KR20150051123A - Method and appratus for heterogeneous carrier aggregation - Google Patents

Abstract

Disclosed are a method and an apparatus for heterogeneous carrier aggregation. A method for heterogeneous carrier aggregation includes a step of calculating interference for the interference paths between an adjacent cell and a serving cell, a step of determining a weighted value for accumulating interference for the interference paths in the serving cell, a step of calculating an accumulation value by accumulating interference for interference paths based on the weighted value in the serving cell, a step of determining component carrier used for carrier aggregation based on the accumulation value in the serving cell, and a step of performing carrier aggregation based on the determined component carrier.

Description

[0001] METHOD AND APPARATUS FOR HETEROGENEOUS CARRIER AGGREGATION [0002]

The present invention relates to wireless communications and, more particularly, to a method and apparatus for determining an element carrier for heterogeneous carrier aggregation.

Recently, rapid diffusion of smart phones and voice-oriented mobile communication services have been converted to data-oriented services centered on wireless multimedia contents. As a result, the trend of mobile data is rapidly increasing. In particular, the number of smartphone users in Korea has reached 20 million units in October 2011, providing an environment in which web contents are freely used in mobile environments. In addition, in recent years, the growth of wireless traffic has risen sharply due to the rapid growth of tablet PCs such as iPad and Galaxy Tab. However, as the mobile data traffic centering on such smart devices is rapidly increasing, the speed of the wireless Internet is rapidly deteriorating and even the connection itself becomes difficult.

Various communication technologies are being developed to accommodate soaring mobile traffic. For example, in 3GPP LTE-Advanced, multiple antenna based MIMO technology for increasing the transmission capacity of a base station, efficient interference control technology (ICIC) for capacity increase at a cell edge, cooperative transmission and reception (CoMP) A device-to-device communication technique for load balancing, and a cognitive radio technique for using an idle TV band (UHF band) are being developed.

As a method for meeting the data transmission speed, which is an IMT-Advanced technology requirement, there is a method of transmitting and receiving data using a wide bandwidth. In 3GPP, the maximum bandwidth of LTE-A is set to 100 MHz. However, CA (carier aggregation) technology has been introduced because it is difficult to allocate a frequency bandwidth of 100 MHz in limited radio frequency resources. CA technology is a communication technology that combines different frequency bands at the same time to create broadband effects.

A first object of the present invention is to provide a method for determining a carrier component for carrier aggregation.

A second object of the present invention is to provide an apparatus for determining a carrier component for carrier aggregation.

According to an aspect of the present invention, there is provided a method of performing carrier aggregation comprising: calculating interference for a plurality of interference paths between an adjacent cell and a serving cell; Determining a weight for accumulating interference on the plurality of interference paths in the serving cell, accumulating interference on the plurality of interference paths based on the weight in the serving cell to calculate cumulative interference, Determining a component carrier to be used in the carrier aggregation based on the accumulated interference in the serving cell, and performing the carrier aggregation based on the determined element carrier. The weighting value,

The licensee may determine the interference by the licensed band device to the licensed band device, the interference by the licensed band device to the licensed band device, the interference by the licensed band device to the license-exempt band device, and the interference by the licensed band device to the license- have. The weight is determined in accordance with the following equation,

≪ Equation &

는 상기 서빙 셀의 상기 비면허 대역 장치가 상기 인접 셀의 상기 비면허 대역 장치로부터 받는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 면허 대역 장치가 상기 인접 셀의 상기 비면허 대역 장치로부터 받는 간섭에 대해 적용되는 가중치, 상기

은 상기 서빙 셀의 상기 비면허 대역 장치가 상기 인접 셀의 상기 면허 대역 장치로부터 받는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 면허 대역 장치가 상기 인접 셀의 상기 면허 대역 장치로부터 받는 간섭에 대해 적용되는 가중치일 수 있다. remind

Is a weight applied to the interference that the license-exempt band device of the serving cell receives from the license-exempt band device of the neighboring cell,

Is a weight applied to the interference that the license band device of the serving cell receives from the license-exiting band device of the neighboring cell,

Is a weight applied to the interference that the license-exempt band device of the serving cell receives from the license band device of the neighboring cell,

May be a weight applied to the interference that the license band device of the serving cell receives from the license band device of the neighboring cell.

