KR20210006047A - Method for reducing inter cell intereference and apparatus thereof - Google Patents

Abstract

Disclosed is an operation method of a first base station corresponding to at least one of a plurality of adjacent cells in a cooperative cell including adjacent portions between a plurality of adjacent cells. The operation method of a first base station according to one embodiment of the present invention comprises the steps of: identifying a sub-region planned to transmit a beam among sub-regions dividing the coverage of the cooperative cell; excluding a sub-region corresponding to a sub-region planned to transmit the beam among the sub-regions related to the first base station in the cooperative cell; and planning to transmit the beam to at least a part of the sub-regions other than the excluded sub-regions among the sub-regions related to the first base station in the cooperative cell.

Description

Method and apparatus for reducing inter-cell interference {METHOD FOR REDUCING INTER CELL INTEREFERENCE AND APPARATUS THEREOF}

The following embodiments relate to a method and apparatus for reducing inter-cell interference, for example, to a beam operation technology in a 5G base station.

The official name of 5G communication is IMT-2020, which is a fifth generation communication standard defined by the International Telecommunication Union (ITU). 3GPP, an industry standard organization, aims to propose the content of standards completed in 2019 to ITU-R and obtain final approval by IMT-2020.

Depending on the frequency band used, the maximum number of beams that the 5G base station (gNodeB) can use is determined. For example, if the used frequency band of a 5G base station corresponds to a frequency of less than 3 GHz, the maximum number of beams that can be used is 4, and if the frequency band of the 5G base station corresponds to a frequency greater than 3 GHz and less than 6 GHz, the maximum usable The number of beams is 8, and when the frequency band used by the 5G base station corresponds to a frequency exceeding 24 GHz, the maximum number of available beams may be 64.

The beam operation method of the 5G base station can be divided into two. Specifically, the 5G base station can fix an available beam and select and use an appropriate beam according to the situation, or create and use an optimized beam in real time based on channel information provided by the terminal.

By performing a method of reducing inter-cell interference according to an embodiment, it may be controlled so that inter-beam interference used between a plurality of adjacent cells does not occur. In addition, the result of the beam transmission plan is equally exchanged between a plurality of base stations corresponding to a plurality of adjacent cells, and a period in which the result of the beam transmission plan is exchanged may be adjusted according to a channel state.

In a cooperative cell including adjacent portions between a plurality of adjacent cells according to an embodiment, the operation method of the first base station corresponding to at least one of the plurality of adjacent cells includes sub-areas for dividing the coverage of the cooperative cell Identifying a sub-area scheduled to transmit a middle beam; Excluding a sub-region corresponding to a sub-region planned to transmit the beam from among sub-regions related to the first base station in the cooperative cell; And planning to transmit a beam to at least some of the remaining sub-areas except for the excluded sub-area among the sub-areas associated with the first base station in the cooperative cell.

According to an embodiment, the method of operating the first base station further comprises transmitting a result of planning to transmit a beam to at least a portion of the remaining sub-regions to at least some of a plurality of base stations corresponding to the plurality of adjacent cells. Can include.

According to an embodiment, in the operating method of the first base station, a result of planning to transmit a beam to at least some of sub-areas dividing the coverage of the cooperative cell is at least part of a plurality of base stations corresponding to the plurality of adjacent cells. It may further include receiving from.

According to an embodiment, the operation method of the first base station is a transmission period of a result of planning transmission of a beam in relation to sub-areas that divide the coverage of the cooperative cell in a plurality of base stations corresponding to the plurality of adjacent cells. Determining; And receiving the transmission period from at least some of a plurality of base stations corresponding to the plurality of adjacent cells.

According to an embodiment, the method of operating the first base station may further include transmitting the transmission period to at least some of a plurality of base stations corresponding to the plurality of adjacent cells.

According to an embodiment, the determining of the transmission period may include determining the transmission period based on a degree to which channel information related to the plurality of adjacent cells changes over time.

According to an embodiment, after the transmission period elapses, the order of beam transmission planning in relation to sub-areas that divides the coverage of the cooperative cell between a plurality of base stations corresponding to the plurality of adjacent cells is changed. Can be.

According to an embodiment, when the corresponding sub-region transmits a beam to the sub-region planned to transmit the beam and the corresponding sub-region simultaneously, the beam transmitted from the sub-region planned to transmit the beam and the corresponding It may correspond to a sub-region where interference occurs between beams transmitted from the sub-region.

According to an embodiment, in relation to the first sub-region and the second sub-region included in the sub-regions related to the first base station, the transmission direction of the beam when the beam is transmitted from the first sub-region, and the When the beam is transmitted from the second sub-region, the transmission directions of the beams may be different from each other.

In a cooperative cell including adjacent portions between a plurality of cells adjacent to each other according to an embodiment, a first base station that performs an operation corresponding to at least one of the plurality of adjacent cells includes a memory in which a program is recorded; And a processor that performs the program, wherein the program comprises: identifying a sub-region scheduled to transmit a beam among sub-regions that divide the coverage of the cooperative cell; Excluding a sub-region corresponding to a sub-region planned to transmit the beam from among sub-regions related to the first base station in the cooperative cell; And a step of planning to transmit a beam to at least a part of the remaining sub-areas except for the excluded sub-area among the sub-areas related to the first base station in the cooperative cell.

1 is a network configuration diagram according to an embodiment.
2 is a diagram illustrating an operation of a cooperative cell including a plurality of base stations corresponding to a plurality of cells adjacent to each other and adjacent portions between a plurality of cells adjacent to each other according to an exemplary embodiment.
3 is an exemplary diagram of a result of planning transmission of a beam in relation to a plurality of cells included in a cooperative cell by a plurality of base stations corresponding to a plurality of adjacent cells according to an embodiment.
4 is an exemplary diagram for explaining the operation of a plurality of base stations corresponding to a plurality of adjacent cells according to an embodiment.
5 is a flowchart illustrating an operation of a first base station included in a cooperative cell according to an embodiment.

