KR20110093565A - Unified feedback frame of supportign a plurality of feedback modes and multiple input multiple output communication system of using the unified feedback frame - Google Patents

Abstract

PURPOSE: A feedback frame and MIMO communication system using the same are provided to support various feedback modes through a frame capable of supporting various feedback modes. CONSTITUTION: A receiver(1020) receives a basic codeword indicator, a differential codeword indicator, and a correlation codeword indicator. The basic codeword indicator indicates one of basic code words on a basic code book. The differential coding word pointer directs one among a plurality of differential coding words included in the differential code book.

Description

Unified feedback frame supporting multiple feedback modes and a multi-input / output communication system using the feedback frame.

The following embodiments are directed to a multiple input / output communication system providing several feedback modes.

The MIMO communication system can provide a variety of multimedia services, including voice services, in high quality by using a plurality of channels in a spatial domain.

In a MIMO communication system, base stations and terminals share channel information and use codebooks to generate an optimal precoding matrix. The base station and the terminals share the channel information using codewords included in the codebook and generate an appropriate precoding matrix.

The specific space may be quantized into a plurality of codewords, and the plurality of codewords generated by quantizing the space may be stored in the base station and the terminals as a codebook. Here, each of the codewords may be a vector or a matrix.

A communication method of a transmitter in a multiple input multiple output (MIMO) communication system includes accessing a memory in which a basic codebook, a differential codebook, and a correlation codebook are stored; A basic codeword indicator indicating any one of a plurality of basic codewords included in the basic codebook from a receiver, a differential codeword indicator indicating any one of a plurality of differential codewords included in the differential codebook, and the correlation Receiving a correlation codeword indicator indicating any one of a plurality of correlation codewords included in the codebook; And generating a precoding matrix for the receiver using the basic codeword indicator, the differential codeword indicator and the correlation codeword indicator.

Generating a precoding matrix for the receiver may comprise: refining the base codeword indicator using the differential codeword indicator; And inner-product each other with the base codeword indicator and the refined base codeword indicator to generate a precoding matrix for the receiver.

The differential codeword indicator indicates a difference in time domain for the base codeword indicator or a difference in frequency domain for the base codeword indicator, and the correlation codeword indicator indicates a correlation of a channel between the transmitter and the receiver. It may represent a correlation.

When the differential codeword indicator is fixed to a preset matrix and the correlation codeword indicator is fixed to a preset matrix, the basic codeword indicator is configured to include the plurality of basic codewords in a wide band including a plurality of subbands. One of the plurality of basic codewords may be indicated in the corresponding subband of the plurality of subbands.

The differential codeword indicator is fixed to a predetermined matrix, and the basic codeword indicator is any one of the plurality of basic codewords in a wide band including a plurality of subbands or a corresponding one of the plurality of subbands. When indicating, generating the precoding matrix for the receiver may include adaptively adjusting the precoding matrix for the receiver using the correlation codeword indicator.

The correlation codeword indicator is fixed to a predetermined matrix, and the basic codeword indicator selects one of the plurality of basic codewords in a corresponding subband among a wide band or a plurality of subbands including a plurality of subbands. And when the differential codeword indicator indicates any one of the plurality of differential codewords in the corresponding one of the plurality of subbands, generating a precoding matrix for the receiver. And refining the base codeword indicator using the differential codeword indicator to generate a precoding matrix.

The basic codeword indicator indicates any one of the plurality of basic codewords in a corresponding subband among a wide band or a plurality of subbands including a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands. Indicating one of the plurality of differential codewords in a corresponding subband of bands, and receiving the basic codeword indicator, the differential codeword indicator and the correlation codeword indicator may include the basic codeword indicator and the Receiving a differential codeword indicator in the same time interval, and generating a precoding matrix for the receiver using the differential codeword indicator to generate a precoding matrix for the receiver. To refine in the frequency domain It may include a system.

The basic codeword indicator indicates any one of the plurality of basic codewords in a wide band including a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands in a corresponding subband of the plurality of subbands. Indicating one of the differential codewords, and receiving the basic codeword indicator, the differential codeword indicator, and the correlation codeword indicator may include the basic codeword indicator and the differential codeword indicator in different time intervals. Receiving and generating a precoding matrix for the receiver using the differential codeword indicator to generate a precoding matrix for the receiver in both time and frequency domains. May comprise a step of refinement. .

The base codeword indicator indicates any one of the plurality of base codewords in a corresponding subband of a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands in a corresponding subband of the plurality of subbands. Indicating one of the differential codewords, and receiving the basic codeword indicator, the differential codeword indicator, and the correlation codeword indicator, receives the basic codeword indicator and the differential codeword indicator in the same time interval. Wherein generating the precoding matrix for the receiver comprises refining the base codeword indicator in the frequency domain using the differential codeword indicator to generate a precoding matrix for the receiver. It may include.

The base codeword indicator indicates any one of the plurality of base codewords in a corresponding subband of a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands in a corresponding subband of the plurality of subbands. Indicating one of the differential codewords, and receiving the basic codeword indicator, the differential codeword indicator, and the correlation codeword indicator may include the basic codeword indicator and the differential codeword indicator in different time intervals. Receiving and generating a precoding matrix for the receiver using the differential codeword indicator to refine the base codeword indicator in the time domain to generate a precoding matrix for the receiver. It may include a step.

Receiving the basic codeword indicator, the differential codeword indicator and the correlation codeword indicator may include sequentially receiving two or more differential codeword indicators for one basic codeword indicator.

In a multiple input multiple output (MIMO) communication system, a communication method of a receiver includes estimating a channel between a transmitter and a receiver; Accessing a memory in which a basic codebook, a differential codebook, and a correlation codebook are stored; A basic codeword indicator indicating one of a plurality of basic codewords included in the basic codebook based on the estimated channel, and a differential code indicating any one of a plurality of differential codewords included in the differential codebook Generating a correlation codeword indicator indicating one of a word indicator and a plurality of correlation codewords included in the correlation codebook; And transmitting the basic codeword indicator, the differential codeword indicator, and the correlation codeword indicator to the transmitter.