The weight is determined in accordance with the following equation,

≪ Equation &

는 상기 서빙 셀의 상기 비면허 대역 장치가 상기 인접 셀의 상기 비면허 장치로 주는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 비면허 대역 장치가 상기 인접 셀의 상기 면허 대역 장치로 주는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 면허 대역 장치가 상기 인접 셀의 상기 비면허 대역 장치로 주는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 면허 대역 장치가 상기 인접 셀의 상기 면허 대역 장치로 주는 간섭에 대해 적용되는 가중치일 수 있다.
remind

Is a weight applied to the interference caused by the license-exempt band device of the serving cell to the license-exempt device of the neighboring cell,

Is a weight applied to the interference caused by the license-exempt band device of the serving cell to the license band device of the neighboring cell,

Is a weight applied to the interference of the license bandwidth device of the serving cell to the license-exiting bandwidth device of the neighboring cell,

May be a weight applied to interference of the license band device of the serving cell to the license band device of the neighboring cell.

According to an aspect of the present invention, there is provided a base station for performing carrier aggregation according to an aspect of the present invention, the base station including: a base station for calculating interference for a plurality of interference paths between a neighboring cell and the serving cell; An interference component calculation unit to be implemented, a weight determination unit configured to determine a weight for accumulating interference with respect to the plurality of interference paths, and an interference accumulation unit to accumulate interference on the plurality of interference paths based on the weight, A frequency band determination unit configured to determine a component carrier to be used for the carrier aggregation based on the cumulative interference and a processor configured to perform the carrier aggregation based on the determined element carrier, . ≪ / RTI > The weighting shall be in the following order: interference caused by the license-exempt band device to the licensed band device, interference from the licensed band device to the licensed band device, interference from the license-exempted band device to the licensed band device, Can be determined.

The weight is determined in accordance with the following equation,

≪ Equation &

는 상기 서빙 셀의 상기 비면허 대역 장치가 상기 인접 셀의 상기 비면허 대역 장치로부터 받는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 면허 대역 장치가 상기 인접 셀의 상기 비면허 대역 장치로부터 받는 간섭에 대해 적용되는 가중치, 상기

은 상기 서빙 셀의 상기 비면허 대역 장치가 상기 인접 셀의 상기 면허 대역 장치로부터 받는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 면허 대역 장치가 상기 인접 셀의 상기 면허 대역 장치로부터 받는 간섭에 대해 적용되는 가중치일 수 있다. remind

Is a weight applied to the interference that the license-exempt band device of the serving cell receives from the license-exempt band device of the neighboring cell,

Is a weight applied to the interference that the license band device of the serving cell receives from the license-exiting band device of the neighboring cell,

Is a weight applied to the interference that the license-exempt band device of the serving cell receives from the license band device of the neighboring cell,

May be a weight applied to the interference that the license band device of the serving cell receives from the license band device of the neighboring cell.

The weight is determined in accordance with the following equation,

≪ Equation &

는 상기 서빙 셀의 상기 비면허 대역 장치가 상기 인접 셀의 상기 비면허 장치로 주는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 비면허 대역 장치가 상기 인접 셀의 상기 면허 대역 장치로 주는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 면허 대역 장치가 상기 인접 셀의 상기 비면허 대역 장치로 주는 간섭에 대해 적용되는 가중치, 상기

는 상기 서빙 셀의 상기 면허 대역 장치가 상기 인접 셀의 상기 면허 대역 장치로 주는 간섭에 대해 적용되는 가중치일 수 있다.remind

Is a weight applied to the interference caused by the license-exempt band device of the serving cell to the license-exempt device of the neighboring cell,

Is a weight applied to the interference caused by the license-exempt band device of the serving cell to the license band device of the neighboring cell,

Is a weight applied to the interference of the license bandwidth device of the serving cell to the license-exiting bandwidth device of the neighboring cell,

May be a weight applied to interference of the license band device of the serving cell to the license band device of the neighboring cell.

As described above, in the method and apparatus for determining the carrier wave for collecting carrier waves according to the embodiment of the present invention, because the cumulative interference is used in the elementary carrier selection algorithm, the total amount of interference to the serving cell and the interference to the adjacent cell is collectively Carrier aggregation can be performed. In addition, since the weighting factor considering the heterogeneous carrier use state of the adjacent interfering cell adjacent to the serving cell and the serving cell is applied, the quality of the interference (or the nature of the interference) is taken into consideration So that the carrier aggregation can be performed.

1 is a conceptual diagram showing a method of aggregating heterogeneous carriers.
2 is a conceptual diagram showing a cell using heterogeneous carrier aggregation.
3 is a conceptual diagram illustrating interference that may exist between a serving cell and an interference cell
4 is a conceptual diagram for collecting carriers by using homogeneous carriers in an interference cell adjacent to a serving cell according to an embodiment of the present invention.
5 is a conceptual diagram of aggregating carriers using heterogeneous carriers in an interference cell adjacent to a serving cell according to an embodiment of the present invention.
6 is a conceptual diagram illustrating a weighting factor determination method according to an embodiment of the present invention.
7 is a conceptual diagram illustrating a method for determining a frequency band for performing carrier aggregation according to an embodiment of the present invention.
8 is a conceptual diagram illustrating an apparatus for determining a frequency band for performing carrier aggregation according to an 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. Like reference numerals are used for like elements in describing each drawing.

