KR20110024232A - Cooperative communication system based on code division miltiple access and method thereof - Google Patents

Abstract

PURPOSE: A cooperative communication system based on CDMA(Code Division Multiple Access) and a method thereof are provided to prevent the lowering of the transmission rate while maintaining the diversity gain. CONSTITUTION: A first code and a second code are allocated to a first terminal(100). A third code and a fourth code are allocated to a second terminal(200). A target terminal(300) multiplies allocated symbols of the first and the second terminal with received signals from the first and the second terminals. The target terminals estimate the transmitted signal of each terminal.

Description

Cooperative communication system based on code division multiple access and its method {COOPERATIVE COMMUNICATION SYSTEM BASED ON CODE DIVISION MILTIPLE ACCESS AND METHOD THEREOF}

The present invention relates to a code division multiple access based cooperative communication system and method for improving communication reliability through a relay terminal, and more particularly, to a cooperative communication system based on code division multiple access capable of bidirectional communication and a method thereof. will be.

Cooperative communication, which achieves cooperative diversity gain with the help of repeaters in a wireless environment, is a technology that enables reliable communication at low cost by overcoming path loss caused by distance and obstacles.

The cooperative communication is composed of a transmitter, a repeater, and a receiver, and the receiver can obtain diversity gain by receiving signals having independent characteristics from the transmitter and the repeater, which are separated by a certain distance.

가 할당되어 있으며, 제2 단말(20)에는 부호

가 할당되어 있다. 1A and 1B are diagrams illustrating a cooperative communication step of a code division multiple access based cooperative communication system according to the prior art. The code division multiple access based cooperative communication system illustrated in FIGS. 1A and 1B includes a first terminal 10, a second terminal 20, and a target terminal 30 capable of bidirectional communication. Here, the first terminal 10 and the second terminal 20 serve as a transmitter for transmitting a signal and a relay for receiving signals from the second terminal 20 and the first terminal 10 and transmitting the signals to the target terminal. Here, the first terminal 10 has a sign

Is assigned, the second terminal 20 has a sign

Is assigned.

The first terminal 10 and the second terminal 20 in cooperation with each other to communicate to the target terminal 30 is as follows.

에 자신에게 할당된 부호

을 곱하여 생성된 신호

을 제2 단말(20)와 목적단말(30)에 전송한다. 그리고, 제2 단말(20) 역시 자신의 첫 번째 신호

에 자신에게 할당된 부호

을 곱하여 생성된 신호

를 제1 단말(10)과 목적단말(30)에 전송한다. In step 1 (broadcast step) illustrated in FIG. 1A, the first terminal 10 transmits its first transmission signal.

Code assigned to myself

Signal generated by multiplying

It transmits to the second terminal 20 and the target terminal 30. And, the second terminal 20 also its first signal

Code assigned to myself

Signal generated by multiplying

It transmits to the first terminal 10 and the target terminal (30).

에 제2 단말(20)에 할당된 부호

을 곱하여 생성된 신호

를 목적단말(30)에 전송한다. 또한, 제2 단말(20)는 제1 단말(10)의 추정된 신호

에 제1 단말(10)에 할당된 부호

을 곱하여 생성된 신호

을 목적단말(30)에 전송한다. In the second step (cooperative transmission step) shown in FIG. 1B, the first signal of the counterpart terminal estimated by each terminal is multiplied by a code assigned to the counterpart terminal and then transmitted. That is, the first terminal 10 is the estimated signal of the second terminal 20

Code assigned to the second terminal 20 to

Signal generated by multiplying

To the destination terminal (30). In addition, the second terminal 20 is an estimated signal of the first terminal 10.

Code assigned to the first terminal 10 to

Signal generated by multiplying

Is transmitted to the target terminal (30).

를 각각 2개의 단말(제1 단말(10)과 제2 단말(20))로부터 모두 수신하게 되므로 다이버시티 이득을 얻어 신뢰도 높은 신호를 추정할 수 있게 된다. Thus, the target terminal 30 is the first signal of the first terminal 10 and the second terminal 20 Wow

Are received from two terminals (the first terminal 10 and the second terminal 20), respectively, so that a diversity gain can be obtained to estimate a reliable signal.

