KR20190099946A - Method and apparatuses for communication in wireless network based on millmeter wave - Google Patents

Abstract

Disclosed are a millimeter wave-based communication method and apparatuses in a wireless network. According to an embodiment of the present invention, a communication method in a wireless network for relaying data over wireless links comprises the steps of: determining an optimal transmission beamforming vector and an optimal reception beamforming vector for maximizing a throughput of the wireless network based on magnetic interference; and performing transmission and reception beamforming using the optimal transmission beamforming vector and the optimal reception beamforming vector. The magnetic interference is generated by a signal transmitted to a user through another one of radio links in the process of receiving a signal through one of the radio links.

Description

METHODS AND APPARATUSES FOR COMMUNICATION IN WIRELESS NETWORK BASED ON MILLMETER WAVE}

The embodiments below relate to effective communication methods and apparatuses considering millimeter wave based magnetic interference in a hierarchical wireless network including a mobile XHole network.

5G is developing the introduction of Heterogeneous Networks (HetNet) rather than a single network to satisfy various types of key performance parameters.Small cell especially for high throughput in high mobile environments ) HetNet research is active.

Recently, the Mobile X-haul Network (MXN) concept has been discussed in the 5G standard for network virtualization and integration optimization. In MXN, heterogeneous networks are basically integrated, and high density small cells efficiently handle high traffic.

The structure of the MXN is that a macro base station or an XDU (Xhaul Distributed Unit) is connected to a Core Network (for example, an Xhaul Central Unit (XCU)) in the form of Cloud RAN, and (Xhaul link) RRH (Radio Link) connected to the XDU Highly integrated small cells are formed through the head to provide services to terminals through a wireless access link. In this case, when the Xhaul link is implemented by wire, high installation cost and management cost are generated to form a small integrated cell.

It is desirable to install the Xhaul link wirelessly, so that the throughput of the Xhaul link becomes the bottleneck of the network in order to deliver high data transmission traffic from the high density small cell to the XCU. .

Therefore, in order to optimize system performance in MXN, it is necessary to develop an effective transmission scheme in an Xhaul link. In addition, unlike conventional wireless backhaul (Xhaul) Xhaul XDUs must consider the mobile environment to configure a highly reliable Xhaul link (Xhaul link).

Embodiments can provide a technique for performing beamforming by considering two radio links simultaneously in in-band communication in which two radio links use the same spectrum.

Thus, the embodiments can obtain the overall system capacity increase effect, and can effectively mitigate magnetic interference through beamforming.

A communication method in a wireless network for relaying data over wireless links according to an embodiment includes determining an optimal transmit beamforming vector and an optimal receive beamforming vector for maximizing a throughput of the wireless network based on magnetic interference; And performing transmission and reception beamforming using the optimal transmission beamforming vector and the optimal reception beamforming vector, wherein the magnetic interference is performed in the process of receiving a signal through any one of the wireless links. Caused by the signal being transmitted to the user through the other one of them.

One may be an X-haul link or a backhaul link, and the other may be an access link.

The wireless network may be a hierarchical wireless network including a mobile X-haul network (MXN).

The radio links may be independent radio links using the same band.

The same band may be a millimeter wave band.

The determining may include setting an initial transmission beamforming vector to have a maximum SNR in the access link, calculating the optimal reception beamforming vector using the initial transmission beamforming vector, and using the XHole link. And calculating the optimal transmission beamforming vector based on the interference of the.

The calculating of the optimal reception beamforming vector and the calculating of the optimal transmission beamforming vector may be repeatedly performed by updating the optimal transmission beamforming vector with the initial transmission beamforming vector.

The calculating of the optimal transmission beamforming vector may include comparing the SINR of the X-hole link and the SNR of the access link, and if the SINR is greater than or equal to the SNR, the optimal transmission beamforming vector is transmitted. Calculating the beamforming vector; and calculating the optimal transmission beamforming vector based on an allowable interference level to the X-hole link when the SINR is smaller than the SNR.

The calculating of the optimal transmission beamforming vector based on the allowable interference level may include determining the optimal transmission beamforming vector as a transmission steering vector when the magnetic interference level of the magnetic interference is less than or equal to the allowable interference level. And calculating the optimal transmission beamforming vector by reducing the allowable interference level by an allowable value in a magnetic interference direction when the magnetic interference level is greater than the allowable interference level.

이고,

은 1번째 경로의 AoA(Angle of arrival)일 수 있다.The transmit steering vector is

ego,

May be the Angle of arrival (AoA) of the first path.

이고,

은 상기 최적 수신 빔포밍 벡터이고,

은 상기 허용 간섭 레벨이고,

은 간섭 신호에 대한 채널 행렬일 수 있다.The above tolerance

ego,

Is the optimal receive beamforming vector,

Is the allowable interference level,

May be a channel matrix for the interfering signal.

