KR101075754B1 - System and method for transmitting data in wireless communication system based on multi-carrier - Google Patents

Abstract

The present invention relates to a data transmission system and method in a wireless communication system based on a multi-carrier, and more particularly to a relay in transmitting data between a source and a destination. It relates to a system and a method for transmitting data using. The wireless communication system includes both a cellular communication system and an ad hoc network. In a cellular communication system, a source and a destination may be both a base station and a mobile station, and a source that first transmits data becomes a source and a destination that receives data finally becomes a destination.

According to an embodiment of the present invention, in a multi-carrier based wireless communication system, a source transmits data to a destination and a repeater; The repeater receives the data transmitted from the source and distinguishes each subcarrier and transmits only the signal-to-noise ratio of the subcarriers to the destination that is greater than or equal to a predetermined threshold.

Repeater, Multi Carrier

Description

System and method for transmitting data in wireless communication system based on multi-carrier}             

1A to 1G are conceptual views of a method for transmitting data in the related art.

2 is a time slot and conceptual diagram of a data transmission system and method according to a first embodiment of the present invention;

3 is a flowchart illustrating operation of the relay R in the first embodiment of the present invention.

4A and 4B are time slot and conceptual diagrams of a data transmission system and method according to a second embodiment of the present invention.

5 is an operational flowchart of a source S in a second embodiment of the present invention.

6A to 6C are time slot and conceptual diagrams of a data transmission system and method according to a third embodiment of the present invention.

7 is an operation flowchart of a source S in a third embodiment of the present invention.

8 is a flowchart illustrating operation of the relay R in the third embodiment of the present invention.

9A to 9C are time slots and a conceptual diagram of a data transmission system and method according to a fourth embodiment of the present invention.                 

10 is a flowchart illustrating operation of the source S in the fourth embodiment of the present invention.

11 is a flowchart illustrating operation of the relay R in the fourth embodiment of the present invention.

12 is a time slot and conceptual diagram of a data transmission system and method according to the fifth embodiment of the present invention.

13 is a flowchart illustrating operation of one repeater in a fifth exemplary embodiment of the present invention.

The present invention relates to a data transmission system and method in a wireless communication system based on a multi-carrier, and more particularly to a relay in transmitting data between a source and a destination. It relates to a system and a method for transmitting data using. The wireless communication system includes both a cellular communication system and an ad hoc network. In a cellular communication system, a source and a destination may be both a base station and a mobile station, and a source that first transmits data becomes a source and a destination that receives data finally becomes a destination. These concepts of sources and destinations apply equally to the following description.

BACKGROUND OF THE INVENTION There are several methods of transmitting data between a source and a destination in a wireless communication system.                         

First, the most basic method is a method in which data is directly transmitted from a source S to a destination D as shown in FIG. 1A.

In a system using multiple antennas, when two transmitting antennas proposed by Alamouti are used, a simple technique called Space-Time Transmit Diversity is used for two data at source S for the same data as shown in FIG. There is a method of transmitting to a destination D using an antenna.

In addition, there is a method of transmitting data from a source S to a repeater R first using a repeater and then transmitting data from the repeater R to the destination D as shown in FIG. 1C. In the figure, arrows indicate the direction of data transmission and numbers indicate the order of data transmission. The same applies to the following description.

On the other hand, there are amplification and forward (AF) and decode and forward (DF) methods to more efficiently transmit data using a repeater.

The AF method is a method in which the source S simultaneously transmits data to the relay R and the destination D as shown in FIG. 1D, and then amplifies the signal received by the relay R to the destination D. Repeater R simply amplifies and retransmits the received analog signal. This AF method has a disadvantage in that noise increases when the channel gain between the source S and the repeater R is low. If the AF method uses different orthogonal time slots, the received analog signal must be stored in the repeater R. To implement this, analog-to-digital signals must be converted into digital signals through Analog-to-Digital Conversion (ADC) and stored in memory. In addition, an operation for synchronizing synchronization between signals should be performed. This causes additional quantization noise.