를 목적단말(30)로 전달하면, 목적단말(30)은 제2 단말(20)로부터 제2 단계에서

를 동시에 수신하게 되므로,

와

신호가 서로 섞이게 된다. 여기서 두 가지 신호는 모두

부호가 결합된 신호이므로 목적단말(30)은 두 가지 신호를 분리할 수 없다. However, in the second step (cooperative transmission step), the first terminal 10 transmits the second transmission signal.

When the transfer to the destination terminal 30, the destination terminal 30 in the second step from the second terminal 20

Receive simultaneously,

Wow

The signals are mixed together. Where both signals are

Since the code is a combined signal, the target terminal 30 cannot separate the two signals.

Therefore, according to the prior art, the cooperative transmission procedure is repeated every two stages, i.e., the broadcast stage and the cooperative transmission stage each time, in which case each terminal transmits only one independent signal during the two stages. There is a disadvantage in that the transmission rate is reduced to 1/2. That is, since the target terminal receives only the first signal of the first terminal 10 and the second terminal 20 during the two stages, the transmission rate is only 1/2, resulting in lowering the frequency efficiency. This will be reduced.

Accordingly, an aspect of the present invention is to provide a communication system and method for a code division multiple access-based cooperative communication system capable of preventing a drop in data rate while maintaining diversity gain.

In accordance with one aspect of the present invention, there is provided a cooperative communication method based on code division multiple access, in which a first terminal performs cooperative communication with a second terminal and a target terminal. Multiplying the allocated first code and the second code and transferring them step by step to the second terminal and the target terminal, respectively, estimating a signal received from the second terminal in a previous step, and adding the estimated signal to the estimated signal And multiplying the third code and the fourth code assigned to the second terminal by alternating transmission.

In a first step, the first terminal transmits a signal generated by multiplying the first transmission signal by the first code to the second terminal and the target terminal, respectively, and transmits the first transmission signal to the first transmission signal of the second terminal. A signal multiplied by three codes can be received.

The first terminal transmits a signal generated by multiplying a second transmission signal by the second code to the second terminal and the target terminal in a second step, and received from the second terminal in the first step. The signal may be estimated and multiplied by the third code to the second terminal and the target terminal, respectively.

In the step m +1 ( m is a natural number of 1 or more), the first terminal generates a signal generated by multiplying the m + 1 th transmission signal by the first code or the second code, and the second terminal and the target terminal. Each signal may be transmitted to the second terminal and the target terminal by estimating a signal received from the second terminal in step m , and multiplying the estimated signal by the fourth code or the third code.

The target terminal can estimate the received signal through the following equation.

는 상기 제1 단말이 전달하는 k번째 전송 신호를 추정하여 생성된 신호이고,

는 상기 목적단말이 추정하는 상기 제1 단말과의 채널 응답의 켤레복소수를 나타내며,

는 상기 목적단말이 추정하는 상기 제2 단말과의 채널 응답의 켤레복소수를 나타낸다. here,

Is a signal generated by estimating a k- th transmission signal transmitted by the first terminal,

Denotes the complex conjugate of the channel response with the first terminal estimated by the target terminal,

Denotes the complex conjugate of the channel response with the second terminal estimated by the target terminal.

In a cooperative communication system based on code division multiple access according to another embodiment of the present invention, in a cooperative communication system including a first terminal, a second terminal, and a destination terminal,

A first terminal assigned a first code and a second code, a second terminal assigned a third code and a fourth code, and the first terminal or the second terminal in a signal received from the first terminal and the second terminal And an objective terminal for estimating a signal transmitted for each terminal by multiplying a code assigned to the terminal, wherein the first terminal alternately multiplies the signal to be transmitted by the first code and the second code. Each signal is transmitted to the terminal, and the signal received from the second terminal in the previous step is estimated, and the estimated signal is alternately multiplied by the third code and the fourth code to be transmitted step by step.