The terms first, second, etc. 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 a second component, and similarly, the second component may also be referred to as a first component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . 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 in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

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

A user equipment (UE) may be fixed or mobile and may be a mobile station (MS), a mobile terminal (MT), a user terminal (UT), a subscriber station (SS), a wireless device, a digital assistant, a wireless modem, a handheld device, and the like.

A base station generally refers to a fixed station that communicates with a terminal and may be referred to by other terms such as an evolved-NodeB (eNB), a base transceiver system (BTS), an access point, and the like.

Hereinafter, embodiments of the present invention will be described using the terms terminal and base station for convenience of explanation.

1 is a conceptual diagram showing a method of aggregating heterogeneous carriers.

Demand for broadband transmission is rapidly increasing in the mobile and wireless communications markets. Carrier aggregation (or carrier aggregation) is widely used as a technique for coping with the demand for such a wide band transmission. The 3GPP LTE-Advanced Release 10 standard can aggregate five carriers with a bandwidth of 20 MHz to support bandwidths up to 100 MHz. In addition, the IEEE 802.11ac standard can aggregate two carriers with a bandwidth of 80 MHz to support bandwidths up to 160 MHz. These standards define techniques for aggregating homogeneous bands (or homogeneous carriers) defined within the frequency band defined by the same standard. Recently, as frequency sharing technology has been actively studied, there is a growing interest in a technique of aggregating heterogeneous carriers (or heterogeneous bands) as well as such a homogeneous carrier (or homogeneous bands) to provide a wide bandwidth.

Referring to FIG. 1, a license band (e.g., LTE (Long Term Evolution) band 110, TVWS 100, an industrial scientific and medical (ISM) band 120, Carriers (heterogeneous carriers) of different frequency bands, such as authorized shared access (ASA) 130, may exist. It is possible to realize wide bandwidth by aggregating the element carriers selected by the element carrier selection algorithm 150 among the carriers of the different frequency bands.

Each of the frequency bands may be set as a single carrier aggregated bandwidth 170 based on a component carrier selection algorithm 150. Hereinafter, in the embodiment of the present invention, when the characteristics of the bands used in the element carrier wave aggregation are the same, they can be expressed by the same carrier wave. For example, a homogeneous carrier may mean that the license band, the license-exempt band, and the shared band are not mixed when the element carrier is aggregated. On the other hand, when the characteristics of the bands are different, they can be expressed in terms of heterogeneous carriers. For example, the heterogeneous carrier may mean that the element carrier wave is mixed with the license band, the license-exempt band, and the shared band.

2 is a conceptual diagram illustrating carrier aggregation based on heterogeneous carriers.

Referring to FIG. 2, a cell is implemented based on different frequency bands such as TVWS, permission band, ISM band, new shared band, and the like.

Each cell may be implemented based on a homogeneous frequency band. The cells may be implemented on the basis of the same frequency band, but specific cells may be implemented to carry out carrier aggregation and transmit and receive data through the carrier aggregated heterogeneous carriers.

For example, if the primary element carrier of a serving cell is in a licensed band (e.g., LTE supported band) 210, then the heterogeneous frequency band set based on carrier aggregation may be the TVWS 200, the ISM band 220 ), A new shared band 230, and the like.

Small cells present in a macrocell may require a large bandwidth for data off-loading, and in this case small cells may transmit and receive data using heterogeneous frequency bands set on the basis of carrier aggregation .

3 is a conceptual diagram illustrating interference that may exist between a serving cell and an interfering cell.

In Fig. 3, four interference paths are shown in which interference may occur between a serving cell and an adjacent interfering cell (s).

Referring to FIG. 3, the interference can be divided into an incoming interference to a serving cell and an outgoing interference from a serving cell.

Serving cell incoming interference is again the base station (HeNB (HeNB _I)), a downlink directed from the terminal (UE _S) in the serving cell of the interfering cell: servings (downlink DL), the interference (300), the terminal (UE _I) of the interfering cell There is an uplink (UL) interference 320 towards a cell's base station (HeNB (HeNB _S )).

It is also possible to define the direction of the first path from the base station of the interference cell to the terminal of the serving cell to the base station of the serving cell from the terminal of the interference cell using the term second path.