In the DF method, as shown in FIG. 1E, when the source S simultaneously transmits data to the relay R and the destination D, the relay R decodes the received data and transmits the data to the destination D only when decoding is successful. In FIG. 1E, (2) means that data is transmitted to the destination D only when the decoding of the data received at the relay R is successful. Such a DF method has a big disadvantage in performance variation depending on the decoding success of the repeater.

Complementing this is the DF method of FIG. 1F. In FIG. 1F, the source S simultaneously transmits data to the relay R and the destination D, and when the relay R fails to decode the received data, the source S is informed to the source S so that the source S can transmit the data to the destination D once again. This method is currently used by Vodafone in the UK, and Source S retransmits data as a kind of repetition code.

In addition, there is a method of transmitting data, a hybrid automatic repeat request (HARQ) method. In the HARQ method, when the source S simultaneously transmits data to the relay R and the destination D as shown in FIG. 1G, when the destination D fails to recover the data, the HARQ method informs the relay R to receive the data transmission from the relay R again.

However, the above-described AF, DF, and HARQ methods are all data transmission methods based on a single carrier, and multicarriers are not considered.

The present invention provides a system and method for transmitting data based on multiple carriers using a repeater.

To this end, an embodiment of the present invention is a wireless communication system based on a multi-carrier, a source transmits data to a destination and a repeater; The repeater receives the data transmitted from the source and distinguishes each subcarrier and transmits only the signal-to-noise ratio of the subcarriers to the destination that is greater than or equal to a predetermined threshold.

Another embodiment of the present invention provides a wireless communication system based on a multi-carrier, a source transmitting data to a destination and a repeater; The repeater receives and decodes the data transmitted from the source; If the decoding is successful, the repeater sends the received data to the destination; If the decoding fails, the source transmits the data to the destination using an interleaver different from the previous interleaver. Here, the repeater transmits the result of performing the decoding to the source.

Another embodiment of the present invention provides a wireless communication system based on a multi-carrier, a source transmitting data to a destination and a repeater; The repeater receives and decodes the data transmitted from the source; Compare channel state information between the repeater and the destination and channel state information between the source and the destination; If the channel state between the repeater and the destination is better than the channel state between the source and the destination, and the decoding succeeds, the repeater sends the received data to the destination using an interleaver different from the previous interleaver; If the channel state between the repeater and the destination is better than the channel state between the source and the destination, and the decoding fails, the repeater distinguishes the received data by subcarriers so that a signal-to-noise ratio of the subcarriers is equal to or greater than a predetermined threshold. Send only to the destination; If the channel state between the source and the destination is better than the channel state between the repeater and the destination, the source transmits the data to the destination using an interleaver different from the previous interleaver. Here, the comparison of the channel state information is performed at the repeater or the source. And another such embodiment is that the repeater transmits the result of performing the decoding information to the source; The destination transmits channel state information between the repeater and the destination and channel state information between the source and the destination to the source and the repeater.

On the other hand, if the data is a space-time block code, the channel state between the repeater and the destination is better than the channel state between the source and the destination, and if the decoding is successful, the source may have the data different from the previous interleaver. Send to the destination using; The channel condition between the repeater and the destination is better than the channel condition between the source and the destination, and if the decoding fails, the source transmits the data to the destination in a different sub-stream from the repeater. It features. And if the data is a space-time block code, and the channel state between the repeater and the destination is better than the channel state between the source and the destination, and the decoding fails, the repeater uses an interleaver different from the previous interleaver. And transmitting the data to the destination in a different substream. In this case, the source, the repeater, and the destination is characterized in that it comprises a single antenna.

According to another embodiment of the present invention, in a wireless communication system based on a multi-carrier, a space-time block code is transmitted from a source having a plurality of antennas to a destination having a plurality of antennas by using a repeater having a plurality of antennas. The source sends the space-time block code to the destination and the repeater; The source retransmits a particular substream of the space-time block code to the destination; The repeater receives and decodes the space-time block code transmitted from the source; If the decoding is successful, the repeater reconstructs the received subspace of the space-time block code into a substream different from the link with the source and transmits the substream to the destination according to the configuration of the antenna; If the decoding fails, the repeater reconstructs and transmits the substream to the destination only for the subcarriers that have successfully detected the subcarriers of the received space-time block code. At this time, the repeater may be a plurality.

