KR20120043597A - Method for transmitting channel information, transmission method and apparatus thereof - Google Patents

Abstract

PURPOSE: A channel information transmission method, transmission method, and apparatuses thereof are provided to improve spectral efficiency by effectively predicting the degradation of channel quality. CONSTITUTION: A channel information creation unit(530) creates channel information including channel quality information for channel state information and channel quality for a pre-coding matrix corresponding to the estimated channel. The channel quality uses the biggest values in interferences of other terminals. The interference of other terminal is used for the pre-coding matrix. A feedback unit(540) gives the created channel information as feedback.

Description

Method for transmitting channel information of a device, method of transmitting a device, devices thereof {Method for Transmitting Channel Information, Transmission Method and Apparatus}

The present specification relates to a wireless communication system, and relates to a wireless communication system using a multiple input multiple output antenna (MIMO) at both a transmitting and receiving end.

As communication systems have evolved, consumers, such as businesses and individuals, have used a wide variety of wireless terminals.

Currently, wireless communication systems such as 3GPP, Long Term Evolution (LTE), and LTE-A (LTE Advanced) are high-speed, high-capacity communication systems that can transmit and receive various data such as video and wireless data beyond voice-oriented services. In addition to the development of technology capable of transmitting large amounts of data comparable to wired communication networks, it was necessary to improve the system performance by minimizing the reduction of information loss and increasing the system transmission efficiency.

In order to solve the demand for high-speed information transmission, a modern communication system uses a transmission and reception technique using a multiple input multiple output antenna (MIMO) at both a transmitting and receiving end. The MIMO communication system has a structure in which each terminal receives or transmits a signal to one or more base stations connected thereto, and each terminal reports information on a forward channel to the base station to help the base station transmit information.

In an embodiment, an estimating step of estimating a channel by receiving a reference signal in a wireless communication system; When using channel state information for a precoding matrix corresponding to the estimated channel and using one of the other precoding matrices of a subset to which the precoding matrix belongs to the other terminal and using the precoding matrix for itself. Generating channel information including channel quality information on channel quality using the largest value among the interferences of other terminals calculated; And transmitting a channel information generated in the channel information generation step to the air.

In another aspect, another embodiment includes a channel estimator for estimating a channel by receiving a reference signal in a wireless communication system; When using channel state information for a precoding matrix corresponding to the estimated channel and using one of the other precoding matrices of a subset to which the precoding matrix belongs to the other terminal and using the precoding matrix for itself. A channel information generator for generating channel information including channel quality information on channel quality using the largest value among the interferences of other terminals calculated; And a feedback unit for feeding back the generated channel information.

In another aspect, another embodiment provides a channel state information for a precoding matrix from at least one terminal and a subset of the subset to which the precoding matrix belongs for itself and to which other precoding matrix belongs. Select one of SU-MIMO transmission or MU-MIMO transmission using channel information including channel quality information on channel quality using the largest value among interferences of other terminals calculated when using one of the precoding matrices. A scheduler for selecting at least one terminal according to the selected transmission mode and generating a precoding matrix for the terminal; A precoder for precoding a data symbol for the terminal using the precoding matrix; And an antenna array comprising two or more antennas for propagating the precoded symbols to the air.

In another aspect, another embodiment provides channel state information for a precoding matrix from at least one terminal and another pre-set of the subset that uses the precoding matrix for itself and belongs to the other for the other terminal. Select one of the SU-MIMO transmission or the MU-MIMO transmission using the channel information including the channel quality information on the channel quality using the largest value among the interferences of other terminals calculated when using one of the coding matrices. A terminal selection step of selecting at least one terminal according to a selected transmission mode and generating a precoding matrix for the terminal; A precoding step of precoding a data symbol for the terminal by using the precoding matrix; And a transmitting step of propagating a precoded symbol to the air through an antenna array including two or more antennas.

1 is a diagram schematically illustrating a wireless communication system to which embodiments are applied.
2 shows that a base station transmits a reference signal to terminals in a wireless communication system.
3 illustrates transmission of channel state information and channel quality information by a terminal to a base station in a wireless communication system according to an embodiment.
FIG. 4 is a configuration diagram of each terminal and base station when the base station drives SU-MIMO and MU-MIMO in the configuration of the base station and terminals of FIGS. 2 and 3.
5 is a functional block diagram of a channel information feedback apparatus according to an embodiment in a MIMO system.
6 is a block diagram of the channel information generation unit of FIG. 5.
7 is a flowchart illustrating a channel state information feedback method according to another embodiment in a MIMO system.
8 is a flowchart of an example of a method of generating channel state information according to another embodiment.
9 is a block diagram of a base station according to another embodiment.
10 is a flowchart illustrating a method of transmitting a base station according to another embodiment.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In addition, in describing the component of this invention, terms, such as 1st, 2nd, A, B, (a), (b), can be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. If a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected to or connected to that other component, but there may be another configuration between each component. It is to be understood that the elements may be "connected", "coupled" or "connected".

1 illustrates a wireless communication system to which embodiments are applied.

Wireless communication systems are widely deployed to provide various communication services such as voice and packet data.

Referring to FIG. 1, a wireless communication system includes a user equipment (UE) 10 and a base station 20 (BS).

Terminal 10 in the present specification is a generic concept that means a user terminal in wireless communication, WCDMA, UE (User Equipment) in LTE, HSPA, etc., as well as MS (Mobile Station), UT (User Terminal) in GSM ), SS (Subscriber Station), wireless device (wireless device), etc. should be interpreted as including the concept.

The terminal 10 may perform feedback of channel information including channel state information and channel quality information described below, and provide an apparatus thereof.

A base station 20 or a cell generally refers to a fixed station communicating with the terminal 10 and includes a Node-B, an evolved Node-B, and a Base Transceiver. It may be called other terms such as a System, an Access Point, a Relay Node, and the like.

The base station 20 may receive channel information including channel state information and channel quality information from the terminal 10 and transmit data or signals using the channel information.

That is, in the present specification, the base station 20 or the cell should be interpreted in a comprehensive sense to indicate some areas covered by the base station controller (BSC) in the code division multiple access (CDMA), the NodeB of the WCDMA, and the like. It is meant to encompass various coverage areas such as megacell, macrocell, microcell, picocell, femtocell and relay node communication range.

In the present specification, the terminal 10 and the base station 20 are two transmitting and receiving entities used to implement the technology or technical idea described in the present specification and are used in a comprehensive sense and are not limited by the terms or words specifically referred to. .