The basic codeword indicator indicates any one of the plurality of basic codewords in a corresponding subband among a wide band or a plurality of subbands including a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands. One of the plurality of differential codewords may be indicated in a corresponding subband among bands.

At least one of the differential codeword indicator or the correlation codeword indicator may be fixed to a predetermined matrix.

Embodiments of the present invention can support multiple feedback modes simultaneously using a frame that can support multiple feedback modes.

Embodiments of the present invention can support multiple feedback modes simultaneously, thereby generating an optimal precoding matrix.

1 is a diagram illustrating a closed loop multiple input / output communication system.
2 is a flowchart illustrating a method of operating a transmitter and a receiver operating in a base mode in a closed loop multiple input / output communication system.
FIG. 3 is a diagram for describing a basic codeword indicator in each of wide bands and a basic codeword indicator in subbands.
4 is a diagram illustrating a differential mode in the time domain.
5 is a diagram illustrating a differential mode in the frequency domain.
6 is a flowchart illustrating a method of operating a transmitter and a receiver operating in a correlation mode in a closed loop multiple input / output communication system.
7 is a diagram illustrating basic codewords in wide band and differential codewords in subbands.
8 is a diagram illustrating basic codewords and differential codewords in subbands.
9 illustrates basic codewords in the wide band and differential codewords in the subbands.
10 is a block diagram showing a transmitter according to an embodiment of the present invention.
11 is a block diagram illustrating a receiver according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating a closed loop multiple input / output communication system.

Referring to FIG. 1, a closed loop multiple input / output communication system includes a transmitter 110 and receivers 120 and 130. 1 illustrates an example of a multi-user multi-input / output communication system, and embodiments of the present invention may be well applied to a single-user multi-input / output communication system. In addition, the term “closed loop” means that the receivers 120 and 130 feed back channel information to the transmitter 110, and the transmitter 110 performs precoding using the channel information.

The transmitter 110 includes a plurality of transmit antennas, such as two, four, and eight, and one or more receive antennas are installed in each of the receivers 120 and 130. A channel is formed between the transmitter 110 and each of the receivers 120 and 130, and each of the receivers 120 and 130 feeds back information about the channel to the transmitter 110. In this case, the channel information may be generated based on different types of codebooks according to the feedback mode, and the feedback mode may include a base mode, a differential mode, and a correlation mode.

For example, if the transmitter 110 and receivers 120, 130 operate according to the base mode, each of the receivers 120, 130 may be any one of the basic codewords included in the base codebook corresponding to the base mode. May be selected as the preferred base codeword, and the base codeword indicator (eg, the index of the preferred base codeword) corresponding to the preferred base codeword may be fed back to the transmitter 110. At this time, the transmitter 110 uses the pre-stored basic codebook to grasp the basic codeword indicator of each of the receivers 120 and 130, and based on the basic codeword indicator of each of the receivers 120 and 130. Determine the precoding matrix. The data streams to be transmitted by the transmitter 110 are precoded by the precoding matrix and then transmitted to the receivers 120 and 130 through transmit antennas installed in the transmitter 110.

In another example, if transmitter 110 and receivers 120 and 130 operate in a differential mode, each of transmitter 110 and receivers 120 and 130 may have a differential codebook corresponding to a pre-stored differential mode. Differential codeword indicators can be used. As will be described in detail below, the differential mode may include a differential mode in the frequency domain and a differential mode in the time domain and a differential mode in both the frequency domain and the time domain. If the differential mode is enabled, each of the receivers 120, 130 may have any of a plurality of differential codewords included in the differential codebook that can best refine the preferred base codeword in base mode. You can choose one. The differential codeword indicator of the selected differential codeword is fed back to the transmitter 110. At this time, the transmitter 110 uses a differential codeword indicator to refine a preferred base codeword fed back from each of the receivers 120 and 130 in at least one of a time domain and a frequency domain, and then refines the base codeword. To determine the optimal precoding matrix.

In another example, if transmitter 110 and receivers 120, 130 operate according to a correlation mode, each of transmitter 110 and receivers 120, 130 may have a correlation codebook corresponding to a pre-stored correlation mode. Can be used to generate a correlation codeword indicator. That is, a channel between each of the transmitter 110 and the receivers 120 and 130 has a correlation property, and in the correlation mode, each of the transmitter 110 and the receivers 120 and 130 has a correlation property of the channel. Can be used to refine the preferred base codeword.

Base mode, differential mode and correlation mode are described again below.

2 is a flowchart illustrating a method of operating a transmitter and a receiver operating in a base mode in a closed loop multiple input / output communication system.

Referring to FIG. 2, the transmitter transmits a pilot to a receiver (210). Here, the pilot is a signal well known to both the transmitter and the receiver. The receiver estimates the channel from the transmitter to the receiver using the pilot sent from the transmitter.

In base mode, the receiver selects any one of a plurality of codewords included in the base codebook as the preferred base codeword w _k based on the channel from the transmitter to the receiver (220). Where k is the index of the preferred codeword in the preferred codebook.

The receiver feeds back 'k' to the transmitter as a basic codeword indicator (230).

The transmitter extracts a preferred base codeword w _k from a prestored base codebook (240) and generates a precoding matrix F _k using the preferred base codeword w _k (250). The transmitter then precodes the data streams using the precoding matrix F _k (260).

Precoded data streams are transmitted 270 using transmit antennas.

FIG. 3 is a diagram for describing a basic codeword indicator in each of wide bands and a basic codeword indicator in subbands.