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

2 is a time slot and conceptual diagram of a data transmission system and method according to a first embodiment of the present invention.

In the first embodiment, first, the source S simultaneously transmits data to the relay R and the destination D through the time slot 1. In this case, the transmitted data is data based on multiple carriers. Then, the repeater R selectively transmits only those whose instantaneous signal-to-noise ratio (SNR) for the received subcarriers is greater than or equal to a predetermined threshold for the received data to the destination D through time slot 2.

Repeater R can divide data by subcarriers in a multi-carrier system by performing a Fast Fourier Transform (FFT) on a digitally converted signal.

A subcarrier with an instantaneous SNR smaller than the threshold increases noise, so the corresponding subcarrier is not transmitted.

Referring to the operation flowchart of the repeater R in the first embodiment as shown in FIG.

When data is received from the source S (S31), the data is classified by subcarriers (S32). In operation S33, it is determined whether the instantaneous SNR of the data classified for each subcarrier is greater than a predetermined threshold value. Accordingly, only the subcarriers having an instantaneous SNR greater than the threshold are transmitted to the destination D (S34). Otherwise, the subcarrier is not transmitted (S35).

4A and 4B are time slots and a conceptual diagram of a data transmission system and method according to a second embodiment of the present invention.                     

First, the source S simultaneously transmits data to the relay R and the destination D through the time slot 1. The repeater R then decodes the received data and transmits its success information to the source S via a signaling minislot. At this time, if the relay R successfully decodes the received data, as shown in FIG. 4A, the relay R transmits the data to the destination D through time slot 2, and if the decoding is not successful, the source S has previously time slot 1 as shown in FIG. 4B. Uses the interleaver and the other interleaver used to transmit data through time slot 2 to the destination D.

In this second embodiment, the channel diversity effect can be obtained by generating an independent channel.

5 is a flowchart illustrating the operation of the source S in the second embodiment.

First, the source S transmits data to the destination D and the relay R (S51). Then, information on whether the decoding is successful is received from the relay R (S52), and it is determined whether the decoding of the relay R is successful (S53). Accordingly, if the relay R does not succeed in decoding, the data is transmitted to the destination D as shown in FIG. 4B by using an interleaver different from the interleaver used when transmitting data in step S51 (S54).

6a to 6c are time slots and a conceptual diagram of a data transmission system and method according to a third embodiment of the present invention.

First, source S sends data to repeater R and destination D simultaneously via time slot 1. The destination D then transmits the instantaneous SNR information of the channel between the source S and the destination D and the instantaneous SNR information of the channel between the relay R and the destination D through the minislot, respectively. The repeater R decodes the received data and transmits the success information to the source S through the signaling minislot.

At this time, SNR _RD which is the instantaneous SNR of the channel between the relay R and the destination D is compared with SNR _SD which is the instantaneous SNR of the channel between the source S and the destination D. Accordingly, if SNR _RD + margin> SNR _{SD, the} relay R transmits data to the destination D, and if SNR _RD + margin <SNR _{SD, the} source S transmits data to the destination D. In this case, if SNR _RD + margin> SNR _SD , the relay R transmits data to the destination D because the state of the channel between the relay R and the destination D is better than that of the channel between the source S and the destination D. On the contrary, if SNR _RD + margin <SNR _SD , the source S transmits data to the destination D because the state of the channel between the source S and the destination D is better than the state of the channel between the relay R and the destination D. In this case, the subject to be compared can be at least one of the source S and the repeater R. When the source S makes such a comparison decision, it informs the repeater R of the result to perform the next operation. Likewise, when the repeater R makes such a comparison decision, the source S is notified of the result to the source S to perform the next operation. Both source S and repeater R may make this comparison. In this case, signaling for transmitting the result information of the comparison decision in each case may be easily performed by those skilled in the art, and thus the description thereof is omitted.

More specifically, when SNR _RD + margin> SNR _SD , if repeater R succeeds in decoding the received data, as shown in FIG. 6A, repeater R is different from the interleaver that source S previously used to transmit data in time slot 1. The interleaver is used to send data through time slot 2 to destination D. That is, in this case, since the state of the channel between the relay R and the destination D is better than the state of the channel between the source S and the destination D, the relay R transmits data to the destination D.