There is no limitation on the multiple access scheme applied to the wireless communication system. Various multiple access techniques such as Code Division Multiple Access (CDMA), Time Division Multiple Access (TDMA), Frequency Division Multiple Access (FDMA), Orthogonal Frequency Division Multiple Access (OFDMA), OFDM-FDMA, OFDM-TDMA, OFDM-CDMA Can be used.

A TDD (Time Division Duplex) scheme in which uplink and downlink transmissions are transmitted using different time periods, or an FDD (Frequency Division Duplex) scheme in which they are transmitted using different frequencies can be used.

One embodiment may be applied to asynchronous wireless communication evolving into Long Term Evolution (LTE) and LTE-advanced through GSM, WCDMA, HSPA, and synchronous wireless communication evolving to CDMA, CDMA-2000 and UMB. The present invention should not be construed as being limited or limited to a specific wireless communication field, but should be construed as including all technical fields to which the spirit of the present invention can be applied.

The wireless communication system to which the embodiments are applied may support uplink and / or downlink HARQ (HARQ), and may use CQI (channel quality indicator) for link adaptation. In addition, multiple access schemes for downlink and uplink transmission may be different. For example, downlink uses Orthogonal Frequency Division Multiple Access (OFDMA), and uplink uses Single Carrier-Frequency Division Multiple Access (SC-FDMA). ) Is the same as can be used.

In order to support high-speed information transmission to a large number of users, a wireless communication system uses a single user multiple input multiple output (SU-MIMO) technique that transmits information to a user through a specific band using multiple antennas. Consideration is given to the selective use of the Multiple User Multiple Input Multiple Output (MU-MIMO) technique, which uses multiple antennas to simultaneously transmit information over the same band to multiple users. MU-MIMO allows two users to share a band when two or more user terminals have a high channel propagation gain for the same band, thus gaining channel propagation gain in addition to gaining more users using a wider band. It is possible to use this good band to improve the overall spectral efficiency.

Meanwhile, to implement an effective MIMO system, a precoder based on channel information may be used. To this end, the terminal 10 needs to identify a channel state and notify the base station 20 of the channel state.

The terminal 10 transmits channel information based on a method in which the terminal 10 directly reports the channel information to the base station 20 (explicit feedback method), and a precoder method or a precoding matrix based on the channel information. The terminal 10 may be largely classified into an implicit feedback determined by the terminal 10 and notified to the base station 20. Closed loop precoding may be possible with less overhead compared to the former (explicit feedback).

In order to smoothly control user-interference when implementing MU-MIMO while using this closed-loop precoding method, implicit feedback of precoder usage based on channel information is provided, but multiple access is performed. You can also implicitly feed back information to support).

Although a wireless communication system to which the above embodiments are applied has been described, a process of exchanging channel information with reference signals by a base station and a terminal in the wireless communication system will now be described with reference to FIGS. 2 and 3.

2 shows that a base station transmits a reference signal to terminals in a wireless communication system. 3 illustrates transmission of channel state information and channel quality information by a terminal to a base station in a wireless communication system according to an embodiment.

Referring to FIGS. 2 and 3, the wireless communication system 100 is the same as the wireless communication system of FIG. 1, and includes at least one terminal, for example, n terminals that exist in the base station 120 and the base station 120. 110, UE0 to UEn-1). These terminals 110 may be terminals currently connected or attempting further access.

Referring to FIG. 2, in order to transmit and receive data between the terminal 110 and the base station 120, the sender side base station 120 transmits a reference signal 230, and the receiver side terminal 110 receives the reference signal. The propagation channel or the frequency domain channel may be estimated using 230. For example, the terminal 110 may estimate the downlink channel during downlink transmission. In particular, during OFDM transmission, the terminal 110 may estimate an complex channel of each subcarrier. In contrast, the base station 120 may estimate the uplink channel during uplink transmission.

Specific signals or symbols can be inserted at regular or irregular intervals in the frequency-domain grid for estimation of the frequency domain channel. In this case, the specific signal or symbol is variously named as a reference signal, a reference symbol, a pilot symbol, etc., but in this specification, the specific signal or symbol is referred to as a reference signal, but is not limited to the term. Do not. Of course, the reference signal 230 may not be used only for the estimation of the frequency domain channel, but may be used for position estimation, control information transmission, transmission and reception of scheduling information, and transmission and reception of feedback information required in a wireless communication process between a terminal and a base station.

Different types of reference signals exist in downlink or uplink transmission, and new reference signals are defined and discussed for various purposes. For example, reference signals in uplink transmission include DM-RS (Demodulation RS) and SRS (Sounding RS). Reference signals in downlink transmission include CRS (Cell-specific RS), MBSFN RS, UE-specific RS. In addition, there is a channel state index-reference signal (CSI-RS) as a reference signal transmitted from a base station to obtain channel state information (CSI) in the terminal 20 during downlink transmission. The CQI (Channel Quality Indicator) / PMI (Precoder Matrix Indicator) / RI (Rank Indicator) is used for reporting.

Referring to FIG. 3, each terminal 110 receives a reference signal 230 and estimates a channel. Thereafter, each terminal 110 feeds back channel information 330 to the base station 120. In this case, the channel information includes channel state information which is information on a propagation channel for the terminal itself, and channel quality information which is information about measured or calculated channel capacity or channel quality. Meanwhile, the channel information may include a channel rank or RI (Rank Indicator) which is information on the number of layers used for downlink transmission in a terminal.

In this case, the channel state information includes information on a UE's own precoding (called "precoding" or "PC") suitable for the estimated channel, for example, an index or identification information about a precoding matrix (PMI). It may include. For example, in the case of MIMO allowing simultaneous access of n terminals, each of the n terminals 110 may feed back channel state information, for example, PMI, to the base station 120.

In addition, each terminal 110 measures the channel capacity (channel capacity) or channel quality (channel quality) of its downlink propagation channel using a reference signal, the base station 120 as a first channel quality information You can report to

The period or frequency resolution used by each terminal 110 to report the first channel quality information may be adjusted by the base station 120. Periodic or aperiodic first channel quality information reporting may be supported in the time base or time domain. Physical Uplink Control Channel (PUCCH) may be used for periodic first channel quality information reporting and Physical Uplink Shared Channel (PUCCH) may be used for aperiodic first channel quality information reporting. And vice versa. In the latter case, the base station 120 may instruct the terminal to report the individual first channel quality information embedded in the scheduled resource during uplink data transmission.

The aperiodic first channel quality information report on the PUSCH may be scheduled by the base station 120. The type of aperiodic first channel quality information report may be configured by the base station 120 by RRC signaling.