Specific structural or functional descriptions of the embodiments are disclosed for illustrative purposes only, and may be changed in various forms and implemented. Accordingly, the embodiments are not limited to a specific disclosure form, and the scope of the present specification includes changes, equivalents, or substitutes included in the technical idea.

Although terms such as first or second may be used to describe various components, these terms should be interpreted only for the purpose of distinguishing one component from other components. For example, a first component may be referred to as a second component, and similarly, a second component may be referred to as a first component.

When a component is referred to as being "connected" to another component, it is to be understood that it may be directly connected or connected to the other component, but other components may exist in the middle.

Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present specification, terms such as "comprise" or "have" are intended to designate that the described feature, number, step, action, component, part, or combination thereof exists, but one or more other features or numbers, It is to be understood that the presence or addition of steps, actions, components, parts, or combinations thereof, does not preclude the possibility of preliminary exclusion.

Unless otherwise defined, all terms, including technical or scientific terms, used herein have the same meaning as commonly understood by one of ordinary skill in the relevant technical field. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this specification. Does not.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. The same reference numerals in each drawing indicate the same members.

1 is a network configuration diagram according to an embodiment.

Referring to FIG. 1, a network configuring mobile communication may include a core network and an access network. The core network may include a part that manages and manages the entire network and a part connected to the access network for each region. An access network is a network directly connected to a subscriber, and a base station can be used as a base.

The base station is installed to provide mobile communication services. The base station may cover a service provision area. Cell refers to an area in which one base station covers a service. A cell is an electromagnetic wavelength having the same intensity, and when only one cell exists on a plane, the shape of the cell may be expressed in the shape of a circle centered on the base station.

If there is only one cell, or even if there are a plurality of cells, if the service provision area is not tightly configured by the plurality of cells, a user moving from one cell to another cell may not be continuously provided with a service. In order to solve this problem, a network may be configured in a form in which a plurality of cells are adjacent to each other. When a plurality of cells exist on a plane and a plurality of cells are adjacent to each other, the shape of the cell may be expressed in various shapes such as polygons according to division adjustment according to the intensity of propagation with the adjacent cells.

According to an embodiment, a plurality of cells may form a network in a hexagonal shape (refer to the drawing). However, even if a plurality of cells form a network closely, it is not necessary to form a network in a hexagonal shape. Hereinafter, for convenience of explanation, embodiments in which a plurality of cells constitute a network in a hexagonal shape will be described. However, in some cases, the plurality of cells may constitute a network in another polygonal shape such as a square, and the plurality of cells It is also possible to construct a network while having various forms that are not unified.

When a plurality of cells are adjacent to each other, inter-cell interference may occur in relation to adjacent portions between cells. In order to discuss the problem of reducing inter-cell interference, a cooperative cell may be defined. The cooperation cell may correspond to a cell including adjacent portions between a plurality of adjacent cells. In order to discuss the problem of reducing inter-cell interference, operations of a plurality of base stations corresponding to a plurality of cells adjacent to each other may be defined.

More details related to the operation of a plurality of base stations and cooperative cells corresponding to a plurality of cells adjacent to each other will be described later with reference to FIG. 2.

2 is a diagram illustrating an operation of a cooperative cell including a plurality of base stations corresponding to a plurality of cells adjacent to each other and adjacent portions between a plurality of cells adjacent to each other according to an exemplary embodiment.

Referring to FIG. 2, a network constituting mobile communication according to an embodiment includes a plurality of cells adjacent to each other. As an example, a network configuring mobile communication may include cell 0 210, cell 1 220 and cell 2 230. In addition, a cooperative cell 240 including adjacent portions between the cell 0 210, the cell 1 220 and the cell 2 230 may be illustrated as shown in the drawing.

The coverage of the cooperative cell 240 including adjacent portions between cell 0 210, cell 1 220 and cell 2 230 is a base station corresponding to cell 0 210 and a base station corresponding to cell 1 220 It includes a plurality of regions (hereinafter, sub-regions for dividing the coverage of the cooperative cell 240) in which a beam can be transmitted by at least one of the base station and the base station corresponding to the cell 2 230. Areas in which the beam can be transmitted by the base station corresponding to cell 0 210 (hereinafter, sub-areas related to the base station corresponding to cell 0 210) are bounded by solid lines in the cooperative cell 240. It may correspond to the upper part. Regions in which the beam can be transmitted by the base station corresponding to cell 1 220 (hereinafter, sub-regions related to the base station corresponding to cell 1 220) are defined by solid lines in the cooperative cell 240 It may correspond to the lower left part. Areas in which a beam can be transmitted by a base station corresponding to cell 2 230 (hereinafter, sub-areas related to a base station corresponding to cell 2 230) are defined by solid lines in the cooperative cell 240 It may correspond to the lower right part.

When beams are transmitted from different subregions related to a base station corresponding to one cell, the transmission directions may be different from each other. For example, in relation to different first sub-regions and second sub-regions included in the sub-regions related to the base station corresponding to cell 1 (220), the beam when transmitting the beam from the first sub-region The transmission direction and the transmission direction of the beam when the beam is transmitted from the second sub-region may be different from each other.

When a plurality of beams are simultaneously transmitted, interference may occur between the plurality of beams. If the distance between the positions from which the beams are transmitted is sufficiently far apart, interference may not occur at all, or even if interference occurs, the effect may be insignificant. On the other hand, as the distance between the positions from which the beams are transmitted becomes closer, interference may occur more.

Among the sub-regions, sub-regions that are related to different base stations and where interference occurs above a predetermined threshold may be defined as sub-regions corresponding to each other. In this case, when the beam is simultaneously transmitted to the sub-region planned to transmit the beam and the sub-region corresponding to the sub-region planned to transmit the beam, the beam transmitted from the sub-region planned to transmit the beam and the beam transmitted from the corresponding sub-region Interference may occur between the beams.