As described above, according to the present invention, two codes are assigned to each communication terminal, and then alternately combined and transmitted to a signal, thereby requiring only one broadcast step while maintaining the same diversity gain as in the conventional cooperative communication method. The fall can be prevented. In addition, it enables reliable high-speed communication at low power and low cost in cooperative communication systems with poor channel conditions.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

2 is a diagram illustrating a code division multiple access based cooperative communication system according to an exemplary embodiment of the present invention.

The cooperative communication system based on CODE DIVISION MILTIPLE ACCESS (CDMA) illustrated in FIG. 2 includes a first terminal 100, a second terminal 200, and a destination terminal 300 capable of bidirectional communication. Here, the first terminal 100 serves as a transmitter for transmitting a signal and a relay for receiving a signal from the second terminal 200 and transmitting the signal to the target terminal 300. Similarly, the second terminal 200 serves as a transmitter for transmitting a signal and a repeater for receiving a signal from the first terminal 100 and transmitting the signal to the target terminal 300.

,

)가 할당되고, 제2 단말(200)에 2개의 부호(

,

)가 할당된다. According to the cooperative communication system according to the present invention, the first terminal 100 and the second terminal 200 are each assigned two codes, and alternately use the two assigned codes to transmit a signal. That is, the first terminal 100 has two codes (

,

) Is assigned to the second terminal 200 and two codes (

,

) Is assigned.

The first terminal 100 and the second terminal 200 estimate and re-encode the signal received from the other terminal, multiply their new signal by a different code from the previous step, and relay the transmission together. The destination terminal 300 receives a signal transmitted from the first terminal 100 and the second terminal 200, and estimates an original signal from the received signal.

3A and 3B are diagrams illustrating a cooperative communication step of a code division multiple access based cooperative communication system according to an exemplary embodiment of the present invention. In particular, Figure 3a shows a broadcast step corresponding to step 1, Figure 3b shows a cooperative transmission step corresponding to step m , which is a step after step 1.

Hereinafter, the operations of the first terminal 100, the second terminal 200, and the target terminal 300 constituting the cooperative communication system will be described in detail with reference to Table 1.

, 제2 단말(200)과 목적단말(300) 사이의 채널을

, 목적단말에서의 m단계의 가산잡음을

이라 정의한다. 또한 제1 단말(100)이 보내는 k번째 신호를

, 제2 단말(200)이 보내는 k번째 신호를

라 가정한다. 또한,

는 제2 단말(200)이 제1 단말(100)로부터 수신한 k번째 신호(

)를 추정한 것이고,

는 제1 단말(100)이 제2 단말(200)로부터 수신한 k번째 신호(

)를 추정한 것이다.Table 1 is a time-series diagram of the components of the signal received by the target terminal 300 through the first terminal 100 and the second terminal 200 in step by step. It is assumed that each channel is fixed while the terminals cooperatively transmit. The channel between the first terminal 100 and the target terminal 300

, The channel between the second terminal 200 and the target terminal 300

M added noise at the target terminal

This is defined as. In addition, the k- th signal sent by the first terminal 100

, The k- th signal sent by the second terminal 200

Assume Also,

The k- th signal received by the second terminal 200 from the first terminal 100 (

) Is estimated,

The k- th signal received by the first terminal 100 from the second terminal 200 (

) Is estimated.

In the present invention, as shown in Table 1, the symbols for each terminal are alternately used two times, which is different from each other. This allows each terminal to separate signals even when receiving various signals at the same time. It only serves to be required once.

과

이다. Referring to Table 1 and Figure 3a in detail with respect to the broadcast step 1, in step 1, each terminal multiplies its first signal by the first code assigned to each of them to broadcast to the other terminal and the target terminal , The signal is respectively

and

to be.

