120, the macro control station 120 is Based on the location information, the femtocell user 132 recognizes that it exists in its network 114, and then searches for a subchannel (frequency resource) to be allocated.

Since the subchannel set generator 410 has macrocell user 112 information, when the femtocell user 132 enters the network 114 based on the user information, the femtocell user 132 is a macrocell user. A subchannel set is generated based on the amount of interference given to (112). The macro control station 120 may calculate how much sub-channel can cause interference to existing macro users. Therefore, the subchannel set giving a small amount of interference to the existing macrocell user 112 is generated based on the calculated amount of interference.

5 is a detailed block diagram illustrating in detail the subchannel set generator 410 of the femtocell-related interference control apparatus 400 according to an embodiment of the present invention. As shown in FIG. 5, the subchannel set generator 410 according to an embodiment of the present invention may include an interference amount calculator 510, an alignment unit 520, and a set generator 530. .

Referring to FIG. 5, first, the interference amount calculator 510 assumes that the femtocell user 132 enters the network 114 for all subchannels, and in the hypothesized situation for all the subchannels. Calculate the amount of interference received by the macrocell user 112. Since the interference amount calculator 510 grasps all user related information existing in the network 114, the interference amount calculator 510 may calculate the amount of interference of an existing user generated when the femtocell user 132 enters for all subchannels. As described above, the amount of interference can be calculated by estimating the power of the interference channel and the interference signal when the femtocell user 132 enters. However, the present invention is not limited thereto, and various interference calculation methods may be used.

Next, the alignment unit 520 sorts the interference amount in ascending order according to the interference amount calculated by the interference amount calculation unit 510. That is, the subchannels allocated in the highest order are the subchannels where the existing macrocell user 112 receives the least interference by the entry of the femtocell user 132.

The set generator 530 generates a subchannel set to be allocated to the femtocell user 132 based on the sorted order in the sorter 520. Preferably, since the order in which the amount of interference is lower is arranged in the higher order, the subchannel set may be generated such that the subchannels assigned to the higher order become priorities. In addition, since the amount of interference estimated through the sorted order can be identified, the subchannel set can be generated by discarding a subchannel that gives an amount of interference above a specific value by setting a specific value as a threshold. In addition, when there is an element related to channel allocation other than the amount of interference when generating the subchannel set, the subchannel set may be generated in consideration of this.

4, after the subchannel set generator 410 generates the subchannel set, the transmitter 420 transmits the generated subchannel set to the femto control station 140.

6 is a flowchart schematically illustrating a femtocell related interference control method according to another embodiment of the present invention. As shown in FIG. 6, the femtocell related interference control method according to another embodiment of the present invention generates a modified subchannel set by excluding a subchannel used by an existing femtocell user based on user information of a femtocell in a subchannel set. And a step 620 of assigning a subchannel that gives the least amount of interference to the existing macro cell user to the femtocell in the modified subchannel set.

Referring to FIG. 6, first, a femto control station 140 receives a subchannel set capable of minimizing an interference amount for an existing user of a macro cell 132 from the macro control station 120. Next, in the step of creating a modified subchannel set 610, since the femto control station 140 grasps information of all femtocell users (eg, subchannel to be used), some modifications are made in the subchannel set based on the information. Create a modified set of subchannels. The modified subchannel set may exclude subchannels used by existing femtocell users from the subchannel set received from the macro control station 120. That is, the modified subchannel set is generated by applying modification to the received subchannel set in consideration of interference between the femtocell users 132.

7 is a detailed flowchart illustrating a modified subchannel set generation step 610 of a femtocell related interference control method according to another embodiment of the present invention. As shown in FIG. 7, the step of creating a modified subchannel set according to another embodiment of the present invention 610 excludes subchannels used by existing femtocell users from the subchannel set (710), and the amount of interference between femtocells. Arranging the subchannel sets in the order of decreasing sizes of 720 and generating a modified subchannel set based on the ordered subchannel set (730).