Sub-regions related to different base stations may correspond to different cells. Specifically, when the sub-areas related to the base station A correspond to cell a, which is an area where the base station A covers the service, and the sub-areas related to the base station B correspond to the cell b, which is an area where the base station B covers the service, If base station A and base station B correspond to different base stations, cell a and cell b may correspond to different cells. In this case, a base station corresponding to cell a may be a base station A, and a base station corresponding to cell b may be a base station B.

According to an embodiment, sub-regions that are related to different base stations and have portions adjacent to each other may be defined as sub-regions corresponding to each other. For example, when sub-regions exist in the cooperating cell 240 as shown by dotted lines in the drawing, the beam is in the leftmost direction among the sub-regions related to the base station corresponding to the cell 0 (210). A subregion transmitting a beam in an uppermost direction among subregions related to a base station corresponding to the cell 1 220 and a subregion transmitting a beam may correspond to each other.

Transmission of a beam may be planned so that a plurality of base stations corresponding to a plurality of adjacent cells do not simultaneously transmit a beam to corresponding subregions. By planning the transmission of the beam in this way, interference between cells can be reduced. To this end, the first base station included in the cooperative cell 240 (the first base station is any of a base station corresponding to cell 0 210, a base station corresponding to cell 1 220, and a base station corresponding to cell 2 230) May be one) identifies a sub-region planned to transmit a beam among sub-regions that divide the coverage of the cooperative cell 240.

According to an embodiment, the first base station may receive a result planned to transmit the beam to at least some of the sub-areas dividing the coverage of the cooperative cell 240 from at least some of the plurality of base stations corresponding to a plurality of adjacent cells. I can. In this case, a plurality of adjacent cells may correspond to a plurality of adjacent cells in the cooperative cell 240 to be discussed. For example, when the first base station is a base station corresponding to cell 0 210, a plurality of adjacent cells may correspond to cell 1 220 and cell 2 230.

When the first base station receives the result of the beam transmission plan from at least some of the plurality of base stations corresponding to a plurality of adjacent cells, the first base station based on the received result is a sub-region for dividing the coverage of the cooperative cell 240 Among them, a sub-area planned to transmit a beam can be identified.

The first base station excludes the sub-region corresponding to the sub-region planned to transmit the beam among the sub-regions related to the first base station in the cooperative cell 240, and covers at least a portion of the remaining sub-regions excluding the excluded sub-region. Plan to send out the beam. By excluding the sub-regions corresponding to the sub-regions for which the first base station is planned to transmit the beam, the situation in which the corresponding sub-regions simultaneously transmit the beam can be prevented.

The first base station may transmit, to at least some of the plurality of base stations corresponding to a plurality of adjacent cells, a result of planning to transmit the beam to at least a portion of the remaining sub-areas excluding the excluded sub-area. In this case, the base station receiving the beam transmission result from the first base station may grasp the sub-area planned to transmit the beam among the sub-areas that divide the coverage of the cooperative cell 240 based on the received result. Furthermore, a base station that has not yet planned to transmit a beam among a plurality of base stations corresponding to a plurality of adjacent cells may plan to transmit a beam to at least some of the sub-areas based on a received result.

According to an embodiment, the first base station determines a period in which a result of the beam transmission plan is transmitted in relation to sub-areas that divide the coverage of the cooperative cell 240 in a plurality of base stations corresponding to a plurality of adjacent cells. I can. According to an embodiment, the first base station may receive a transmission period from at least some of a plurality of base stations corresponding to the plurality of adjacent cells.

)를 결정할 수 있다. 일 예시로, 셀 0(210)에 대응되는 기지국은 빔의 송출을 계획한 결과를 전송하는 주기를 결정할 수 있다. 이 경우, 셀 0(210)에 대응되는 기지국은 셀 1(220)에 대응되는 기지국 및 셀 2(230)에 대응되는 기지국 중 적어도 일부에 결정된 전송 주기를 전송할 수 있다. 또한, 셀 1(220)에 대응되는 기지국 및 셀 2(230)에 대응되는 기지국 중 적어도 일부는 셀 0(210)에 대응되는 기지국에서 결정된 전송 주기를 수신할 수 있다. 다른 예시로, 셀 0(210)에 대응되는 기지국 및 셀 1(220)에 대응되는 기지국은 빔의 송출을 계획한 결과를 전송하는 주기를 결정할 수 있다. 이 경우, 셀 0(210)에 대응되는 기지국 및 셀 1(220)에 대응되는 기지국 중 적어도 일부는 결정된 전송 주기를 셀 2(230)에 대응되는 기지국으로 전송할 수 있다. 또한, 셀 2(230)에 대응되는 기지국은 셀 0(210)에 대응되는 기지국 및 셀 1(220)에 대응되는 기지국에서 결정된 전송 주기를 셀 0(210)에 대응되는 기지국 및 셀 1(220)에 대응되는 기지국 중 적어도 일부로부터 수신할 수 있다.Specifically, the transmission period of the result of the transmission of the beam by the base station corresponding to at least one cell among the plurality of cells included in the cooperative cell 240 (= scheduling information exchange period

) Can be determined. As an example, the base station corresponding to the cell 0 210 may determine a period in which a result of planning transmission of a beam is transmitted. In this case, the base station corresponding to cell 0 210 may transmit the determined transmission period to at least some of the base station corresponding to cell 1 220 and the base station corresponding to cell 2 230. In addition, at least some of the base station corresponding to cell 1 220 and the base station corresponding to cell 2 230 may receive a transmission period determined by the base station corresponding to cell 0 210. As another example, the base station corresponding to the cell 0 210 and the base station corresponding to the cell 1 220 may determine a period in which a result of a beam transmission plan is transmitted. In this case, at least some of the base station corresponding to cell 0 210 and the base station corresponding to cell 1 220 may transmit the determined transmission period to the base station corresponding to cell 2 230. In addition, the base station corresponding to cell 2 (230) determines the transmission period determined by the base station corresponding to cell 0 (210) and the base station corresponding to cell 1 (220), and the base station corresponding to cell 0 (210) and cell 1 (220). ) Can be received from at least some of the base stations corresponding to.

