KR101914100B1 - Two-path relay cooperative communication system based on MIMO-OFDM and interference cancellation method thereof - Google Patents

Abstract

The present invention relates to a dual-path cooperative communications system and an interference cancellation method thereof. According to the present invention, a transmitting terminal transmits a transmission symbol (S_t) and a cyclic delay symbol (S_(t,δ)) thereof through a plurality of antennas, respectively, wherein the transmitting terminal transmits the symbols to a first relay terminal in an odd-numbered time slot and transmits the symbols to a second relay terminal in an even-numbered time slot. In an (n-1)^th timeslot (n is an odd number of 3 or greater), the first relay terminal demodulates a transmission symbol (S_(n-2)) from a signal received in a previous time slot and re-transmits the transmission symbol (S_(n-2)) and a cyclic delay symbol (S_(n−2,δ)) to a reception terminal through a plurality of antennas, respectively. In an n^th time slot, the second relay terminal demodulates a transmission symbol (S_(n-1)) from a signal received in a previous time slot and re-transmits the transmission symbol (S_(n−1)) and a cyclic delay symbol (S_(n−1,δ)) to the reception terminal through the antennas, respectively. After the n^th time slot, each of the relay terminals removes an interference signal by the counterpart relay terminal that is introduced into a received signal of a previous time slot by using an MMSE detection technique during demodulation, so as to demodulate a corresponding symbol. According to the present invention, an interference component generated between relay terminals in a dual path cooperative communications system using two relay terminals is removed from the relay terminals to improve reception performance of a reception terminal. The system reliability can be improved by changing a transmission symbol structure of a relay terminal and a transmission terminal.

Description

[0001] MIMO-OFDM based dual path cooperative communication system and its interference cancellation method [0002]

The present invention relates to a dual path cooperative communication system based on MIMO-OFDM and an interference cancellation method thereof, and more particularly to a dual path cooperative communication system that removes interference components generated between relay terminals in a dual path cooperative communication system from a relay terminal, To a dual-path cooperative communication system for improving reception performance of a receiving terminal by changing a transmission symbol structure of a terminal and an interference cancellation method thereof.

A cooperative communication technique used in a wireless communication system enables a reliable communication by positioning a relay terminal between a transmitting terminal and a receiving terminal when there is no direct path between the transmitting terminal and the receiving terminal or when the channel state is poor.

A relay terminal located between a transmitting terminal and a receiving terminal is widely used for half duplex transmission for convenience of implementation. Although the single-path cooperative communication system using one half-duplex relay terminal is advantageous in that it is the simplest cooperative communication system, since the half-duplex relay terminal can not receive a signal from the transmitting terminal while relaying the signal to the receiving terminal, Channel capacity and bandwidth efficiency are reduced by half compared to direct transmission systems.

To solve this problem, a dual-path cooperative communication system using two half-duplex terminals has been studied. In the case of the dual path cooperative communication system, the transmitting terminal transmits a signal to one of the two relay terminals in a specific time slot, and the other relay terminal relays the signal received from the transmitting terminal to the receiving terminal again in the previous time slot . At this time, since the transmitting terminal can transmit signals to two relay terminals alternately, it effectively solves the channel capacity and bandwidth efficiency loss problem.

However, since the transmitting terminal and the relay terminal of one of the two relay terminals concurrently transmit signals in a specific time slot, interference occurs in the other relay terminals. If the interference is not removed, the interference is propagated to the receiving terminal and the error performance of the system is drastically reduced. As the distance between the relay terminals becomes closer, the influence of the interference becomes greater. Accordingly, there is a need for a method for improving the reliability of a dual path cooperative communication system by eliminating interference generated at a relay terminal.

The technology that is the background of the present invention is disclosed in Korean Patent No. 1425142 (published on Aug. 20, 2014).

The present invention relates to a dual path cooperative communication system in which an interference component generated between relay terminals is removed from a relay terminal and a transmission symbol structure of a transmitting terminal and a relay terminal is changed to improve the reception performance of the receiving terminal and the reliability of the system, -OFDM based dual path cooperative communication system and its interference cancellation method.