에 제1 단말(100)에게 할당된 첫 번째 부호

을 곱하여 생성된 신호

를

채널을 통하여 목적단말(300)로 전송한다. 또한, 제2 단말(200)은 첫 번째 신호

에 제2 단말(200)에게 할당된 첫 번째 부호

을 곱하여 생성된 신호

를 채널을 통하여 목적단말(300)로 전송한다. 따라서, 1 단계에서 목적단말(300)이 수신하는 신호 r(t)는

+

+

로 표현할 수 있다. That is, in the first stage (broadcast stage), the first terminal 100 is the first signal

The first sign assigned to the first terminal 100 to

Signal generated by multiplying

To

It transmits to the target terminal 300 through the channel. In addition, the second terminal 200 is the first signal

The first sign assigned to the second terminal 200 to

Signal generated by multiplying

To It transmits to the target terminal 300 through the channel. Therefore, in step 1, the signal r (t) received by the target terminal 300 is

+

+

.

과

이다. Table 1 and Figure 3b will be described in detail for the cooperative transmission step after step 1. For convenience of description, m steps are shown in FIG. 3B. In step 2, each terminal multiplies its second signal by the second sign assigned to each of them and estimates the signal received from the other terminal in the previous step and adds the value obtained by multiplying the first sign assigned to the other terminal by the target terminal. Directly and relay to the signal,

and

to be.

에 두 번째 부호

를 곱하여 신호

를 생성하고, 1단계에서 제2 단말(200)로부터 수신한 신호를 추정(

)하여 제2 단말(200)에 할당된 첫 번째 부호(

)를 곱하여 신호

를 생성한다. 그리고 제1 단말(100)은 두 신호를 합한 신호

를 목적단말(300)로 전송한다. That is, in the second step (cooperative transmission step), the first terminal 100 is the second signal

Second sign on

Multiply by

Generates a signal and estimates the signal received from the second terminal 200 in step 1

The first sign assigned to the second terminal 200

Multiply by)

. And the first terminal 100 is a signal of the sum of the two signals

To transmit to the destination terminal (300).

에 두 번째 부호

를 곱하여 신호

를 생성하고, 1단계에서 제1 단말(200)로부터 수신한 신호(

)를 추정(

)하여 제1 단말(100)에 할당된 첫 번째 부호(

)를 곱하여 신호

를 생성한다. 그리고 제2 단말(200)은 두 신호를 합한 신호

를 목적단말(300)로 전송한다. 따라서, 2 단계에서 목적단말(300)이 수신하는 신호 r(t+T)는

(

) +

(

)+

로 표현할 수 있다. Similarly, the second terminal 200 is the second signal

Second sign on

Multiply by

And a signal received from the first terminal 200 in step 1

)

The first sign assigned to the first terminal 100

Multiply by)

. And the second terminal 200 is a signal of the sum of the two signals

To transmit to the destination terminal (300). Therefore, in step 2, the signal r (t + T) received by the target terminal 300 is

(

) +

(

) +

.

과

이다. In step 3 (cooperative transmission), each terminal multiplies its third signal by the first code assigned to each of them and multiplies the second code assigned to the other terminal by estimating the signal received from the other terminal in the previous step. The values are added directly and relayed to the target terminal.

and

to be.

에 첫 번째 부호

를 곱하여 신호

를 생성하고, 2단계에서 제2 단말(200)로부터 수신한 신호를 추정(

)하여 제2 단말(200)에 할당된 두 번째 부호(

)를 곱하여 신호

를 생성한다. 그리고 제1 단말(100)은 두 신호를 합한 신호

를 목적단말(300)로 전송한다. That is, in the third step (cooperative transmission step), the first terminal 100 is the third signal

First sign on

Multiply by

And estimate the signal received from the second terminal 200 in step 2 (

The second sign assigned to the second terminal 200

Multiply by)

. And the first terminal 100 is a signal of the sum of the two signals

To transmit to the destination terminal (300).