According to an embodiment, the transmission period may be determined based on a degree to which channel information related to a plurality of adjacent cells included in the cooperative cell 240 changes over time. As an example, if the environment for providing mobile communication services related to a plurality of adjacent cells is a city center, and the main user receiving the mobile communication service is a walking person and a person riding in a vehicle moving at a relatively low speed, the channel information is time Depending on the degree of change may not be relatively large. In this case, since the necessity of frequently planning the transmission of the beam is relatively small, the transmission period may be determined relatively large. As another example, when the environment for providing mobile communication services related to a plurality of adjacent cells is a highway, and the main user receiving the mobile communication service is a person who rides a vehicle moving at a relatively high speed, channel information changes with time. The degree can be relatively large. In this case, since the necessity of frequently planning the transmission of the beam is relatively large, the transmission period may be determined relatively small.

As already described above, the first base station included in the cooperative cell 240 is any one of a base station corresponding to cell 0 (210), a base station corresponding to cell 1 (220), and a base station corresponding to cell 2 (230). Can be Therefore, identifying the sub-area planned to transmit the beam, excluding the sub-area corresponding to the sub-area planned to transmit the beam among sub-areas related to the sub-area, and the remaining sub-areas excluding the excluded sub-area. The step of planning to transmit the beam to at least a portion may be performed in both the base station corresponding to the cell 0 210, the base station corresponding to the cell 1 220, and the base station corresponding to the cell 2 230. However, between the base station corresponding to cell 0 (210), the base station corresponding to cell 1 (220), and the base station corresponding to cell 2 (230), the order of who plans to transmit the beam first or later will be variously determined. (Or at least some of the operations may be performed simultaneously in a plurality of cells).

According to an embodiment, a transmission period of a result of planning transmission of a beam may be determined by a base station that first plans transmission of a beam. In this case, the base station that first plans to transmit the beam can transmit the beam transmission plan to the other base station based on the transmission period determined by itself without having to wait to receive the transmission period determined by the other base station. Therefore, when the transmission period of the result of planning the transmission of the beam is determined by the base station that first plans to transmit the beam, it is possible to prevent the entire operation of the base stations in the cooperative cell 240 from becoming unnecessarily complicated. However, this is exemplary, and if necessary, a transmission period of a result of planning transmission of a beam may be determined by a base station other than a base station that first plans to transmit the beam.

After the base station corresponding to cell 0 (210), the base station corresponding to cell 1 (220), and the base station corresponding to cell 2 (230) have planned transmission of the beam, each cell during the transmission period of the result of planning the transmission of the beam. The beam can be sent out based on the plan at. After the transmission period of the result of planning the transmission of the beam has elapsed, the step of identifying the sub-region planned to transmit the beam, excluding the sub-region corresponding to the sub-region planned to transmit the beam among the sub-regions related to itself. Steps, and the steps of planning to transmit the beam to at least a portion of the remaining sub-areas excluding the excluded sub-areas are to the base station corresponding to cell 0 (210), the base station corresponding to cell 1 (220), and the cell 2 (230). It can be performed again in the corresponding base station. In this case, between the base station corresponding to cell 0 (210), the base station corresponding to cell 1 (220), and the base station corresponding to cell 2 (230), the order of who plans to transmit the beam first or later will be changed. I can.

When the transmission period of the result of planning the transmission of the beam is determined by the base station that first plans to transmit the beam, the base station corresponding to cell 0 (210), the base station corresponding to cell 1 (220), and cell 2 (230) As the order of who plans to transmit the beam first or later among the base stations corresponding to is changed, the subject that determines the transmission period of the result of planning to transmit the beam may also change. For example, when a base station corresponding to cell 0 (210) first plans to transmit a beam, the base station corresponding to cell 0 (210) may determine the transmission period, but the transmission period of the result of planning the transmission of the beam After elapses, the order of who plans to transmit the beam first or later between the base station corresponding to cell 0 (210), the base station corresponding to cell 1 (220), and the base station corresponding to cell 2 (230) is changed. Thus, when the base station corresponding to cell 1 (220) first plans to transmit a beam, the base station corresponding to cell 1 (220) may determine a transmission period.

According to an embodiment, the order of planning transmission of a beam between a base station corresponding to cell 0 210, a base station corresponding to cell 1 220, and a base station corresponding to cell 2 230 is rotationally can be changed. As an example, when a base station corresponding to cell 0 210, a base station corresponding to cell 1 220, and a base station corresponding to cell 2 230 at a specific point in time plan to transmit beams sequentially, from the time point After the transmission period has elapsed, the base station corresponding to cell 1 (220), the base station corresponding to cell 2 (230), and the base station corresponding to cell 0 (210) sequentially plan the transmission of the beam and transmit from that point in time. After the two cycles have elapsed, the base station corresponding to cell 2 230, the base station corresponding to cell 0 210, and the base station corresponding to cell 1 220 sequentially plan the transmission of the beam, and from that point in time. After the transmission period has elapsed three times, the base station corresponding to cell 0 210, the base station corresponding to cell 1 220, and the base station corresponding to cell 2 230 may sequentially plan transmission of the beam. .

By performing a method of reducing inter-cell interference according to an embodiment, it may be controlled so that inter-beam interference used between a plurality of adjacent cells does not occur. In addition, the result of the beam transmission plan is equally exchanged between a plurality of base stations corresponding to a plurality of adjacent cells, and a period in which the result of the beam transmission plan is exchanged may be adjusted according to a channel state.