Referring to FIG. 7, in an exclusion step 710, the femto control station 140 excludes a subchannel used by an existing femtocell user. Since the femto control station 140 knows all the information of the femtocell user 132 existing in the femto network 134, it can identify the subchannel used by the existing femtocell user, and excludes it from the received subchannel set. Let's do it. In addition, since the femto base station 130 may communicate with the neighbor femto base station, the interference to the neighbor femtocell based on the communication may also be considered.

Next, in the sorting step 720, as in the sorting step 320, the subchannel sets are sorted in the order of the smallest amount of interference between femtocells. However, the difference from the alignment step 320 is that the alignment is performed based on the amount of interference between femtocells, not the amount of interference given to the macro cell user. As described above, the interference here also considers the amount of interference that the incoming femtocell has on the existing femtocell user. In addition, the amount of interference can be calculated by estimating the power of the interference channel and the interference signal when the femtocell enters as described above. However, the present invention is not limited thereto, and various interference calculation methods may be used.

Next, in the set generation step 730, a modified subchannel set to be allocated to the femtocell user 132 is generated based on the sorted order in the sorting step 720. Preferably, since the order in which the amount of interference is lower is arranged in the higher order, the modified subchannel set may be generated such that the subchannels assigned to the higher order become priorities. In addition, since the estimated amount of interference can be identified through the sorted order, a modified subchannel set can be generated by discarding a subchannel that gives an amount of interference above a specific value by setting a specific value as a threshold. In addition, if there is an element related to channel allocation other than the amount of interference when generating the modified subchannel set, the modified subchannel set may be generated in consideration of this.

6, in the subchannel allocation step 620, the femto control station 140 again considers the relationship with the macrocell user 112 in the modified subchannel set generated in the modification subchannel set generation step 610. Thus, when the femtocell user 132 enters, the subchannel giving the least amount of interference to the macrocell user 112 may be identified and the subchannel may be allocated to the femtocell user 132. That is, even in the modified subchannel set, the relationship with the macro cell user 112 may be considered once more. When the allocated subchannel is used, the entering femtocell user 132 can effectively control the interference by using a subchannel that minimizes interference to the existing macrocell user 112 and the existing femtocell user.

FIG. 8 is a block diagram schematically illustrating a femtocell related interference control device 800 according to another embodiment of the present invention. As shown in FIG. 8, the femtocell related interference control apparatus 800 according to another embodiment of the present invention may include a modified subchannel set generator 810 and a subchannel allocator 820.

Referring to FIG. 8, first, the femto control station 140 receives a subchannel set capable of minimizing the amount of interference for the existing macrocell user 132 from the macro control station 120. Next, since the modified subchannel set generation unit 810 grasps information of all femtocell users (eg, subchannels to be used), the modified subchannel set generator 810 generates a modified subchannel set to which the subchannel set is partially modified based on the information. do. The modified subchannel set may exclude subchannels used by existing femtocell users from the subchannel set received from the macro control station 120. That is, the modified subchannel set is generated by modifying the received subchannel set in consideration of the interference between the femtocell users 132.

9 is a detailed flowchart illustrating a modified subchannel set generator 810 of the femtocell related interference control apparatus 800 according to another embodiment of the present invention. As shown in FIG. 9, the modified subchannel set generator 810 according to another embodiment of the present invention may include an exclusion unit 910, an alignment unit 920, and a set generation unit 930.

Referring to FIG. 9, the exclusion unit 910 excludes a subchannel used by an existing femtocell user. Since the femto control station 140 knows all the user information of the femtocell user 132 existing in the femto network 134, it can grasp the subchannel used by the existing femtocell user and from the received subchannel set Exclude. In addition, since the femto base station 130 may communicate with the neighbor femto base station, the interference to the neighbor femtocell based on the communication may also be considered.