The present invention relates to a method for eliminating interference in a dual-path cooperative communication system using a half-duplex communication scheme, in which a transmitting terminal transmits a transmission symbol S _t and a symbol S _t cyclically delayed symbols S _t, Th time slot (where n is an odd number of 3 or more), respectively, to the first relay terminal in the odd-numbered time slot and to the second relay terminal in the even-numbered time slot, 1, relay terminal before the time slot in the n-2 time transmitted symbols from the received signal in the slot after demodulation of (S _n-2) the demodulated transmission symbols (S _n-2) and circulation delayed symbols (S _{n-2, In} a nth time slot, the second relay terminal retransmits the transmission symbol (S _n-1 ) from the signal received in the n-1 time slot, which is the previous time slot, to the reception terminal via the plurality of antennas, a demodulation and then demodulating transmit symbols (S _n-1) and the cyclic delay symbols (S _{n-1, δ)} suit. Each of the first and second relay terminals retransmits to the reception terminal through the antenna of the previous time slot using the MMSE detection technique in the demodulation from the third time slot, There is provided an interference cancellation method for demodulating a corresponding symbol by removing an interference signal.

Also, the reception signal of the first relay terminal in the nth time slot may be defined by the following equation.

및

는 상기 제1 중계 단말에 장착된 제1 및 제2 안테나에 각각 수신된 신호,

는 상기 송신 단말의 i번째 안테나와 상기 제1 중계 단말의 j번째 안테나 사이의 채널 계수,

는 상기 제2 중계 단말의 i번째 안테나와 상기 제1 중계 단말의 j번째 안테나 사이의 채널 계수,

과

은 상기 제n 타임슬롯에서 상기 제2 중계 단말에 의한 간섭 심볼,

는 상기 제1 중계 단말의 i번째 안테나에서의 잡음, i={1,2}, j={1,2}이다.here,

And

The first relay terminal, and the second relay terminal,

Is a channel coefficient between the i-th antenna of the transmitting terminal and the j-th antenna of the first relay terminal,

Is a channel coefficient between the i-th antenna of the second relay terminal and the j-th antenna of the first relay terminal,

and

N is the interference symbol by the second relay terminal in the nth time slot,

Is the noise at the i-th antenna of the first relay terminal, i = {1,2}, j = {1,2}.

Also, the reception signal of the second relay terminal in the (n-1) th time slot may be defined by the following equation.

및

는 상기 제2 중계 단말에 장착된 제1 및 제2 안테나에 각각 수신된 신호,

는 상기 송신 단말의 i번째 안테나와 상기 제2 중계 단말의 j번째 안테나 사이의 채널 계수,

는 상기 제1 중계 단말의 i번째 안테나와 상기 제2 중계 단말의 j번째 안테나 사이의 채널 계수,

과

은 상기 제n-1 타임슬롯에서 상기 제1 중계 단말에 의한 간섭 심볼,

는 상기 제2 중계 단말의 i번째 안테나에서의 잡음을 나타낸다.here,

And

The first relay terminal and the second relay terminal,

Is a channel coefficient between the i < th > antenna of the transmitting terminal and the j < th > antenna of the second relay terminal,

Is a channel coefficient between the i-th antenna of the first relay terminal and the j-th antenna of the second relay terminal,

and

Is an interference symbol by the first relay terminal in the (n-1) th time slot,

Represents the noise at the i-th antenna of the second relay terminal.

The received signal of the first relay terminal in the nth time slot and the received signal of the second relay terminal in the (n-1) th time slot may be defined by the following equations.

,

,

Where N is the number of subcarriers, k is the subcarrier frequency, and w is the noise matrix.

Also, in the (n + 1) th time slot, the first relay terminal multiplies the signal Y _n received in the previous nth time slot by the MMSE filter to obtain the interference symbol S _n of the second relay terminal after separating the _n-1) is detected, each of the retransmission to the receiving terminal for detecting transmitted symbols (S _n) and cyclic delay symbols (S _{n, δ)} via a plurality of antennas, and in the n-th time slot, and the second The relay terminal multiplies the signal Y _n-1 received in the previous n-1 time slot by the MMSE filter to detect the transmission symbol S _n-1 and the interference symbol S _n-2 of the first relay terminal separately , The detected transmission symbol (S _n-1 ), and the cyclically delayed symbol (S _{n-1, δ} ) to the receiving terminal via a plurality of antennas.