3 is an exemplary diagram of a result of planning transmission of a beam in relation to a plurality of cells included in a cooperative cell by a plurality of base stations corresponding to a plurality of adjacent cells according to an embodiment.

Referring to FIG. 3, a plurality of base stations corresponding to a plurality of adjacent cells included in the cooperative cell, cell 0 (310), cell 1 (320), and cell 2 (330) simultaneously transmit beams to corresponding sub-areas. The transmission of the beam can be planned so that it does not. The cooperative cell corresponds to the cooperative cell 240 of FIG. 2, the cell 0 310 corresponds to the cell 0 210 of FIG. 2, and the cell 1 320 corresponds to the cell 1 220 of FIG. , Cell 2 330 may correspond to cell 2 230 of FIG. 2. Sub-regions corresponding to each other may be sub-regions that are related to different base stations and in which interference exceeds a predetermined threshold.

According to an embodiment, the subregions corresponding to each other may be subregions in which portions adjacent to each other exist while being related to different base stations. In this case, as shown in Figure 3, the base station corresponding to the cell 0 (310). The transmission of the beam may be planned so that the base station corresponding to the cell 1 320 and the base station corresponding to the cell 2 330 do not simultaneously transmit the beam to sub-regions in which portions adjacent to each other exist.

4 is an exemplary diagram for explaining the operation of a plurality of base stations corresponding to a plurality of adjacent cells according to an embodiment.

및 t를 정의할 수 있다(410). 협력 셀은 도 2의 협력 셀(240)에 대응될 수 있다. n은 협력 셀에 포함되는 인접한 복수의 셀인 셀 0, 셀 1 및 셀 2에 대응되는 복수의 기지국의 동작 및 복수의 기지국들 간에 누가 먼저 혹은 나중에 빔의 송출을 계획할 것인지에 대한 순서를 일반적으로 설명하기 위하여 정의되는 변수로서, 그 초기값이 0으로 설정될 수 있다. 셀 0은 도 2의 셀 0(210)에 대응되고, 셀 1은 도 2의 셀 1(220)에 대응되며, 셀 2는 도 2의 셀 2(230)에 대응될 수 있다.

는 스케쥴링 정보 교환 주기로서, 협력 셀이 포함하는 복수의 셀에 대응되는 복수의 기지국 중 적어도 하나의 셀에 대응되는 기지국이 빔의 송출을 계획한 결과를 전송하는 주기일 수 있다. 이전 시행에 따라 결정된

값이 이후 시행에 영향을 미치는 일을 방지하기 위하여,

의 초기값은 0으로 설정될 수 있다.

는 도 2의 '빔의 송출을 계획한 결과의 전송 주기'에 대응될 수 있다. t는

만큼의 시간이 경과했는지를 판단하기 위하여 정의되는 변수로서, 그 초기값이 0으로 설정될 수 있다. t가

값을 초과하면 t가 0으로 리셋(reset)되고 셀 0, 셀 1 및 셀 2에 대응되는 복수의 기지국에서 빔의 송출이 다시 계획될 수 있다.4, in order to explain the operation of a plurality of base stations in a cooperative cell according to an embodiment, n,

And t can be defined (410). The cooperative cell may correspond to the cooperative cell 240 of FIG. 2. n is a general description of the operation of a plurality of base stations corresponding to cell 0, cell 1, and cell 2, which are adjacent cells included in the cooperative cell, and the sequence of who plans to transmit the beam first or later between the plurality of base stations. As a variable defined to be used, its initial value may be set to 0. Cell 0 may correspond to cell 0 210 of FIG. 2, cell 1 may correspond to cell 1 220 of FIG. 2, and cell 2 may correspond to cell 2 230 of FIG. 2.

Is a scheduling information exchange period, and may be a period in which a base station corresponding to at least one cell among a plurality of base stations corresponding to a plurality of cells included in the cooperative cell transmits a result of planning transmission of a beam. Determined by previous enforcement

To prevent the value from affecting subsequent enforcement,

The initial value of may be set to 0.

May correspond to the'transmission period of the result of planning transmission of the beam' of FIG. 2. t is

As a variable defined to determine whether the amount of time has elapsed, its initial value may be set to 0. t

If the value is exceeded, t is reset to 0, and transmission of the beam may be rescheduled from a plurality of base stations corresponding to cells 0, 1, and 2.

를 결정하기 위하여, 채널 정보가 시간에 따라 변하는 정도가 각 셀에 대응되는 각 기지국에서 계산될 수 있다(420).

는 셀 0, 셀 1 및 셀 2와 관련되는 채널 정보가 시간에 따라 변하는 정도에 기초하여 결정될 수 있다. 계산된 채널 정보에 기초하여, 협력 셀 내 대표 셀에 대응되는 기지국에서

를 결정할 수 있다(430). 대표 셀에 대응되는 기지국은

를 결정하는 기지국에 대응될 수 있다. 일실시예에 따르면, 대표 셀은 하나의 셀에 대응될 수 있다. 일실시예에 따르면, 대표 셀은 복수의 셀에 대응될 수도 있다.

In order to determine the channel information, the degree to which the channel information changes over time may be calculated at each base station corresponding to each cell (420).

May be determined based on a degree to which channel information related to cell 0, cell 1, and cell 2 changes over time. Based on the calculated channel information, in the base station corresponding to the representative cell in the cooperative cell

Can be determined (430). The base station corresponding to the representative cell

It may correspond to the base station determining the. According to an embodiment, the representative cell may correspond to one cell. According to an embodiment, the representative cell may correspond to a plurality of cells.