According to an embodiment, a communication apparatus for performing a communication method in a wireless network for relaying data through wireless links includes a massive antenna, an optimal transmit beamforming vector, and an optimal transmission beam for maximizing throughput of the wireless network based on magnetic interference. A controller for determining a reception beamforming vector, and a beamformer for performing transmission and reception beamforming through the massive antenna using the optimal transmission beamforming vector and the optimal reception beamforming vector, wherein the magnetic interference is determined by the radio link. In the process of receiving a signal through any one of these are generated by a signal transmitted to a user through the other of the radio links.

One may be an X-haul link or a backhaul link, and the other may be an access link.

The wireless network may be a hierarchical wireless network including a mobile X-haul network (MXN).

The radio links may be independent radio links using the same band.

The same band may be a millimeter wave band.

The controller sets an initial transmit beamforming vector to have a maximum SNR in the access link, calculates the optimal receive beamforming vector using the initial transmit beamforming vector, and based on the interference to the XHole link. The optimal transmission beamforming vector can be calculated.

The controller may update the optimal transmission beamforming vector with the initial transmission beamforming vector and iteratively calculate the optimal reception beamforming vector and the optimal transmission beamforming vector.

The controller compares the SINR of the XHole link with the SNR of the access link, and when the SINR is greater than or equal to the SNR, calculates the initial transmission beamforming vector as the optimal transmission beamforming vector, and the SINR is If less than the SNR, the optimal transmission beamforming vector may be calculated based on the allowable interference level to the X-hole link.

The controller determines the optimal transmission beamforming vector as a transmission steering vector when the magnetic interference level of the magnetic interference is less than or equal to the allowable interference level, and when the magnetic interference level is greater than the allowable interference level, the allowable The optimal transmission beamforming vector can be calculated by reducing the interference level in the direction of magnetic interference by an allowable value.

이고,

은 1번째 경로의 AoA(Angle of arrival)일 수 있다.The transmit steering vector is

ego,

May be the Angle of arrival (AoA) of the first path.

이고,

은 상기 최적 수신 빔포밍 벡터이고,

은 상기 허용 간섭 레벨이고,

은 간섭 신호에 대한 채널 행렬일 수 있다.The above tolerance

ego,

Is the optimal receive beamforming vector,

Is the allowable interference level,

May be a channel matrix for the interfering signal.

1 illustrates a schematic data transmission environment for explaining a communication method of a communication system in a wireless network environment according to an embodiment.
FIG. 2 is a schematic block diagram of the relay communication device shown in FIG. 1.
3 is a view for explaining the geometrical analysis of the beamforming method considering magnetic interference.
4 shows an example of an algorithm for determining an optimal transmission beamforming vector and an optimal reception beamforming vector in consideration of magnetic interference.
FIG. 5 is a diagram for describing an example of a channel information feedback method for extending the beamforming transmission strategy described with reference to FIGS. 2 to 4.
6 and 7 are graphs for explaining the performance through the simulation of the beamforming method according to the embodiment.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings. However, various changes may be made to the embodiments so that the scope of the patent application is not limited or limited by these embodiments. It is to be understood that all changes, equivalents, and substitutes for the embodiments are included in the scope of rights.

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

Terms such as first or second may be used to describe various components, but the components should not be limited by the terms. The terms are for the purpose of distinguishing one component from another component only, for example, without departing from the scope of the rights according to the concepts of the embodiment, the first component may be named a second component, and similarly The second component may also be referred to as the first component.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

In addition, in the description with reference to the accompanying drawings, the same components regardless of reference numerals will be given the same reference numerals and duplicate description thereof will be omitted. In the following description of the embodiment, when it is determined that the detailed description of the related known technology may unnecessarily obscure the gist of the embodiment, the detailed description thereof will be omitted.

1 illustrates a schematic data transmission environment for explaining a communication method of a communication system in a wireless network environment according to an embodiment.

1 and 2, the communication system 10 includes an XCU 100, an XDU 200, a relay communication device 300, and one or more terminals 400.

The communication system 10 performs communication in a wireless network that relays data over wireless links. For example, the wireless network may be a hierarchical wireless network including a Mobile X-haul Network (MXN). The MXN consists of links between the XDUs 200, and the MXN topology consisting of the connections of the XDU 200 links may have a star and partial mesh structure.

The XCU 100 may manage the topology and data path of the MXN and may centrally control the XDUs 200 which are transmission nodes.

The XDU 200 may perform multi-hop wireless transmission and reception of the MXN. For example, the XDU 200 may be in charge of wireless transmission and reception of fronthaul, midhole, and backhaul traffic in the MXN.

The relay communication device 300 may relay data between the XDU 200 and the terminal 400 through wireless links. For example, the relay communication device 300 collectively refers to all types of radio stations serving a user in coverage, and may be implemented as a small base station, an RRH, an f-TRP, or the like.