The present invention relates to a dual path cooperative communication system using a half duplex communication scheme, in which a transmission symbol (S _t ) and a symbol (S _{t, δ} ) in which a transmission symbol (S _t ) is cyclically delayed are transmitted (N is an odd number greater than or equal to 3), and a transmission terminal for transmitting an n-th time slot to a first relay terminal in an odd-numbered time slot and to a second relay terminal in an even- after demodulating the transmitted symbols (S _n-2) from the signal received in one time slot -2 demodulating transmit symbols (S _n-2) and circulation delayed symbols (S _{n-2, δ)} receive each through a plurality of antennas ( _N-1 ) th time slot, which is a previous time slot, in the n th time slot, and a transmission node S _n-1 demodulated after demodulating the transmission symbol S _n- ) and a cycling delayed symbols (S _{n-1, δ)} for each of said received via the plurality of antennas Wherein the first and second relay terminals each include a second relay terminal for retransmitting an interference signal from the first relay terminal to the first relay terminal, Path cooperative communication system for demodulating a corresponding symbol by removing a signal.

According to the present invention, in a dual path cooperative communication system using two relay terminals, an interference component generated between relay terminals is removed from the relay terminal to improve the reception performance at the reception terminal, and at the same time, The diversity gain can be obtained by changing the structure and the reliability of the system can be improved.

Particularly, the present invention can provide more reliable communication than the existing dual-path cooperative communication system because there is little influence of interference even when the distance between relay terminals approaches.

1 is a diagram illustrating a dual path cooperative communication system according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating transmission symbols according to time slots of the transmitting terminal and the first and second relay terminals shown in FIG. 1;
3 is a diagram illustrating signals received by the first relay terminal in each time slot shown in FIG.
4 is a diagram illustrating signals received by the second relay terminal shown in FIG. 1 in each time slot.
FIG. 5 is a graph comparing BER performances according to distances of relay terminals between a technique according to an embodiment of the present invention and an existing interference cancellation technique.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

1 is a diagram illustrating a dual path cooperative communication system according to an embodiment of the present invention.

As shown in FIG. 1, a MIMO-OFDM system according to an embodiment of the present invention includes a transmitting terminal S, first and second relay terminals R 1 and R 2, and a receiving terminal D. Here, each of the terminals S, R1, R2, and D transmits and receives signals using two antennas.

Sending terminal (S) is, but each individual transmitted through two antennas transmission symbol (S _t) and the transmitted symbols a symbol (S _{t, δ)} obtained by delaying the (S _t) circulating as δ every time slot (t), (T = 2, 4, 6, ...) to the first relay terminal R 1 in the odd-numbered time slots (t = Lt; / RTI > Here,? Represents a cyclic delay length.

Since both the first and second relay terminals R1 and R2 can not simultaneously perform a transmission operation and a reception operation in one time slot as a half duplex terminal, the operation of receiving a signal from the transmission terminal S, (D), as shown in Fig.

The relay terminals Rl and R2 use a DF (Decode and Forward) technique to relay the transmission signal of the transmitting terminal S to the receiving terminal D. [ Therefore, each of the relay terminals Rl and R2 demodulates the signal received from the transmitting terminal S, modulates the signal, and transmits the modulated signal to the receiving terminal D. [

1, the transmitting terminal S transmits the signals S _n , S _{n, and δ} to the first relay terminal R 1 and at the same time, the second relay terminal R 2 transmits the signals S _n , (Retransmits) a signal received from the terminal S to the receiving terminal D. [ At this time, it can be confirmed that the signal retransmitted by the second relay terminal R 2 also flows into the first relay terminal R 1. This is because the reception signal of the first relay terminal R 1 (S _n , S _n, ). ≪ / RTI >

Similarly, in an even time slot, the transmitting terminal S transmits the signals S _n-1 , S _{n-1, and 隆} to the second relay terminal R2, (Retransmits) the signal received from the transmitting terminal S to the receiving terminal D. At this time, it can be confirmed that a signal retransmitted by the first relay terminal R 1 also flows into the second relay terminal R 2. This is because the reception signal of the second relay terminal R 2 (S _n-1 , S _{n -1,?} ).