If the repeater R does not succeed in decoding the received data when SNR _RD + margin> SNR _SD , the repeater R selectively selects only those whose instantaneous SNR is greater than or equal to a predetermined threshold for each subcarrier, as shown in FIG. 6B. Send to destination D via time slot 2. Since the method is the same as the method of FIG. 2 described above, it is omitted here. In this case, although the relay R has not succeeded in decoding the received data, the relay R transmits data to the destination D because the state of the channel between the relay R and the destination D is better than that of the channel between the source S and the destination D. However, since the decoding was not successful, only the subcarriers whose SNRs exceed the predetermined threshold are partially transmitted to the destination D for each subcarrier.

On the other hand, if SNR _RD + margin <SNR _SD , as shown in FIG. 6C, the source S transmits data to the destination D through time slot 2 using an interleaver different from the interleaver previously used to transmit data in time slot 1. That is, in this case, since the state of the channel between the source S and the destination D is better than the state of the channel between the relay R and the destination D, the source S transmits data to the destination D.

An operation flowchart of the source S in the third embodiment is as shown in FIG. 7.

First, the source S transmits data to the destination D and the relay R (S71). Then, from the destination D, the instantaneous SNR information of the channel between the source S and the destination D, and the instantaneous SNR information of the channel between the repeater R and the destination D are received, and information about whether decoding is successful from the repeater R is received (S72). . Then, SNR _RD , which is the instantaneous SNR of the channel between the relay R and the destination D, is compared with SNR _SD , which is the instantaneous SNR of the channel between the source S and the destination D, and the data is processed in the process of S71 when SNR _RD + margin <SNR _SD (S73). The data is transmitted to the destination D as shown in FIG. 6C by using an interleaver different from the interleaver used at the time of transmission (S74).

8 is a flowchart illustrating the operation of the repeater R in the third embodiment.

The relay R receives data from the source S (S80), and receives instantaneous SNR information of the channel between the source S and the destination D from the destination D, and instantaneous SNR information of the channel between the relay R and the destination D (S81). Then, the data received from the source S is decoded (S82) and the success information is transmitted to the source S (S83). The SNR _RD which is the instantaneous SNR of the channel between the repeater R and the destination D is compared with the SNR _SD which is the instantaneous SNR of the channel between the source S and the destination D, and is equal to SNR _RD + margin> SNR _SD (S84). It is determined whether the decoding is successful (S85). At this time, if the relay R has successfully decoded, the data is transmitted to the destination D as shown in FIG. 6A by using an interleaver different from the interleaver used when the source S transmits the data in step S80 (S86). On the other hand, if the relay R does not succeed in decoding, the data received from the source S is classified by subcarriers (S87). In operation S88, it is determined whether an instantaneous SNR of data divided by subcarriers is greater than a predetermined threshold value. Accordingly, only the subcarriers having an instantaneous SNR greater than the threshold are transmitted to the destination D (S89). Otherwise, the subcarrier is not transmitted (S90).

Hereinafter, the fourth and fifth embodiments will be described in which the present invention is applied to a partial space-time block code (STBC) in which antennas of a source and a repeater are distributed.

9A to 9C are time slots and conceptual diagrams of a data transmission system and method according to a fourth exemplary embodiment of the present invention, and are applied when a source, a repeater, and a destination are configured with only a single antenna.

First, source S transmits STBC to repeater R and destination D simultaneously through time slot 1. The destination D then transmits the instantaneous SNR information of the channel between the source S and the destination D and the instantaneous SNR information of the channel between the relay R and the destination D through the minislot, respectively. The repeater R decodes the received STBC and transmits the success information to the source S through the signaling minislot.

At this time, SNR _RD which is the instantaneous SNR of the channel between the relay R and the destination D is compared with SNR _SD which is the instantaneous SNR of the channel between the source S and the destination D. In this case, the subject to be compared can be at least one of the source S and the repeater R. When the source S makes such a comparison decision, it informs the repeater R of the result to perform the next operation. Likewise, when the repeater R makes such a comparison decision, the source S is notified of the result to the source S to perform the next operation. Both source S and repeater R may make this comparison. In this case, signaling for transmitting the result information of the comparison decision in each case may be easily performed by those skilled in the art, and thus the description thereof is omitted.