The radio links may be independent radio links using the same band. For example, the same band may be a millimeter wave band.

The wireless links may include a first wireless link and a second wireless link. For example, the first wireless link may be an X-haul link or a backhaul link, and the second wireless link may be an access link.

Self-interference refers to a second wireless link, for example, a connection link, in a process in which the relay communication device 300 receives a signal from the XDU 200 through a first wireless link, for example, an XHole link. It may be generated by a signal transmitted to the terminal 400 (for example, a user) through.

In order to effectively mitigate magnetic interference, the relay communication device 300 may perform beamforming in consideration of an exhaul link (or a backhaul link) and an access link at the same time in an in-band communication in which two radio links use the same spectrum. . The bandwidth occupancy period is longer than orthogonal resource sharing, and the overall system capacity is increased. Magnetic interference can be effectively mitigated through beamforming.

Hereinafter, a communication method of a relay communication device for mitigating magnetic interference will be described in detail with reference to FIGS. 2 to 7.

FIG. 2 is a schematic block diagram of the relay communication apparatus shown in FIG. 1, FIG. 3 is a diagram for explaining a geometrical analysis of a beamforming method considering magnetic interference, and FIG. 4 is an optimal transmission beamforming vector considering magnetic interference. And an example of an algorithm for determining an optimal reception beamforming vector.

2 to 4, the relay communication device 300 includes a controller 310, a beamformer 330, and a massive antenna ANT.

The controller 310 may determine an optimal transmit beamforming vector and an optimal receive beamforming vector for maximizing a throughput of the wireless network based on magnetic interference.

The beamformer 330 may transmit / receive beamforming through the massive antenna ANT by using the optimal transmission beamforming vector and the optimal reception beamforming vector.

In order to maximize the throughput of the wireless network, the optimal transmit beamforming vector and the optimal receive beamforming vector may be determined in consideration of magnetic interference generated during a communication process.

To illustrate this, we can consider the following simple channel model, which is widely used to verify the performance of multi-antenna technology in the millimeter wave band.

와

은 송신단과 수신단에서의 안테나 개수를 뜻하며,

은 다중 경로(path)의 개수를 의미한다.

은 수신단에서의 수신 조향 벡터(Rx steering vector)이며,

는

번째 경로의 도래각(Angle of arrival(AoA))을 뜻한다.

는 수식적으로 수학식 2와 같이 정의된다.here,

Wow

Is the number of antennas at the transmitter and receiver,

Is the number of multiple paths.

Is the Rx steering vector at the receiver,

Is

Angle of arrival (AoA) of the first path.

Is mathematically defined as in Equation 2.

와

는 각각 안테나 간의 간격 및 반송파의 파장이다.

는 송신 조향 벡터(Tx steering vector)이며,

와 유사하게 정의할 수 있다.here,

Wow

Are the spacing between antennas and the wavelength of the carrier, respectively.

Is the Tx steering vector,

Can be defined similarly to

개 안테나를 이용하여 엑스홀 링크를 통해 다운링크 데이터를 수신하고, 동시에

개 안테나를 이용하여 단말기들(400)에게 접속 링크(Access link)를 통해 다운링크 데이터를 송신한다.As shown in FIG. 1, a downlink data transmission environment is considered in an in-band full-duplex environment. At this time, the relay communication device 300 from the XDU (200)

Receiving downlink data via the XHole link using

The downlink data is transmitted to the terminals 400 using an access antenna through an access link.

For convenience of explanation of the beamforming method according to the embodiment, it is assumed that the terminals 400 of the access link are allocated resources orthogonally to each other in terms of time or frequency.

Assuming that the terminal 400 has one antenna, the signal received by the active terminal 400 at a specific time may be expressed as in Equation 3 below.

는 백색 가우시안 잡음(Additive White Gaussian Noise(AWGN))이 된다.

는 접속 링크의 채널 행렬이며, 수학식 1과 유사하게 수학식 4와 같이 정의할 수 있다.Here, is a transmission signal transmitted from the relay communication device 300 through the access link to the activated terminal 400,

Becomes White Gaussian Noise (AWGN).

Is a channel matrix of the access link, and can be defined as in Equation 4 similarly to Equation 1.

는 거리

에서 경로 손실(path loss)을 뜻하며,

로 주어진다. 또한 수학식 4에서

은

번째 경로의 스몰-스케일 페이딩(small-scale fading)을 나타낸다. 참고로, 수학식 3에서 단말기들(400)간에 자원을 직교하도록 할당 받았기 때문에, 단말기들(400)간의 간섭없이 신호를 수신할 수 있으며, 또한 XDU(200)로부터 중계 통신 장치(300)로 송신되는 신호는 밀리미터파 빔포밍을 통해 높은 지향성을 가지고 중계 통신 장치(300)로 송신되며, 밀리미터파 대역의 신호가 가지는 높은 경로 손실로 무시할 수 있어, 수학식 3에 표현하지 않을 수 있다.here,

Distance

Means path loss in,

Is given by Also in Equation 4

silver

Represents small-scale fading of the first path. For reference, since Equation 3 is allocated to orthogonal resources between the terminals 400, the signal can be received without interference between the terminals 400, and also transmitted from the XDU 200 to the relay communication device 300. The signal is transmitted to the relay communication device 300 with high directivity through the millimeter wave beamforming, and can be ignored because of the high path loss of the signal in the millimeter wave band.