If the base station 120 wants to receive periodic reports of the first channel quality information, the terminal 110 may report using the PUCCH. The type of periodic first channel quality information report may be configured by the base station 120 by RRC signaling.

In addition, each terminal 110 calculates channel capacity or channel quality of the downlink propagation channel when the terminal itself and another terminal are multi-accessed to the base station 120, and calculates the calculated value in the second channel. The quality information may be reported to the base station 120.

Each terminal 110 is information about precoding of another terminal that is expected to have the least amount of interference received by each terminal when transmitting a signal according to channel state information received from the terminal 110 by the base station 120 (Best Companion). Indicator, BCI) or vice versa, when other UEs that report information about precoding (Worst Companion Indicator (WCI)) that are expected to be most likely and use a PMI that matches this BCI or WCI are connected together (BCIn = PMIm, n means the terminal itself, and m means another terminal) to calculate channel performance or channel quality and report it as second channel quality information. Alternatively, each terminal 110 selects an orthogonal subset with orthogonal precoding matrices as described below with reference to FIGS. 4 and 5, and the terminals reporting channel state information included in the orthogonal subset are connected together. The representative value representing the channel performance or the channel quality in the case of the second channel quality information. The latter method does not report BCI or WCI when compared to the former method as described below, so that channel information can be reported with smaller feedback overhead, and if the orthogonal subset is small, the former method does not report BCI or WCI. Performance can be achieved according to the method. However, in order to guarantee the performance of the latter method, it is necessary to select second channel quality information representative of channel quality in multiple access.

In other words, each terminal 110 configures subsets or orthogonal subsets of precoding matrices, respectively, without reporting BCI or WCI in order to minimize feedback overhead, and configures channel state information included in the orthogonal subset. A representative value representing channel performance or channel quality when the reported terminals are connected together may be reported as second channel quality information.

The manner in which each terminal 110 reports the second channel quality information to the base station 120 may be the same as or substantially the same as the manner in which each terminal 110 reports the first channel quality information to the base station 120. Can be.

The base station 120 determines the SU-MIMO transmission or the MU-MIMO transmission based on the channel information 330 including the channel state information and the channel quality information reported from each terminal 110 and selects the terminals. . In detail, the base station 120 includes terminals corresponding to an orthogonal subset having the same PMI among the terminals connected to the base station 120, and the first channel quality information and the second channel quality information of the terminals transmit MU-MIMO transmission. If acceptable, the MU-MIMO transmission may be determined; otherwise, the SU-MIMO transmission may be determined.

The base station 120 selects one terminal when determining the SU-MIMO transmission. Meanwhile, when determining MU-MIMO transmission, the base station 120 selects terminals by comparing the channel state information reported from each terminal 110 with the channel information 330 including the channel quality information.

The base station 120 forms a downlink channel with the selected terminal 110 and communicates with the selected terminal 110 through the downlink channel.

In the above-described wireless communication system, a process of exchanging channel information with reference signals by a base station and a terminal has been described. Hereinafter, a configuration of each of the base station and terminals will be described with reference to FIG. 4 and with reference to FIG. The channel information feedback apparatus according to the present invention will be described.

FIG. 4 is a configuration diagram of each terminal and base station when the base station drives SU-MIMO and MU-MIMO in the configuration of the base station and terminals of FIGS. 2 and 3.

Referring to FIG. 4, each of the terminals 410 includes a receiving antenna array 411, a post-decoder 412, and a channel information feedback device 414 that receive signals from the air. The base station 420 includes a reference signal generator 421 for generating a reference signal, a precoder 422 for precoding data symbols using a precoding matrix, and a transmission antenna for transmitting the precoded signal on air. An array 428, and a scheduler 426 that manages them.

Receive antenna array 411 may include at least one antenna, for example four antennas. In this case, the reception antenna array 411 is conceptually described as being for reception, but may be used for transmission or transmission.

Post decoder 412 processes the received signal and decodes it into the original data symbols using the precoding matrix. Post decoder 412 corresponds to precoder 422 of base station 420. The post decoder 412 may transfer the received reference signal to the channel information feedback device 414 to help generate feedback information.

The channel information feedback device 414 may receive the reference signal and estimate the channel using the reference signal. The channel information feedback device 414 may generate channel information including channel state information and channel quality information. Meanwhile, the channel information feedback device 414 may feed back the channel information to the base station 420.

For example, the channel information feedback device 414 selects an index (PMI) of the terminal's own precoding matrix suitable for the channel estimated by the channel state information from the codebook stored by the terminal, and then selects the base station 420, specifically, the preamble. Feedback may be made to the coder 422. Specifically, in the case of MIMO allowing simultaneous access of n terminals, each of the n terminals 410 may feed back channel state information to the base station 420.

For example, in an environment using a two-stage precoder, the channel information feedback device 414 may include a first index of a terminal's own precoding matrix suitable for a channel estimated for a specific frequency band with first channel state information. The first PMI may be selected from a codebook stored by the terminal and may be fed back to the base station 420, specifically, the precoder 422 at a short feedback interval. On the other hand, the channel information feedback device 414 in the codebook that the terminal itself stores a second index (second PMI) for the terminal's own precoding matrix suitable for the channel estimated for the wideband or full band as the second channel state information. It can be selected and fed back to the precoder 422 at a long feedback interval.

In addition, the channel information feedback apparatus 414 may measure channel capacity or channel quality using a reference signal, and report the measured value to the base station 420 as first channel quality information. have.

In addition, the channel information feedback apparatus 414 may configure subsets or orthogonal subsets of precoding matrices having correlations between the precoding matrices, for example, orthogonality. For example, when performing rank 1 MIMO downlink transmission using a codebook suggested by LTE Rel-8 (LTE Release-8), the channel information feedback apparatus 414 may use {0, 1, 2 as shown in Table 1 below. , 3}, {4,5,6,7}, {8,9,10,11}, and {12,13,14,15} may be selected as orthogonal subsets.

The channel information feedback device 414 calculates channel capacity or channel quality when the terminal itself and another terminal are connected to the base station 420, and converts the calculated value into second channel quality information. Report to base station 420. In detail, the channel information feedback apparatus 414 uses a precoding matrix corresponding to PMI which is channel state information, and another terminal uses another precoding matrix of an orthogonal subset to which the precoding matrix corresponding to PMI belongs. When multi-access or simultaneous access to 420, the channel capacity (channel capacity) or channel quality (channel quality) of the downlink propagation channel can be calculated, and the calculated value can be reported to the base station 420 as the second channel quality information. have.