에 첫 번째 부호

를 곱하여 신호

를 생성하고, 2단계에서 제1 단말(200)로부터 수신한 신호(

)를 추정(

)하여 제1 단말(100)에 할당된 두 번째 부호(

)를 곱하여 신호

를 생성한다. 그리고 제2 단말(200)은 두 신호를 합한 신호

를 목적단말(300)로 전송한다. 따라서, 3 단계에서 목적단말(300)이 수신하는 신호 r(t+2T)는

(

) +

(

) +

로 표현할 수 있다. Similarly, the second terminal 200 is the third signal

First sign on

Multiply by

And a signal received from the first terminal 200 in step 2

)

) And the second code assigned to the first terminal 100 (

Multiply by)

. And the second terminal 200 is a signal of the sum of the two signals

To transmit to the destination terminal (300). Therefore, in step 3, the signal r (t + 2T) received by the target terminal 300 is

(

) +

(

) +

.

과

를 적용하고, 짝수번째 단계에서는 제1 단말(100)과 제2 단말(200)은 각각 부호

과

를 적용하도록 한다. In this way, the first terminal 100 and the second terminal 200 transmits a signal to the target terminal 300 while sequentially converting the code in each step. That is, in the odd-numbered step, the first terminal 100 and the second terminal 200 each have a sign.

and

In the even step, the first terminal 100 and the second terminal 200 are respectively signed

and

To apply.

+

의 신호를 목적단말(300)로 전송하게 되고, 제2 단말(200)은

의 신호를 목적단말(300)로 전송하게 된다. 여기서 x는 m이 홀수라면 2, 짝수라면 1이고 y는 그 반대이다.In this manner, in step m , the first terminal 100

+

Is transmitted to the target terminal 300, the second terminal 200

Is transmitted to the target terminal (300). Where x is 2 if m is odd, 1 if even and y is the opposite.

,

,

,

)가 상호 간에 직교한다면, 목적단말(300)에서는 동시에 들어오는 네 개의 신호를 분리할 수 있게 된다. 또한 각 신호들은 두 단계에 걸쳐 제1 단말(100)과 제2 단말(200)로부터 목적단말(300)로 전송되므로 다이버시티 이득을 얻을 수 있다. 이는 본 발명으로 인해 브로드캐스트 단계는 처음 시작 시 한번만 요구되므로 전송률이 1에 수렴하면서도 종래 기술과 동일한 다이버시티 이득을 얻을 수 있어 주파수 효율을 대폭 향상 시킬 수 있음을 의미한다.Here, the code used by the first terminal 100 and the second terminal 200 (

,

,

,

) Are orthogonal to each other, the target terminal 300 can separate the four signals coming in at the same time. In addition, since the signals are transmitted from the first terminal 100 and the second terminal 200 to the target terminal 300 in two steps, a diversity gain can be obtained. This means that the broadcast step is required only once at the first start, and therefore, the data rate converges to 1 and the same diversity gain as in the prior art can be obtained, thereby significantly improving frequency efficiency.

는 다음의 수학식 1과 같다. Signal for the target terminal 300 to estimate the k- th signal of the first terminal 100

Is the same as Equation 1 below.

는 목적단말(300)이 추정하는 제1 단말(100)과 목적단말(300) 사이의 채널 응답의 켤레복소수를 나타내며,

는 목적단말(300)이 추정하는 제2 단말(200)과 목적단말(300) 사이의 채널 응답의 켤레복소수를 나타낸다. 수신 신호에서 채널 응답은 채널 응답의 켤레복소수와 곱해져서 상쇄되고, 부호는 직교하므로, 동일한 부호가 곱해진 신호만 남게 되어 원하는 신호의 추출이 가능함을 할 수 있다.here,

Denotes the complex conjugate of the channel response between the first terminal 100 and the target terminal 300 estimated by the target terminal 300,

Denotes the complex conjugate of the channel response between the second terminal 200 and the target terminal 300 estimated by the target terminal 300. In the received signal, the channel response is canceled by multiplying by the complex conjugate of the channel response, and since the sign is orthogonal, only the signal multiplied by the same sign remains, so that a desired signal can be extracted.

는 다음의 수학식 2와 같다.Likewise, the target terminal 300 estimates the k- th signal of the second terminal 200.

Is the same as Equation 2 below.

