KR20120092520A - Apparatus and method for receiving data in communication system - Google Patents

Abstract

PURPOSE: A data reception apparatus in a communication system and method thereof are provided to give feedback on channel information to a data stream using restricted resources. CONSTITUTION: A reception unit(110) receives data transmitted from an AP(Access Point) to an MIMO(Multi Input Multi Output) method. A detection unit(120) detects the data stream of the received data using an LQ decomposition method. A creation unit(130) creates channel information for the data stream. A transmission unit(140) gives feedback on the channel information to the AP.

Description

Apparatus and method for receiving data in communication system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication system, and in particular, to provide a service to a plurality of users in a multi-input multi-output (MIMO: Multi-Input (MIMO)) method. A data receiving apparatus and method for feeding back channel information using an LQ decomposition scheme.

In the current communication system, active researches are being conducted to provide users with services of various quality of service (QoS) having a high transmission speed (hereinafter referred to as 'QoS'). As an example of such a communication system, in a wireless local area network (WLAN) system, researches on methods for transmitting a large amount of data at high speed and stability through limited resources Is actively underway. In particular, in a communication system, research on data transmission through a wireless channel has been conducted. Recently, methods for transmitting and receiving a large amount of data normally using a limited wireless channel have recently been proposed.

Meanwhile, in a recent communication system, a method of transmitting and receiving a large amount of data in a MIMO manner to a plurality of terminals, for example, STAs through a plurality of base stations, for example, an access point (AP). This has been proposed. Here, the STAs can access all APs. Accordingly, the STAs can wirelessly access any one AP from among the APs, and transmit a large amount of data with one AP through a wireless channel in a MIMO manner. Send and receive

However, in the current communication system, in order for any AP to transmit a large amount of data to the STAs in the MIMO scheme, a specific scheme for feeding back channel information on the data stream between the AP and the STAs during the data transmission in the MIMO scheme This has not been proposed yet. In other words, as described above, in order to transmit and receive a large amount of data between the AP and the STA in a MIMO scheme, for example, a single user-MIMO scheme and a multi-user-MIMO scheme, Channel information for the data stream should be fed back to the receiver, eg STAs, to the transmitter, eg AP. However, in the current communication system, a specific method for feeding back channel information to the transmitter in order to normally receive a large amount of data in a single user-MIMO scheme and a multi-user-MIMO scheme has not been proposed. There is a limitation in transmitting and receiving a large amount of data normally in a single user-MIMO method and a multi-user-MIMO method.

Therefore, in a communication system such as a WLAN system, a receiver receives channel information about a data stream to transmit and receive large amounts of data to a plurality of STAs through a plurality of APs in a single user-MIMO scheme and a multi-user-MIMO scheme with limited resources. There is a need for a method of receiving data that normally returns.

Accordingly, an object of the present invention is to provide an apparatus and method for receiving data in a communication system.

Another object of the present invention is a data receiving apparatus and method for normally feeding back channel information on a data stream in order to transmit and receive a large amount of data in a single user-MIMO scheme and a multi-user-MIMO scheme through limited resources in a communication system. In providing.

An apparatus of the present invention for achieving the above objects, in the data receiving apparatus in the communication system, the data transmitted from the access point (AP) in a multi-input multi-output (MIMO: Multi-Input Multi-Output) scheme Receiving unit for receiving; A detector for detecting the data stream of the received data by using an LQ decomposition method; A generation unit for generating channel information on the data stream; And a transmitter for feeding back the channel information to the access point.

The method of the present invention for achieving the above object, in the data receiving method in a communication system, data transmitted from an access point (AP) in a multi-input multi-output (MIMO: Multi-Input Multi-Output) scheme Receiving; Detecting a data stream of the received data by using an LQ decomposition scheme; Generating channel information for the data stream; And feeding back the channel information to the access point.