Next, the alignment unit 920 aligns the subchannel set in the order of the smallest amount of interference between femtocells. As described above, the interference here also considers the amount of interference that the incoming femtocell has on the existing femtocell user. In addition, the amount of interference can be calculated by estimating the power of the interference channel and the interference signal when the femtocell enters as described above. However, the present invention is not limited thereto, and various interference calculation methods may be used.

Next, the set generator 930 generates a modified subchannel set to be allocated to the femtocell user 132 based on the sorting order of the sorter 920. Preferably, since the order in which the amount of interference is lower is arranged in the higher order, the modified subchannel set may be generated such that the subchannels assigned to the higher order become priorities. In addition, since the estimated amount of interference can be identified through the sorted order, a modified subchannel set can be generated by discarding a subchannel that gives an amount of interference above a specific value by setting a specific value as a threshold. In addition, if there is an element related to channel allocation other than the amount of interference when generating the modified subchannel set, the modified subchannel set may be generated in consideration of this.

8 again, the subchannel allocator 820 reconsiders the relation with the macrocell user 112 in the modified subchannel set generated by the modified subchannel set generator 810 to allow the femtocell user 132 to reconsider. Upon entering, the subchannel giving the least amount of interference to the macrocell user 112 may be identified and the subchannel may be allocated to the femtocell user 132. That is, even in the modified subchannel set, the relationship with the macro cell user 112 may be considered once more. When the allocated subchannel is used, the entering femtocell user 132 can effectively control the interference by using a subchannel that minimizes interference to the existing macrocell user 112 and the existing femtocell user.

10 is a flowchart illustrating a femtocell related interference control method according to another embodiment of the present invention. Referring to FIG. 10, when a macro cell enters a network of a base station 1020, a base station (meaning a macro base station) 1020 transmits network entry to a control station (meaning a macro control station) 1030. The control station 1030 allocates subchannel resources to the base station 1020. The base station 1020 may schedule the basic resource based on the allocated resource. When the femto control station 1040 and the neighbor femto base station 1050 also enter the network of the neighbor femto control station 1050, it can schedule the femto control station 1040 and the basic resources. Therefore, resource allocation between femtocells can be performed.

In the case of the femto base station 1010, when the femto cell enters the network, the femto base station 1010 transmits a network entry to the control station 1030. The control station 1030 may receive the network entry to confirm the presence of the femtocell. Thereafter, the control station 1030 configures a subchannel set to be allocated to the femtocell based on the macro cell user information. The femto control station 1040 then transmits the subchannel set. The femto control station 1040 receives the subchannel set and configures the modified subchannel set in consideration of the amount of interference between femtocells. The femto control station 1040 allocates the subchannel set to the femto base station 1010. The femto base station 1010 performs resource scheduling based on the allocated resources.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions as defined by the following claims It will be understood that various modifications and changes may be made thereto without departing from the spirit and scope of the invention.

110: macro base station, 112: macro cell user
114: macro network 120: macro control station
130: femto base station 132: femtocell user
134: femto network 140: femto control station

Claims (19)