Referring to FIG. 3, when the base mode is enabled, one base codeword indicator may be generated in the wide band f, and one base codeword in each of the subbands f ₁ , f ₂ , and f ₃ . An indicator can be generated.

That is, the receiver can estimate a channel in wide band f and select one preferred base codeword in wide band f based on that channel. In addition, the receiver sub-bands _{(f 1, f 2, f} 3) The default is to estimate the channel from each, and one preferred in the basis of the channel sub-bands _{(f 1, f 2, f} 3) each Codewords can be selected.

4 is a diagram illustrating a differential mode in the time domain.

As described above, the differential mode according to embodiments of the present invention may be enabled in the time domain.

Referring to FIG. 4, the differential mode in the time domain may be independently enabled in each of the subbands f ₁ , f ₂ , and f ₃ . That is, for a given subband, a differential codeword indicator may be generated in each of the time intervals. In FIG. 4, T _jt denotes a differential codeword indicator in a t-th time interval.

The receiver sequentially generates differential codeword indicators in each of the subbands f ₁ , f ₂ , f ₃ .

More specifically, the receiver sequentially generates differential codeword indicators T _j1 , T _j2 , T _jT in subband f ₁ . Here, the differential codeword indicator refines the basic codeword indicator w _k . In particular, the differential codeword indicator T _jt in the t th time interval is a refinement of the base codeword indicator w _k or is a product of the basic codeword indicator w _k and the differential codeword indicator T _jt-1 in the t-1 th time interval. T _jt-1 w _k can be purified.

Similar to the above, the receiver sequentially generates differential codeword indicators in the other subbands f ₂ and f ₃ as well. The differential codeword indicators generated in each of the subbands f ₁ , f ₂ , f ₃ are sequentially fed back to the transmitter. At this time, the transmitter generates a precoding matrix by refining the product of the base codeword indicator or the base codeword indicator w _k and the differential codeword indicator in the previous time interval by using the sequentially fed back differential codeword indicators.

5 is a diagram illustrating a differential mode in the frequency domain.

Referring to FIG. 5, when the differential mode in the frequency domain is enabled, the receiver generates a differential codeword indicator in at least one of the subbands f ₁ , f ₂ , and f _{3 for a} given time interval.

That is, as shown in FIG. 5, the receiver generates a differential codeword indicator T _j1 in subband f ₂ of a given time interval t = 1. Of course, the receiver may generate differential codeword indicators in other subbands of a given time interval t = 1. The receiver also generates a differential codeword indicator in at least one of the subbands f ₁ , f ₂ , f _{3 for} another given time intervals t = 2,..., T.

In this case, the transmitter and the receiver may refine the basic codeword indicator by using the differential codeword indicator of a given time interval, and then generate the precoding matrix in the corresponding subband by using the refined basic codeword indicator.

6 is a flowchart illustrating a method of operating a transmitter and a receiver operating in a correlation mode in a closed loop multiple input / output communication system.

Referring to FIG. 6, when the correlation mode is enabled, the receiver calculates a characteristic regarding a correlation of a channel (610). The characteristics of channel correlation may be calculated in wideband and may be calculated as long term information. Specific examples of calculating the characteristics of the correlation of the channel will be described later.

In addition, the receiver selects a correlation codeword R _i from the correlation codebook based on the characteristics of the correlation of the channel (620). Here, the correlation codebook includes a plurality of correlation codewords, and the receiver selects a correlation codeword R _i that best represents a characteristic relating to channel correlation.

In addition, the receiver feeds back 630 an index of the correlation codeword R _{i to} the transmitter as a correlation codeword indicator.

The transmitter extracts the correlation codeword R _i from the correlation codebook using the correlation codeword indicator i (640). That is, the transmitter extracts a correlation codeword R _i corresponding to the correlation codeword indicator i among a plurality of correlation codewords included in the correlation codebook.

In addition, the receiver and transmitter refine at least one basic codeword included in the basic codebook using the correlation codeword R _i (650). For example, all basic codewords are refined according to the correlation characteristics of the channel.

The receiver also selects any one of the refined base codewords included in the refined base codebook as the preferred refined base codeword w _k (not shown). The receiver feeds back 660 the 'k', which is the index of the preferred refined basic codeword w _k , to the transmitter.

The transmitter generates a precoding matrix using the preferred refined base codeword w _k (670) and performs the precoding (680). The transmit signal after precoding is transmitted via several transmit antennas (690).

Each of the basic mode, differential mode, and correlation mode has been described above. The following describes the unified versions of basic mode, differential mode and correlation mode. That is, according to embodiments of the present invention, the basic mode, the differential mode and the correlation mode may be enabled through the integrated feedback frame.

의 사이즈는 N_t x r이고, 이것은 다음과 같이 표현될 수 있다.
The number of transmit antennas is N _t , and the rank is r. Overall recommended precoding matrix

The size of is N _t xr, which can be expressed as follows.

는 추천되는 차동 코드워드들

및

의 함수이다. 그리고,

는 추천되는 기본 코드워드를 나타낸다.here,

Is the recommended differential codewords

And

Is a function of. And,

Indicates the recommended default codeword.

Embodiments of the present invention can propose the following two structures.

Structure 1 :

To be

=

=

Structure 2 :

To be

=

=

는

에 의해 얻어지는 매트릭스를 기초로 생성되는 매트릭스이다.here,

Is

It is a matrix produced based on the matrix obtained by.

In the above, i represents the index of the recommended correlation codeword among the correlation codewords included in the correlation codebook, and j _t (t = 1, 2, .T) is the recommended among the differential codewords included in the differential codebook. The index of the differential codeword is represented, and k represents the index of the recommended basic codeword among the basic codewords included in the basic codebook.

1. Default codebook and recommended default codeword

는 기본 코드북에서 k 번째 기본 코드워드를 나타낸다.