에 기초하여, 셀 REM(n,3)에 대응되는 기지국에서 향후

동안의 스케쥴링(scheduling)을 결정할 수 있다(440). REM(a,b)는 a를 b로 나눈 나머지를 의미할 수 있다. 예를 들어, REM(4,3)은 1을 의미할 수 있다. 따라서, n이 0인 경우, 셀 REM(n,3)은 셀 0일 수 있다. 스케쥴링을 결정하는 동작에 의하여 생성되는 스케쥴(schedule)은 빔의 송출을 계획한 결과와 관련된 정보를 포함할 수 있다. 셀 REM(n,3)에 대응되는 기지국은 스케쥴링한 결과를 인접한 복수의 셀에 대응되는 기지국 중 적어도 일부에 전송할 수 있다. 일실시예에 따르면, 셀 REM(n,3)에 대응되는 기지국은 스케쥴링한 결과를 셀 REM(n+1,3)에 대응되는 기지국 및 셀 REM(n+2,3)에 대응되는 기지국에 전송할 수 있다.determined

Based on, in the future in the base station corresponding to the cell REM(n,3)

During scheduling, it is possible to determine (440). REM(a,b) may mean the remainder of dividing a by b. For example, REM(4,3) may mean 1. Therefore, when n is 0, cell REM(n,3) may be cell 0. The schedule generated by the operation of determining the scheduling may include information related to a result of planning transmission of the beam. The base station corresponding to the cell REM(n,3) may transmit the scheduling result to at least some of the base stations corresponding to a plurality of adjacent cells. According to an embodiment, the base station corresponding to the cell REM(n,3) transmits the scheduling result to the base station corresponding to the cell REM(n+1,3) and the base station corresponding to the cell REM(n+2,3). Can be transmitted.

에 기초하여, 셀 REM(n+1,3)에 대응되는 기지국에서 향후

동안의 스케쥴(schedule)을 결정할 수 있다(450). n이 0인 경우, 셀 REM(n+1,3)은 셀 1일 수 있다. 셀 REM(n+1,3)에 대응되는 기지국은 인접한 복수의 셀에 대응되는 기지국 중 적어도 일부로부터 해당 셀에 대한 스케쥴링(scheduling) 결과를 수신하고, 수신된 정보에 기초하여 스케쥴을 결정할 수 있다. 일실시예에 따르면, 셀 REM(n+1,3)에 대응되는 기지국은 셀 REM(n,3)에 대응되는 기지국으로부터 셀 REM(n,3)에 대한 스케쥴링 결과를 수신하고, 수신된 정보에 기초하여 스케쥴을 결정할 수 있다. 또한, 셀 REM(n+1,3)에 대응되는 기지국은 스케쥴링한 결과를 인접한 복수의 셀에 대응되는 복수의 기지국 중 적어도 일부에 전송할 수 있다. 일실시예에 따르면, 셀 REM(n+1,3)에 대응되는 기지국은 스케쥴링한 결과를 셀 REM(n+2,3)에 대응되는 기지국에 전송할 수 있다.determined

Based on, in the future in the base station corresponding to the cell REM (n+1,3)

It is possible to determine a schedule (schedule) during (450). When n is 0, cell REM(n+1,3) may be cell 1. The base station corresponding to the cell REM (n+1,3) may receive a scheduling result for a corresponding cell from at least some of the base stations corresponding to a plurality of adjacent cells, and determine a schedule based on the received information. . According to an embodiment, a base station corresponding to cell REM(n+1,3) receives a scheduling result for cell REM(n,3) from a base station corresponding to cell REM(n,3), and received information The schedule can be determined based on. In addition, the base station corresponding to the cell REM (n+1,3) may transmit the scheduling result to at least some of the plurality of base stations corresponding to a plurality of adjacent cells. According to an embodiment, the base station corresponding to the cell REM (n+1,3) may transmit the scheduling result to the base station corresponding to the cell REM (n+2,3).

에 기초하여, 셀 REM(n+2,3)에 대응되는 기지국에서 향후

동안의 스케쥴을 결정할 수 있다(460). n이 0인 경우, 셀 REM(n+2,3)은 셀 2일 수 있다. 셀 REM(n+2,3)에 대응되는 기지국은 인접한 복수의 셀 중 적어도 일부로부터 해당 셀에 대한 스케쥴링 결과를 수신하고, 수신된 정보에 기초하여 스케쥴을 결정할 수 있다. 일실시예에 따르면, 셀 REM(n+2,3)에 대응되는 기지국은 셀 REM(n,3)에 대응되는 기지국 및 셀 REM(n+1,3)에 대응되는 기지국으로부터 스케쥴링 결과를 수신하고, 수신된 정보에 기초하여 셀 REM(n+2,3)에 대한 스케쥴을 결정할 수 있다.determined

Based on, in the future in the base station corresponding to the cell REM (n+2,3)

It is possible to determine the schedule during the period (460). When n is 0, cell REM(n+2,3) may be cell 2. The base station corresponding to the cell REM(n+2,3) may receive a scheduling result for a corresponding cell from at least some of a plurality of adjacent cells, and may determine a schedule based on the received information. According to an embodiment, a base station corresponding to cell REM(n+2,3) receives a scheduling result from a base station corresponding to cell REM(n,3) and a base station corresponding to cell REM(n+1,3) And, based on the received information, a schedule for the cell REM (n+2,3) may be determined.

에 대응되는 값을 가질 수 있다. 구체적으로, 0으로 초기값이 설정되었던 t 값이

를 초과하는지가 판단될 수 있다(470). 이 경우, t 값은 빔이 송출되기 시작한 순간부터 시간이 흐른 만큼 그 값이 증가할 수 있다. 예를 들어, 빔이 송출되기 시작한 순간부터 3초가 지난 경우, t 값도 빔이 송출되기 시작한 순간의 값에 비해 3초만큼 그 값이 증가할 수 있다. 따라서, t 값의 초기값이 0으로 설정되었던 경우, 빔이 송출되기 시작한 순간부터 x초가 지났을 때의 t 값이 x초가 될 수 있다(x는 임의의 양의 실수).Based on the scheduling result at the base station corresponding to the cell REM(n,3), the base station corresponding to the cell REM(n+1,3), and the base station corresponding to the cell REM(n+2,3), each cell The beam can be sent out. The time at which the beam is transmitted based on the scheduling result is

It can have a value corresponding to. Specifically, the t value whose initial value was set to 0

It may be determined whether it exceeds (470). In this case, the value of t may increase as time passes from the moment when the beam starts to be transmitted. For example, when 3 seconds elapse from the moment when the beam starts to be transmitted, the value of t may also increase by 3 seconds compared to the value at the moment when the beam starts to be transmitted. Accordingly, when the initial value of the t value is set to 0, the t value when x seconds elapse from the moment when the beam starts to be transmitted may be x seconds (x is an arbitrary positive real number).