Furthermore, the terminal of the interfering cell at the base station (HeNB _S) of the interference is the serving cell, again get out of the serving cell (UE _I) of the downlink interference 340 and the serving interference from the terminal (UE _S) of the cell-cell destined for the base station (HeNB _I 0.0 > 360 < / RTI >

It may be defined that the direction from the base station of the serving cell to the terminal of the interference cell is referred to as the third path and that of the serving cell to the base station of the interference cell is defined as the fourth path.

An algorithm for determining a secondary component carrier (SCC), which is a frequency band for performing carrier aggregation, calculates a committed information rate (CIR) margin for the four interference paths disclosed in FIG. 3, It can only be judged whether or not it is. If the CIR margin has a negative value even in one of the first to fourth paths, the corresponding element carrier may not be used as the SCC.

Equation (1) below represents the calculation of the CIR margin for the above-described four interference paths.

&Quot; (1) "

는 서빙 셀로 들어오는 간섭 중 간섭 셀의 기지국(HeNB(HeNB_I))에서 서빙 셀의 단말(UE_S)로 향하는 하향링크 간섭(300)에 대한 제1 CIR 마진이다. 즉, 제1 CIR 마진은 간섭 셀의 기지국(HeNB(HeNB_I))에서 서빙 셀의 단말(UES)로 향하는 하향링크 간섭(300)의 SINR의 크기(

)에서 서빙 셀에서 SCC로 사용되기 위해 요구되는 최소 목표 SINR의 크기(

)를 뺀 값이다. In Equation (1)

Is the first CIR margin for the downlink interference 300 from the base station (HeNB _I ) of the interfering cell to the serving cell UEs ( _S ) during interfering to the serving cell. That is, the first CIR margin is determined based on the size of the SINR of the downlink interference 300 from the base station (HeNB _I ) of the interference cell to the terminal UES of the serving cell

The size of the minimum target SINR required to be used as the SCC in the serving cell

).

는 서빙 셀로 들어오는 간섭 중 간섭 셀의 단말(UE_I)에서 서빙 셀의 기지국(HeNB(HeNB_S))으로 향하는 상향링크 간섭(320)에 대한 제2 CIR 마진이다. 제2 CIR 마진은 간섭 셀의 단말(UE_I)에서 서빙 셀의 기지국(HeNB(HeNB_S))으로 향하는 상향링크 간섭(320)의 SINR의 크기(

)에서 서빙 셀에서 SCC로 사용되기 위해 요구되는 최소 목표 SINR의 크기(

)를 뺀 값이다.

Is the second CIR margin for the uplink interference 320 from the UE _I of the interfering cell to the serving cell's base station (HeNB _S ) during interfering to the serving cell. The second CIR margin is the size of the SINR of the uplink interference 320 from the UE _I of the interfering cell to the base station of the serving cell HeNB (HeNB _S )

The size of the minimum target SINR required to be used as the SCC in the serving cell

).

는 서빙 셀에서 나가는 간섭 중 서빙 셀의 기지국(HeNB_S)에서 간섭 셀의 단말(UE_I)로 향하는 하향링크 간섭(340)에 대한 제3 CIR 마진이다. 제3 CIR 마진은 서빙 셀의 기지국(HeNB_S)에서 간섭 셀의 단말(UE_I)로 향하는 하향링크 간섭(340)의 SINR의 크기(

)에서

를 뺀 값이다.

는 간섭 셀에서 해당 요소 반송파가 사용되는 용도에 따라 달라지는 값으로 간섭 셀에서 서빙 셀의 요소 반송파가 PCC(primary component carrier)로 사용되면

를 사용하고 SCC로 사용되면

를 사용할 수 있다.

Is the third CIR margin for the downlink interference 340 from the base station (HeNB _S ) of the serving cell to the terminal UE _I of the interfering cell during the outgoing interference from the serving cell. The third CIR margin is the size of the SINR of the downlink interference 340 from the base station (HeNB _S ) of the serving cell to the UE _I of the interfering cell

)in

.

Is a value that depends on the application in which the corresponding elementary carrier is used in the interference cell. If the elementary carrier of the serving cell is used as a primary component carrier (PCC) in the interference cell

And is used as an SCC

Can be used.

는 서빙 셀에서 나가는 간섭 중 서빙 셀의 단말(UE_S)에서 간섭 셀의 기지국(HeNB_I)으로 향하는 상향링크 간섭(360)에 대한 제4 CIR 마진이다. 제4 CIR 마진은 서빙 셀의 단말(UE_S)에서 간섭 셀의 기지국(HeNB_I)으로 향하는 상향링크 간섭(360)의 SINR 크기(

)에서

를 뺀 값이다.

는 간섭 셀에서 해당 요소 반송파가 사용되는 용도에 따라 달라지는 값으로 간섭 셀에서 서빙 셀의 요소 반송파가 PCC(primary component carrier)로 사용되면

를 사용하고 SCC로 사용되면

를 사용할 수 있다.