More specifically, when SNR _RD + margin> SNR _SD , if the relay R succeeds in decoding the received STBC, as shown in FIG. 9A, the source S and the relay R, when the source S previously transmitted the STBC in time slot 1, may be used. The interleaver and the other interleaver are used to transmit STBC through time slot 2 to destination D, respectively.

And when SNR _RD + margin> SNR _SD , if the relay R does not succeed in decoding the received STBC, as shown in FIG. 9B, the relay R selectively selects only those whose instantaneous SNR is greater than or equal to a predetermined threshold for each subcarrier with respect to the received STBC. Send to destination D via time slot 2. Since the method is the same as the method of FIG. 2 described above, it is omitted here. Here, the repeater transmits data using an interleaver different from the interleaver used when the source S previously transmits STBC in time slot 1 unlike in FIG. 2. In this case, the source S also transmits STBC to the destination D. However, at this time, it is preferable that the sub-streams of the STBC transmitted by the relay R and the source S are different.

On the other hand, if SNR _RD + margin <SNR _SD , as shown in FIG. 9C, the _ST S transmits STBC to destination D through time slot 2 using an interleaver different from the interleaver previously used to transmit data in time slot 1. That is, in this case, since the state of the channel between the source S and the destination D is better than the state of the channel between the relay R and the destination D, the source S transmits the STBC to the destination D.

If we apply the fourth embodiment using a single antenna to a mobile repeater, the application is applied to the downlink where the base station is the source and the mobile station is the destination, and the uplink where the mobile station is the source and the base station is the destination. All is easy.

An operation flowchart of the source S in the fourth embodiment is as shown in FIG. 10.

First, the source S transmits STBC to the destination D and the relay R (S101). In addition, instantaneous SNR information of the channel between the source S and the destination D and the instantaneous SNR information of the channel between the repeater R and the destination D are received from the destination D, and information about whether or not decoding is successful is received from the repeater R (S102). . The SNR _RD which is the instantaneous SNR of the channel between the relay R and the destination D is compared with the SNR _SD which is the instantaneous SNR of the channel between the source S and the destination D, and is received at S102 when SNR _RD + margin> SNR _SD (S103). The decoding success of the repeater R is determined with reference to the decoding information (S104). At this time, if the relay R has successfully decoded, the source S transmits the STBC to the destination D as shown in FIG. 9A by using an interleaver different from the interleaver used when transmitting the STBC in step S101 (S105). On the other hand, if the relay R does not succeed in decoding, the source S transmits STBC to the destination D in a substream different from the relay R as shown in FIG. 9B (S106). If SNR _RD + margin> SNR _SD in step S103, that is, SNR _RD + margin <SNR _SD , the source S uses an interleaver different from the interleaver used when transmitting STBC in step S101, as shown in FIG. 9C. The STBC is transmitted to the destination D (S105).

11 is a flowchart illustrating the operation of the repeater R in the fourth embodiment.

The relay R receives the STBC from the source S (S110), and receives the instantaneous SNR information of the channel between the source S and the destination D from the destination D and the instantaneous SNR information of the channel between the relay R and the destination D (S111). The STBC received from the source S is decoded (S112), and the success information is transmitted to the source S (S113). Then, SNR _RD , which is the instantaneous SNR of the channel between the relay R and the destination D, and SNR _SD , which is the instantaneous SNR of the channel between the source S and the destination D, are compared, and if SNR _RD + margin> SNR _SD (S114), It is determined whether the decoding is successful (S115). At this time, if the decoding is successful, the relay R transmits the STBC to the destination D as shown in FIG. 9A by using an interleaver different from the interleaver used when the source S transmits the STBC in step S110 (S116). On the other hand, if the decoding is not successful, the repeater R divides the data received from the source S by subcarriers (S117). Then, it is determined whether the instantaneous SNR of STBCs classified by subcarriers is larger than a predetermined threshold value (S118). Accordingly, the relay R transmits only the subcarriers whose instantaneous SNR is larger than the threshold value to the destination D as shown in FIG. 9B using an interleaver different from the interleaver used when the source S transmits the STBC (S119). Otherwise, the subcarrier is not transmitted (S120).