를 초과하지 않는 경우, t 값이

를 초과하는지가 지속적으로 판단될 수 있다 (470 → 470). 반면, t 값이

를 초과하는 경우, n 값이 1 증가하고, t는 0으로 다시 리셋될 수 있다(470 → 480). n 값이 1 증가한 뒤, 단계 440 내지 470의 과정이 다시 반복될 수 있다. n 값이 증가함에 따라서 빔의 송출을 계획하는 순서는 돌아가면서(rotationally) 변경될 수 있다. 일 예시로, n이 0인 경우 셀 0, 셀 1 및 셀 2 순서로 스케쥴이 결정되지만, t 값이

를 초과하게 되어 n 값이 1이 되면 셀 1, 셀 2 및 셀 0 순서로 스케쥴이 결정될 수 있다.t value

Does not exceed, the t value is

It can be continuously judged whether it exceeds (470 → 470). On the other hand, the value of t is

If it exceeds, the value of n increases by 1, and t may be reset back to 0 (470 → 480). After the n value is increased by 1, the process of steps 440 to 470 may be repeated again. As the value of n increases, the order in which the transmission of the beam is planned may be rotationally changed. As an example, when n is 0, the schedule is determined in the order of cell 0, cell 1, and cell 2, but the t value is

When the value of n exceeds 1, the schedule may be determined in the order of cell 1, cell 2, and cell 0.

5 is a flowchart illustrating an operation of a first base station included in a cooperative cell according to an embodiment.

5, in a cooperative cell including adjacent portions between a plurality of cells adjacent to each other, a first base station corresponding to at least one of a plurality of adjacent cells transmits a beam among sub-areas that divide the coverage of the cooperative cell. A sub-area scheduled to be performed is identified (510). The cooperative cell corresponds to the cooperative cell 240 of FIG. 2, and the first base station may correspond to the first base station of FIG. 2. According to an embodiment, the first base station receives the result of the plan to transmit the beam to at least some of the sub-regions that divide the coverage of the cooperative cell from at least some of the plurality of base stations corresponding to the adjacent cells, thereby receiving the beam. You can identify the sub-areas planned to be sent.

The first base station excludes a sub-region corresponding to a sub-region planned to transmit a beam from among the sub-regions associated with the first base station in the cooperative cell (520). Among the sub-regions, sub-regions that are related to different base stations and where interference occurs above a predetermined threshold may be defined as sub-regions corresponding to each other. When transmitting a beam simultaneously to a sub-area planned to transmit a beam and a sub-area corresponding to a sub-area planned to transmit a beam, between the beam transmitted from the sub-area planned to transmit the beam and the beam transmitted from the corresponding sub-area Interference may occur. According to an embodiment, sub-areas associated with different base stations and having portions adjacent to each other may be defined as sub-areas corresponding to each other.

The first base station plans to transmit a beam to at least some of the remaining sub-areas excluding the excluded sub-area among the sub-areas related to the first base station in the cooperative cell (530). Inter-cell interference can be reduced through such a plan. According to an embodiment, the first base station may transmit a result of planning to transmit a beam to at least some of the remaining sub-areas excluding the excluded sub-area to at least some of the plurality of base stations corresponding to a plurality of adjacent cells. In this case, a plurality of base stations corresponding to a plurality of adjacent cells identify a sub-area planned to transmit a beam among the sub-areas that divide the coverage of the cooperative cell based on the received result, and the base station has not yet planned to transmit the beam. May plan to transmit the beam to at least some of the sub-areas based on the received result.

The embodiments described above may be implemented as a hardware component, a software component, and/or a combination of a hardware component and a software component. For example, the devices, methods, and components described in the embodiments include, for example, a processor, a controller, an arithmetic logic unit (ALU), a digital signal processor, a microcomputer, a field programmable gate (FPGA). array), programmable logic unit (PLU), microprocessor, or any other device capable of executing and responding to instructions, such as one or more general purpose computers or special purpose computers. The processing device may execute an operating system (OS) and one or more software applications executed on the operating system. In addition, the processing device may access, store, manipulate, process, and generate data in response to the execution of software. For the convenience of understanding, although it is sometimes described that one processing device is used, one of ordinary skill in the art, the processing device is a plurality of processing elements and/or a plurality of types of processing elements. It can be seen that it may include. For example, the processing device may include a plurality of processors or one processor and one controller. In addition, other processing configurations are possible, such as a parallel processor.

The software may include a computer program, code, instructions, or a combination of one or more of these, configuring the processing unit to behave as desired or processed independently or collectively. You can command the device. Software and/or data may be interpreted by a processing device or to provide instructions or data to a processing device, of any type of machine, component, physical device, virtual equipment, computer storage medium or device. , Or may be permanently or temporarily embodyed in a transmitted signal wave. The software may be distributed over networked computer systems and stored or executed in a distributed manner. Software and data may be stored on one or more computer-readable recording media.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the embodiment, or may be known and usable to those skilled in computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floptical disks. -A hardware device specially configured to store and execute program instructions such as magneto-optical media, and ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those produced by a compiler but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware device described above may be configured to operate as one or more software modules to perform the operation of the embodiment, and vice versa.