Meanwhile, the interference used when calculating the second channel quality information may use a worst value of interferences among the interferences of other terminals, and an average or interference (average of interferences) or the sum of interferences of other terminals. summation of interferences may be used.

In order to minimize the feedback overhead, the channel information feedback device 414 is another terminal that the base station 420 is expected to have the least amount of interference received by each terminal upon signal transmission according to the channel state information fed back from the terminal 410. The information on the precoding (Best companion indicator) or, conversely, the multi-connection information, which is information about the precoding of the other terminal (Worst companion indicator) which is expected to be the most, may not be fed back to the base station 120.

That is, each of the n terminals 410 uses a precoding matrix corresponding to PMI, which is its channel state information, and uses another precoding matrix of an orthogonal set to which the precoding matrix corresponding to PMI used by another UE belongs. When multiple accesses or simultaneous accesses to the base station 420 may be reported to the base station 420 as second channel quality information obtained by calculating channel capacity or channel quality of the downlink propagation channel.

Referring back to FIG. 4, the base station 420 pre-codes the reference signal generator 421 for generating the reference signal, the precoder 422 for precoding the data symbols using the precoding matrix, and the precoded signal in the air ( transmit antenna array 428 for transmitting on air, and a scheduler 426 for managing them.

The reference signal generator 421 may generate downlink reference signals, for example, a CSI-RS. Reference signals generated by the reference signal generator 421 may be transmitted to the air through the transmission antenna array 428.

The precoder 422 may perform precoding of data symbols by using a precoding matrix corresponding to the channel state information fed back from each terminal 410.

The transmit antenna array 428 may include at least one antenna, for example four antennas. In this case, although the transmission antenna array 428 is conceptually described as being for transmission, it may be used for reception.

The scheduler 426 of the base station 420 transmits SU-MIMO or MU-MIMO based on channel information including channel state information and channel quality information reported from the channel state feedback device 414 of each terminal 410. Determine and select the terminals. In more detail, the scheduler 426 includes terminals corresponding to an orthogonal subset having the same PMI among the terminals connected to the base station 420, and the first channel quality information and the second channel quality information of the terminals transmit MU-MIMO transmission. If acceptable, the MU-MIMO transmission may be determined; otherwise, the SU-MIMO transmission may be determined.

Meanwhile, the scheduler 426 selects one terminal when determining the SU-MIMO transmission. When the MU-MIMO transmission is determined, the scheduler 426 selects / selects terminals by comparing the channel status information reported from each terminal 410 with the channel information including the channel quality information.

The scheduler 426 may generate precoding matrices of the selected one or more terminals. As a result, the precoder 422 may precode the data symbols using the precoding matrices provided from the scheduler 426.

A detailed process of selecting / selecting the SU / MU-MIMO transmission mode and terminals by the scheduler 426 will be described in more detail when the base station or the base station apparatus is described with reference to FIGS. 9 and 10.

5 is a functional block diagram of a channel information feedback apparatus according to another embodiment in a MIMO system.

Referring to FIG. 5, the channel information feedback device 414 may be implemented in hardware or software in a currently connected UE or an additional access UE attempting additional access, but is not limited thereto. May be implemented.

The channel information feedback apparatus 414 according to an embodiment largely includes a reference signal from a base station, for example, a channel state index-reference signal (CSI-RS), a common reference signal (CRS), and a demodulation (DM-RS). A reference signal receiver 510 for receiving a reference signal, a channel estimator 520 for estimating a channel using the received reference signal, and a channel corresponding to the channel estimation result of the channel estimator 520 And a channel information generator 530 for generating information and a feedback unit 540 for feeding back the generated channel information.

The reference signal receiver 510 and the channel estimator 520 may be implemented separately or integrated, and may be integrated in some cases.

For example, the CSI-RS is described below as a reference signal. However, the present invention is not limited thereto and any other reference signal may be used.

The reference signal receiver 510 receives a cell-specific CSI-RS and has a time-frequency because it has information on which band (which subcarrier) and which symbol (Symbol) the CSI-RS is received. By determining the signal of the region, the CSI-RS reception value can be measured.

The CSI-RS is a reference signal transmitted by the base station so that the terminal can estimate the downlink channel.

The channel estimator 520 may function to estimate a channel using the received CSI-RS. Channel estimation of the channel estimation unit 520 is performed as follows.

은 수신된 CSI-RS 수신값, H은 전파 채널(propagation channel),

은 전송된 CSI-RS 송신값, 그리고

은 가우시안 잡음이다.The received value of the CSI-RS received by the reference signal receiver 510 is equal to Equation 1 below,

Is a received CSI-RS received value, H is a propagation channel,

Is the transmitted CSI-RS transmission value, and

Is Gaussian noise.

는 위와 같은 측정에 의하여 알 수 있고, CSI-RS 송신값인

은 기지국과 단말 사이에 이미 알려진 값이므로, 통상적인 채널 추정 기법을 이용하여 전파 채널(propagation channel)인 H을 추정할 수 있다. 채널추정부(520)의 채널 추정 결과인 전파 채널(propagation channel) H는 채널 행렬(Channel matrix) 또는 공분산 행렬(covariance matrix)일 수 있다. The CSI-RS received value received above

Can be known by the above measurement, and the CSI-RS transmission value

Since is a known value between the base station and the terminal, it is possible to estimate the propagation channel H using a conventional channel estimation technique. The propagation channel H, which is a channel estimation result of the channel estimation unit 520, may be a channel matrix or a covariance matrix.

In addition, the channel estimator 520 may estimate the long term / wideband statistic property of the propagation channel H , which is a channel estimation result, at regular intervals. For example, the statistical characteristic may be an average value of the channel matrix for a predetermined time or may be a channel correlation matrix R expressed by Equation 2 below.

In Equation 2, E denotes the average of the product of the Hermitian matrix formed by the product of the channel matrix and the channel matrix with the conjugate transposition, where N is the number of channel matrices considering the statistical characteristics for a certain time. Means.

Next, the channel information generation unit 530 may calculate channel state information based on a propagation channel H or a long term / wideband statistic property, for example, a channel correlation matrix R, that is a channel estimation result of the channel estimation unit 520. Can be generated.

In addition, the channel information generation unit 530, as described above, has a correlation between precoding matrices, for example, orthogonal precoding matrices, {0, 1, 2, 3}, {4,5, as shown in Table 1 below. Subsets or orthogonal subsets, respectively, such as, 6,7}, {8,9,10,11}, and {12,13,14,15}.