의 사이즈는 N_t x r이다. 기본 코드북은 3GPP LTE Release 8-10 표준 문서들과 같은 다양한 표준 문서들에서 정의된 것일 수 있으며, 2 개, 4 개, 8 개의 송신 안테나들을 위한 기본 코드북일 수 있다.

는 와이드 밴드 전체에서 추천된 것일 수 있으며, 와이드 밴드에 포함된 복수의 서브 밴드들 중 적어도 하나에서 추천된 것일 수 있다.

가 와이드 밴드 전체에서 추천된 것인지 또는 하나의 서브 밴드에서 추천된 것인지는 동작 모드 또는 시나리오에 따라 달라질 수 있다.

Denotes the k th basic codeword in the basic codebook.

The size of is N _t xr. The base codebook may be defined in various standard documents, such as 3GPP LTE Release 8-10 standard documents, and may be a base codebook for two, four, and eight transmit antennas.

May be recommended in the whole wide band, or may be recommended in at least one of a plurality of subbands included in the wide band.

Whether is recommended in the wide band or in one subband may vary depending on the operation mode or scenario.

2. Differential Codebooks and Recommended Differential Codewords

는 차동 코드북에 포함된 어느 하나의 차동 코드워드를 나타낸다. 추천되는 차동 코드워드

는 추천되는 기본 코드워드

를 서브 밴드에서 정제하거나, 숏 텀 시간에서 정제한다. 예를 들어, 추천되는 기본 코드워드

가 와이드 밴드에서 추천된 경우, 차동 코드워드

는 그 와이드 밴드에 포함된 서브 밴드들 중 어느 하나의 서브 밴드에서 추천된 것으로서

에 대한 주파수 도메인에서의 차이를 나타내는 것일 수 있다. 또한, 추천되는 기본 코드워드

가 시간 t=0에서 추천된 것인 경우,

는 시간 t=x에서 추천된 것으로서

를 시간 도메인에서의 차이를 나타내는 것일 수 있다.

Denotes any one differential codeword included in the differential codebook. Recommended Differential Codewords

Is the recommended default codeword

Are purified in subbands or at short term times. For example, the recommended default codeword

Codeword is recommended for wideband

Is recommended in any one of the subbands included in the wide band.

It may represent a difference in the frequency domain for. Also, the recommended default codeword

Is recommended at time t = 0,

Is recommended at time t = x

May represent a difference in the time domain.

는 상술한 구조 1에서 Nt x Nt 사이즈의 유니터리 매트릭스일 수 있으며, 상술한 구조 2에서 Nt x r 사이즈의 유니터리 매트릭스로 고정될 수 있다.

는 상술한 구조 1에서 모든 t 에 대하여 아이덴티티 매트릭스로 고정될 수도 있다. 비슷하게,

는 상술한 구조 2에서

를 보장하도록 선택될 수 있다.

가 아이덴티티 매트릭스로 고정되거나,

를 보장하도록 선택되는 경우, 그러한

를 미리 고정된 매트릭스 A라고 가정한다. 이러한 경우, 숏 텀 시간 또는 서브 밴드에서 추가적인 정제가 필요하지 않을 수 있다.

May be a unitary matrix of size Nt x Nt in Structure 1 described above, and may be fixed to a unitary matrix of Nt xr size in Structure 2 described above.

May be fixed to the identity matrix for all t in structure 1 described above. similarly,

In the above-described structure 2

Can be chosen to ensure.

Is fixed to the identity matrix,

If chosen to ensure that such

Let is assumed to be the fixed matrix A in advance. In such cases, no further purification may be needed at short term time or subbands.

는 시간 도메인에서의 차동 코드북 기반 피드백 또는 주파수 도메인에서의 차동 코드북 기반 피드백을 수행하는 것을 가능하게 할 수 있다. 여기서,

및

가 동일한 시간에서 피드백되는지 또는 다른 시간에서 피드백되는지에 따라 다음과 같이 두 가지 케이스들이 구별될 수 있다.
Also,

May enable performing differential codebook based feedback in the time domain or differential codebook based feedback in the frequency domain. here,

And

The two cases can be distinguished as follows depending on whether is fed back at the same time or at a different time.

및

가 동일한 시간 구간에서 피드백되는 경우
(One)

And

Is fed back in the same time interval

및

가 동일한 시간 구간에서 피드백되는 경우,

는 와이드 밴드에서 추천된 것으로서, 기본 코드북으로부터 선택된 것일 수 있다. 구조 1에 대하여 T=1라면(즉, 서브 밴드들 각각에서 하나의

가 단지 하나 이하의

에 의해 정제된다면),

와 같이 나타낼 수 있다. 유사하게, 구조 2에 대해서도

와 같이 나타낼 수 있다. 여기서, T=2라면, 구조 1에 대하여

이고,

이다. 즉, 시간 구간 t=2에서, 서브 밴드들 각각에서 하나의

는 두 개의

에 의해 정제된다.One)

And

Is fed back in the same time interval,

Is recommended in the wide band, and may be selected from a basic codebook. If T = 1 for structure 1 (ie one in each of the subbands

Is only one or less

If purified by),

Can be expressed as: Similarly, for structure 2

Can be expressed as: Where T = 2, for structure 1

ego,

to be. That is, in time interval t = 2, one in each of the subbands

Two

Purified by

는 서브 밴드에서 추천된 차동 코드워드를 나타내며, 그것은 와이드 밴드에서 추천된

에 대한 채널 상태 정보와 관련된 추가적인 서브 밴드-와이즈 정보를 제공한다. 차동 코드북은 주파수 도메인에서의 차동 피드백을 동작시키는 것을 가능하게 할 수 있다.

Denotes the recommended differential codeword in the subband, which is recommended in the wideband

Provides additional subband-wise information related to channel state information for. The differential codebook may enable operating differential feedback in the frequency domain.