Is the fourth CIR margin for the uplink interference 360 from the serving cell's UE _S to the base station of the interfering cell (HeNB _I ) during the outgoing interference from the serving cell. Claim 4 CIR margin SINR size of the serving cell, uplink interference terminal 360 is directed to a base station (HeNB _I) of the interfering cell in the _(S UE) of (

)in

.

Is a value that depends on the application in which the corresponding elementary carrier is used in the interference cell. If the elementary carrier of the serving cell is used as a primary component carrier (PCC) in the interference cell

And is used as an SCC

Can be used.

와

간에 발생하는 간섭 성분이 무시할 수 없을 정도로 클 경우 상황에 따라 해당 간섭 성분도 추가로 고려할 수도 있다. 예를 들어, 추가적으로

가

에 미치는 제 5 경로 간섭(일종의 outgoing UL 간섭),

가

에 미치는 제 6 경로 간섭 (일종의 incoming UL 간섭)을 고려할 수 있다.
FIG. 3 shows one embodiment of the interference component. According to embodiments of the present invention, additional interference components may be further considered depending on the situation. For example, in Figure 3

Wow

If the interfering component is large enough that it can not be ignored, the interfering component may also be considered depending on the situation. For example,

end

The fifth path interference (a kind of outgoing UL interference)

end

(A kind of incoming UL interference) can be considered.

Previously, homogeneous carriers were aggregated, so the nature of the interferences between the two cells was the same. For example, only the interference between the same carrier bands, such as interference from users in the license band to users in the licensed band, or interference from users in the license-exempt band to users in the license-exempt band, are considered.

However, when heterogeneous carriers are aggregated, the nature of the interferences between the two cells can vary. For example, interference between different frequency bands may be a problem, such as interference from users in licensed bands such as the LTE band to users using IEEE 802.11 using the ISM band. Therefore, in the embodiment of the present invention, it is necessary to select the element carrier in consideration of not only the amount of interference but also the quality of interference (or the nature of interference) in an environment in which carrier aggregation for heterogeneous carriers is performed. Hereinafter, a method for calculating interference in a frequency band and selecting a frequency band for collecting heterogeneous carriers will be described in the embodiment of the present invention.

According to the embodiment of the present invention, an element carrier to perform carrier aggregation can be selected based on the cumulative value calculated by applying the weighting factor.

In the embodiment of the present invention, the carrier aggregation is performed in consideration of cumulative margins accumulated by applying weighting factors to cumulative interference or CIR margins in which interference generated through a plurality of paths such as the first to fourth paths described above is accumulated The element carrier can be selected. The cumulative value can be used as a term including cumulative interference and cumulative margin.

Equation (2 ) represents an equation for calculating the cumulative value A (c) based on the CIR margin for the element carrier c.

&Quot; (2) "

는 도 3에서 개시한 제1 경로 내지 제4 경로에 적용하는 가중치 요소이다. 수학식 2는 하나의 예시로 각 셀에 위치한 단말 간의 간섭도 추가적으로 고려할 수 있다.Referring to Equation (2), a cumulative value calculated by applying a weighting factor to the CIR margin for each of the first to fourth paths is shown.

Is a weighting factor applied to the first to fourth paths disclosed in Fig. Equation (2) may further consider interference between terminals located in each cell as an example.

Of the plurality of elementary carriers, the primary frequency band of the serving cell and the elementary carrier for performing the carrier aggregation can be determined by Equation (3) below.

&Quot; (3) "

Equation (3) shows that when the CIR margin is used to determine the interference component for each path, the element carrier having the largest cumulative value (cumulative margin) is used for carrier aggregation.

If A (c) is an expression calculated based on an interference other than a CIR margin as shown in Equation (2 ) , an element carrier to perform carrier aggregation among a plurality of element carriers may be determined by Equation (4) below.

&Quot; (4) "

Referring to Equation (4 ) , when A (c) is calculated based on the interference itself, the element carrier having the smallest cumulative value (cumulative interference) can be used for carrier aggregation.

4 is a conceptual diagram illustrating the use of a homogeneous carrier in an interference cell adjacent to a serving cell according to an embodiment of the present invention.

Referring to FIG. 4, since the carrier waves interfering with the serving cell 400 are all of the same kind, the weighting factors applied to calculate the cumulative interference may all be the same value. That is, in the case of the homogeneous carrier, it is possible to determine the homogeneous carrier to perform the carrier aggregation by calculating the cumulative interference without considering the weight factor.

5 is a conceptual diagram illustrating the use of a heterogeneous carrier in an interfering cell adjacent to a serving cell according to an embodiment of the present invention.