The present invention provides a channel for a data stream by feeding back channel information on a data stream of a large amount of data transmitted and received in a single user-MIMO scheme and a multi-user-MIMO scheme in a communication system by using an LQ decomposition scheme. Information is fed back normally, and accordingly, a large amount of data can be transmitted and received at high speed and stability in a single user-MIMO method and a multi-user-MIMO method through limited resources.

1 is a view schematically showing a data receiving apparatus in a communication system according to an embodiment of the present invention.
2 is a view schematically illustrating an operation process of a data receiving apparatus in a communication system according to an exemplary embodiment of the present invention.
3 to 26 are diagrams schematically illustrating the performance of a data receiving apparatus in a communication system according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

The present invention proposes an apparatus and method for receiving data in a communication system, such as a wireless local area network (WLAN) system. Here, although an embodiment of the present invention will be described using a WLAN system as an example, the data receiving method proposed by the present invention may be applied to other communication systems.

In addition, an embodiment of the present invention proposes a data receiving apparatus and method for providing a service in a MIMO manner to a plurality of users through a limited resource, for example, a wireless channel in a communication system. Here, in the embodiment of the present invention, in a communication system, a transmitter, for example, an access point (AP) is called a receiver, for example, a terminal, for example, a station (STA). In order to transmit / receive a large amount of data in a MIMO scheme, for example, a single user-MIMO scheme and a multi-user-MIMO scheme, the receiver may perform an operation on a data stream of a large volume of data. The channel information is normally fed back using the LQ decomposition scheme, and accordingly, a large amount of data is quickly and stably received in the single user-MIMO scheme and the multi-user-MIMO scheme.

That is, in an embodiment of the present invention, when a large amount of data is transmitted and received in a MIMO manner to a plurality of terminals, for example, STAs through a plurality of base stations, for example, APs, a wireless connection is made to any one of the APs. In order to receive a large amount of data in the single user-MIMO scheme and the multi-user-MIMO scheme, the channel information of the data stream between the AP and the STA is fed back using an LQ decomposition scheme. In other words, in the embodiment of the present invention, when receiving a large amount of data from a transmitter, for example, an AP in the single user-MIMO scheme and the multi-user-MIMO scheme, a receiver, for example, an STA, may receive a large data stream. Channel information is fed back to the transmitter using the LQ decomposition scheme. Next, the data receiving apparatus in the communication system according to the exemplary embodiment of the present invention will be described in more detail with reference to FIG. 1.

1 is a diagram schematically illustrating a structure of a data receiving apparatus in a communication system according to an exemplary embodiment of the present invention.

Referring to FIG. 1, the data receiving apparatus 100 may include a receiving unit 110 that receives data from a data transmitting apparatus such as an AP in a single user-MIMO scheme and a multi-user-MIMO scheme via a wireless channel. The detector 120 detects a data stream of data, and the generator 130 generates channel information on the detected data stream, for example, channel state information (CSI). And a transmitter 140 for feeding back channel information on the data stream to the data transmitter, for example, an AP. Here, the data receiving apparatus 100 will be referred to as a maximum log likelihood (ML) method or zero-forcing (ZF). Receive data transmitted in a single user-MIMO scheme and a multi-user-MIMO scheme over a wireless channel.

As described above, the receiver 110 receives a large amount of data from the AP through a single user-MIMO scheme and a multi-user-MIMO scheme. Here, the AP, that is, the data transmission apparatus, receives channel information on the data stream during data transmission in the single user-MIMO scheme and the multi-user-MIMO scheme from the data receiving apparatus, and receives the received channel information. Based on the data transmission to the terminal, that is, the data receiving apparatus 100 by performing beamforming (beamformming) to transfer the large-capacity data to the data receiving apparatus 100 in the single user-MIMO method and multi-user-MIMO method Send.

