KR101357490B1 - Adaptively cooperative communicating method and system thereof - Google Patents

Abstract

The present invention relates to an adaptive cooperative communication method, an adaptive cooperative communication relay terminal and a system thereof, and an adaptive cooperative communication method according to an embodiment of the present invention includes a first terminal and a second terminal for transmitting and receiving first data. An adaptive cooperative communication method of a relay terminal for performing adaptive cooperative communication and performing second data communication with a third terminal, the method comprising: a first step of receiving the first data from the first terminal; A second step of receiving a decoding determination message for determining whether the first data can be decoded from a terminal, and a third step of transmitting the first data to the second terminal according to the decoding determination message. It is possible to reduce the bit error rate between the terminal and the terminal for transmitting and receiving data.

Description

Adaptive cooperative communication method, adaptive cooperative communication relay terminal and its system {ADAPTIVELY COOPERATIVE COMMUNICATING METHOD AND SYSTEM THEREOF}

The present invention relates to an adaptive cooperative communication method, an adaptive cooperative communication relay terminal and a system thereof, and more particularly, to a technique of determining whether a relay terminal retransmits data according to whether a receiving terminal can decode data of a transmitting terminal. will be.

Recently, due to the proliferation of various wireless communication services, limited frequency resources are gradually getting saturated. In the future, the ever-increasing variety of wireless content and services will attract more users, which means that another frequency will need to be allocated. However, according to a report by the Federal Communications Commission (FCC), which is responsible for the frequency management policy of the United States, the actual spectrum utilization is very low, within 6.5%, which means that the existing frequency policy is efficient. It shows that it is not operating. Therefore, if the efficiency of finite frequency utilization can be improved, it suggests that the current shortage problem can be solved.

A representative technique proposed to solve the frequency shortage problem is a cognitive radio technology that can increase the efficiency of the spectrum. In addition to the primary system that is allowed to use a particular frequency, an unlicensed secondary system can gain access to the frequency that is granted to the primary system, resulting in higher spectral efficiency. Wireless communication systems have continually evolved to achieve greater reliability, wider coverage and performance of transmission and reception between terminals to meet the objectives of all who use them. Among them, MIMO (Multiple-Input-Multiple-Output) technology is well known as a technique for obtaining the transmit diversity gain generated by using multiple antennas in a transmitter and a receiver.

However, MIMO using multiple antennas is difficult to apply to small terminals such as cellular or sensor networks. Therefore, many researchers have proposed a cooperative communication technology that can achieve diversity gain by establishing a virtual MIMO environment between terminals having a single antenna. Cooperative communication uses a repeater between a transmitting end and a receiving end. When the channel status between the transmitter and receiver is better than a predetermined reference value, it can be determined that decoding can be performed immediately at the receiving end even if the process of retransmitting the signal transmitted from the transmitting end is omitted. In this case, an incremental relay technique has been developed that can increase the spectral efficiency by omitting the retransmission process from the repeater.

However, in the existing cooperative communication, the primary system and the secondary system coexist, and the transmitting end of the secondary system can transmit a signal to the receiving end of the secondary system while serving as a relay of the primary system. Due to the process of combining the signal of the primary system with the signal that the secondary system wants to send, the receiving end of the primary / secondary system receiving it mixes unwanted signals with the desired signal, which reduces reception performance. There was a problem.

The technical problem to be solved by the present invention is that, in the adaptive cooperative communication system, the relay terminal can decode the data received from the transmitting terminal while transmitting its own signal in addition to relaying communication between the transmitting terminal and the receiving terminal. An adaptive cooperative communication method, an adaptive cooperative communication relay terminal and a system capable of selectively relaying communication between a transmitting terminal and a receiving terminal according to whether or not are provided.

Adaptive cooperative communication method according to an embodiment of the present invention is the first terminal for transmitting and receiving the first data, the second terminal performs the adaptive cooperative communication, and the third terminal of the relay terminal for performing the second data communication In the adaptive cooperative communication method, a first step of receiving the first data from the first terminal, and a second step of receiving a decoding determination message to determine whether the first data can be decoded from the second terminal And a third step of transmitting the first data to the second terminal according to the decoding determination message.

The second terminal receives the first data from the first terminal and decodes the first data when the signal-to-noise ratio of the channel between the first terminal and the second terminal is greater than a predetermined threshold signal-to-noise ratio. If it is determined to be successful, and if it is smaller than or equal to, it may be determined as a failure of decoding of the first data.