Example 1

의 인덱스 k는 기본 코드북에서 k 번째 기본 코드워드를 나타낸다. 또한, 주어진 시간 구간에서

는 복수의 서브 밴드들 각각에서

에 의해 정제된다. 이 때, 복수의 서브 밴드들 각각에서의

의 인덱스는 모두 동일한 시간 구간에서 피드백된다.In a given time interval (e.g. t = 0, t = 1, ...), the recommended

The index k of denotes the k th basic codeword in the basic codebook. Also, in a given time interval

In each of the plurality of subbands

Purified by At this time, in each of the plurality of subbands

The indices of are all fed back in the same time interval.

및

가 동일한 시간 구간에서 피드백되고, 주어진 서브 밴드에서 하나의

가 단지 하나 이하의

에 의해 정제되는 경우를 설명한다.Referring to Figure 7,

And

Are fed back in the same time interval, one in a given subband

Is only one or less

The case where it refine | purifies by is demonstrated.

7 is a diagram illustrating basic codewords in wide band and differential codewords in subbands.

Referring to FIG. 7, at time interval t = 1, an indicator indicating the recommended basic codeword A in the wide band is fed back from the receiver to the transmitter. Further, in time interval t = 1, an indicator indicating a recommended differential codeword a in subband 1, an indicator indicating a recommended differential codeword b in subband 2, and a recommended differential codeword c in subband 3 The indicator indicating is fed back. Here, each of the recommended differential codewords a, b, and c refines the basic codeword A in the wide band in subbands 1, 2, and 3 respectively.

In addition, at time interval t = 2, an indicator indicating the recommended basic codeword B in the wide band is fed back from the receiver to the transmitter. As in time interval t = 1, an indicator indicating the recommended differential codeword d in subband 1 in time interval t = 2, an indicator indicating the recommended differential codeword e in subband 2, in subband 3 The indicator indicating the recommended differential codeword f is fed back. Here, each of the recommended differential codewords d, e, and f refines the basic codeword B in the wide band in subbands 1, 2, and 3, respectively.

가 와이드 밴드에서 생성된 것이고, 추천되는 차동 코드워드가 서브 밴드에서 추천되는 기본 코드워드

를 정제하는 케이스에 대해 설명하였다.2) with respect to FIG. 7, the recommended default codeword

Is generated in the wide band, and the recommended differential codeword is the recommended base codeword in the subband.

The case of refining was described.

각각이 서브 밴드들 각각에서 생성된 것이고, 추천되는 차동 코드워드들 각각이 서브 밴드들 각각에서 추천되는 기본 코드워드들

각각을 정제하는 케이스에 대해 설명하겠다. 또한, 구조 1에 대하여 T=1(즉, 서브 밴드들 각각에서 하나의

가 단지 하나 이하의

에 의해 정제함)인 것으로 가정한다. 유사하게 구조 2에서도

라고 가정한다. Recommended default codewords below

Each is generated in each of the subbands, and each of the recommended differential codewords is recommended in each of the subbands.

I will explain the case of refining each. In addition, T = 1 for structure 1 (ie, one in each of the subbands).

Is only one or less

Purified by). Similarly in structure 2

Assume that

는 와이드 밴드에서의

가 아니라 서브 밴드 각각에서의

를 정제한다. 이에 대해서는 도 8을 참조하여 구체적으로 설명한다.
In each of the subbands

In the wideband

Not in each of the subbands

Purify. This will be described in detail with reference to FIG. 8.

Example 2-

8 is a diagram illustrating basic codewords and differential codewords in subbands.

Referring to FIG. 8, the receiver feeds back the index of the recommended basic codeword B in subband 2 and the index of the recommended basic codeword A in subband 4 to the transmitter in time interval t = 1. In addition, the receiver feeds back the index of the recommended differential codeword b in subband 2 and the index of the recommended differential codeword a in subband 4 to the transmitter in the same time interval t = 1. In this case, the transmitter may generate a precoding matrix in subband 4 by refining the recommended basic codeword A using the index of the differential codeword a. Similarly, at this time, the transmitter can generate the precoding matrix in subband 2 by refining the recommended base codeword B using the index of the differential codeword b.

The receiver also feeds back the index of the recommended base codeword D in subband 1 and the index of the recommended base codeword C in subband 3 to the transmitter, at time interval t = 2. In addition, the receiver feeds back the index of the recommended differential codeword d in subband 1 and the index of the recommended differential codeword c in subband 3 to the transmitter in the same time interval t = 2. In this case, the transmitter may generate a precoding matrix in subband 2 by refining the recommended basic codeword A using the index of the differential codeword a.

및

가 다른 시간 구간에서 피드백되는 경우
(2)

And

Is fed back in different time intervals

및

가 동일한 시간 구간에서 피드백되는 경우에 대해 설명한다. 본 발명의 실시예들은

및

를 서로 다른 시간 구간들에서 피드백할 수 있으며,

및

의 피드백 주기는 다를 수 있다.In connection with item (1)

And

Will be described in the case of being fed back in the same time interval. Embodiments of the invention

And

Can feed back at different time intervals,

And

The feedback period may be different.

가 와이드 밴드에서 생성된 것이고, T=1인 경우, 서브 밴드에서의 추천되는 차동 코드워드

의 인덱스만큼 자주

의 인덱스를 피드백하는 것은 비효율적일 수 있다. 즉,

의 인덱스는

의 인덱스보다 덜 자주 피드백될 수 있다.E.g,

Is generated in wide band and T = 1, the recommended differential codeword in subband

As often as the index of

Feeding back the index of may be inefficient. In other words,

The index of

May be fed back less frequently than the index of.

가 서브 밴드에서 생성된 경우,

이

를 연속적으로(successively) 피드백하는 것이 효율적일 수 있다. 예를 들어, T=2인 경우,

는

를 정제하고,

는

가 아니라

를 정제할 수 있다.For another example

Is generated in the subband,

this

It may be efficient to feed back continuously. For example, if T = 2

Is

Refines,

Is

Not

Can be purified.