As described above, although the embodiments have been described by the limited drawings, a person of ordinary skill in the art can apply various technical modifications and variations based on the above. For example, the described techniques are performed in a different order from the described method, and/or components such as a system, structure, device, circuit, etc. described are combined or combined in a form different from the described method, or other components Alternatively, even if substituted or substituted by an equivalent, an appropriate result can be achieved.

Therefore, other implementations, other embodiments, and claims and equivalents fall within the scope of the claims to be described later.

Claims (19)

In a cooperative cell including adjacent portions between a plurality of cells adjacent to each other, in the operating method of the first base station corresponding to at least one of the plurality of adjacent cells,
Identifying a sub-area scheduled to transmit a beam among sub-areas dividing the coverage of the cooperative cell;
Excluding a sub-region corresponding to a sub-region planned to transmit the beam from among sub-regions related to the first base station in the cooperative cell; And
Planning to transmit a beam to at least a portion of the remaining sub-areas except for the excluded sub-area among the sub-areas related to the first base station in the cooperative cell
Containing,
Method of operation of the first base station.
The method of claim 1,
Transmitting a result of planning to transmit a beam to at least a portion of the remaining sub-areas to at least a portion of a plurality of base stations corresponding to the plurality of adjacent cells
Further comprising,
Method of operation of the first base station.
The method of claim 1,
Receiving, from at least some of the plurality of base stations corresponding to the plurality of adjacent cells, a result of the plan to transmit the beam to at least some of the sub-areas dividing the coverage of the cooperative cell
Further comprising,
Method of operation of the first base station.
The method of claim 1,
Determining a transmission period of a result of planning transmission of a beam in relation to sub-areas for dividing the coverage of the cooperative cell by a plurality of base stations corresponding to the plurality of adjacent cells; And
Receiving the transmission period from at least some of a plurality of base stations corresponding to the plurality of adjacent cells
Further comprising any one of,
Method of operation of the first base station.
The method of claim 4,
Transmitting the transmission period to at least some of a plurality of base stations corresponding to the plurality of adjacent cells
Further comprising,
Method of operation of the first base station.
The method of claim 4,
The step of determining the transmission period is
Determining the transmission period based on the degree to which channel information related to the plurality of adjacent cells changes over time
Containing,
Method of operation of the first base station.
The method of claim 4,
After the above transmission period has elapsed,
The order of planning the transmission of the beam is changed in relation to the sub-areas for dividing the coverage of the cooperative cell between a plurality of base stations corresponding to the plurality of adjacent cells,
Method of operation of the first base station.
The method of claim 1,
The corresponding sub-region is
When the beam is simultaneously transmitted to the sub-region planned to transmit the beam and the corresponding sub-region, interference occurs between the beam transmitted from the sub-region planned to transmit the beam and the beam transmitted from the corresponding sub-region Corresponding to the sub-area,
Method of operation of the first base station.
The method of claim 1,
In relation to the first sub-region and the second sub-region included in the sub-regions related to the first base station,
The beam transmission direction when the beam is transmitted from the first sub-region and the beam transmission direction when the beam is transmitted from the second sub-region are different from each other,
Method of operation of the first base station.
A computer-readable recording medium containing a program for performing the method of any one of claims 1 to 9.
In a first base station that performs an operation corresponding to at least one of the plurality of adjacent cells in a cooperative cell including adjacent portions between a plurality of cells adjacent to each other,
A memory in which a program is recorded; And
Processor that executes the above program
Including,
The above program,
Identifying a sub-area scheduled to transmit a beam among sub-areas dividing the coverage of the cooperative cell;
Excluding a sub-region corresponding to a sub-region planned to transmit the beam from among sub-regions related to the first base station in the cooperative cell; And
Planning to transmit a beam to at least a portion of the remaining sub-areas except for the excluded sub-area among the sub-areas related to the first base station in the cooperative cell
To do,
The first base station.
The method of claim 11,
Transmitting a result of planning to transmit a beam to at least a portion of the remaining sub-areas to at least a portion of a plurality of base stations corresponding to the plurality of adjacent cells
To do more,
The first base station.
The method of claim 11,
Receiving, from at least some of the plurality of base stations corresponding to the plurality of adjacent cells, a result of the plan to transmit the beam to at least some of the sub-areas dividing the coverage of the cooperative cell
Further comprising,
The first base station.
The method of claim 11,
Determining a transmission period based on a result of planning transmission of a beam in relation to sub-regions for dividing coverage of the cooperative cell by a plurality of base stations corresponding to the plurality of adjacent cells; And
Receiving the transmission period from at least some of a plurality of base stations corresponding to the plurality of adjacent cells
Further comprising any one of,
The first base station.
The method of claim 14,
Transmitting the transmission period to at least some of a plurality of base stations corresponding to the plurality of adjacent cells
Further comprising,
The first base station.
The method of claim 14,
The step of determining the transmission period is
Determining the transmission period based on the degree to which channel information related to the plurality of adjacent cells changes over time
Containing,
The first base station.
The method of claim 14,
After the above transmission period has elapsed,
The order of planning the transmission of the beam is changed in relation to the sub-areas for dividing the coverage of the cooperative cell between a plurality of base stations corresponding to the plurality of adjacent cells,
The first base station.
The method of claim 11,
The corresponding sub-region is
When the beam is simultaneously transmitted to the sub-region planned to transmit the beam and the corresponding sub-region, interference occurs between the beam transmitted from the sub-region planned to transmit the beam and the beam transmitted from the corresponding sub-region Corresponding to the sub-area,
The first base station.
The method of claim 11,
In relation to the first sub-region and the second sub-region included in the sub-regions related to the first base station,
The beam transmission direction when the beam is transmitted from the first sub-region and the beam transmission direction when the beam is transmitted from the second sub-region are different from each other,
The first base station.

Images