The embodiment of the present invention enhances the signal detection performance at the receiving terminal by removing the interference between the two relay terminals R1 and R2 in the relay terminal in the dual path cooperative communication system as described above. At the same time, a diversity gain is obtained by using transmit symbols based on CDD (Cyclic Delay Diversity) in the transmitting terminal S and the relay terminals R1 and R2.

FIG. 2 is a diagram illustrating transmission symbols according to time slots of the transmitting terminal and the first and second relay terminals shown in FIG. 1; In FIG. 2, each terminal has two antennas TX1 and TX2. TX1 and TX2 denote a first antenna (first antenna) and a second antenna (second antenna) mounted on each terminal.

For each time slot t, the transmitting terminal S transmits the transmission symbol S _t through the first antenna and its cyclic delayed symbol S _{t, δ} via the second antenna. At this time, as shown in FIG. 1, the transmitting terminal S transmits to the first relay terminal R 1 in the odd-numbered time slot and transmits to the second relay terminal R 2 in the even-numbered time slot.

In FIG. 2, S _n denotes a symbol transmitted by the transmitting terminal S in the nth time slot, and S _{n, δ} is a version of a symbol transmitted by applying the CDD technique, that is, a symbol S _{n in} which the symbol S _n is delayed by δ . In this case, since the same signal is transmitted twice at the same time, diversity gain is obtained.

For convenience of explanation, assuming that n is an odd-numbered time, the transmitting terminal S transmits the original symbol S _n to the first relay terminal R 1 through the first antenna TX 1 in the n th time slot And transmits a symbol S _{n, delta} S by cyclically delaying S _n by delta to the first relay terminal Rl through the second antenna TX2.

과

을 수신 단말(D)로 중계한다. 여기서,

은 이전의 n-1번째 타임 슬롯에서 제2 중계 단말(R2)이 송신 단말(S)로부터 수신한 심볼을 복조 후 다시 변조한 것을 나타내고,

는

을 δ만큼 순환 지연시킨 심볼을 의미한다.At the same time, in the nth time slot, the second relay terminal R2

and

To the receiving terminal (D). here,

Indicates that the second relay terminal (R2) modulates the symbol received from the transmitting terminal (S) in the previous (n-1) th time slot and then modulates the received symbol,

The

By delta < RTI ID = 0.0 >.≪ / RTI >

2, first, in an n-1 time slot (n is an odd number of 3 or more), the first relay terminal Rl transmits a transmission symbol through after demodulating the (S _n-2) demodulate the transmitted symbols (S _n-2) and its cyclic delayed symbols (S _{n-2, δ)} their first antenna (TX1) and the second antenna (TX2) To the receiving terminal D, respectively.

Here, the (n-1) th time slot means the second, fourth, sixth, etc. time slot, i.e., the even timeslot (t = 2,4,6, ...) when n = 3,5,7. In the case of the second time slot, for example, in the second time slot of t = 2 in FIG. 2, the first relay terminal R ₁ demodulates S ₁ from the signal received at the previous t = 1, S ₁ to the receiving terminal D through the second antenna TX 2 through the first antenna TX ₁ and the cyclically delayed symbols S _{1 and} S ₅ for the demodulated S ₁ .

Also, in the nth time slot, the second relay terminal R2 demodulates the transmission symbol S _n-1 from the signal received in the n-1 time slot which is the previous time slot and demodulates the transmission symbol S _{n- 1} and its cyclic delayed symbols S _{n-1, δ} to its receiving terminal D through its first antenna TX ₁ and second antenna TX 2, respectively.

Here, the nth time slot means time slots (t = 3, 5, 7,...) In the third, In the case of the third time slot, for example, in the third time slot with t = 3 in Fig. 2, the second relay terminal R2 demodulates S ₂ from the signal received at the previous t = 2, ₂ to the receiving terminal D via the first antenna TX1 and its cyclic delayed symbol S _{2, delta} via the second antenna TX2.

When the transmission symbol structure of FIG. 2 is used, since the signal is continuously transmitted in each time slot in the transmitting terminal S, the problem of the conventional single-path cooperative communication system using one half-duplex relay terminal is solved do. However, as shown in FIG. 1, in each time slot, the transmitting terminal S and one of the two relay terminals R1 and R1 transmit signals at the same time, so that interference occurs in the remaining relay terminals.