12 is a time slot and conceptual diagram of a data transmission system and method according to a fifth embodiment of the present invention, and is applied to a multi-antenna system in which a source, a repeater, and a destination are configured with a plurality of antennas. In particular, the following description will be given of a case in which a source simultaneously transmits STBC to a plurality of repeaters taking advantage of the characteristics of a multi-antenna system.

First, the source S simultaneously transmits STBC to the relays R1 to Rn and the destination D through time slot 1. Source S then retransmits the particular substream of STBC to destination D via time slot 2. At this time, the repeater having successfully decoded among the repeaters R1 to Rn reconfigures the substream of STBC into a substream different from the link with the source S according to the configuration of the antenna, and transmits it to the destination D. However, the repeater which does not succeed in decoding among the repeaters R1 to Rn reconfigures the substream only for the subcarriers that have successfully detected the detection because the received signal level is high and retransmits the destination D. That is, the repeater selectively reconfigures the substream and retransmits it to the destination D only those whose instantaneous SNR is greater than or equal to a predetermined threshold.

13 is a flowchart illustrating the operation of one repeater in the fifth embodiment.

When the repeater receives the STBC from the source S (S131), the repeater decodes the received STBC (S132). At this time, if decoding is successful (S133), the substream of STBC is reconfigured and transmitted to a substream different from the link with the source S (S134). If the decoding is not successful, the received STBC is classified by subcarriers (S135). Then, it is determined whether the instantaneous SNR of the STBCs classified by subcarriers is larger than a predetermined threshold value (S136). Accordingly, the substream is reconstructed only for subcarriers having an instantaneous SNR greater than a threshold value and retransmitted to the destination D (S137). Otherwise, the subcarrier is not transmitted (S138).

If the fifth embodiment using a plurality of antennas in a fixed repeater is applied, it is easy to apply the downlink to which the base station is the source and the mobile station is the destination.

As described above, the present invention provides a system and method for transmitting data using a repeater in a wireless communication system based on a multi-carrier.

This invention is largely divided into a case where a repeater performs decoding of received data and a case where it is not. Accordingly, the present invention is characterized in that the repeater selectively transmits only subcarriers with high instantaneous SNR when the repeater does not perform decoding. When the decoding fails, the repeater may decode data using a different interleaver from the source, or the repeater may reconfigure and transmit only a subcarrier having a high instantaneous SNR.

In addition, the present invention is not simply applied to the conventional transmission scheme, but is characterized by using the transmission characteristics of the multi-carrier, such as retransmission using an independent interleaver, partially transmitting a subcarrier, or applying a distributed STBC.

The present invention having such a feature is applicable to an orthogonal frequency-division multiplexing access (OFDMA) system based on time division duplex (TDD) and hybrid division duplex (HDD). In addition, it is applicable to a frequency division duplex (FDD) -FH (Frequency Hopping) -OFDMA-based air interface. In addition, 4G based on other OFDMA (Fourth-Generation) Can be used in cellular systems.

According to the present invention, the channel diversity effect can be obtained by generating an independent channel by using an interleaver different from the previous one when retransmitting data.

In addition, it is possible to obtain an effect of improving performance by determining the state of the channel based on the instantaneous SNR information of the channel and determining whether to use the relay R according to the state of the channel.