The detector 120 detects a data stream of data received from the data transmitter through the receiver 110, and detects the data stream of the received data using an LQ decomposition scheme. Here, the detection unit 120 decomposes the received data into a unitary matrix and a low-triangular matrix using LQ decomposition, that is, the received signal of the received data ( Decompose y) into an L matrix in the form of a lower triangle and a Q matrix in the form of a unitary matrix. For example, the received signal y may be represented by an L matrix, a Q matrix, an original signal s, and a noise n through LQ decomposition (y = L? Q? S + n).

Here, the detection unit 120, as another embodiment, the data stream of the received data using a singular value decomposition (SVD) scheme different from the LQ decomposition scheme (hereinafter referred to as SVD) Can be detected. In this case, when the detection unit 120 detects the data stream of the received data by the LQ decomposition method than the SVD method, the performance of the data receiving apparatus is further improved. It is more desirable to detect the data stream. Further, when the data stream of the received data is detected by the LQ decomposition method by the SVD method, the received signal y may be U matrix, S matrix, V matrix, original signal s, and the like through SVD. It can be expressed as noise n (y = U? S? V ^H ? S + n). The LQ decomposition and SVD of the received data in the detector 120 will be described in more detail with reference to the following equations.

In addition, the generation unit 120 generates channel information on the data stream detected by the detection unit 120 through LQ decomposition. Here, the generation unit 120, as described above, through the LQ decomposition, the data of the Q matrix in the received signal (y) represented by the L matrix, the Q matrix, the original signal (s), and the noise (n) The transmitter 140 generates the channel information on the stream, and the transmitter 140 feeds back the Q matrix obtained through the LQ decomposition to the data transmitter as the channel information on the data stream. Here, when the detection unit 120 detects the data stream through the SVD method rather than the LQ decomposition method, the data transmission device uses the V matrix obtained through the SVD as channel information for the data stream. Feedback to. Next, an operation of receiving data of the data receiving apparatus in the communication system according to an exemplary embodiment of the present invention will be described in more detail with reference to FIG. 2.

2 is a diagram schematically illustrating an operation process of a data receiving apparatus in a communication system according to an exemplary embodiment of the present disclosure.

Referring to FIG. 2, in step 210, the data receiving apparatus receives a large amount of data transmitted through a single user-MIMO scheme and a multi-user-MIMO scheme from the data transmitter as described above.

In operation 220, the data receiving apparatus detects a data stream of the received data by using an LQ decomposition scheme. Here, the data receiving apparatus may detect a data stream of the received data by using an SVD scheme different from the LQ decomposition scheme, and when detecting the data stream by using the LQ scheme, the data receiving apparatus. It is more preferable that the data stream of the received data is detected by using the LQ decomposition scheme since the performance of. The detection of the data stream of the received data through the LQ decomposition scheme and the SVD scheme will be described in more detail with reference to the following equations.

In operation 230, the data receiving apparatus generates channel information on the data stream detected through the LQ decomposition scheme, and then, in step 240, the channel information is fed back to the data transmitting apparatus, that is, the data transmitting apparatus. The channel information is transmitted. Here, the Q matrix is fed back from the data stream detected through the LQ decomposition scheme to the data transmission apparatus as channel information about the data stream. In this case, as described above, when the data stream is detected through the SVD scheme, the V matrix is fed back from the data stream detected through the SVD scheme to the data transmission apparatus as channel information about the data stream. Next, the data stream detected through the LQ decomposition scheme and the SVD scheme will be described in more detail.

First, when the data transmitting apparatus, that is, the AP transmits data to data receiving apparatuses, that is, terminals through a wireless channel in a single user-MIMO scheme, the data received at the terminals, that is, the received signal y, is Equation 1 to Equation 4 may be represented. Here, in Equation 1, one AP transmits data through a single user-MIMO scheme through four transmit antennas, one terminal, that is, one STA receives data through two receive antennas, and the SVD The reception signal y when two data streams are detected by the scheme is shown. In addition, as described above, the data receiving apparatus, that is, the STA, feeds back the V matrix to the data transmitting apparatus, that is, the AP, with channel information on the data stream detected through the SVD scheme. In this case, the AP transmits data to the STA in a single user-MIMO scheme by performing beamforming based on the V matrix fed back with the channel information, and an effective channel for data transmission according to the beamforming. Is a matrix in the form of a unitary matrix x diagonal matrix.