Therefore, in the embodiment of the present invention, each relay terminal removes the interference component from the relay terminal in the opposite side in the retransmission process after demodulation, and then retransmits it. However, the interference cancellation operation of the other side relay terminal can be performed from the third time slot.

The reason for this is that in the case of the first time slot, the process of retransmitting after demodulation does not exist in the relay terminal, but in the case of the second time slot, the first relay terminal R1 performs demodulation and retransmission, There is no interference from the relay terminal R2.

Specifically, after the third time slot (t? 3), each of the first and second relay terminals (R1, R2) uses a Minimum Mean Square Error (MMSE) detection technique during demodulation to input And demodulates the corresponding symbol by removing the interference signal from the other side relay terminal. That is, the interference signal from the counterpart relay terminal is removed from the received signal, and only the original signal (the signal received from the transmitting terminal at the previous time) is retransmitted to the receiving terminal.

First, the reception signal of the first relay terminal Rl in the nth time slot is defined as Equation (1) below. Here, the nth time slot means all of the odd-numbered time slots (t = 3, 5, 7, ...) of 3 or more as described above.

및

는 제1 중계 단말(R1)의 제1 및 제2 안테나에 각각 수신된 신호,

는 송신 단말(S)의 i번째 안테나와 제1 중계 단말(R1)의 j번째 안테나 사이의 채널 계수,

는 제2 중계 단말(R2)의 i번째 안테나와 제1 중계 단말(R1)의 j번째 안테나 사이의 채널 계수,

는 제1 중계 단말(R1)의 i번째 안테나에서의 잡음(AWGN;Additive White Gaussian Noise), i={1,2}, j={1,2}이다. here,

And

A signal received by the first and second antennas of the first relay terminal R1,

Is a channel coefficient between the i-th antenna of the transmitting terminal S and the j-th antenna of the first relaying terminal Rl,

Is a channel coefficient between the i-th antenna of the second relay terminal (R2) and the j-th antenna of the first relay terminal (R1)

Is an additive white Gaussian noise (AWGN) at the i-th antenna of the first relay terminal R1, i = {1,2}, j = {1,2}.

과

은 제n 타임슬롯에서 제2 중계 단말(R2)에 의한 간섭 심볼(간섭 성분)이다. 즉, 수학식 1의 우변에서 셋째 항

과 넷째 항

은 제2 중계 단말(R2)에 의해 제1 중계 단말(R1)에서 발생한 간섭을 나타낸다.

and

Is an interference symbol (interference component) by the second relay terminal R2 in the nth time slot. That is, from the right side of the equation (1) to the third term

And the fourth term

Indicates interference caused by the first relay terminal (R1) by the second relay terminal (R2).

The received signal of the second relay terminal R2 in the (n-1) th time slot is defined by the following equation (2). In this case, the (n-1) th time slot means the even timeslot (t = 2, 4, 6, ...) as described above.

및

는 제2 중계 단말(R2)의 제1 및 제2 안테나에 각각 수신된 신호,

는 송신 단말(S)의 i번째 안테나와 제2 중계 단말(R2)의 j번째 안테나 사이의 채널 계수,

는 제1 중계 단말(R1)의 i번째 안테나와 제2 중계 단말(R2)의 j번째 안테나 사이의 채널 계수,

는 제2 중계 단말(R2)의 i번째 안테나에서의 잡음(AWGN)이다.here,

And

A signal received by the first and second antennas of the second relay terminal R2,

Is a channel coefficient between the i-th antenna of the transmitting terminal S and the j-th antenna of the second relaying terminal R2,

Is the channel coefficient between the i-th antenna of the first relay terminal (R1) and the j-th antenna of the second relay terminal (R2)

(AWGN) at the i-th antenna of the second relay terminal R2.

과

은 제n-1 타임슬롯에서 제1 중계 단말(R1)에 의한 간섭 심볼이다. 즉, 수학식 2의 우변에서 셋째 항

과 넷째 항

은 제1 중계 단말(R1)에 의하여 제2 중계 단말(R2)에서 발생한 간섭을 나타낸다.

and

Is an interference symbol by the first relay terminal Rl in the (n-1) th time slot. That is, in the right side of Equation 2,

And the fourth term

Represents an interference generated in the second relay terminal (R2) by the first relay terminal (R1).