The two examples described above are described in detail below.

가 와이드 밴드에서 생성된 추천되는 기본 코드워드라고 가정한다. T=1인 경우, 구조 1에 대하여

이며, 구조 2에 대하여는

이다. 여기서,

는 서브 밴드에서 추천되는 차동 코드워드를 나타내며,

에 대한 추가적인 서브 밴드-와이즈 정보를 제공한다. One)

Assume is the recommended default codeword generated in wideband. For structure 1, if T = 1

For structure 2

to be. here,

Denotes the recommended differential codeword in the subband,

Provides additional subband-wise information for.

가 얻어질 수 있으며, 구조 2에 대하여

가 얻어질 수 있다. 여기서,

는 구조 1에서

에 대한 추가적인 서브 밴드-와이즈 정보를 제공하며, 구조 2에서

에 대한 추가적인 서브 밴드-와이즈 정보를 제공한다. If T is large, for structure 1

Can be obtained, for structure 2

Can be obtained. here,

In structure 1

Provides additional subband-wise information for

Provides additional subband-wise information for.

,

,

및

는 차동 코드북으로부터 선택된 것들이며,

,

,

,

및

는 서로 다른 시간 구간들에서 피드백된다. T는 시간 도메인 차동 피드백에 있는 차동 스텝들의 개수를 정의한다.

,

,

And

Are selected from the differential codebook,

,

,

,

And

Is fed back in different time intervals. T defines the number of differential steps in the time domain differential feedback.

는 와이드 밴드에서의

를 정제하므로, 주파수 도메인에서의 차동 피드백이 구현되며, 와이드 밴드에서의

와 서브 밴드에서의

가 서로 다른 시간 구간들에서 피드백되므로 시간 도메인에서의 차동 피드백이 구현될 수 있다.Here, embodiments of the present invention may make it possible to operate differential feedback in both the frequency domain and the time domain. That is, in the subband

In the wide band

Since refinement is performed, differential feedback in the frequency domain is realized and

In the subband

Is fed back in different time intervals, so differential feedback in the time domain can be implemented.

9 illustrates basic codewords in the wide band and differential codewords in the subbands.

Example 3

Assume that T = 1. Referring to FIG. 9, the index of the basic codeword A recommended in a given time interval, such as t = 0, is fed back from the receiver to the base station. At this time, at time interval t = 0, the transmitter generates a precoding matrix based on the recommended basic codeword A.

If the recommended basic codeword A fed back in the time interval t = 0 is stable in the time domain, the index of the recommended basic codeword in the time interval t = 1 is not fed back. In time interval t = 1, only the indices of the recommended differential codewords a, b in the subbands to refine the recommended base codeword A are fed back. At this time, the transmitter refines the recommended basic codeword A using each of the differential codewords a and b recommended in each of the subbands, and generates a precoding matrix in each of the subbands.

Even in time interval t = 2, the index of the recommended basic codeword is not fed back. In time interval t = 2, only the indices of the differential codewords c, d in the subbands to refine the recommended base codeword A are fed back. Similar to the above, the transmitter refines the recommended basic codeword A using each of the differential codewords c and d recommended in each of the subbands, and generates a precoding matrix in each of the subbands.

Example 4

However, the recommended differential codewords can continuously refine the basic codeword A, such a case where T is greater than one. These cases are described again below.

If the recommended basic codeword A fed back in the time interval t = 0 is stable in the time domain, the index of the recommended basic codeword in the time interval t = 1 is not fed back. In time interval t = 1, only the indices of the recommended differential codewords a, b in the subbands to refine the recommended base codeword A are fed back. At this time, the transmitter refines the recommended basic codeword A using each of the differential codewords a and b recommended in each of the subbands, and generates a precoding matrix in each of the subbands.

Even in time interval t = 2, the index of the recommended basic codeword is not fed back. In time interval t = 2, only the indexes of the differential codewords c, d in the subbands to refine aA or bA, not the recommended base codeword A, are fed back. Similarly, the transmitter refines aA or bA rather than the recommended base codeword A using each of the differential codewords c and d recommended in each of the subbands, and refines the precoding matrix in each of the subbands. Create

는 서브 밴드에서 생성된 것일 수 있다. 그리고,

는 구조 1에서

를 서브 밴드에서 정제하는 것으로서 또는 구조 2에서

를 서브 밴드에서 정제하는 것으로서, 추가적인 서브 밴드-와이즈 정보를 제공한다.2) Recommended default codeword

May be generated in the subband. And,

In structure 1

In the subband or in structure 2

Is refined in the subbands to provide additional subband-wise information.

,

,

및

는 차동 코드북으로부터 선택된 것들이며,

,

,

,

및

는 시간 도메인에서의 차동 피드백을 위하여 서로 다른 시간 구간들에서 피드백될 수 있다. T는 시간 도메인 차동 피드백에 있는 차동 스텝들의 개수를 정의한다.

,

,

And

Are selected from the differential codebook,

,

,

,

And

May be fed back in different time intervals for differential feedback in the time domain. T defines the number of differential steps in the time domain differential feedback.

,

가 서로 다른 시간 구간에서 피드백된다면,

에 대한 채널 상태 정보와 관련된 추가적인 시간-와이즈 정보를 제공한다. 이러한 케이스에서,

는 시간 구간 t-1에서서브 밴드에 관한 것일 수 있으며,

로 나타내기로 한다.

가 시간 구간 t에서 차동 코드북으로부터 선택되었다면, 해당 서브 밴드에서 시간 구간 t에서의 추천되는 프리코딩 매트릭스는

로 나타낼 수 있다.
For example, if T = 1, there is only one differential feedback.

,

If is fed back in different time intervals,

Provide additional time-wise information related to channel state information for the. In these cases,

May be for the subband in time interval t-1,

It is represented by.