The third step may transmit the second data to the third terminal if the decoding determination message is successful in decoding.

The third step may transmit data combining the first data and the second data to the second terminal and the third terminal if the decoding determination message is a decoding failure.

In addition, when transmitting the data combining the first data and the second data to the second terminal and the third terminal, the second terminal decodes the combined data in a maximum ratio combining scheme, and the third terminal The combined data may be decoded by a linear combining method.

An adaptive cooperative communication relay terminal according to another embodiment of the present invention performs an adaptive cooperative communication with a first terminal and a second terminal for transmitting and receiving first data, and a relay for performing second data communication with a third terminal. A terminal, comprising: a receiving unit for receiving the first data from the first terminal and receiving a decoding determination message for determining whether the first data can be decoded from the second terminal, and the first according to the decoding determination message. And a determining unit determining whether to transmit one data to the second terminal, and a transmitting unit transmitting the first data or the second data to the second terminal or the third terminal.

In an adaptive cooperative communication system according to another embodiment of the present invention, a relay for performing adaptive cooperative communication with a first terminal and a second terminal for transmitting and receiving first data, and performing a second data communication with a third terminal In an adaptive cooperative communication system of a terminal, the first terminal transmits first data to the second terminal, the third terminal, and the relay terminal, and the second terminal determines whether the first data can be decoded. And transmitting a decoding determination message of the first data to the relay terminal, wherein the relay terminal transmits the second data to the third terminal if the decoding determination message is successful in decoding, and if the decoding determination message is a decoding failure, Data combining the first data and the second data is transmitted to the second terminal and the third terminal.

According to the present invention, in the adaptive cooperative communication system, the relay terminal transmits its own signal in addition to relaying communication between the transmitting terminal and the receiving terminal, and according to whether the receiving terminal can decode the data received from the transmitting terminal. By selectively relaying the communication between the terminal and the receiving terminal, it is possible to reduce the bit error rate between the relay terminal and the terminal for transmitting and receiving data. In particular, when the relay terminal does not retransmit data to the receiving terminal, it is possible to improve reception performance by transmitting only its own signal to the terminal transmitting and receiving data with itself.

1 is a block diagram of an adaptive cooperative communication system according to an embodiment of the present invention;
2a and 2b is a flow chart of the adaptive cooperative communication method of the relay terminal included in the cooperative communication system according to FIG.
3 is a configuration diagram of a relay terminal included in a cooperative communication system according to FIG. 1;
4A and 4B are exemplary diagrams for describing reception performances of a second terminal and a third terminal by the adaptive cooperative communication method of the relay terminal included in the cooperative communication system according to FIG. 1.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of the functions in the embodiments, and the meaning of the terms may vary depending on the user, the intention or the precedent of the operator, and the like. Therefore, the meaning of the terms used in the following embodiments is defined according to the definition when specifically defined in this specification, and unless otherwise defined, it should be interpreted in a sense generally recognized by those skilled in the art.

1 is a block diagram of an adaptive cooperative communication system according to an embodiment of the present invention.

Referring to FIG. 1, the adaptive cooperative communication system of the present invention includes a first terminal 100, a second terminal 200, a relay terminal 300, and a third terminal 400. The first terminal 100 and the second terminal 200 transmit and receive the first data, the relay terminal 300 and the third terminal 400 transmits and receives the second data. In this case, the first terminal 100 may be represented as a transmitting terminal, a second terminal 200, a third terminal 400 as a receiving terminal, and the relay terminal 300 as a transmitting terminal and a relay terminal 300. The terminal includes one antenna. The cooperative communication system transmits data in two stages of transmission. In the first transmission step, the first terminal 100 transmits the first data to the second terminal 200, the third terminal 400, and the relay terminal 300 included in the transmission range. In this case, the second terminal 200 receives the first data from the first terminal 100, determines whether the first data can be decoded, and transmits the first data to the terminal included in the transmission range of the second terminal 200. 1 Sends a data decoding decision message. In this case, the relay terminal 300 is included in the transmission range of the second terminal 200, and the relay terminal 300 receives a decoding determination message.