Although elements of the channel information feedback apparatus according to the embodiment are described in the MIMO system, the channel information generation unit, which is one of the elements of the channel information feedback apparatus according to the embodiment in the MIMO system, is described with the channel state information. The operation of generating channel quality information is described in detail.

6 is a block diagram of the channel information generation unit of FIG. 5.

The channel information generation unit 530 is determined by the PC-PDC retrieval unit 532 and the PC-PDC retrieval unit 532 for searching for an optimal precoder and post decoder based on the estimation result of the channel estimator 520. And a channel state information generator 534 for generating channel state information based on the optimal precoder and post decoder information, and a channel quality information generator 536 for generating channel quality information.

The PC-PDC search unit 532 performs an optimal precoder and post decoder search based on the estimation result of the channel estimator 520, and uses an optimal precoding method or a precoder (PC) using various precoding techniques. ), An optimal post decoding scheme or post decoder (PDC) can be determined.

The PC-PDC retrieval unit 532 may obtain optimal precoder information (precoding matrix) based on a propagation channel or a long term / wideband statistic property estimated by the channel estimator 520. The post decoder can be estimated based on the retrieved precoder information.

The channel state information generator 534 generates a precoding matrix indicator (PMI), which is an index of the above-described precoding matrix, based on the precoder information and the post decoder estimated by the PC-PDC searcher 532. On the other hand, in an environment using a two-stage precoder, the channel state information generation unit 534, as described above, for the terminal's own precoding matrix suitable for the channel estimated for the specific frequency band as the first channel state information. The first index (first PMI) is selected from the codebook stored by the terminal itself, and the second index (second PMI) for the terminal's own precoding matrix suitable for the channel estimated for the wideband or the entire band as the second channel state information. The terminal may select from a codebook stored by itself.

Meanwhile, the channel quality information generator 536 may measure the channel quality of the terminal n represented by Equation 3 based on the precoder information and the post decoder estimated by the PC-PDC searcher 532.

는 노이즈 성분이다.

은 행렬 X의 각 성분들의 전력(element power)의 합이다. In this case, Fn is a post decoder or post-decoding matrix or receiver filtering corresponding to the precoding matrix of UE n, H is a propagation channel, and Wn is a channel reported by UE n. Precoding matrix corresponding to state information.

Is a noise component.

Is the sum of the element powers of the components of the matrix X.

The channel quality information generation unit 5355 may generate the measured channel quality itself as the first channel quality information, but the information volume may be increased. Accordingly, the channel state information generator 535 may quantize the measured channel quality to generate the first CQI, which is an index corresponding to the quantized channel quality, as the first channel quality information.

The period or frequency resolution used by the terminal to report the first CQI may be adjusted by the base station. Periodic or aperiodic first CQI reporting may be supported in the time base or time domain. Physical Uplink Control Channel (PUCCH) may be used for periodic 1CQI reporting and Physical Uplink Shared Channel (PUSCH) may be used for aperiodic 1CQI reporting and vice versa. . In the latter case, the base station may indicate to the terminal individual CQI report embedded in the scheduled resource during uplink data transmission.

The first CQI reporting mode may be a wideband CQI, an e-Node B configured subband feedback, or a UE configured subband feedback.

An aperiodic first CQI report on the PUSCH may be scheduled by the base station. The type of aperiodic first CQI report may be configured by RRC signaling by the base station. The type of aperiodic first CQI reporting is a difference between the CQI value and the wideband CQI calculated for each subband calculated assuming that only the relevant subbands are transmitted together with the wideband CQI reporting the one wideband CQI value for the entire system band and the wideband CQI. A value (2 bits) may be a difference value (2 bits) between one CQI value and a wideband CQI reflecting an average of M subbands selected by the UE within the entire system band.

If the base station wants to receive the periodic report of the CQI, the terminal may report using the PUCCH. In this case, only one CQI value reflecting the average of the M subbands selected by the wideband CQI and the UE and the difference value (2 bits) of the wideband CQI may be possible in the periodic CQI reporting. The type of periodic 1CQI report may be configured by RRC signaling by the base station.

Hereinafter, assuming that the first CQI, which is the first channel quality information, is transmitted only in an associated subband together with an aperiodic wideband CQI, the difference between the calculated CQI and the wideband CQI for each subband (Subband differential CQI offset level) = subband CQI index-wideband CQI index (2 bits), but the present invention is not limited thereto and may be any type of report of periodic or aperiodic. In this case, a subband differential CQI value of the first CQI may be as shown in Table 2.

Subband differential CQI value Offset level 0 0 One One 2 ≥2 3 ≤-1

 As described above, the channel quality information generation unit 536 has correlations between the precoding matrices, for example, the precoding matrices having orthogonality, as shown in Table 1, as shown in Table 1, {0, 1, 2, 3}, {4,5, 6,7}, {8,9,10,11}, and {12,13,14,15}, respectively, to configure subsets or orthogonal subsets.

The channel quality information generation unit 536 generates a second CQI (also referred to as a delta-CQI) corresponding to the channel quality of the terminal when the terminal itself and another terminal are multiplexed with the base station 420 by using the aforementioned second channel quality information. can do.

Hereinafter, the second CQI, which is the second channel quality information, will be described as a difference value (2 bits) between the calculated CQI and the wideband CQI for each subband calculated on the assumption that the second CQI is transmitted only in the associated subband together with the aperiodic wideband CQI. It is not limited to this and may be any type of report, periodic or aperiodic.

The second CQI informs the base station of the decrease in channel quality due to the switching from SU-MIMO to MU-MIMO. The base station may determine the information reception rate of each terminal during the selection of the SU / MU-MIMO mode and the MU-MIMO based on the second CQI.

When using a single precoder, the second CQI may be calculated in the following manner.

일 수 있다. 이때 Fn은 단말 n의 프리코딩 행렬에 대응하는 포스트 디코더 또는 포스트 디코딩 행렬(post-decoding matrix) 또는 수신측 필터링(receiver filtering)을 수행하는 행렬이며 H는 전파 채널이며

은 단말 n이 보고한 채널상태정보, 예를 들어 PMI와 동일한 직교서브세트에 해당하는 프리코딩 행렬들 중 하나이며,

은 행렬 X의 각 성분들의 전력(element power)의 합이다. The expected interference of terminal n is

Can be. In this case, Fn is a post decoder or post-decoding matrix or receiver filtering corresponding to the precoding matrix of UE n, and H is a propagation channel.

Is one of precoding matrices corresponding to channel state information reported by UE n, for example, an orthogonal subset equal to PMI,

Is the sum of the element powers of the components of the matrix X.