Claims (30)

delete In a wireless communication system based on a multi-carrier, a method for transmitting data from a source to a destination using a repeater, A source transmitting data to a destination and a repeater; Receiving and decoding the data transmitted from the source by the repeater; If the decoding is successful, transmitting, by the repeater, the received data to the destination; And If the decoding fails, the source transmits the data to the destination using an interleaver different from a previous interleaver. 3. The method of claim 2, And transmitting, by the repeater, the result of performing the decoding to the source, in the multi-carrier-based wireless communication system. In a wireless communication system based on a multi-carrier, a method for transmitting data from a source to a destination using a repeater, A source transmitting data to a destination and a repeater; Receiving and decoding the data transmitted from the source by the repeater; Comparing channel state information between the repeater and the destination and channel state information between the source and the destination; If the channel state between the repeater and the destination is better than the channel state between the source and the destination, and the decoding succeeds, the repeater transmits the received data to the destination using an interleaver different from a previous interleaver; If the channel state between the repeater and the destination is better than the channel state between the source and the destination, and the decoding fails, the repeater distinguishes the received data by subcarriers so that a signal-to-noise ratio of the subcarriers is equal to or greater than a predetermined threshold. Transmitting only to the destination; And If the channel state between the source and the destination is better than the channel state between the repeater and the destination, then the source transmits the data to the destination using an interleaver different from a previous interleaver. Data transmission method in a wireless communication system based on. The method of claim 4, wherein Comparing the channel state information, the data transmission method in a multi-carrier based wireless communication system, characterized in that performed in the repeater. The method of claim 4, wherein Comparing the channel state information, the data transmission method in a multi-carrier based wireless communication system, characterized in that performed at the source. The method according to any one of claims 5 and 6, Transmitting, by the repeater, the result of performing the decoding to the source; And transmitting, by the destination, channel state information between the repeater and the destination and channel state information between the source and the destination to the source and the repeater. How to transfer data from the system. The method according to any one of claims 5 and 6, If the data is a space-time block code, If the channel state between the repeater and the destination is better than the channel state between the source and the destination, and the decoding succeeds, the source transmitting the data to the destination using an interleaver different from the previous interleaver; If the channel condition between the repeater and the destination is better than the channel condition between the source and the destination, and the decoding fails, the source further comprises transmitting the data to the destination in a different substream from the repeater. A data transmission method in a wireless communication system based on a multi-carrier characterized in that. The method of claim 8, If the channel state between the repeater and the destination is better than the channel state between the source and the destination, and the decoding fails, And the repeater transmits the data to the destination in a substream different from the source, using an interleaver different from the previous interleaver. The method of claim 9 The source, the repeater, and the destination is a data transmission method in a multi-carrier based wireless communication system, characterized in that it comprises a single antenna. In a wireless communication system based on a multi-carrier, a method for transmitting a space-time block code from a source having a plurality of antennas to a destination having a plurality of antennas by using a repeater having a plurality of antennas, The source transmitting the space-time block code to the destination and the repeater; The source retransmitting a specific substream of the space-time block code to the destination; Receiving and decoding the space-time block code transmitted from the source by the repeater; If the decoding is successful, the repeater reconstructs the received subspace of the space-time block code into a substream different from the link with the source according to the configuration of the antenna and transmits the substream to the destination; And If the decoding fails, the repeater includes reconstructing a substream only for the subcarriers that have successfully detected the subcarriers of the received space-time block code and transmitting the substream to the destination. How to transfer data from the system. The method of claim 11, The repeater is a data transmission method in a wireless communication system based on a multi-carrier, characterized in that a plurality. delete In a wireless communication system based on a multi-carrier, a system for transmitting data from a source to a destination using a repeater, A source for transmitting data to a destination and a repeater, and transmitting the data to the destination using an interleaver different from a previous interleaver if the repeater fails to decode the data; Receiving a data transmitted from the source to perform the decoding, and if the decoding is successful, a repeater for transmitting the received data to the destination; data transmission in a multi-carrier based wireless communication system system. 