The signal received from the relay communication device 300 may be expressed as Equation 5 below.

는

을 공분산 행렬로 가지는 AWGN이다. 일반적으로 엑스홀-링크의 경우 LoS(Line-of-Sight)를 확보한 상태의 채널을 가지게 되므로, XDU(200)에서 중계 통신 장치(300)까지의 채널 행렬

(즉, 엑스홀 링크의 채널 행렬)은 다음 수학식 6과 같이 모델링할 수 있다.Is a transmission signal transmitted by the XDU 200 to the relay communication device 300 through an X-haul link,

Is

Is an AWGN with a covariance matrix. In general, since the XHOLE-Link has a channel having a state of securing a line-of-sight (LOS), a channel matrix from the XDU 200 to the relay communication device 300 is provided.

(Ie, the channel matrix of the XHole link) may be modeled as in Equation 6 below.

는 거리

에서 경로 손실을 뜻하며,

로 주어진다. 또한,

는 In-band Full duplex 송신에 의해 발생하는 간섭 신호에 대한 채널 행렬이다. 수학식 5를 참고하면, 엑스홀 링크 다운링크 신호를 가 수신하는데 있어서 중계 통신 장치(300)가 접속 링크를 통해 단말기(400)로 송신하는 신호가 간섭 신호로 작용한다. 즉,

는 In-band Full duplex 송신을 통해 스펙트럼을 공유해서 동시에 송수신하기 때문에 생기는 간섭 신호에 대한 채널 행렬이다.here,

Distance

Means path loss in,

Is given by Also,

Is the channel matrix for the interference signal generated by the in-band full duplex transmission. Referring to Equation 5, a signal transmitted from the relay communication device 300 to the terminal 400 through an access link serves as an interference signal in receiving an x-hole link downlink signal. In other words,

Is a channel matrix for interfering signals caused by sharing and transmitting spectrum simultaneously through in-band full duplex transmission.

At this time, the attainable rate in the channel for the X-hole link can be expressed by Equation 7 below.

으로 주어지므로 유도된다. 또한, 접속 링크에 대한 채널에서의 달성 가능한 레이트(Achievable rate)은 수학식 8과 같이 나타낼 수 있다.In Equation 7, the second equal sign is the optimal transmission beamforming vector in the XDU 200

Derived from In addition, the achievable rate in the channel for the access link can be expressed as Equation (8).

은 중계 통신 장치(300)에서 단말기(400)로 전송하기 위한 신호를 만들 때 필요한 송신 빔포밍 벡터이고,

은 엑스홀 링크를 통해 XDU(200)에서 송신한 신호를 중계 통신 장치(300)에서 수신할 때 필요한 수신 빔포밍 벡터이다.here,

Is a transmission beamforming vector required when generating a signal for transmission from the relay communication device 300 to the terminal 400,

Is a reception beamforming vector required when the relay communication device 300 receives a signal transmitted from the XDU 200 through the XHole link.

In this case, since the throughput (or attainable rate) of the mobile XHole network is determined by the minimum value of the channel capacity of the XHole link and the access link, the optimization problem for maximizing the system throughput can be set as follows.

가

과

모두에 영향을 미치기 때문에, 닫힌 해가 존재하지 않는다. (P1) is non-convex,

end

and

Because it affects all, there is no closed solution.

와

에 대한 통찰력을 얻기 위해, 접속 링크에 해당하는 채널이 Rank-one이라 가정한다. 예를 들어, 접속 링크에 해당하는 채널이 LoS가 확보되어 하나의 경로를 가지는 것으로 모델링된 것일 수 있다.Optimized

Wow

To gain insight into, assume that the channel corresponding to the access link is Rank-one. For example, the channel corresponding to the access link may be modeled as having one path by securing LoS.

이라 두면, 수학식 8은 다음 수학식 10과 같은 수식으로 표현할 수 있다.In other words,

In this case, Equation 8 may be expressed by an equation shown in Equation 10 below.

Therefore, the optimization problem P1 may be converted into Equation 11 below.

로 주어진다. 참고로,

은 엑스홀 링크의 SINR(Signal to Interference-plus-Noise Ratio)을 나타내며,

은 접속 링크의 SNR(Signal to Noise Ratio)이다.