Equation (1) can be expressed in a matrix form as shown in Equation (3) below.

의 위상 회전이 곱해진 형태가 된다. Where N is the number of subcarriers, k is the subcarrier frequency, and w is the noise matrix. Since the cyclic delay used in the CDD technique appears as a multipath in the receiving terminal and the relay terminal receiving the cyclic delayed symbol,

Is multiplied by the phase rotation.

Similarly, Equation (2) can be expressed in a matrix form as shown in Equation (4) below.

In the embodiment of the present invention, the MMSE technique, which is a linear MIMO detection technique, is used to remove the interference generated in the relay terminal. The linear MMSE detection scheme has a merit of lower complexity than other nonlinear detection schemes by multiplying the received signal by the MMSE filter.

Equation (5) represents an MMSE filter. H denotes a channel matrix, H ^H denotes a hermetian matrix of a channel matrix H, or a complex transpose matrix of H. Also, σ ² is the variance of the noise, and I is the unit matrix.

Equation (6) represents a linear MIMO detection process performed by the first relay terminal Rl in the (n + 1) th time slot (t = 4, 6, 8, ...).

를 검출할 수 있다. 이때

은 제1 중계 단말(R1)이 제n 타임슬롯에 송신 단말(S)로부터 받은 신호이고

은 제2 중계 단말(R2)에 의한 간섭 신호이다. Here, Y _n represents Equation 3, which is the signal received at the first relay terminal Rl in the previous nth time slot (t = 3, 5, 7, ...). When the MMSE filter of Equation (5) is multiplied by Equation (3)

Can be detected. At this time

Is a signal received from the transmitting terminal S in the nth time slot by the first relay terminal Rl

Is an interference signal by the second relay terminal R2.

)과 그에 대해 간섭이 되는 간섭 심볼(

)을 분리 검출할 수 있고, 검출한 심볼(

)과 이를 순환 지연시킨 심볼(

)을 재변조하여 수신 단말(D)로 재전송한다.In this manner, the first relay terminal R1 multiplies the MMSE filter of Equation (3) by Equation (3) to obtain the original symbol

) And an interference symbol (

), And the detected symbol (

) And a symbol delayed by circulating the symbol

) And retransmits it to the receiving terminal (D).

To summarize this, in the (n + 1) th time slot, the first relay terminal Rl multiplies the signal Y _n received in the previous nth time slot by the MMSE filter to obtain the transmission symbol S _n and the second relay terminal through interference symbols (after detecting remove the S _n-1), the detected transmitted symbols (S _n) and cyclic delay symbols (S _{n, δ)} their first and second antenna (TX1, TX2) of R2) To the receiving terminal (D).

Equation (7) represents a linear MIMO detection process performed by the second relay terminal (R2) in the nth time slot (t = 3,5,7, ...) with the same principle.

를 검출할 수 있다. 이때의

은 제2 중계 단말(R2)이 제n-1 타임슬롯에 송신 단말(S)로부터 받은 신호이고

은 제1 중계 단말(R1)에 의한 간섭 신호이다. Here, Y _{n -1} represents Equation 4, which is the signal received at the second relay terminal R 2 in the previous n-1 time slot (t = 2, 4, 6, ...). When the MMSE filter of Equation (5) is multiplied by Equation (4)

Can be detected. At this time

Is a signal received from the transmitting terminal S in the (n-1) th time slot by the second relay terminal R2

Is an interference signal by the first relay terminal R1.

)과 간섭 심볼(

)을 분리 검출할 수 있으며, 검출한 심볼(

)과 순환 지연 심볼(

)을 다시 재변조하여 수신 단말(D)로 재전송할 수 있다.In this way, the second relay terminal R2 multiplies the MMSE filter of Equation (4) by Equation (4) to obtain the original symbol

) And an interference symbol (

), And the detected symbol (

) And the cyclic delay symbol (

) Can be re-modulated again and retransmitted to the receiving terminal (D).