Referring to FIG. 5, a neighboring cell located in the vicinity of a serving cell may include a cell that performs a service based on the same kind of carrier wave as the serving cell, and a cell that supports a service based on a serving cell and a heterogeneous carrier. For example, the serving cell is implemented as LTE, LTE-A based license band 500, and the adjacent cell is LTE, LTE-A based license band 500, heterogeneous carrier ISM band 530, The TVWS band 520, and the ASA band 510, respectively.

When carrying out carrier aggregation based on a heterogeneous carrier in a serving cell, a weighting factor for calculating cumulative interference can be determined in consideration of a relationship between an interfering carrier and an interfering carrier. In calculating the weighting factor, the interference can be separately calculated by dividing the interference into the incoming interference to the serving cell and the outgoing interference from the serving cell.

Cumulative interference can be calculated to determine the heterogeneous carrier to perform carrier aggregation. When a heterogeneous carrier wave is carrier-aggregated, the weighting factors for determining the cumulative interference can be set differently in view of the influence of the interference received or received by the apparatus operating in the serving cell and the interference received or received by the apparatus operating in the neighboring cell .

For example, in order to calculate the cumulative interference, the influence of the interference of the device of the licensed band carrier (hereinafter referred to as the licensed band device) is reflected to be larger than the interference of the device of the license-exempted band carrier . Also, in order to calculate the cumulative interference, it is possible to reflect the influence of the interference given by the license-exempt band device to a greater influence than the interference of the license band device.

In other words, if the weighting elements are listed in order of magnitude, the licensee's equipment may cause interference to the licensee's equipment, the licensee's equipment to interfere with the licensee's equipment, the licensee's equipment to interfere with the licensee's equipment, The size of the weighting factor can be determined in the order of the interference given to the weighting factor.

Table 1 below shows the magnitude of the interference between licensed band devices and license-exempt band devices.

<Table 1>

In other words, referring to Table 1, if the weight elements are listed in order of magnitude, interference caused by the unlicensed band device to the licensed band, the license band licensed to the licensed band device, The size of the weighting factor can be determined by the order of the unlicensed band (unlicensed) to the unlicensed band device, and the interference that the licensed band device gives to the unlicensed band device (unlicensed).

6 is a conceptual diagram illustrating a weighting factor determination method according to an embodiment of the present invention.

FIG. 6 illustrates a method for determining a weighting factor when performing carrier aggregation based on a heterogeneous carrier.

, 서빙 셀에서 인접 셀로 나가는 간섭의 가중치는

로 표시하여 구분할 수 있다.Referring to FIG. 6, the accumulated interference can be divided into an incoming interference from a neighboring cell to a serving cell and an outgoing interference from a serving cell to an adjacent cell. Also, the cumulative interference can be calculated in consideration of the weight for the interference to the serving cell in the neighboring cell and the weight for the interference to the neighboring cell in the serving cell. The weight of the interference from the neighboring cell to the serving cell is

, The weight of the interference from the serving cell to the adjacent cell is

As shown in Fig.

, 서빙 셀의 면허 대역 장치(620)가 인접 셀의 비면허 대역 장치(640)로부터 받는 간섭에 대해 적용되는 가중치를

, 서빙 셀의 비면허 대역 장치(600)가 인접 셀의 면허 대역 장치(660)로부터 받는 간섭에 대해 적용되는 가중치를

, 서빙 셀의 면허 대역 장치(620)가 인접 셀의 면허 대역 장치(660)로부터 받는 간섭에 대해 적용되는 가중치를

라고 할 수 있다. Based on the interference received to the serving cell, the weighted weight applied to the interference that the license-exempt band device 600 of the serving cell receives from the license-exempt band device 640 of the neighboring cell

, The license band device 620 of the serving cell applies the weight applied to the interference received from the license-exempt band device 640 of the neighboring cell

, A weight applied to the interference that the license-exempt band device 600 of the serving cell receives from the licensed band device 660 of the neighboring cell

, The weight applied to the interference that the license band device 620 of the serving cell receives from the license band device 660 of the neighboring cell

.

, 서빙 셀의 비면허 대역 장치(600)가 인접 셀의 면허 대역 장치(660)로 주는 간섭에 대해 적용되는 가중치를

, 서빙 셀의 면허 대역 장치(620)가 인접 셀의 비면허 대역 장치(640)로 주는 간섭에 대해 적용되는 가중치를

, 서빙 셀의 면허 대역 장치(620)가 인접 셀의 면허 대역 장치(640)로 주는 간섭에 대해 적용되는 가중치를

라고 할 수 있다. Based on the outgoing interference from the serving cell, the weight applied to the interference caused by the license-exempt band device 600 of the serving cell to the license-exempt band device 640 of the neighbor cell

, The weight applied to the interference that the license-exempt band device 600 of the serving cell gives to the license band device 660 of the neighboring cell

, The weight applied to the interference of the serving cell's license band device 620 to the license-exempt band device 640 of the neighboring cell

, A weight applied to the interference of the serving cell's license band device 620 to the adjacent cell's license band device 640

.