For example, if PMI reported by UE n is "0" and the orthogonal subset included in PMI = 0 is {0,1,2,3}, the interference of precoding matrices corresponding to the same orthogonal subset is equal to PMI. Respectively, I _n1 = -3 dB for CI (companion indicator) = 1, I _n2 = -6 dB for CI = 2, and I _n3 = -6 dB for CI = 3.

MU-MIMO expected SINR of the terminal n may be as shown in Equation 4.

는 노이즈 성분이며 In은 단말 n이 보고한 채널상태정보, 예를 들어 PMI와 동일한 직교서브세트의 간섭들 중 가장 큰 값이다. I_n1=-3dB, I_n2=-6dB, I_n3=-6dB인 경우 수학식 4에서 In은 위 간섭들 중 가장 큰 값인 I_n1=-3dB이다.In this case, Wn is a precoding matrix corresponding to channel state information reported by UE n.

Is the noise component and In is the largest value among the interferences of the channel state information reported by UE n, for example, an orthogonal subset equal to PMI. In the case of I _n1 = -3 dB, I _n2 = -6 dB, and I _n3 = -6 dB, E in Equation 4 is I _n1 = -3 dB, which is the largest value of the above interferences.

In Equation 4, the channel state information reported by UE n, for example, an average value or a sum of interferences of an orthogonal subset equal to PMI may be used as In. As described later, when In is used as the average value or the sum of interferences of the orthogonal subset, the worst case, that is, the case where the interference is largest may not be known.

Accordingly, the second CQI may be equal to Equation 5 below when Equation 3 and Equation 4 are summarized.

For the same reason as described with respect to the first channel quality information, the channel quality information generation unit 540 determines the channel quality itself of the terminal when the terminal itself and another terminal are multiplexed with the base station 420. Although the channel quality calculated to reduce the amount of information may be quantized, an index corresponding to the quantized channel quality may be generated as the second channel quality information, the second CQI.

For example, it is assumed that the second CQI, which is the second channel quality information, is transmitted only in the associated subband together with the aperiodic wideband CQI (aperiodic wideband CQI). Subband differential CQI offset level = subband CQI index-wideband CQI index (2 bits), but is not limited thereto.

The channel quality information generation unit 536 may generate the channel quality information in the same manner even when a rank 2 or more is transmitted at the same time through at least two layers, or according to the characteristics of the orthogonal subset. Rank modulation techniques may be used.

For example, when the second channel quality information is generated using only the orthogonal subset shown in Table 1, the orthogonal subset in Table 1 is a subset of the case where the terminal receives the rank 1 reception. If performed, it may be impossible to generate second channel quality information using the subset. Therefore, in case of a terminal reporting a rank 2 or more reception, it is possible to calculate the orthogonal subset and the second channel quality information on the assumption that the rank 1 reception is performed. For example, a terminal reporting rank 2 reception and PMI = 5 generates an orthogonal subset and second channel quality information on the assumption that ranking 1 reception and PMI = 5 are reported. However, when defining orthogonal subsets for rank 2 and above, orthogonal subsets and second channel quality information may be generated without rank modulation.

Referring back to FIG. 5, the feedback unit 540 may feed back channel information generated by the channel information generation unit 530 to the base station 420. The feedback unit 540 may feed back channel state information to the base station 420.

In addition, the feedback unit 540 measures the first channel quality information by the channel state information generation unit 534 and the channel quality information generation unit 536 in terms of channel capacity or channel quality. The calculated second CQI, which is 1 CQI and / or second channel quality information, may be reported to the base station 420. For example, the feedback unit 540 may report the second CQI to the base station 420 using uniform power allocation among the layers for at least two layers.

The channel state information feedback apparatus according to the embodiment has been described above in the MIMO system, but the channel state information feedback method according to the embodiment is described in the MIMO system.

7 is a flowchart illustrating a channel state information feedback method according to another embodiment in a MIMO system.

The MU-MIMO channel state information feedback method 700 according to another embodiment includes a reference signal from a base station, for example, a channel state index-reference signal (CSI-RS), a common reference signal (CRS), and a DM. A reference signal receiving step of receiving a RS (Demodulation-Reference Signal) (S710), a channel estimation step (S720) of estimating a channel using the received reference signal, and a channel estimation result of the channel estimation step (S720) A channel information generation step (S730) of generating corresponding channel information on the basis of the step, and a feedback step (S740) of feeding back the channel information.

The reference signal receiving step S710 and the channel estimating step S720 may be implemented separately or integrated, and may be integrated in some cases.

In the reference signal receiving step (S710), a cell-specific CSI-RS is received, and because it has information about which band (which subcarrier) and which symbol (Symbol) the CSI-RS is received, the time- By determining the signal in the frequency domain, the CSI-RS reception value can be measured.

는 위와 같은 측정에 의하여 알 수 있고, CSI-RS 송신값인

은 기지국과 단말 사이에 이미 알려진 값이므로, 통상적인 채널 추정 기법을 이용하여 전파 채널(propagation channel)인 H을 추정할 수 있는 것이다. A channel estimation function is performed by using the CSI-RS received in the channel estimation step S720, and the channel estimation is performed as follows. The received value of the CSI-RS received by the reference signal receiving step S710 is shown in Equation 1 above. Received CSI-RS received value

Can be known by the above measurement, and the CSI-RS transmission value

Since is a known value between the base station and the terminal, it is possible to estimate the propagation channel H using a conventional channel estimation technique.

Although some steps of the channel information feedback apparatus according to the embodiment are described in the MIMO system, examples of the channel information generation step, which is one of the steps of the channel information feedback method according to the embodiment in the MIMO system, are described below. List it.

8 is a flowchart of an example of a method of generating channel information according to another embodiment.

The channel information generation method 800 illustrated in FIG. 8 may correspond to a part of the channel state information generation step S730 described above and may configure an independent method. In other words, the channel information generation method 800 illustrated in FIG. 8 may configure a method independent of the before and after steps of the channel information generation step S730 of FIG. 7. Therefore, this channel information generation method 800 can be included in implementing other techniques.

7 and 8, an estimated propagation channel and a long term / wideband statistic property, which are the channel estimation results of the channel estimation step S720, are received (S810). The propagation channel and the statistical characteristics may be the same as described with reference to Equations 1 and 2 as described above.

Next, an optimal precoder and post decoder search is performed based on the input propagation channel and the long term / wideband statistic property, and an optimal precoding scheme or precoder (PC) using various precoding techniques is performed. ), An optimal post decoding scheme or post decoder (PDC) may be determined (S820).