In addition, in Equation 2, one AP transmits data through a single user-MIMO scheme through four transmission antennas, one terminal, that is, one STA receives data through two reception antennas, and the SVD The reception signal y when there is one data stream detected through the scheme is shown. In addition, as described above, the data receiving apparatus, that is, the STA, feeds back the V matrix to the data transmitting apparatus, that is, the AP, with channel information on the data stream detected through the SVD scheme. In this case, the AP performs beamforming based on the V matrix fed back with the channel information to transmit data to the STA in a single user-MIMO scheme, and an effective channel for data transmission according to the beamforming is a unitary matrix. X diagonal matrix.

In Equation 3, one AP transmits data through a single user-MIMO scheme through four transmit antennas, and one UE, that is, one STA receives data through two receive antennas, and the LQ The reception signal y when two data streams are detected by the decomposition method is shown. In addition, as described above, the data receiving apparatus, that is, the STA, feeds back a Q matrix to the data transmitting apparatus, that is, the AP, with channel information on the data stream detected through the LQ decomposition scheme. In this case, the AP performs beamforming based on the Q matrix fed back with the channel information to transmit data to the STA in a single user-MIMO scheme, and an effective channel for data transmission according to the beamforming is a unitary matrix. × The matrix is in the form of a lower triangular matrix. When the data stream is detected by the LQ decomposition method, the data reception device receives the data by the effective channel having the unitary matrix × lower triangular matrix form, as described above. Performance is improved.

In addition, in Equation 4, one AP transmits data through a single user-MIMO scheme through four transmit antennas, and one UE, that is, one STA receives data through two receive antennas, and the LQ The reception signal y when there is one data stream detected through the decomposition method is shown. In addition, as described above, the data receiving apparatus, that is, the STA, feeds back a Q matrix to the data transmitting apparatus, that is, the AP, with channel information on the data stream detected through the LQ decomposition scheme. In this case, the AP performs beamforming based on the Q matrix fed back with the channel information to transmit data to the STA in a single user-MIMO scheme, and an effective channel for data transmission according to the beamforming is a unitary matrix. × The matrix is in the form of a lower triangular matrix. When the data stream is detected by the LQ decomposition method, the data reception device receives the data by the effective channel having the unitary matrix × lower triangular matrix form, as described above. Performance is improved.

In addition, Equation 5 is that one AP transmits data through a multi-user-MIMO scheme through four transmit antennas, and two terminals, that is, two STAs receive data through two receive antennas, The reception signal y when two data streams are detected by the SVD method is shown. In addition, as described above, the data receiving apparatuses, that is, STAs, feed back a V matrix to the data transmitting apparatus, that is, the AP, with channel information on the data stream detected through the SVD scheme. In this case, the AP performs beamforming based on the V matrix fed back with the channel information to transmit data to STAs in a multi-user-MIMO scheme, and an effective channel for data transmission according to the beamforming is a diagonal matrix. Is a matrix of types.

In Equation 6, one AP transmits data through a multi-user-MIMO scheme through four transmit antennas, and two terminals, that is, two STAs receive data through three receive antennas, The reception signal y when two data streams are detected by the SVD method is shown. In addition, as described above, the data receiving apparatuses, that is, STAs, feed back a V matrix to the data transmitting apparatus, that is, the AP, with channel information on the data stream detected through the SVD scheme. In this case, the AP performs beamforming based on the V matrix fed back with the channel information to transmit data to STAs in a multi-user-MIMO scheme, and an effective channel for data transmission according to the beamforming is a diagonal matrix. Is a matrix of types. Here, the STAs, that is, the data receiving apparatuses, store the unitary matrix U in advance, and then multiply the received signal y to use eigen-mode selection.