과 서빙 셀에서 인접 셀로 나가는 간섭은

의 크기는 아래의 수학식 5와 같은 관계를 가질 수 있다. The interference from the adjacent cell to the serving cell

And the interference from the serving cell to the neighboring cell

May have a relationship expressed by Equation (5) below.

&Quot; (5) &quot;

Based on the magnitude of the weight set as described above, it is possible to determine the heterogeneous carrier to perform the carrier aggregation by calculating the accumulated interference.

When using this method, since the elementary carrier selection algorithm uses the cumulative interference, the carrier aggregation can be performed by taking into consideration the total amount of interference to the serving cell and the interference to the adjacent cell.

In addition, since the weighting factor considering the heterogeneous carrier use state of the serving cell and the adjacent interference cell is applied, it is possible to consider the quality of interference (or the nature of interference) from the method of considering only the amount of interference.

7 is a conceptual diagram illustrating a method for determining a frequency band for performing carrier aggregation according to an embodiment of the present invention.

In Fig. 7, an interference component can be calculated (step S700).

In step S700, the interference component for each interference path can be calculated as described above.

For example, in step S700, the first path from the base station of the interference cell to the terminal of the serving cell, the second path from the terminal of the interference cell to the base station of the serving cell, and the second path from the base station of the serving cell to the terminal of the interference cell The third path, the interference from the terminal of the serving cell to the base station of the interference cell to the fourth path can be calculated. Interference of additional paths other than the first to fourth paths may be calculated depending on the magnitude of the interference.

A weight for calculating the cumulative interference is determined (step S720).

It is possible to determine whether the frequency band for performing the carrier aggregation is a heterogeneous carrier and to calculate cumulative interference on different weighting criteria. For example, when carrier aggregation is performed based on a homogeneous carrier, a plurality of weights for calculating cumulative interference can be determined to be the same value. If the frequency band on which the carrier aggregation is to be performed is a homogeneous carrier, the weight used for calculating the cumulative interference can be set to the same value and used. If the frequency band to perform carrier aggregation is a homogeneous carrier, the cumulative interference can be calculated assuming that the influence of the interference according to the frequency band is the same.

On the contrary, when the carrier aggregation is performed based on the heterogeneous carrier, the size of the plurality of weights for calculating the cumulative interference can be determined to be a different value. When the frequency band to perform carrier aggregation is a heterogeneous frequency band, the weights used for calculating the cumulative interference may be set to different values and used. The weighting factors used to calculate the cumulative interference to select the elementary carrier in performing carrier aggregation based on the heterogeneous carrier as described above with reference to FIG. 6 are determined by the influence of the interference received or received by the apparatus operating in the serving cell, It can be set differently considering the influence of the interference received or received by the operating device.

And the cumulative interference is calculated (step S730).

The cumulative interference can be calculated based on the weight determined based on step S720. Cumulative interference can be calculated by dividing into an incoming interference from a neighboring cell to a serving cell and an outgoing interference from a serving cell to an adjacent cell. Also, the cumulative interference can be calculated in consideration of the weight for the interference to the serving cell in the neighboring cell and the weight for the interference to the neighboring cell in the serving cell.

A frequency band to perform carrier aggregation is determined based on the calculated cumulative interference (step S740).

Based on the calculated cumulative interference, it is possible to determine a homogeneous carrier or heterogeneous carrier to perform carrier aggregation. It is possible to determine the homogeneous carrier or the heterogeneous carrier to perform the carrier aggregation based on the value of the accumulated interference calculated for a plurality of homogeneous carrier bands or a plurality of heterogeneous carrier bands.

8 is a conceptual diagram illustrating an apparatus for determining a frequency band for performing carrier aggregation according to an embodiment of the present invention.

FIG. 8 is a conceptual diagram showing an apparatus for determining a frequency band for performing carrier aggregation. In FIG. 8, it is assumed that the base station determines the frequency band to perform carrier aggregation and performs carrier aggregation.

The base station may include a communication unit 800, a frequency band determination unit 810, a weight determination unit 820, a cumulative interference calculation unit 830, a frequency band determination unit 840, and a processor 850.

The communication unit 800 may receive interference information or CIR margin information for determining a frequency band to perform carrier aggregation.

The interference component calculation unit 810 may be implemented to calculate an interference component for the interference path.