15. The method of claim 14, The repeater is a data transmission system in a multi-carrier based wireless communication system, characterized in that for transmitting the result of performing the decoding to the source. In a wireless communication system based on a multi-carrier, a system for transmitting data from a source to a destination using a repeater, A source for transmitting data to a destination and a repeater, and transmitting the data to the destination using an interleaver different from a previous interleaver if the channel state between itself and the destination is better than the channel state between the repeater and the destination; Receiving and decoding data transmitted by the source, comparing channel state information between itself and the destination with channel state information between the source and the destination, and as a result of the comparison, the channel state between the source and the destination is determined by the source and the destination; When the decoding is successful and the channel state is better than the destination, the received data is transmitted to the destination using an interleaver different from the previous interleaver, and as a result of the comparison, the channel state between the self and the destination is the channel between the source and the destination. And a repeater for distinguishing the received data by subcarriers and transmitting only the signal-to-noise ratio of the subcarriers to the destination if the decoding fails. Wireless communication system Data transmission system in. The method of claim 16, The repeater is a data transmission system in a multi-carrier based wireless communication system, characterized in that for transmitting the decoding result and the comparison result information of the channel state information to the source. The method of claim 17, And the destination transmits channel state information between the repeater and itself and channel state information between the source and itself to the source and the repeater. The method of claim 16, If the data is a space-time block code, The source is, If the channel state between the repeater and the destination is better than the channel state between itself and the destination, and the decoding is successful, the data is transmitted to the destination using an interleaver different from the previous interleaver, The channel state between the repeater and the destination is better than the channel state between itself and the destination, and if the decoding fails, the data is transmitted to the destination in a substream different from the repeater. Data transmission system in a wireless communication system based on. The method of claim 19, If the channel state between the repeater and the destination is better than the channel state between the source and the destination, and the decoding fails, And the repeater transmits the data to the destination in a substream different from the source, using an interleaver different from the previous interleaver. The method according to any one of claims 19 and 20, And said source, said repeater and said destination comprise a single antenna. In a wireless communication system based on a multi-carrier, a system for transmitting data from a source to a destination using a repeater, Transmits data to a destination and a repeater, and compares channel state information between itself and the destination and channel state information between the repeater and the destination, and as a result of the comparison, a channel state between itself and the destination is a channel state between the repeater and the destination. A source for transmitting the data to the destination, preferably using an interleaver different from the previous interleaver; Receives and decodes the data transmitted by the source, and if the channel state between itself and the destination is better than the channel state between the source and the destination and the decoding is successful, the received data is stored using an interleaver different from the previous interleaver. Transmit to a destination, and if the channel state between itself and the destination is better than the channel state between the source and the destination, and the decoding fails, the received data is distinguished by subcarriers and only the signal-to-noise ratio of the subcarriers is greater than or equal to a certain threshold. And a repeater for transmitting to the destination a data transmission system in a multi-carrier based wireless communication system. 23. The method of claim 22, The source is a data transmission system in a multi-carrier based wireless communication system, characterized in that for transmitting the comparison result information of the channel state information to the repeater. 23. The method of claim 22, The repeater is a data transmission system in a multi-carrier based wireless communication system, characterized in that for transmitting the result of performing the decoding to the source. 23. The method of claim 22, And the destination transmits channel state information between the repeater and itself and channel state information between the source and itself to the source and the repeater. 23. The method of claim 22, If the data is a space-time block code, The source is, If the channel state between the repeater and the destination is better than the channel state between itself and the destination, and the decoding is successful, the data is transmitted to the destination using an interleaver different from the previous interleaver, The channel state between the repeater and the destination is better than the channel state between itself and the destination, and if the decoding fails, the data is transmitted to the destination in a different substream from the repeater. Data transmission system in wireless communication system. The method of claim 26, If the channel state between the repeater and the destination is better than the channel state between the source and the destination, and the decoding fails, And the repeater transmits the data to the destination in a substream different from the source, using an interleaver different from the previous interleaver. The method according to any one of claims 26 and 27, And said source, said repeater and said destination comprise a single antenna. In a wireless communication system based on a multi-carrier, a system for transmitting a space-time block code from a source having a plurality of antennas to a destination having a plurality of antennas by using a repeater having a plurality of antennas, A source for transmitting a space-time block code to a destination and a repeater, and retransmitting a specific substream of the transmitted space-time block code to the destination; Receives and decodes the space-time block code transmitted by the source, and if the decoding is successful, reconstructs the received sub-space of the space-time block code into a substream different from the link with the source according to the configuration of the antenna to the destination. And a repeater for reconstructing a substream and transmitting the substream to only the subcarriers that have successfully detected the subcarriers of the received space-time block code if the decoding fails. Data transmission system. The method of claim 29, The repeater is a data transmission system in a wireless communication system based on multiple carriers, characterized in that a plurality.

Images