In addition, Equation (7) shows that one AP transmits data through a multi-user-MIMO scheme through four transmit antennas, and two terminals, that is, two STAs receive data through two receive antennas. The reception signal y when two data streams are detected by the LQ decomposition scheme is shown. In addition, as described above, the data receiving apparatuses, that is, STAs, feed back a Q matrix to the data transmitting apparatus, that is, the AP, with channel information on the data stream detected through the LQ decomposition scheme. In this case, the AP performs beamforming based on the Q matrix fed back with the channel information to transmit data to STAs in a multi-user-MIMO scheme, and an effective channel for data transmission according to the beamforming is block diagonal. It becomes a matrix in the form of a block diagonal matrix. As described above, when the data stream is detected by the LQ decomposition method, the data reception performance of the data receiving apparatuses is improved by the effective channel in the form of the block diagonal matrix. .

In addition, Equation 8 is that one AP transmits data through a multi-user-MIMO scheme through four transmit antennas, and two terminals, that is, two STAs receive data through three receive antennas, The reception signal y when two data streams are detected by the LQ decomposition scheme is shown. In addition, as described above, the data receiving apparatuses, that is, STAs, feed back a Q matrix to the data transmitting apparatus, that is, the AP, with channel information on the data stream detected through the LQ decomposition scheme. In this case, the AP performs beamforming based on the Q matrix fed back with the channel information to transmit data to STAs in a multi-user-MIMO scheme, and an effective channel for data transmission according to the beamforming is block diagonal. It becomes a matrix in matrix form. As described above, when the data stream is detected by the LQ decomposition method, the data reception performance of the data receiving apparatuses is improved by the effective channel in the form of the block diagonal matrix. . Here, the STAs, that is, the data receiving apparatuses, perform a reception chain selection, that is, a reception antenna selection in advance, and in this case, when performing antenna selection on a per-tone basis. The selection index is stored in advance.

3 to 26, the data receiving performance of the data receiving apparatus in the SVD scheme and the LQ decomposition scheme in the communication system according to an exemplary embodiment of the present invention will be described in more detail.

3 to 26 are diagrams schematically illustrating the performance of a data receiving apparatus in a communication system according to an embodiment of the present invention. 3 to 26 are diagrams illustrating data reception performance of a data receiving apparatus for detecting a data stream using an SVD scheme and an LQ decomposition scheme, for example, an ML data receiver. In particular, FIGS. 3 to 26 show data using the SVD scheme and the LQ decomposition scheme when the data transmission apparatus transmits data in a single user-MIMO scheme and a multi-user-MIMO scheme through 1 to 8 transmit antennas. The data reception performance of the ML type data receiving apparatus for detecting a stream is referred to as a packet error ratio (PER) and a signal-to-noise ratio (SNR). Referred to as).