는 SINR과 SNR에 모두 영향을 미치므로

역시 닫힌 해가 존재하지 않는다.here,

Is given by Note that,

Represents the Signal to Interference-plus-Noise Ratio (SINR) of the XHole link,

Is the Signal to Noise Ratio (SNR) of the access link.

Affects both SINR and SNR,

Again, there is no closed solution.

의 최적해를 구하기 위해 문제

을 두 가지 부문제로 나누어서 Iterative방식을 취할 수 있다.therefore

Problem to find the optimal solution

It can be divided into two sectors to take an iterative approach.

가 주어졌을 때, 첫번째 부문제는 다음과 같이 나타낼 수 있다.

Given, the first division can be expressed as

가 주어졌을 때, 두번째 부문제는 다음과 같다.

Given the second division,

At this time, the inequality of the constraint was introduced to control the amount of interference in the X-hole link direction.

의 최적해는 다음과 같이 주어진다. Division

The optimal solution of is given by

로 주어지는 정규화 파라미터이다.

는

의 크기가 1이 되도록 하기 위한 정규화 상수이다.here,

Normalization parameter given by.

Is

Normalization constant to ensure that the size of 1 is 1.

의 최적해는 다음 수학식 15과 같이 유도될 수 있다. Also,

The optimal solution of may be derived as in Equation 15 below.

이고

이다. ,

는 중계 통신 장치(300)에서 XDU(200)로부터 신호를 수신하는데 자기 간섭을 발생시키는 방향을 가리키는 방향 벡터를 의미할 수 있다.

는

를

방향에 직교한 성분으로 표현된 방향 벡터를 의미할 수 있다.here,

ego

to be. ,

May refer to a direction vector indicating a direction in which magnetic interference is generated when the relay communication device 300 receives a signal from the XDU 200.

Is

To

It can mean a direction vector expressed by a component orthogonal to the direction.

를 위한 최적 빔포밍 벡터

는

와

를

의 Null space로 투영시킨 벡터로 이루어진 공간에 존재한다. 수학식 15을 수학식 13

에 대입하면, 문제

는 다음 수학식 16과 같이 변환할 수 있다.That is, looking at the physical meaning of the equation (15),

Optimal beamforming vector

Is

Wow

To

It exists in a space consisting of vectors projected by null space of. Equation 15 to Equation 13

Assigning to, problem

Can be converted as shown in Equation 16 below.

로 표현된다.

는

가

성분을 얼마나 가지고 있는지를 나타내는 값이며,

는

가

성분을 얼마나 가지고 있는 나타내는 값이다.here,

It is expressed as

Is

end

Is a value indicating how much of the component

Is

end

It is a value that indicates how much of a component is held.

의 최적해는 수학식 17과 같이 주어진다.Also,

The optimal solution of is given by

인 경우, 최적

는 수학식 18과 같이 주어진다.From above

If is optimal

Is given by Equation 18.

는 수학식 19과 같다. Otherwise, optimal

Is the same as (19).

는 엑스홀 링크가 허용하는 간섭 레벨, 즉 허용 간섭 레벨을 의미하고,

은 자기 간섭의 자기 간섭 레벨을 의미한다. here,

Means the interference level allowed by the XHole link, that is, the allowed interference level,

Means the magnetic interference level of the magnetic interference.

쪽으로 Maximal ratio transmission임을 확인할 수 있다. 또한, 자기 간섭이 허용 간섭 레벨보다 클 경우(CASE 2), 자기 간섭 방향으로의 간섭 레벨을 허용치(

) 만큼 줄여서 빔포밍하는 것이 최적의 전송 전략임을 확인할 수 있다. As shown in Figure 3, when the magnetic interference level is less than the allowable interference level (CASE 1), the optimal beamforming strategy is

We can see that it is the maximum ratio ratio transmission. In addition, when the magnetic interference is greater than the allowable interference level (CASE 2), the interference level in the direction of the magnetic interference is allowed (

It can be confirmed that beamforming by reducing the number of the beams is a best transmission strategy.

와

를 구하는 Iterative algorithm은 도 4에 도시된 알고리즘과 같이 정리할 수 있다.Based on the above,

Wow

Iterative algorithm to obtain the can be summarized as the algorithm shown in FIG.

를 접속 링크에서 최대 SNR을 가질 수 있는 MRT기법을 취하도록 초기화한 뒤, Iterative algorithm을 시작할 수 있다. 즉, 컨트롤러(310)는

를 접속 링크에서 최대 SNR을 갖도록 초기 송신 빔포밍 벡터를 설정할 수 있다. 컨트롤러(310)는 초기 송신 빔포밍 벡터를 이용하여

을 계산할 수 있다.First, the controller 310

It can be initialized to take the MRT technique that can have the maximum SNR on the access link, then start the Iterative algorithm. That is, the controller 310

May set an initial transmit beamforming vector to have a maximum SNR at the access link. The controller 310 uses the initial transmit beamforming vector

Can be calculated.