In the second transmission step, the relay terminal 300 transmits data to the second terminal 200 or the third terminal 400. In this case, if the decoding determination message received from the second terminal 200 is successful in decoding, the relay terminal 300 transmits the second data to the third terminal 400. The relay terminal 300 transmits the data combining the first data and the second data to the second terminal 200 and the third terminal 400 when the decoding determination message is the decoding failure. In this case, the relay terminal 300 may transmit data by differently setting the transmission power according to the channel environment between the second terminal 200 or the third terminal 400. Therefore, when data transmission and reception between the first terminal 100 and the second terminal 200 is normal, the relay terminal 300 does not combine the first data with the second data, and only the second data is the third terminal 400. By transmitting to, the reception performance in the third terminal 400 can be improved.

2A and 2B are flowcharts of an adaptive cooperative communication method of a relay terminal included in the cooperative communication system according to FIG. 1.

FIG. 2A is a flowchart of an adaptive cooperative communication method of the relay terminal 300 when data transmission and reception between the first terminal 100 and the second terminal 200 is normal, and FIG. 2B is a relay terminal 300 when it is not normal. A flowchart of an adaptive cooperative communication method is provided. First, the first terminal 100 transmits first data to be transmitted to the second terminal 200 to the terminals included in the transmission range, and the relay terminal 300 included in the transmission range of the first terminal 100. ) Receives the first data (S200). For example, when the second terminal 200, the relay terminal 300, and the third terminal 400 are included in the transmission range of the first terminal 100, each terminal receives the first data. The first data is data modulated by the first terminal 100 and noise may be included in the receiving end according to a channel environment. Although a plurality of terminals are included in the transmission range of the first terminal 100, complete data or incomplete data signals are transmitted according to each terminal according to the channel environment.

Next, the second terminal 200 receives the first data to determine whether decoding is possible (S201), and the relay terminal 300 receives a decoding determination message from the second terminal 200 (S202). In this case, the second terminal 200 receives the first data from the first terminal 100, and determines whether the decoding succeeds based on the signal-to-noise ratio of the channel between the first terminal 100 and the second terminal 200. do. That is, when the signal-to-noise ratio of the channel between the first terminal 100 and the second terminal 200 is greater than the predetermined threshold signal-to-noise ratio, it is determined that the decoding of the first data is successful. Judging by the failure.

Next, the relay terminal 300 receives the decoding determination message to determine whether retransmission of the first data is necessary (S203), and the data to the second terminal 200 or the third terminal 400 according to the decoding determination message. (S204, S206, S208). In the case of FIG. 2A, the decryption determination message is successful in decoding, and the relay terminal 300 determines that it is not necessary to transmit the first data to the second terminal 200 (S203) and the second data to the third terminal 400. It is transmitted (S204). In this case, the third terminal 400 receives and decodes only the second data (S205). Therefore, since the third terminal 400 receives only the second data, the data reception rate is improved as compared with the case of receiving and decoding the data combining the first data and the second data. This is because when the data combining the first data and the second data is received, the signal strength of the desired data is weakened, so that the bit error rate is increased for decoding. Signals used for decoding in the second terminal 200 and the third terminal 400 may be represented by Equation 1 below.

In Equation 1, y ₂ represents a signal decoded in the second terminal 200, and y ₃ represents a signal decoded in the third terminal 400. h ₂ is the channel coefficient of the second terminal 200, h ₃ is the channel coefficient of the third terminal 400, P _p is the transmission power of the first terminal 100, P _s is the transmission power of the relay terminal 300 , x _p is the first data, x _s is the second data, n ₂ is the noise generated in the second terminal 200 (Addictive White Gaussian Noise, AWGN), n ₃ is generated in the third terminal 400 Indicates noise In this case, the second terminal 200 decodes the first data signal transmitted in the first transmission step, that is, the first data x _p directly received from the first terminal 100. The third terminal 400 decodes the second data signal transmitted in the second transmission step, that is, the second data x _s directly received from the relay terminal 300. As such, since the second terminal 200 decodes the first data directly received from the first terminal 100, the relay terminal 300 can transmit only the second data to the third terminal 400. In the three terminals 400, reception performance is improved.

Meanwhile, in the case of FIG. 2B, the decoding determination message is a decoding failure, and the relay terminal 300 determines that it is necessary to transmit the first data to the second terminal 200 (S203), and the second terminal 200 and the third terminal are decoded. The data combining the first data and the second data is transmitted to the terminal 400 (S206 and S207). In this case, the first data decoded by the relay terminal 300 and the second data which is data to be transmitted to the third terminal 400 are combined and transmitted. The relay terminal 300 may differently set power allocation to each data signal upon linear combination of transmission data according to channel conditions in order to improve reception performance of the second terminal 200 and the third terminal 400. Signals used for decoding in the second terminal 200 and the third terminal 400 may be represented by Equation 2 below.