As described above, even if the first terminal 100 and the second terminal 200 transmit their new signals at every step, the signals are transmitted by alternately using the two assigned codes. Since the terminal 300 can accurately separate the received signal can receive the signal with high reliability.

Hereinafter, the performance improvement when using the embodiment of the present invention through FIGS. 4 and 5 will be described.

4 is a graph comparing bit error rates of a non-cooperative communication method and a cooperative communication method according to an embodiment of the present invention when a channel code is not used in a Rayleigh channel model. FIG. 5 is a channel code of a Rayleigh channel model. Is a graph comparing bit error rates of the non-cooperative communication method and the cooperative communication method according to the embodiment of the present invention.

4 and 5, the vertical axis represents the bit error rate (BER), and the horizontal axis represents the signal-to-noise ratio (SNR) of the terminal 1-target terminal channel. In the simulation, it is assumed that time and frequency synchronization and channel estimation are perfect, and the signal-to-noise ratio of the first terminal 100-target terminal 300 channel and the signal-to-noise ratio of the second terminal 200-target terminal 300 channel The noise ratio is assumed to be the same. And, for a fair comparison, it is assumed that the power used by each terminal to relay its own signal and the signal of the other party is the same and the sum is the same as that of non-cooperative communication.

In the graph shown in FIG. 4, in the case of non-cooperative communication using a single antenna (Standard 1X1), non-cooperative communication using Alamouti's space-time block code (STBC) with two antennas In the present invention, the channel signal-to-noise ratio (SNR) between the terminals is 10 dB, 20 dB, and 30 dB, respectively. In addition, the graph shown in FIG. 5 evaluates the performance at the time of using a channel code on the conditions similar to FIG.

As can be seen in Figures 4 and 5, according to an embodiment of the present invention, as the channel signal-to-noise ratio (SNR) between terminals increases, the bit error rate decreases, and the non-cooperation using Alamouti's space-time block code (STBC) Compared with the communication, it can be seen that the performance is excellent.

4 and 5, in the cooperative transmission scheme according to the embodiment of the present invention, if only the channel signal-to-noise ratio (SNR) of the first terminal 100-the second terminal 200 is sufficiently secured (ideal repeater case) It can be seen that the frequency efficiency can be improved by reducing the frequency of the broadcast stage. In addition, when using the embodiment of the present invention, since it is possible to maintain the cooperative diversity, it can be confirmed that similar reliability is obtained by using two antennas.

As described above, according to the embodiment of the present invention, a plurality of codes are assigned to each communication terminal, and then alternately combined and transmitted to a signal, thereby requiring only one broadcast step while maintaining the same diversity gain as in the conventional cooperative communication method. The lowering of the transmission rate can be prevented. In addition, it enables reliable high speed communication at low power and low cost in the cooperative communication system with poor channel status.

On the other hand, in the above-described code division multiple access-based cooperative communication system, a method of preventing a drop in rate is implemented by computer-readable codes / instructions / programs. For example, the method may be implemented in a general-purpose digital computer operating the code / instructions / program using a computer readable recording medium. The computer-readable recording media may include magnetic storage media (ex, ROM, floppy disk, hard disk, magnetic tape, etc.), optical reading media (ex, CD-ROM, DVD, etc.) and carrier waves (ex, transmission via the Internet). Storage media, and the like. In addition, embodiments of the present invention may be implemented as a medium (s) containing computer readable code, such that a plurality of computer systems connected via a network can be distributed and processing operations. It is obvious that the functional programs, codes and code segments realized by the method of the present invention can be easily inferred by programmers in the technical field to which the present invention belongs.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1A and 1B are diagrams illustrating a cooperative communication step of a code division multiple access based cooperative communication system according to the prior art.

2 is a diagram illustrating a code division multiple access based cooperative communication system according to an exemplary embodiment of the present invention.

3A and 3B are diagrams illustrating a cooperative communication step of a code division multiple access based cooperative communication system according to an exemplary embodiment of the present invention.