을 계산할 수 있다. 예를 들어, 컨트롤러(310)는 엑스홀 링크의 SINR과 상기 접속 링크의 SNR을 비교하여

을 계산할 수 있다.Thereafter, the controller 310 is based on the interference to the XHole link

Can be calculated. For example, the controller 310 compares the SINR of the XHole link with the SNR of the access link.

Can be calculated.

로 계산하고, 알고리즘을 종료할 수 있다.If SINR is greater than or equal to SNR, controller 310 returns the initial transmit beamforming vector.

Calculate and terminate the algorithm.

를 계산할 수 있다. 이때, 컨트롤러(310)는

을 계산하기 위해 엑스홀 링크로의 허용 간섭 레벨을 고려할 수 있다.If SINR is less than the SNR, controller 310 does not terminate the algorithm.

Can be calculated. At this time, the controller 310

The allowable interference level to the XHole link can be taken into account to calculate.

를

(송신 조향 벡터)로 결정할 수 있다.If the magnetic interference level of the magnetic interference is less than or equal to the allowable interference level, the controller 310

To

(Transmission steering vector).

)만큼 줄여서

를 계산할 수 있다.If the magnetic interference level is greater than the allowable interference level, the controller 310 sets the allowable interference level in the direction of the magnetic interference (

By

Can be calculated.

 Since the transmission beamforming vector and the reception beamforming vector are influenced by each other, the controller 310 may calculate an optimal transmission beamforming vector and an optimal reception beamforming vector by performing an iterative update process through an iteration operation. have. As shown in the algorithm illustrated in FIG. 4, the controller 310 may repeatedly perform steps 2 to 4 by updating the optimal transmission beamforming vector calculated in step 4 with the initial transmission beamforming vector.

In other words, if the channel capacity of the XHole link is large even though the interference of the XHole link is allowed, the controller 310 determines that the optimal solution has been found and terminates the algorithm, otherwise iteratively until the optimal solution is found. Do the above.

FIG. 5 is a diagram for describing an example of a channel information feedback method for extending the beamforming transmission strategy described with reference to FIGS. 2 to 4.

)이라 가정하고 중계 통신 장치(300)의 빔포밍 전송 전송 전략을 설명하였다.2 to 4, the channel corresponding to the access link is Rank-one (

), The beamforming transmission transmission strategy of the relay communication device 300 has been described.

The beamforming transmission strategy according to the embodiment is not limited thereto, and the general rank-deficient channel () may be extended.

) 및 CQI(

, 또는

의 추정치)를 중계 통신 장치(300)로 피드백할 수 있다.To this end, the terminal 400 is a CDI (

) And CQI (

, or

May be fed back to the relay communication device 300.

(CDI)를 추정하여 feedback한다.As shown in FIG. 5, in order to estimate channel direction indicator (CDI) information in the terminal 400, the terminal 400 is represented by Equation 20.

It estimates and feeds back (CDI).

를 쉽게 추정할 수 있으며, 중계 통신 장치(400)에서는

이라 가정하고, 최적의

와

를 구하는 Iterative algorithm을 적용할 수 있다.In addition, in the case of the channel quality indicator (CQI) in the relay communication device 400 in the analog feedback method, etc.

Can be easily estimated, the relay communication device 400

Assuming, optimal

Wow

Iterative algorithm can be applied.

In FIG. 5, the required number of feedback bits is set as in Equation 21 in proportion to the number of transmitting antennas.

)가 증가함에 따라 log

에 비례해서 피드백 비트 수를 증가시키면 채널을 완벽하게 알 때에 비해 성능 저하가 없게 된다. 이때,

는 채널 정보가 완벽할 때 대비 성능 간격(gap)에 따라 결정되는 상수이다.That is, the number of antennas (

Log increases with)

Increasing the number of feedback bits in proportion to, results in no performance penalty compared to knowing the channel perfectly. At this time,

Is a constant that depends on the performance gap when the channel information is complete.

6 and 7 are graphs for explaining the performance through the simulation of the beamforming method according to the embodiment.

으로 가정하였고, 중계 통신 장치(300)의 송수신 안테나 개수는 각각

으로 정의하였다.Simulation was performed through Matlab to verify the performance of the beamforming method according to the embodiment. The number of Tx antennas of the XDU 200 is

Assume that the number of transmit and receive antennas of the relay communication device 300 is

As defined.

이며, 중계 통신 장치(300)에서의 수신 SNR은

로 정의된다. 그리고 X-haul link의 경우 LoS 채널 환경을 확보하였다는 가정을 하고 송수신기 간 거리를 350m로 정의하였다. 이에 따른 path loss는

으로 주어진다.

이면서 Rank-deficient channel에서의 성능을 비교하였다.