To summarize this, in the nth time slot, the second relay terminal R2 multiplies the signal Y _{n -1} received in the previous n-1 time slot by the MMSE filter to obtain the transmission symbol S _n-1 and the first And detects the transmission symbol S _{n -1} and the cyclically delayed symbol S _{n -1} and _δ after detecting the interference symbol S _{n -1} of the relay terminal R ₁ separately from the first antenna TX _1, And the second antenna TX2 to the receiving terminal D, respectively.

As described above, in the dual-path cooperative communication system having two relay terminals, in order to solve the problem of increasing the interference occurring when the distances between the two relay terminals are close to each other and reducing the reliability thereof, Filters are used to eliminate interference, and transmission and relay terminals use CDD symbol structures to improve reliability.

FIG. 5 is a graph comparing BER performances according to distances of relay terminals between a technique according to an embodiment of the present invention and an existing interference cancellation technique.

Assuming that the distance between the two relay terminals is a normalized distance, the distance between the transmitting terminal and the relay terminal, and the distance between the relay terminal and the receiving terminal is 1, The simulation was performed in three cases. Here, the distance between relay terminals is closer to 1 to 0.1.

The existing interference cancellation method is a case where the transmitting terminal, the relay terminal, and the receiving terminal in the cooperative communication system remove interference from the receiving terminal, not the relay terminal, but a single antenna instead of multiple antennas, and the CDD technique is not used.

From the results of FIG. 5, it can be seen that the technique of the present invention is substantially unaffected by the distances between the relay terminals unlike the conventional method, and more reliable communication is possible.

According to the present invention as described above, in the dual path cooperative communication system using two relay terminals, the interference component generated between the relay terminals is removed from the relay terminal to improve the reception performance at the reception terminal, It is possible to improve the reliability of the system by obtaining the diversity gain through the modification of the transmission symbol structure.

The present invention can provide more reliable communication than the existing dual-path cooperative communication system because there is almost no interference even when the distances between the relay terminals are close to each other.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

S: transmitting terminal R1: first relay terminal
R2: second relay terminal D: receiving terminal

Claims (10)

A method of canceling interference in a dual path cooperative communication system using a half duplex communication method,
The transmitting terminal to the first relay terminal transmits the symbol (S _t) and the transmitted symbols (S _t) is, but each transmitted via a plurality of antennas for circular delayed symbols (S _{t, δ),} is odd-numbered time slots and odd-numbered To the second relay terminal in the time slot,
In the n-1 time slot (n is an odd number of 3 or more), the first relay terminal demodulates the transmission symbol (S _n-2 ) from the signal received in the n-2 time slot which is the previous time slot and demodulates (S _n-2 ) and cyclic delayed symbols (S _n-2,? ) To the receiving terminal via a plurality of antennas,
The n in a time slot, the second relay terminal before the time slot in the n-1 time slots and then demodulate the transmitted symbols (S _n-1) from the received signal to demodulate the transmitted symbols (S _n-1) and the circulation Delays the delayed symbols (S _n-1,? ) To the receiving terminal via a plurality of antennas,
Each of the first and second relay terminals uses an MMSE detection technique in the demodulation to remove an interference signal from the other relay terminal that has entered the reception signal of the previous time slot and demodulate the corresponding symbol . The method according to claim 1,
Wherein the received signal of the first relay terminal in the nth time slot is defined by the following equation:

here,

And

The first relay terminal, and the second relay terminal,

Is a channel coefficient between the i-th antenna of the transmitting terminal and the j-th antenna of the first relay terminal,

Is a channel coefficient between the i-th antenna of the second relay terminal and the j-th antenna of the first relay terminal,

and

N is the interference symbol by the second relay terminal in the nth time slot,

Is the noise at the i-th antenna of the first relay terminal, i = {1,2}, j = {1,2}. The method of claim 2,
And the received signal of the second relay terminal in the (n-1) th time slot is defined by the following equation:

here,

And

The first relay terminal and the second relay terminal,

Is a channel coefficient between the i < th > antenna of the transmitting terminal and the j < th > antenna of the second relay terminal,

Is a channel coefficient between the i-th antenna of the first relay terminal and the j-th antenna of the second relay terminal,

and

Is an interference symbol by the first relay terminal in the (n-1) th time slot,

Represents the noise at the i-th antenna of the second relay terminal. The method of claim 3,
Wherein the received signal of the first relay terminal in the nth time slot and the received signal of the second relay terminal in the nth time slot are defined by the following equations, respectively:

,

Where N is the number of subcarriers, k is the subcarrier frequency, and w is the noise matrix. The method according to claim 1,
In the (n + 1) th time slot, the first relay terminal multiplies the signal Y _n received in the previous nth time slot by the MMSE filter, and generates a transmission symbol S _n and an interference symbol S _{n- 1} ), and then retransmits the detected transmission symbol (S _n ) and the cyclically delayed symbol (S _{n, δ} ) to the reception terminal via a plurality of antennas,
In the nth time slot, the second relay terminal multiplies the signal Y _{n -1} received in the previous ( _n-1 ) _th time slot by the MMSE filter to obtain the interference symbol S _n-1 of the first relay terminal S _{n -1} and S _{n -1} are transmitted to the receiving terminal through a plurality of antennas after the detection of the interference symbols S _{n -1} and S _n-2 . In a dual-path cooperative communication system using a half-duplex communication scheme,
(S _{t, 隆} ) that are cyclically delayed with the transmission symbol (S _t ) and the transmission symbol (S _t ) are transmitted through a plurality of antennas, respectively. In the odd-numbered time slot, A transmitting terminal for transmitting to the second relay terminal, respectively;
(S _n-2 ) obtained by demodulating and demodulating the transmission symbol (S _n-2 ) from the signal received in the ( _n-2 ) _th time slot which is the previous time slot in the ( _n-1 ) _th time slot A first relay terminal for retransmitting cyclically delayed symbols (S _n-2,? ) To the receiving terminal through a plurality of antennas; And
( _N-1 ) _th time slot, which is a demodulated and demodulated transmission symbol (S _n-1 ) from a signal received in the n th time slot which is the previous time slot, and a circulating delayed symbol S _{n- , delta} ) to the receiving terminal via a plurality of antennas, respectively,
Each of the first and second relay terminals uses a MMSE detection technique in the demodulation to remove an interference signal caused by a counterpart relay terminal that has entered a reception signal of a previous time slot and demodulate the corresponding symbol, Communication system. The method of claim 6,
Wherein the received signal of the first relay terminal in the nth time slot is defined by the following equation:

here,

And

The first relay terminal, and the second relay terminal,

Is a channel coefficient between the i-th antenna of the transmitting terminal and the j-th antenna of the first relay terminal,

Is a channel coefficient between the i-th antenna of the second relay terminal and the j-th antenna of the first relay terminal,

and

N is the interference symbol by the second relay terminal in the nth time slot,

Is the noise at the i-th antenna of the first relay terminal, i = {1,2}, j = {1,2}. The method of claim 7,
Wherein the received signal of the second relay terminal in the n-l < th > time slot is defined by the following equation:

here,

And

The first relay terminal and the second relay terminal,

Is a channel coefficient between the i < th > antenna of the transmitting terminal and the j < th > antenna of the second relay terminal,

Is a channel coefficient between the i-th antenna of the first relay terminal and the j-th antenna of the second relay terminal,

and

Is an interference symbol by the first relay terminal in the (n-1) th time slot,

Represents the noise at the i-th antenna of the second relay terminal. The method of claim 8,
Wherein the received signal of the first relay terminal in the nth time slot and the received signal of the second relay terminal in the nth time slot are respectively defined by the following equation:

,

Where N is the number of subcarriers, k is the subcarrier frequency, and w is the noise matrix. The method of claim 6,
In the (n + 1) th time slot, the first relay terminal multiplies the signal Y _n received in the previous nth time slot by the MMSE filter, and generates a transmission symbol S _n and an interference symbol S _{n- 1} ), and then retransmits the detected transmission symbol (S _n ) and the cyclically delayed symbol (S _{n, δ} ) to the reception terminal via a plurality of antennas,
In the nth time slot, the second relay terminal multiplies the signal Y _{n -1} received in the previous ( _n-1 ) _th time slot by the MMSE filter to obtain the interference symbol S _n-1 of the first relay terminal after separating the S _n-2) is detected, the detected transmitted symbols (S _{n -1)} and cyclic delay symbols (S _{n-1, δ),} each dual-path cooperative communication system for retransmitting to the receiving terminal via a plurality of antennas .

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