In more detail, FIG. 3 shows that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 TX antennas, and the data receiving apparatus receives data through one receiving antenna. When one data stream is detected through the SVD scheme and the V matrix is fed back to the channel information of the data stream according to the SVD scheme, the antennas transmit data reception performance, that is, PER and SNR, of the data receiver. This is a graph of each. In addition, FIG. 4 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmission antennas (TX antennas), the data reception apparatus receives data through one reception antenna, and the LQ decomposition. When there is only one data stream detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 5 shows that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data receiving apparatus receives data through two receiving antennas. In the case of one data stream detected through the PDP and the feedback of the V matrix with channel information of the data stream according to the SVD scheme, the data reception performance of the data receiving apparatus, that is, PER and SNR, is a graph for each transmit antenna. . 6 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmission antennas (TX antennas), and the data reception apparatus receives data through two reception antennas, and the LQ decomposition. When there is only one data stream detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 7 shows that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas, and the data receiving apparatus receives data through three receiving antennas. In the case of one data stream detected through the PDP and the feedback of the V matrix with channel information of the data stream according to the SVD scheme, the data reception performance of the data receiving apparatus, that is, PER and SNR, is a graph for each transmit antenna. . 8 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmission antennas (TX antennas), the data reception apparatus receives data through three reception antennas, and the LQ decomposition. When there is only one data stream detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 9 shows that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data receiving apparatus receives data through 4 receiving antennas. When there is only one data stream detected through the scheme, and the V matrix is fed back to the channel information of the data stream according to the SVD scheme, a graph showing data reception performance of the data receiving apparatus, that is, PER and SNR for each transmit antenna. to be. In addition, FIG. 10 shows that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 TX antennas, and the data receiving apparatus receives data through 4 receiving antennas. When there is only one data stream detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 11 shows that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data receiving apparatus receives data through two receiving antennas. In the case of two data streams detected through the PDP and feeding back the V matrix with the channel information of the data stream according to the SVD scheme, it is a graph showing the data reception performance of the data receiving apparatus, that is, PER and SNR for each transmitting antenna. . 12 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 TX antennas, and the data reception apparatus receives data through two reception antennas, and the LQ decomposition. When two data streams are detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 13 shows that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data receiving apparatus receives data through three receiving antennas. In the case of two data streams detected through the PDP and feeding back the V matrix with the channel information of the data stream according to the SVD scheme, it is a graph showing the data reception performance of the data receiving apparatus, that is, PER and SNR for each transmitting antenna. . In addition, FIG. 14 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmission antennas (TX antennas), and the data reception apparatus receives data through three reception antennas. When two data streams are detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 15 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmission antennas (TX antennas), and the data reception apparatus receives data through four reception antennas. When two data streams are detected through the scheme, and the V matrix is fed back to the channel information of the data stream according to the SVD scheme, a graph showing data reception performance of the data receiver, that is, PER and SNR, for each transmit antenna. to be. In addition, FIG. 16 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmission antennas (TX antennas), and the data reception apparatus receives data through four reception antennas, and the LQ decomposition. When two data streams are detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 17 illustrates that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data receiving apparatus receives data through three receiving antennas. In the case of three data streams detected through the VD and feedback of the V matrix with channel information of the data stream according to the SVD scheme, the data reception performance of the data receiving apparatus, that is, PER and SNR, is a graph showing transmission antennas by transmission antennas. . 18 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmission antennas (TX antennas), and the data reception apparatus receives data through three reception antennas, and the LQ decomposition. When three data streams are detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 19 shows that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data receiving apparatus receives data through four receiving antennas. In the case of three data streams detected through the VD and feedback of the V matrix with channel information of the data stream according to the SVD scheme, the data reception performance of the data receiving apparatus, that is, PER and SNR, is a graph showing transmission antennas by transmission antennas. . In addition, FIG. 20 illustrates that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 TX antennas, and the data receiving apparatus receives data through 4 receiving antennas, and the LQ decomposition. When three data streams are detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 21 illustrates that the data transmitting apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data receiving apparatus receives data through four receiving antennas. 4 data streams detected through the scheme, and when the V matrix is fed back to the channel information of the data stream according to the SVD scheme, a graph showing data reception performance of the data receiver, that is, PER and SNR for each transmit antenna. to be. In addition, FIG. 22 illustrates that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmission antennas (TX antennas), and the data reception apparatus receives data through four reception antennas, and the LQ decomposition. When four data streams are detected through the scheme, and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, the data reception capability of the data receiver, that is, PER and SNR, is represented for each transmit antenna. It is a graph.

In addition, FIG. 23 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data reception apparatus receives data to detect a data stream detected through the SVD scheme. When three, and fed back the V matrix to the channel information of the data stream according to the SVD scheme, it is a graph showing the data reception performance of the data receiving apparatus, that is, PER and SNR for each transmit antenna. In addition, FIG. 24 illustrates that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data reception apparatus receives data and detects the data stream through the LQ decomposition scheme. When there are three and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, it is a graph showing the data reception performance of the data receiving apparatus, that is, PER and SNR for each transmission antenna.