The received SNR at the relay communication device 300 is

Is defined as In the case of X-haul link, we assume the LoS channel environment is secured and define the distance between transceivers as 350m. The resulting path loss is

Given by

In addition, we compared the performance in Rank-deficient channel.

FIG. 6 compares the Achievable rate performance of a mmWave-based beamspace MIMO technology considering only a beamforming method and an existing access link according to an SNR according to an embodiment.

In Figure 6 it can be seen that the beamforming method according to the embodiment is superior to about 1bps / Hz compared to the existing technology. In other words, if the channel status of the access link is better than the XHOLE link, the bottleneck is applied to the transmission speed of the entire system. Therefore, the performance of the XHOLE link is improved by controlling the magnetic interference of the access link. This will have a significant impact on.

로 두었을 때의 성능을 비교하였다. 여기서

으로 설정하였으며 도 7에서

로 정의한다.7 is a graph comparing achievable rate performance according to the number of antennas. For reference, when the transmitter of the relay communication device 300 knows the channel perfectly, the number of feedback bits is expressed as in Equation 20.

The performance when compared to was compared. here

In FIG. 7

It is defined as

로 설정하였을 때와

로 안테나 개수와 상관없이 설정하였을 때의 성능을 비교하였다. 도 7에서 확인할 수 있듯이 중계 통신 장치(300)가 채널을 완벽하게 알 때에는 안테나의 개수가 증가함에 따라 전송 속도가 증가함을 확인할 수 있다. 참고로 안테나 개수가 증가함에 따라 전송 속도 증가폭은 줄어들게 된다. 그리고 수학식 20와 같이 Feedback비트수를 결정할 때에는 채널을 완벽하게 알 때와 거의 비슷한 성능을 내는 것을 확인할 수 있다.Also for performance comparison

When set to

We compared the performance when the antenna was set regardless of the number of antennas. As shown in FIG. 7, when the relay communication apparatus 300 completely knows a channel, it may be confirmed that a transmission speed increases as the number of antennas increases. For reference, as the number of antennas increases, the increase rate of transmission speed decreases. In addition, as shown in Equation 20, when determining the number of feedback bits, it can be seen that the performance is almost the same as when the channel is perfectly known.

로 설정하였을 때에는 안테나 개수가 증가함에 따라 어느 정도 성능은 개선되나 안테나 개수가 40개보다 많아질 때, 성능이 오히려 감소함을 알 수 있다. 이는 안테나 개수가 증가함에 따라 보다 Sharp한 형태의 빔을 형성할 수 있어 자기 간섭을 줄일 수 있으나, Sharpness가 증가할수록, 바라보는 각도가 일치하지 않게 되면 그만큼 큰 beamforming gain loss가 생기게 되므로 이에 비례해서 AoD의 quantization error를 줄여야 성능 loss가 줄어들게 된다. 따라서

로 설정하였을 경우, 안테나의 개수가 증가함에 따라 Rate loss가 커지게 되어 도 7과 같은 그래프를 얻을 수 있게 된다.On the other hand,

When it is set to, the performance is somewhat improved as the number of antennas increases, but when the number of antennas is greater than 40, the performance decreases rather. As the number of antennas increases, it is possible to form a beam having a sharper shape, thereby reducing magnetic interference. However, as the sharpness increases, the beamforming gain loss becomes larger when the viewing angles do not coincide. Reducing the quantization error will reduce the performance loss. therefore

If set to, the rate loss increases as the number of antennas increases, thereby obtaining a graph as shown in FIG. 7.

This application is the result of research conducted under the support of the Information and Communication Technology Promotion Center as a source of information (Ministry of Science and Technology Information and Communication) in 2017 (No.2014-0-00282, Development of Core Technology for 5G Mobile Communication for Ultra-Connected Smart Service ).

The method according to the embodiment may be embodied in the form of program instructions that can be executed by various computer means and recorded in a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the media may be those specially designed and constructed for the purposes of the embodiments, or they may be of the kind well-known and available to those having skill in the computer software arts. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical media such as CD-ROMs, DVDs, and magnetic disks, such as floppy disks. Magneto-optical media, and hardware devices specifically configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code 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 operations of the embodiments, and vice versa.

The software may include a computer program, code, instructions, or a combination of one or more of the above, and configure the processing device to operate as desired, or process it independently or collectively. You can command the device. Software and / or data may be any type of machine, component, physical device, virtual equipment, computer storage medium or device in order to be interpreted by or to provide instructions or data to the processing device. Or may be permanently or temporarily embodied in a signal wave to be transmitted. The software may be distributed over networked computer systems so that they may be stored or executed in a distributed manner. Software and data may be stored on one or more computer readable recording media.

Although the embodiments have been described with reference to the accompanying drawings, those skilled in the art may apply various technical modifications and variations based on the above. For example, the described techniques may be performed in a different order than the described method, and / or components of the described systems, structures, devices, circuits, etc. may be combined or combined in a different form than the described method, or other components Or even if replaced or substituted by equivalents, an appropriate result can be achieved.