The weight determining unit 820 may determine a weight for calculating the cumulative interference. For example, as described above with reference to FIG. 6, the weight determining unit 820 may determine different weights according to whether the frequency band for performing the carrier aggregation is a homogeam carrier or a heterogeneous carrier according to the determination of the frequency band determination unit.

The cumulative interference calculator 830 may calculate the cumulative interference based on the weight determined by the weight determiner 820. [ Cumulative interference can be calculated by dividing into an incoming interference from a neighboring cell to a serving cell and an outgoing interference from a serving cell to an adjacent cell. Also, the cumulative interference can be calculated in consideration of the weight for the interference to the serving cell in the neighboring cell and the weight for the interference to the neighboring cell in the serving cell.

The frequency band determining unit 840 can determine a frequency band to perform carrier aggregation in consideration of the information on the accumulated interference.

The processor 850 can control operations of the communication unit 800, the frequency band determination unit 810, the weight determination unit 820, the cumulative interference calculation unit 830, and the frequency band determination unit 840.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. It will be possible.

Claims (8)

A method for performing carrier aggregation,
Calculating interference for a plurality of interference paths between adjacent cells and the serving cell;
Determining a weight for the plurality of interference paths in the serving cell;
Calculating cumulative values (cumulative margin or cumulative interference) for the plurality of interference paths based on the weights in the serving cell;
Determining an element carrier to be used in the carrier aggregation based on the accumulated value in the serving cell; And
And performing the carrier aggregation based on the determined element carrier. 2. The method of claim 1,
The extent to which the licensed band device is subject to interference from the licensed band device, the interference from the licensed band device to the licensed band device, the interference from the license-exempt band device to the license-exempt band device, Carrier aggregation method. 3. The method of claim 2,
The weight is determined in accordance with the following equation,
&Lt; Equation &

remind

Is a weight applied to the interference that the license-exempt band device of the serving cell receives from the license-exempt band device of the neighboring cell,
remind

Quot; is a weight applied to the interference that the license band device of the serving cell receives from the license-exempt band device of the neighboring cell,
remind

Is a weight applied to the interference that the license-exempt band device of the serving cell receives from the license band device of the neighboring cell,
remind

Is a weight applied to the interference that the license band device of the serving cell receives from the license band device of the neighboring cell. 3. The method of claim 2,
The weight is determined in accordance with the following equation,
&Lt; Equation &

remind

Is a weight applied to the interference of the license-exempt band device of the serving cell to the license-exempt device of the neighboring cell,
remind

Is a weight applied to the interference of the license-exempt band device of the serving cell to the license band device of the neighboring cell,
remind

Is a weight applied to the interference of the license bandwidth device of the serving cell to the license-exiting bandwidth device of the neighboring cell,
remind

Is a weight applied to interference of the license band device of the serving cell to the license band device of the neighboring cell. 1. A base station for performing carrier aggregation,
An interference component calculator configured to calculate interference for a plurality of interference paths between adjacent cells and the serving cell;
A weight determiner configured to determine a weight for accumulating interference for the plurality of interference paths;
An accumulated value calculation unit configured to calculate an accumulated value by accumulating interference on the plurality of interference paths based on the weight;
A frequency band determination unit configured to determine an element carrier to be used for the carrier aggregation based on the accumulated value; And
And perform the carrier aggregation based on the determined element carrier. 6. The method of claim 5,
The extent to which the licensed band device is subject to interference from the licensed band device, the interference from the licensed band device to the licensed band device, the interference from the license-exempt band device to the license-exempt band device, Base station. The method according to claim 6,
The weight is determined in accordance with the following equation,
&Lt; Equation &

remind

Is a weight applied to the interference that the license-exempt band device of the serving cell receives from the license-exempt band device of the neighboring cell,
remind

Quot; is a weight applied to the interference that the license band device of the serving cell receives from the license-exempt band device of the neighboring cell,
remind

Is a weight applied to the interference that the license-exempt band device of the serving cell receives from the license band device of the neighboring cell,
remind

Is a weight applied to the interference that the license band device of the serving cell receives from the license band device of the neighboring cell. The method according to claim 6,
The weight is determined in accordance with the following equation,
&Lt; Equation &

remind

Is a weight applied to the interference of the license-exempt band device of the serving cell to the license-exempt device of the neighboring cell,
remind

Is a weight applied to the interference of the license-exempt band device of the serving cell to the license band device of the neighboring cell,
remind

Is a weight applied to the interference of the license bandwidth device of the serving cell to the license-exiting bandwidth device of the neighboring cell,
remind

Is a weight applied to the interference of the license band device of the serving cell to the license band device of the neighboring cell.

Images