In a macro control station, a method for controlling interference caused by a femtocell to a macro cell,
A subchannel set generation step of generating a subchannel (frequency resource) set based on an amount of interference that a femtocell gives to an existing user of the macrocell based on user information of the macrocell; And
Transmitting the subchannel set to a femto control station;
The generating of the subchannel set includes generating the subchannel set by extracting a subchannel having the least amount of interference by calculating an amount of interference given to an existing user of the macro cell. Control method.
The method of claim 1, wherein generating the subchannel set
Calculating an amount of interference given to an existing user of the macro cell when the femtocell uses the subchannel for all subchannels;
Arranging the subchannels in order of decreasing magnitude of the interference amount based on the calculated interference amount; And
And generating the subchannel set based on the sorted order.
delete The method of claim 1,
Checking whether the femtocell exists in a network; And
And receiving the location information of the femtocell from the femtocell based on the presence of the femtocell.
In a macro control station, an apparatus for controlling interference that a femtocell gives to a macro cell,
A subchannel set generation unit generating a subchannel (frequency resource) set based on an amount of interference that a femtocell gives to an existing user of the macrocell based on user information of the macrocell; And
A transmitter for transmitting the subchannel set to a femto control station,
The subchannel set generation unit calculates an amount of interference given to an existing user of the macro cell, and extracts a subchannel having the least amount of interference to generate the subchannel set.
The method of claim 5, wherein the subchannel set generator
An interference amount calculator for calculating an amount of interference given to an existing user of the macro cell when the femtocell uses the subchannel for all subchannels;
An alignment unit to align the subchannels in order of decreasing magnitude of the interference amount based on the calculated interference amount; And
And a set generator for generating the subchannel set based on the sorted order.
delete The method of claim 5, wherein
A femtocell identification unit for confirming whether the femtocell exists in a network; And
And a location information receiver configured to receive location information of the femtocell from the femtocell based on the presence of the femtocell.
A method for controlling interference that a second femtocell at a femto control station gives to a first femtocell,
Create a modified subchannel set to generate a modified subchannel set by excluding a subchannel used by the first femtocell user from a subchannel (frequency resource) set received from a macro control station based on user information of the first femtocell. step; And
And a subchannel allocation step of allocating the second femtocell with a subchannel that gives the least amount of interference to the existing macro user in the modified subchannel set.
The generating of the modified subchannel set includes generating the modified subchannel set in consideration of the amount of interference between the first and second femtocells based on the subchannel set. .
delete 10. The method of claim 9, wherein generating the modified subchannel set
Excluding a subchannel used by the first femtocell user from the subchannel set;
Aligning the subchannel sets in the order of the smallest amount of interference between the first and second femtocells; And
And generating the modified subchannel set based on the sorted subchannel set.
10. The method of claim 9, wherein generating the modified subchannel set
And calculating the amount of interference between the first and second femtocells based on the amount of interference the second femtocell gives to the first femtocell user.
The method of claim 9,
The subchannel allocating step includes allocating the subchannel to the second femtocell based on the amount of interference that the second femtocell gives to an existing user of the macro cell.
An apparatus for controlling interference that a second femtocell at a femto control station gives to a first femtocell,
Create a modified subchannel set to generate a modified subchannel set by excluding a subchannel used by the first femtocell user from a subchannel (frequency resource) set received from a macro control station based on user information of the first femtocell. part; And
And a subchannel allocator for allocating a second channel to the second femtocell that has the least amount of interference to the existing macro user in the modified subchannel set.
The modified subchannel set generator generates the modified subchannel set in consideration of the amount of interference between the first and second femtocells based on the subchannel set.
delete 15. The apparatus of claim 14, wherein the modified subchannel set generator
An exclusion unit excluding a subchannel used by the first femtocell user from the subchannel set;
An alignment unit for aligning the subchannel sets in the order of a small amount of interference between the first and second femtocells; And
And a set generator configured to generate the modified subchannel set based on the sorted subchannel set.
15. The apparatus of claim 14, wherein the modified subchannel set generator
The femtocell-related interference control device for calculating the amount of interference between the first and the second femtocell based on the amount of interference that the second femtocell to the first femtocell user.
15. The method of claim 14,
And the subchannel allocator allocates the subchannel to the second femtocell based on the amount of interference that the second femtocell gives to an existing user of the macro cell.
In the method for controlling the interference that the second femtocell to the first femtocell and macro cell,
Generating, by the macro control station, a subchannel set generating a subchannel set having the least amount of interference by calculating an amount of interference that the second femtocell gives to an existing user of the macrocell based on user information of the macrocell;
Generating, by the femto control station, a subchannel set modified by excluding a subchannel used by a first femtocell user from the subchannel set based on the user information of the first femtocell; And
And a subchannel allocating step of the femto control station allocating a subchannel that gives the least amount of interference to an existing user of the macro cell in the modified subchannel set to the second femtocell,
The generating of the modified subchannel set includes generating the modified subchannel set in consideration of the amount of interference between the first and second femtocells based on the subchannel set. .

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