Therefore, other implementations, other embodiments, and equivalents to the claims are within the scope of the following claims.

Claims (22)

A communication method in a wireless network for relaying data over wireless links, the method comprising:
Determining an optimal transmit beamforming vector and an optimal receive beamforming vector for maximizing throughput of the wireless network based on magnetic interference; And
Performing transmission and reception beamforming using the optimal transmission beamforming vector and the optimal reception beamforming vector
Including,
The magnetic interference is generated by a signal transmitted to a user through another one of the radio links in the process of receiving a signal through one of the radio links.
The method of claim 1,
Wherein one is an X-haul link or a backhaul link and the other is an access link.
The method of claim 1,
The wireless network is a hierarchical wireless network including a Mobile X-haul Network (MXN).
The method of claim 1,
And the wireless links are independent radio links using the same band.
The method of claim 4, wherein
Wherein said same band is a millimeter wave band.
The method of claim 2,
The determining step,
Setting an initial transmit beamforming vector to have a maximum SNR on the access link;
Calculating the optimal received beamforming vector using the initial transmit beamforming vector; And
Calculating the optimal transmit beamforming vector based on the interference to the XHole link
Communication method comprising a.
The method of claim 6,
Calculating the optimal reception beamforming vector and calculating the optimal transmission beamforming vector are repeatedly performed by updating the optimal transmission beamforming vector with the initial transmission beamforming vector.
The method of claim 6,
Computing the optimal transmission beamforming vector,
Comparing the SINR of the XHole link with the SNR of the access link;
If the SINR is greater than or equal to the SNR, calculating the initial transmit beamforming vector as the optimal transmit beamforming vector; And
If the SINR is less than the SNR, calculating the optimal transmit beamforming vector based on an allowable interference level to the XHole link
Communication method comprising a.
The method of claim 8,
Calculating the optimal transmission beamforming vector based on the allowable interference level,
If the magnetic interference level of the magnetic interference is less than or equal to the allowed interference level, determining the optimal transmission beamforming vector as a transmission steering vector; And
Calculating the optimal transmission beamforming vector by reducing the allowable interference level by an allowable value in a magnetic interference direction when the self interference level is greater than the allowable interference level.
Communication method comprising a.
The method of claim 9,
The transmit steering vector is

ego,

The communication method is AoA (Angle of arrival) of the first path.
The method of claim 9,
The above tolerance

ego,

Is the optimal receive beamforming vector,

Is the allowable interference level,

Is a channel matrix for the interfering signal.
A communication apparatus for performing a communication method in a wireless network for relaying data over wireless links, the method comprising:
Massive antenna;
A controller that determines an optimal transmit beamforming vector and an optimal receive beamforming vector for maximizing throughput of the wireless network based on magnetic interference; And
A beamformer for performing transmission and reception beamforming through the massive antenna using the optimal transmission beamforming vector and the optimal reception beamforming vector
Including,
And the magnetic interference is generated by a signal transmitted to a user through another one of the radio links in the course of receiving a signal through one of the radio links.
The method of claim 12,
Wherein one is an X-haul link or a backhaul link and the other is an access link.
The method of claim 12,
The wireless network is a hierarchical wireless network including a Mobile X-haul Network (MXN).
The method of claim 12,
And the wireless links are independent radio links using the same band.
The method of claim 15,
Wherein said same band is a millimeter wave band.
The method of claim 13,
The controller,
Set an initial transmit beamforming vector to have a maximum SNR on the access link, calculate the optimal receive beamforming vector using the initial transmit beamforming vector, and based on the interference to the X-hole link, the optimal transmit beam Communication device for calculating the forming vector.
The method of claim 17,
The controller,
And updating the optimal transmission beamforming vector with the initial transmission beamforming vector to repeatedly calculate the optimal reception beamforming vector and the optimal transmission beamforming vector.
The method of claim 17,
The controller,
Compare the SINR of the XHole link with the SNR of the access link,
If the SINR is greater than or equal to the SNR, calculate the initial transmit beamforming vector as the optimal transmit beamforming vector,
And if the SINR is less than the SNR, calculate the optimal transmit beamforming vector based on an allowable interference level to the XHole link.
The method of claim 19,
The controller
If the magnetic interference level of the magnetic interference is less than or equal to the allowable interference level, determine the optimal transmission beamforming vector as a transmission steering vector,
And when the magnetic interference level is greater than the allowed interference level, reducing the allowed interference level by an allowable value in a direction of magnetic interference to calculate the optimal transmission beamforming vector.
The method of claim 20,
The transmit steering vector is

ego,

Is a communication device of the first path AoA (Angle of arrival).
The method of claim 20,
The above tolerance

ego,

Is the optimal receive beamforming vector,

Is the allowable interference level,

Is a channel matrix for the interfering signal.

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