If is selected from the differential codebook in time interval t, then the recommended precoding matrix in time interval t in that subband is

It can be represented as.

3. Correlation Codebook and Recommended Correlation Codeword

는 상관 코드북에 포함된 i 번째 상관 코드워드를 나타내며, 그것은 채널의 상관 특성을 고려한다.

의 사이즈는 Nt x Nt이며,

는 와이드 밴드에서 생성된 것일 수 있으며, 채널의 상관 특성에 관한 롱 텀 정보일 수 있다.

Denotes the i th correlation codeword included in the correlation codebook, which takes into account the correlation characteristics of the channel.

The size of is Nt x Nt,

May be generated in a wide band and may be long term information about a correlation characteristic of a channel.

의 x-root(여기서, x=1/2 또는 1)를 사용할 수 있다. 만약 x=1/2 일 경우

는

의 양자화된 버전으로 보여질 수 있다.

에 따른(along)

의 프로젝션은 롱텀 상관 매트릭스 또는 와이드 밴드 상관 매트릭스의 함수로서 숏텀에서의 채널 상태 정보 또는 서브 밴드에서의 채널 상태 정보를 회전하고, 스케일링할 수 있다.Correlation Matrix of Channel Matrix

X-root (where x = 1/2 or 1) can be used. If x = 1/2

Is

It can be seen as a quantized version of.

Allong

The projection of may rotate and scale channel state information in the short term or channel state information in the subband as a function of a long term correlation matrix or a wide band correlation matrix.

는 서브 밴드에서 추천되는 프리코딩 매트릭스 또는 숏텀에서 추천되는 프리코딩 매트릭스로 볼 수 있으며,

는

의 양자화된 버전으로 선택되는 경우에

는 적응적 프리코딩 매트릭스를 나타낸다. 여기서,

는 아이덴티티 매트릭스로서 선택될 수 있다.therefore,

Is a precoding matrix recommended in the subband or a precoding matrix recommended in the short term.

Is

If chosen as a quantized version of

Denotes an adaptive precoding matrix. here,

May be selected as the identity matrix.

=A라면 구조 2에 있는

가 성립하도록 하는 차동 코드북에 있는 차동 코드워드로서 매트릭스 A를 정의한다. 또한, 구조 1에서

를 정의한다.Embodiments of the present invention described above can be arranged as a table as follows. Where for all t

If = A, structure 2

We define matrix A as the differential codeword in the differential codebook to ensure that. Also, in structure 1

.

Achievable schemes

and

and

Wideband

Recommended precoding matrix in wide band Subband

Recommend Precoding Matrix in Subband

and

Wideband or subband

Adaptive Precoding Matrix According to Adaptive Feedback Mode

, T = 1 and

Wideband

and subband

Is fed back in the same time interval Differential Feedback in Frequency Domain Wideband

and subband

Is fed back in different time intervals Differential Feedback in Both Frequency Domain and Time Domain Subband

and subband

Is fed back in the same time interval Improve the accuracy of feedback Subband

and subband

Is fed back in the same time interval Differential Feedback in Time Domain

with t = 1… T, T> 1 and

Wideband

and subband

Is fed back in different time intervals Differential Feedback in Time Domain Subband

and subband

Is fed back in different time intervals Differential Feedback in Time Domain

with t = 1… T, T> 1 and

Wideband or subband

Combined Adaptive Feedback Mode and Differential Feedback Mode

The methods described above may be embodied in the form of program instructions that may be executed by various computer means and may be recorded in a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the media may be those specially designed and constructed for the purposes of the present invention, 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 devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

10 is a block diagram showing a transmitter according to an embodiment of the present invention.

Referring to FIG. 10, a transmitter according to an embodiment of the present invention includes a memory 1010, a receiver 1020, a precoding matrix generator 1030, and a precoder 1040.

The memory 1010 stores a basic codebook, a differential codebook, and a correlation codebook.

The receiver 1020 may include a basic codeword indicator indicating one of a plurality of basic codewords included in the basic codebook from a receiver, and a differential code indicating one of a plurality of differential codewords included in the differential codebook. A correlation codeword indicator indicating one of a word indicator and a plurality of correlation codewords included in the correlation codebook is received.

The precoding matrix generator 1030 generates a precoding matrix for the receiver by using the basic codeword indicator, the differential codeword indicator, and the correlation codeword indicator.

Precoder 1040 precodes at least one data stream using the generated precoding matrix, and the precoded data stream is transmitted through a plurality of transmit antennas.

1 through 9 may be applied to the transmitter illustrated in FIG. 10 as it is, and thus, a detailed description thereof will be omitted.

11 is a block diagram illustrating a receiver according to an embodiment of the present invention.

Referring to FIG. 11, a receiver according to an embodiment of the present invention includes a channel estimator 1110, a memory 1120, an indicator generator 1130, and a transmitter 1140.

The channel estimator 1110 estimates a channel from a transmitter to a receiver by using a pilot.

The memory 1120 stores a basic codebook, a differential codebook, and a correlation codebook.

The indicator generator 1130 may include a basic codeword indicator indicating one of a plurality of basic codewords included in the basic codebook based on the estimated channel, and any one of a plurality of differential codewords included in the differential codebook. A differential codeword indicator indicating one and a correlation codeword indicator indicating one of a plurality of correlation codewords included in the correlation codebook are generated.

The indicators are fed back to the transmitter via the transmitter 1140.