In Equation 2, y ₂ represents a signal decoded by the second terminal 200, and y ₃ represents a signal decoded by the third terminal 400. h ₂ is the channel coefficient of the second terminal 200, h ₃ is the channel coefficient of the third terminal 400, P _s is the transmission power of the relay terminal 300, α is the distribution ratio of the transmission power, x _p 'is The first data decoded by the relay terminal 300, x _s denotes second data, n ₂ denotes noise generated by the second terminal 200, and n ₃ denotes noise generated by the third terminal 400. The second terminal 200 and the third terminal 400 decode a signal obtained by combining the decoded first data and the second data signal transmitted in the second transmission step. In this case, the second terminal 200 decodes the combined data by the maximum ratio combining (MRC) method, and the third terminal 400 decodes the combined data by the linear combinig method.

3 is a block diagram of a relay terminal 300 included in the cooperative communication system according to FIG. 1.

Referring to FIG. 3, the relay terminal 300 includes a receiver 310, a determiner 320, and a transmitter 330. The receiver 310 receives first data from the first terminal 100, and receives a decoding determination message from the second terminal 200 to determine whether the first data can be decoded. Here, the first data is data to be transmitted from the first terminal 100 to the second terminal 200. The receiver 310 receives data a total of two times. In the first step, the receiver 310 receives the first data from the first terminal 100, and in the second step, receives the decoding determination message from the second terminal 200. The receiver 310 is connected to the determiner 320 and outputs a decoding determination message received from the second terminal 200 to the determiner 320.

The determiner 320 determines whether to transmit the first data to the second terminal 200 according to the decoding determination message input from the receiver 310. The determination unit 320 determines to transmit the second data to the third terminal 400 without transmitting the first data to the second terminal 200 when the decoding determination message is a successful decoding. Here, the second data refers to data to be transmitted from the relay terminal 300 to the third terminal 400.

On the other hand, the determination unit 320 determines to transmit the data combining the first data and the second data to the second terminal 200 and the third terminal 400 if the decoding determination message is the decoding failure. Here, the first data refers to the first data decoded by the relay terminal 300, which is the first data received from the first terminal 100. The determination unit 320 may set the transmission power differently according to each terminal when transmitting data coupled to the second terminal 200 and the third terminal 400. That is, by adjusting the value of α in Equation 2, the reception performance of each terminal can be improved.

The transmitter 330 transmits the first data or the second data determined by the determiner 320 to the second terminal 200 or the third terminal 400. That is, if the decoding determination message is successful in decoding, only the second data is transmitted to the third terminal 400. If the decoding determination message is decoded, the decoded first data and the second data are transmitted to the second terminal 200 and the third terminal. Send to 400.

4A and 4B illustrate the reception performance of the second terminal 200 and the third terminal 400 by the adaptive cooperative communication method of the relay terminal 300 included in the cooperative communication system according to FIG. 1. It is an illustration.

4A and 4B illustrate a distance d ₁ between the first terminal 100 and the second terminal 200 and a distance d ₃ between the first terminal and the third terminal 400 to 1, and the first terminal. between 100 and relay station 300, distance (d _2), the relay terminal 300 and second terminal 200, between the distance (d _4), the relay terminal 300 and the third terminal 400, the distance ( d ₅ ) is set to 0.5, path loss is set to 3, data modulation is set to quadrature phase-shift keying (QPSK), and E _b / N ₀ is set to 0 to 30 dB. Shows the reception performance.

In the case of FIG. 4A, when an adaptive cooperative communication method for selectively receiving combined data is applied (Adaptive Incremental Decode-and Forward, AIDF), a communication method for always receiving combined data (Non-Adaptive Incremental Decode-and) The bit error rate in the second terminal 200 when Forward, NAIDF) is applied is shown. In FIG. 4A, it can be seen that the bit error rate decreases as the distribution ratio α of the transmit power increases. This means that only when the first data is transmitted to the second terminal 200 when AIDF is applied, the bit error rate is further reduced than in the case of NAIDF, thereby improving reception performance.