4 is a graph comparing bit error rates of a non-cooperative communication method and a cooperative communication method according to an embodiment of the present invention when a channel code is not used in a Rayleigh channel model.

5 is a graph comparing bit error rates of a non-cooperative communication method and a cooperative communication method according to an embodiment of the present invention when a channel code is used in a Rayleigh channel model.

Claims (10)

In the method in which the first terminal performs the cooperative communication with the second terminal and the target terminal, Multiplying the first code and the second code allocated to the signal to be transmitted and transferring them step by step to the second terminal and the target terminal, respectively; Estimating a signal received from the second terminal in a previous step, and adding the multiplied by the third code and the fourth code assigned to the second terminal alternately and transmitting stepwise. Cooperative communication method based on multiple access. The method of claim 1, In the first step, the first terminal, Transmitting a signal generated by multiplying the first transmission signal by the first code, to the second terminal and the target terminal, respectively, And a code division multiple access method for receiving a signal obtained by multiplying the first transmission signal of the second terminal by the third code. The method of claim 2, In the second step, the first terminal, Transmitting a signal generated by multiplying a second transmission signal by the second code to the second terminal and the target terminal, respectively; Estimating a signal received from the second terminal in the first step, multiplying the estimated signal by the third code, and transmitting the multiplied signal to the second terminal and the target terminal, respectively. The method of claim 3, In the first terminal step m + 1 ( m is a natural number of 1 or more), Transmitting a signal generated by multiplying the m + 1th transmission signal by the first code or the second code to the second terminal and the target terminal, respectively Estimating a signal received from the second terminal in step m , and multiplying the estimated signal by the fourth code or the third code to transmit the multiplied signal to the second terminal and the target terminal, respectively. Communication method. The method of claim 4, wherein The target terminal is a cooperative communication method based on code division multiple access for estimating a received signal through the following equation:

here,

Is a signal generated by estimating a k- th transmission signal transmitted by the first terminal,

Denotes a complex conjugate of the channel response with the first terminal estimated by the target terminal,

Denotes the complex conjugate of the channel response with the second terminal estimated by the target terminal. In the cooperative communication system comprising a first terminal, a second terminal and the target terminal, A first terminal to which a first code and a second code are assigned; A second terminal to which a third code and a fourth code are assigned, and And a target terminal for estimating a signal transmitted for each terminal by multiplying a signal assigned to the first terminal or the second terminal by a signal received from the first terminal and the second terminal, The first terminal, Alternately multiplying the first code and the second code by a signal to be transmitted and transmitting the signals to the second terminal and the target terminal, respectively; And a step of estimating a signal received from the second terminal in a previous step, and multiplying the estimated signal by alternately multiplying the third code and the fourth code. The method of claim 6, In the first step, the first terminal, Transmitting a signal generated by multiplying the first transmission signal by the first code, to the second terminal and the target terminal, respectively, And a code division multiple access system for receiving a signal obtained by multiplying the first coded signal of the second terminal by the third code. The method of claim 7, wherein In the second step, the first terminal, Transmitting a signal generated by multiplying a second transmission signal by the second code to the second terminal and the target terminal, respectively; And a code division multiple access system for estimating a signal received from the second terminal in the first step, multiplying the estimated signal by the third code, and transmitting the multiplied signal to the second terminal and the target terminal, respectively. The method of claim 8, In the first terminal step m + 1 ( m is a natural number of 1 or more), Transmitting a signal generated by multiplying the m + 1th transmission signal by the first code or the second code to the second terminal and the target terminal, respectively Estimating a signal received from the second terminal in step m , and multiplying the estimated signal by the fourth code or the third code to transmit the multiplied signal to the second terminal and the target terminal, respectively. Communication system. 10. The method of claim 9, The target terminal is a cooperative communication system based on a code division multiple access for estimating a received signal through the following equation:

here,

Is a signal generated by estimating a k- th transmission signal transmitted by the first terminal,

Denotes the complex conjugate of the channel response with the first terminal estimated by the target terminal,

Denotes the complex conjugate of the channel response with the second terminal estimated by the target terminal.

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