Next, channel state information including a precoding matrix indicator (PMI) which is an index for the precoding matrix described above is generated based on the precoder information estimated by the step S820 and the post decoder (S850).

Next, a propagation channel and a long term / wideband statistic property estimated by the channel estimation step S720 and precoder information and a post decoder estimated by the step S820, Equations 3 to 5 The above-described channel quality information is generated based on the operation (S860).

Meanwhile, in step S860, channel quality information may be generated in the same manner even when rank 2 or more transmitting at least two codewords at the same time through at least two layers, or a rank modulation technique according to the characteristics of an orthogonal subset. Can be used.

As described above, in the case of a terminal reporting a rank 2 or more reception, the UE may calculate the orthogonal subset and the second channel quality information on the assumption that the rank 1 reception is performed. For example, a terminal reporting rank 2 reception and PMI = 5 generates an orthogonal subset and second channel quality information on the assumption that ranking 1 reception and PMI = 5 are reported. However, when defining orthogonal subsets for rank 2 and above, orthogonal subsets and second channel quality information may be generated without rank modulation.

Referring back to FIG. 7, the feedback step S740 feeds back channel information including the channel state information and channel quality information to the base station.

As described above, the channel information feedback method according to the embodiment is described in the MIMO system, but the base station according to another embodiment is described below.

9 is a block diagram of a base station according to another embodiment.

The base station or base station apparatus 900 includes a layer mapper 920 for mapping the codeword 910 to a layer, a precoder 930 for precoding data symbols, and two or more antennas for propagating the precoded symbols to the air. An antenna array 940 is included. Since the layer mapper 920, the precoder 930, and the antenna array 940 are the same as or substantially the same as the general configuration of the present or future, detailed descriptions thereof will be omitted.

Base station 900 may precode data symbols using precoder 930. In this case, the precoder 930 may precode data symbols by its precoding matrices.

Each terminal delivers channel information including channel state information and channel quality information to the base station 900 in the above-described manner.

The base station 900 also includes a terminal selector 960 and a precoder generator 970. In this case, the terminal selector 960 and the precoder generator 970 may be a part of the scheduler 426 illustrated in FIG. 4, or may be a separate component from the scheduler 426. Therefore, the description regarding the terminal selector 960 and the precoder generator 970 may correspond to the description regarding the scheduler 426 illustrated in FIG. 4.

The terminal selector 960 determines SU-MIMO transmission or MU-MIMO transmission based on the CQIs reported from each terminal, and channel information including channel state information and channel quality information, and selects the terminals. In more detail, the terminal selection unit 960 determines SU-MIMO transmission or MU-MIMO transmission based on PMI, which is channel state information of each terminal, first CQI, which is first channel quality information, and second CQI, which is second channel quality information. .

In this case, the terminal selecting unit 960 transmits MU-MIMO when the first CQI, which is the first channel quality information of each terminal, is relatively large and the second CQI, which is the second channel quality information having the largest interference, is large enough to enable MU-MIMO. Determine. On the contrary, the terminal selection unit 960 transmits SU-MIMO when the first CQI, which is the first channel quality information of each terminal, is relatively large, but the second CQI, which is the second channel quality information with the largest interference, is not large as MU-MIMO capable information. Can be determined.

When determining the SU-MIMO transmission, the terminal selector 960 may select one terminal based on the first CQI, which is the first channel quality information of each terminal.

On the other hand, when the MU-MIMO transmission is determined, the terminal selection unit 960 compares the channel state information reported from each terminal with the channel information including the channel quality information to determine the correlation between each terminal channel.

For example, simultaneous access or multiple access is allowed to terminals corresponding to a case where PMI, which is channel state information of each terminal, corresponds to the same orthogonal subset, and second CQI, which is second channel quality information of each terminal, is sufficiently large. can do. Specifically, the base station when the PMC = 0 reported from the terminal n and the PMIm = 1 reported from the other terminal m correspond to the same orthogonal subset and the second CQI reported from the terminal n and the second CQIm reported from the other terminal m are sufficiently large. Allows simultaneous access of UE n and UE m in MU-MIMO mode.

However, when calculating the second CQI, which is the second channel quality information of each terminal, the worst case, that is, the largest interference, is obtained when In is used as the average value or sum of interferences of the orthogonal subset equal to the PMI reported by the terminal n. It may not be.

If the PMI reported by UE n is "0" and the orthogonal subset included in PMIn = 0 is {0,1,2,3}, the interference of precoding matrices corresponding to the same orthogonal subset as PMIn is respectively CI ( Companion indicator) Assume I _n1 = -3 dB for = 1, I _n2 = -6 dB for CI = 2, and I _n3 = -6 dB for CI = 3. In this case, if PMIn = 0 reported by UE n and I _n1 = -3dB, I _n2 = -6dB, and I _n3 = -6dB, if PMIm = 2 or 3 of another UE m is selected, interference is sufficient when transmitting MU-MIMO. Although small, choosing PMIm = 1 may cause excessive interference in MU-MIMO transmission. As a result, the terminal n is PMIn = 0 and the other terminal m is PMIm = 1, so the first CQI of each terminal is too small to transmit the SU-MIMO due to excessive interference in MU-MIMO transmission. When the SU-MIMO transmission again, the PM n of the terminal n is 0 and the 1CQI and the 2CQI are sufficiently large to switch to the MU-MIMO mode. By switching, the SU-MIMO mode and the MU-MIMO mode can be repeated.

However, when calculating the second CQI, which is the second channel quality information of each terminal, In can predict the worst case when using the largest value among the interferences of the orthogonal subset that is identical to the PMI reported by the terminal n. Repeated MU-MIMO transmission may not occur.

The precoder generator 970 generates precoding matrices of one or more terminals selected by the terminal selector 960. At this time, the precoder generating unit 670 is one or more terminals based on the channel information reported from the terminals selected by the terminal selection unit 960, for example, the PMIs of the selected terminals and an orthogonal subset to which the PMIs belong. Create a precoding matrix of these.

As mentioned above, another base station has been described with reference to another embodiment, but the following describes a transmission method of a base station according to another embodiment.

10 is a flowchart illustrating a method of transmitting a base station according to another embodiment.

Referring to FIG. 10, a method 1000 of transmitting a base station according to another embodiment includes a layer mapping step S1020 of mapping a codeword S1010 to a layer, and a precoding step S1030 of precoding symbols. The transmission step (S1040) for propagating the precoded symbol through the antennas in the air. Since the layer mapping step S1020, the precoding step S1030, and the transmission step S1040 are the same as or substantially the same as the general configurations of the present or future, detailed descriptions thereof will be omitted.