1 to 9 may be applied to the receiver illustrated in FIG. 10 as it is, so a detailed description thereof will be omitted.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

1010: memory
1020: receiver
1030: precoding matrix generator
1040: precoder

Claims (15)

In the method of communication of a transmitter in a multiple input multiple output (MIMO) communication system,
Accessing a memory in which a basic codebook, a differential codebook, and a correlation codebook are stored;
A basic codeword indicator indicating any one of a plurality of basic codewords included in the basic codebook from a receiver, a differential codeword indicator indicating any one of a plurality of differential codewords included in the differential codebook, and the correlation Receiving a correlation codeword indicator indicating any one of a plurality of correlation codewords included in the codebook; And
Generating a precoding matrix for the receiver using the basic codeword indicator, the differential codeword indicator and the correlation codeword indicator
Communication method of the transmitter comprising a. The method of claim 1,
Generating a precoding matrix for the receiver
Refine the basic codeword indicator using the differential codeword indicator; And
Inner-product each other with the base codeword indicator and the refined base codeword indicator to generate a precoding matrix for the receiver.
Communication method of the transmitter comprising a. The method of claim 1,
The differential codeword indicator indicates a difference in time domain for the base codeword indicator or a difference in frequency domain for the base codeword indicator, and the correlation codeword indicator indicates a correlation of a channel between the transmitter and the receiver. A method of communication of a transmitter indicative of a correlation. The method of claim 1,
When the differential codeword indicator is fixed to a preset matrix and the correlation codeword indicator is fixed to a preset matrix, the basic codeword indicator is configured to include the plurality of basic codewords in a wide band including a plurality of subbands. Or any one of the plurality of basic codewords in a corresponding subband of the plurality of subbands. The method of claim 1,
The differential codeword indicator is fixed to a predetermined matrix, and the basic codeword indicator is any one of the plurality of basic codewords in a wide band including a plurality of subbands or a corresponding one of the plurality of subbands. If instructed to:
Generating a precoding matrix for the receiver
Adaptively adjusting a precoding matrix for the receiver using the correlation codeword indicator
Communication method of the transmitter comprising a. The method of claim 1,
The correlation codeword indicator is fixed to a predetermined matrix, and the basic codeword indicator selects one of the plurality of basic codewords in a corresponding subband among a wide band or a plurality of subbands including a plurality of subbands. And the differential codeword indicator indicates any one of the plurality of differential codewords in a corresponding subband of the plurality of subbands.
Generating a precoding matrix for the receiver
Refine the base codeword indicator using the differential codeword indicator to generate a precoding matrix for the receiver
Communication method of the transmitter comprising a. The method of claim 1,
The basic codeword indicator indicates any one of the plurality of basic codewords in a corresponding subband among a wide band or a plurality of subbands including a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands. Indicates one of the plurality of differential codewords in a corresponding subband of bands,
Receiving the basic codeword indicator, the differential codeword indicator and the correlation codeword indicator is
Receiving the basic codeword indicator and the differential codeword indicator in the same time interval,
Generating a precoding matrix for the receiver
Refine the base codeword indicator in the frequency domain using the differential codeword indicator to generate a precoding matrix for the receiver
Communication method of the transmitter comprising a. The method of claim 1,
The basic codeword indicator indicates any one of the plurality of basic codewords in a wide band including a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands in a corresponding subband of the plurality of subbands. Indicates any one of the differential codewords,
Receiving the basic codeword indicator, the differential codeword indicator and the correlation codeword indicator is
Receiving the basic codeword indicator and the differential codeword indicator in different time intervals,
Generating a precoding matrix for the receiver
Refine the base codeword indicator in both time and frequency domains using the differential codeword indicator to generate a precoding matrix for the receiver
Communication method of the transmitter comprising a. The method of claim 1,
The base codeword indicator indicates any one of the plurality of base codewords in a corresponding subband of a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands in a corresponding subband of the plurality of subbands. Indicates any one of the differential codewords,
Receiving the basic codeword indicator, the differential codeword indicator and the correlation codeword indicator is
Receiving the basic codeword indicator and the differential codeword indicator in the same time interval,
Generating a precoding matrix for the receiver
Refine the base codeword indicator in the frequency domain using the differential codeword indicator to generate a precoding matrix for the receiver
Communication method of the transmitter comprising a. The method of claim 1,
The base codeword indicator indicates any one of the plurality of base codewords in a corresponding subband of a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands in a corresponding subband of the plurality of subbands. Indicates any one of the differential codewords,
Receiving the basic codeword indicator, the differential codeword indicator and the correlation codeword indicator is
Receiving the basic codeword indicator and the differential codeword indicator in different time intervals,
Generating a precoding matrix for the receiver
Refine the base codeword indicator in the time domain using the differential codeword indicator to generate a precoding matrix for the receiver
Communication method of the transmitter comprising a. The method of claim 6,
Receiving the basic codeword indicator, the differential codeword indicator and the correlation codeword indicator is
Sequentially receiving two or more differential codeword indicators for one basic codeword indicator
Communication method of the transmitter comprising a. In the method of communication of a receiver in a multiple input multiple output (MIMO) communication system,
Estimating a channel between the transmitter and the receiver;
Accessing a memory in which a basic codebook, a differential codebook, and a correlation codebook are stored;
A basic codeword indicator indicating one of a plurality of basic codewords included in the basic codebook based on the estimated channel, and a differential code indicating any one of a plurality of differential codewords included in the differential codebook Generating a correlation codeword indicator indicating one of a word indicator and a plurality of correlation codewords included in the correlation codebook; And
Transmitting the basic codeword indicator, the differential codeword indicator, and the correlation codeword indicator to the transmitter.
Communication method of the receiver comprising a. The method of claim 12,
The basic codeword indicator indicates any one of the plurality of basic codewords in a corresponding subband among a wide band or a plurality of subbands including a plurality of subbands, and the differential codeword indicator indicates the plurality of subbands. And a communication method of a receiver indicating one of the plurality of differential codewords in a corresponding subband of bands. The method of claim 12,
At least one of the differential codeword indicator or the correlation codeword indicator is fixed to a predetermined matrix. A computer-readable recording medium having recorded thereon a program for performing the method of claim 1.

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