In the case of FIG. 4B, when the adaptive cooperative communication method for selectively receiving combined data is applied (AIDF) and at the third terminal 400 when the communication method (NAIDF) for always receiving combined data is applied. Shows the bit error rate. In FIG. 4B, as in FIG. 4A, the bit error rate decreases as the distribution ratio α of the transmit power increases. This means that only when the first data is transmitted to the third terminal 400 when AIDF is applied, the bit error rate is further reduced than in the case of NAIDF, thereby improving reception performance. Therefore, in the case of using the adaptive cooperative communication method of the present invention, the reception performance may be improved by reducing the bit error rate at the receiving end as compared with the case where it is not.

According to the present invention, in the adaptive cooperative communication system, the relay terminal 300 transmits its own signal in addition to relaying communication between the transmitting terminal and the receiving terminal, and whether the receiving terminal can decode the data received from the transmitting terminal. Accordingly, by selectively relaying communication between the transmitting terminal and the receiving terminal, it is possible to reduce the bit error rate between the relay terminal 300 and the terminal for transmitting and receiving data. In particular, when the relay terminal 300 does not retransmit the data to the receiving terminal, the reception performance may be improved by transmitting only its own signal to the terminal transmitting and receiving data with itself.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, Therefore, the present invention should be construed as a description of the claims which are intended to cover obvious variations that can be derived from the described embodiments.

100: first terminal 200: second terminal
300: relay terminal 310: receiver
320: determination unit 330: transmission unit
400: third terminal

Claims (11)

In the adaptive cooperative communication method of the relay terminal for performing adaptive cooperative communication with the first terminal, the second terminal for transmitting and receiving the first data, and the second data communication with the third terminal,
A first step of receiving the first data from the first terminal;
Receiving a decoding determination message for determining whether the first data can be decoded from the second terminal;
A third step of transmitting the first data to the second terminal according to the decoding determination message;
In the third step,
And if the decoding determination message fails to decode, transmitting data combining the first data and the second data to the second terminal and the third terminal. The method of claim 1,
When the first data is received from the first terminal and the signal-to-noise ratio of the channel between the first terminal and the second terminal is greater than a preset threshold signal-to-noise ratio, it is determined that the decoding of the first data is successful and is equal to or less than. And if it is determined that the decoding of the first data has failed. The method of claim 1, wherein the third step,
The adaptive cooperative communication method for transmitting the second data to the third terminal if the decoding decision message is successful decoding. delete The method of claim 1,
When transmitting the data combining the first data and the second data to the second terminal and the third terminal,
The second terminal decodes the combined data in a maximum ratio combining scheme,
And the third terminal decodes the combined data by linear combination. In a relay terminal for performing adaptive cooperative communication with a first terminal and a second terminal for transmitting and receiving first data, and performing a second data communication with a third terminal,
A receiver which receives the first data from the first terminal and receives a decoding determination message that determines whether the first data can be decoded from the second terminal;
A determining unit determining whether to transmit the first data to the second terminal according to the decoding determination message;
It includes a transmitter for transmitting the first data or the second data to the second terminal or the third terminal,
Wherein,
And if the decoding determination message fails decoding, determining the transmission of data combining the first data and the second data to the second terminal and the third terminal. The method of claim 6, wherein the second terminal,
Receiving the first message from the first terminal, if the signal-to-noise ratio of the channel between the first terminal and the second terminal is greater than a predetermined threshold signal-to-noise ratio, it is determined that the decoding success of the first data, and less than or equal to And if it is determined that the decoding of the first data has failed. The method of claim 6, wherein the determining unit,
The adaptive cooperative communication relay terminal to determine the transmission of the second data to the third terminal if the decoding determination message is successful decoding. delete The method according to claim 6,
When transmitting the data combining the first data and the second data to the second terminal and the third terminal,
The second terminal decodes the combined data in a maximum ratio combining scheme,
The third terminal is an adaptive cooperative communication relay terminal for decoding the combined data in a linear combination. In an adaptive cooperative communication system of a relay terminal for performing adaptive cooperative communication with a first terminal and a second terminal for transmitting and receiving first data, and performing a second data communication with a third terminal,
The first terminal transmits first data to the second terminal, the third terminal, the relay terminal,
The second terminal determines whether the first data can be decoded, and transmits a decoding determination message of the first data to the relay terminal,
The relay terminal transmits the second data to the third terminal if the decoding determination message is successful in decoding, and if the decoding determination message is the decoding failure, the first data and the second terminal to the second terminal and the third terminal. Adaptive cooperative communication system for transmitting data combining data.

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