However, in operation S1040, data symbols may be precoded by using one precoding matrix in each of the two precoders by using two precoders.

 In addition, the transmission method 1000 of the base station according to another embodiment includes a terminal selection step (S1060) and the precoder generation step (S1070).

The terminal selection step S1060 determines SU-MIMO transmission or MU-MIMO transmission based on channel information including channel state information and channel quality information reported from each terminal, and selects the terminals. The terminal selection step (S1060) selects one terminal when determining the SU-MIMO transmission. On the other hand, if the MU-MIMO transmission is determined, the terminal selection step (S760) to determine the correlation between each terminal channel by comparing the channel status information reported from each terminal and the channel information including the channel quality information.

Specifically, as described above, the terminal selection step S1060 may determine precoding matrices of one or more terminals based on an orthogonal subset equal to the channel state information as described above with respect to the terminal selection unit 960. have.

The precoder generation step S1070 generates precoding matrices of one or more terminals based on an orthogonal subset equal to the channel state information as described above of the terminal (s) selected by the terminal selection step S1060.

In the above-described embodiments, the UE can effectively predict the channel quality degradation caused by the interference generated during the MU-MIMO transmission and report it to the base station with less feedback overhead. In particular, the above-described embodiments can support the effective SU / MU-MIMO switching by transmitting information on the operation when transmitting MU-MIMO with little feedback overhead without transmitting multi-interference information and a plurality of channel quality information. have.

Although the embodiments have been described in detail with reference to the drawings, the present invention is not limited thereto.

Embodiments as described above may be applied to uplink / downlink MIMO systems, as well as a single cell environment, as well as a coordinated multi-point transmission / reception system (CoMP) and heterogeneous networks. It can be applied to all uplink / downlink MIMO system.

In the above description, all elements constituting the embodiments of the present invention are described as being combined or operating in combination, but the present invention is not necessarily limited to the embodiments. In other words, within the scope of the present invention, all of the components may be selectively operated in combination with one or more. In addition, although all of the components may be implemented in one independent hardware, each or all of the components may be selectively combined to perform some or all functions combined in one or a plurality of hardware. It may be implemented as a computer program having a. Codes and code segments constituting the computer program may be easily inferred by those skilled in the art. Such a computer program may be stored in a computer readable storage medium and read and executed by a computer, thereby implementing embodiments of the present invention. The storage medium of the computer program may include a magnetic recording medium, an optical recording medium, a carrier wave medium, and the like.

In addition, the terms "comprise", "comprise" or "having" described above mean that the corresponding component may be included, unless otherwise stated, and thus excludes other components. It should be construed that it may further include other components instead. All terms, including technical and scientific terms, have the same meanings as commonly understood by one of ordinary skill in the art unless otherwise defined. Terms commonly used, such as terms defined in a dictionary, should be interpreted to coincide with the contextual meaning of the related art, and shall not be construed in an ideal or excessively formal sense unless explicitly defined in the present invention.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

Claims (20)

In a wireless communication system,
Estimating a channel by receiving a reference signal;
When using channel state information for a precoding matrix corresponding to the estimated channel and using one of the other precoding matrices of a subset to which the precoding matrix belongs to the other terminal and using the precoding matrix for itself. Generating channel information including channel quality information on channel quality using the largest value among the interferences of other terminals calculated; And
And transmitting the channel information generated in the channel information generation step to the air. The method of claim 1,
And precoding matrices belonging to the subset are orthogonal to each other. The method of claim 1,
And transmitting channel quality information included in the channel information aperiodically using a physical uplink shared channel (PUSCH) in the transmitting step. The method of claim 1,
And the channel quality information is information about channel quality for the entire system band or channel quality for at least one subband of the system band. The method of claim 1,
And the device is one of a base station or a terminal. In a wireless communication system,
Channel estimation for receiving a reference signal and estimating a channel;
When using channel state information for a precoding matrix corresponding to the estimated channel and using one of the other precoding matrices of a subset to which the precoding matrix belongs to the other terminal and using the precoding matrix for itself. A channel information generator for generating channel information including channel quality information on channel quality using the largest value among the interferences of other terminals calculated; And
And a feedback unit for feeding back the generated channel information. The method of claim 6,
The precoding matrices belonging to the subset are orthogonal to each other. The method of claim 6,
And the feedback unit aperiodically transmits channel quality information included in the channel information by using a physical uplink shared channel (PUSCH). The method of claim 6,
The channel quality information is information on the channel quality for the entire system band or the channel quality for at least one subband of the system band information channel information feedback device. The method of claim 6,
And the apparatus is one of a base station and a terminal. Computed when using channel state information for a precoding matrix from at least one terminal and using one of the other precoding matrices of a subset to which the precoding matrix belongs to itself and for another terminal Select one of SU-MIMO transmission or MU-MIMO transmission using channel information including channel quality information on channel quality using the largest value among interferences of other terminals and select at least one terminal according to the selected transmission mode. A scheduler for selecting and generating a precoding matrix for the terminal;
A precoder for precoding a data symbol for the terminal using the precoding matrix; And
And an antenna array comprising two or more antennas that propagate the precoded symbol into the air. The method of claim 11,
And precoding matrices belonging to said subset are orthogonal to each other. The method of claim 11,
And the scheduler aperiodically receives channel quality information included in the channel information through a physical uplink shared channel (PUSCH). The method of claim 11,
The channel quality information is information on the channel quality for the entire system band or the channel quality for at least one subband of the system band. The method of claim 11,
The apparatus is characterized in that the base station or one of the terminal. Computed when using channel state information for a precoding matrix from at least one terminal and using one of the other precoding matrices of a subset to which the precoding matrix belongs to itself and for another terminal Select one of SU-MIMO transmission or MU-MIMO transmission using channel information including channel quality information on channel quality using the largest value among interferences of other terminals and select at least one terminal according to the selected transmission mode. A terminal selection step of selecting and generating a precoding matrix for the terminal;
A precoding step of precoding a data symbol for the terminal by using the precoding matrix; And
A method of transmitting an apparatus comprising propagating a precoded symbol to the air through an antenna array comprising two or more antennas. The method of claim 16,
And the precoding matrices belonging to the subset are orthogonal to each other. The method of claim 16,
And in the terminal selection step, aperiodically receive channel quality information included in the channel information through a physical uplink shared channel (PUSCH). The method of claim 16,
Wherein the channel quality information is information on channel quality for the entire system band or channel quality for at least one subband of the system band. The method of claim 16,
The device is a method of transmitting a device, characterized in that one of the base station or the terminal.

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