In addition, FIG. 25 shows that the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 TX antennas, and the data reception apparatus receives data to detect a data stream detected through the SVD scheme. In the case of four, when the V matrix is fed back with channel information of the data stream according to the SVD scheme, it is a graph showing data reception performance of the data receiving apparatus, that is, PER and SNR for each transmission antenna. In addition, FIG. 26 illustrates a data stream in which the data transmission apparatus transmits data through a MIMO scheme through 1 to 8 transmit antennas (TX antennas), and the data reception apparatus receives data to detect the data stream through the LQ decomposition scheme. When there are four and the Q matrix is fed back to the channel information of the data stream according to the LQ decomposition scheme, it is a graph showing the data reception performance of the data receiving apparatus, that is, PER and SNR for each transmission antenna.

3 to 26, rather than detecting the data stream through the SVD method and feeding back the V matrix with the channel information, the LQ decomposition method detects the data stream and converts the Q matrix into the channel information. In the case of feedback, data reception performance of the data reception apparatus, that is, data detection performance of the ML method of the data reception apparatus is improved, thereby improving data reception performance.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be determined by the scope of the appended claims, as well as the appended claims.

Claims (14)

A data receiving apparatus in a communication system,
A receiving unit for receiving data transmitted from an access point (AP) in a multi-input multi-output (MIMO) scheme;
A detector for detecting the data stream of the received data by using an LQ decomposition method;
A generation unit for generating channel information on the data stream; And
And a transmitter for feeding back the channel information to the access point.
The method of claim 1,
The receiving unit receives data, characterized in that for receiving data transmitted from the access point via a wireless channel in a single user (multiple input) multiple output scheme or a multi user (multi user) multiple input multiple output scheme Device.
The method of claim 2,
The detector receives the data by using the LQ decomposition method, decomposing the received data into an L matrix having a low-triangular matrix form and a Q matrix having a unitary matrix form. Device.
The method of claim 3,
And the transmitting unit feeds back the Q matrix to the access point with the channel information.
The method of claim 4, wherein
And the access point performs beamforming for data transmission in the multiple input multiple output scheme based on the Q matrix.
The method of claim 5,
The effective channel of the radio channel is in the form of a unitary matrix x lower triangular matrix in the single user-multi-input multiple output scheme according to the beamforming. The method of claim 5,
The effective channel of the wireless channel is in the form of a block diagonal matrix in the multi-user-multi-input multiple-output scheme according to the beamforming.
In the communication system receiving data,
Receiving data transmitted from an access point (AP) in a multi-input multi-output (MIMO) scheme;
Detecting a data stream of the received data by using an LQ decomposition scheme;
Generating channel information for the data stream; And
And feeding back the channel information to the access point.
9. The method of claim 8,
The receiving may include receiving data transmitted from the access point through a wireless channel in a single user-multiple input multiple output scheme or a multi-user multi-multiple input multiple output scheme. How to receive data.
10. The method of claim 9,
The detecting may include decomposing the received data into an L matrix in the form of a low-triangular matrix and a Q matrix in the form of a unitary matrix by using the LQ decomposition method. How to receive data.
The method of claim 10,
The transmitting may include feeding back the Q matrix to the access point with the channel information.
The method of claim 11,
And performing, by the access point, beamforming for data transmission in the multi-input multi-output scheme based on the Q matrix.
The method of claim 12,
The effective channel of the wireless channel is in the form of a unitary matrix x lower triangular matrix in the single user-multi-input multiple output scheme according to the beamforming.
The method of claim 12,
The effective channel of the wireless channel is in the form of a block diagonal matrix in the multi-user-multi-input multiple-output scheme according to the beamforming.

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