KR101390301B1 - Method for processing signal in two-relay system - Google Patents

Abstract

Disclosed is a signal processing method for estimating a channel in a dual relay system. The disclosed method, which is the signal processing method performed by a first relay for estimating the channel in the dual relay system including the first relay and a second relay, comprises: a step (a) of receiving a signal including a training sequence u_1 from a transmitting part and a signal including at least one between a training sequence u_2 and a training sequence u_3 in a reception mode and performing a preset signal process; and a step (b) of adding at least one between the training sequence u_2 and the training sequence u_3 to the signal resulted from the signal process in the preset manner and transmitting the added signal in a transmission mode, wherein the training sequence u_2 is a training sequence cyclic-shifted by preset Ks from the training sequence u_1, the training sequence u_3 is a training sequence cyclic-shifted by preset 2Ks from the training sequence u_1 and the training sequence u_1 has a self-correlation characteristic. The disclosed method may efficiently estimate the channel for eliminating interference in a system using the dual relay.

Description

TECHNICAL FIELD [0001] The present invention relates to a signal processing method for a channel estimation in a repeater system,

Embodiments of the present invention relate to a signal processing method for channel estimation, and more particularly, to a signal processing method for channel estimation in a dual repeater system in which signals are relayed by two repeaters.

1 is a diagram illustrating a dual repeater system having dual paths to which the present invention is applied.

Referring to FIG. 1, a dual repeater system to which the present invention is applied includes a transmitter S, a receiver D, and two relays R1 and R2.

Each of the two repeaters operates in a half duplex manner, and when one of them is in the transmission mode, the other operates in the reception mode. That is, the first repeater R1 and the second repeater R2 alternately repeat transmission and reception.

In FIG. 1, (a) shows operation in an odd-numbered time slot and (b) shows operation in an even-numbered time slot.

The signal transmission in the odd-numbered time slot and the even-numbered time slot can be performed as follows.

- Odd time slot -

In the odd-numbered time slot, the received signal of the first repeater R1 is expressed by Equation (1).

는 송신단의 평균 출력을 나타내며

는 가우시안 잡음 벡터로써 벡터의 각 성분의 평균은 0이고 분산은

로 나타낸다. 또한

는 홀수 번째 타임 슬롯에서 제2 중계기(R2)에서 송신되는 신호로서 다음의 수학식 2와 같다. In Equation (1)

Represents the average power of the transmitting end

Is the Gaussian noise vector, the mean of each component of the vector is 0 and the variance is

Respectively. Also

Is a signal transmitted from the second repeater R2 in an odd-numbered time slot, and is expressed by the following equation (2).

이고

는 릴레이의 출력)이다.

는 릴레이 2에서 발생하는 가우시안 잡음으로써 평균은 0이고 분산은

이다. 홀수 번째 타임슬롯에서 송신부와 제2 중계기에서 보낸 신호는 수신부에서도 수신한다. 수신부에서의 수신신호의 수학식 3과 같다.here

ego

Is the output of the relay.

Is the Gaussian noise at relay 2, the average is 0 and the variance is

to be. In the odd-numbered time slot, the signal transmitted from the transmitter and the second repeater is also received by the receiver. (3) of the reception signal at the receiver.

는 수신부에 유입되는 가우시안 잡음으로써 평균은 0이고 분산은

으로 나타낸다. 식 수학식 2를 수학식 3에 대입하면, 다음의 수학식 4와 같이 표현된다.here

Is the Gaussian noise introduced into the receiver and the average is 0 and the variance is

Respectively. Substituting equation (2) into equation (3), it can be expressed as the following equation (4).

이고 위 수학식 4. 수신부에서의 수신신호는 S→R₂→D 링크로부터 수신되는 ISI성분과 R₁→R₂→D링크로부터 수신되는 IRI성분으로 인해 SINR (Signal-to-interference-plus-noise ratio) 성능이 크게 열화되는 것을 관찰 할 수 있다. here

And the above equation 4. The received signal of the receiver is S → R ₂ → received ISI component from the link D and R ₁ → R ₂ → due to IRI component D received from the link SINR (Signal-to-interference- plus- noise ratio) performance is greatly deteriorated.

- even timeslot -

Similarly to the above-described odd-numbered time slot, the received signal of the second repeater in an even-numbered time slot is expressed by Equation (5).

는 다음의 수학식 6과 같이 정의된다.here

Is defined by the following Equation (6).

At this time, the received signal at the receiving unit is expressed by Equation (7).

Substituting Equation (6) into Equation (7), Equation (8) can be expressed as Equation (8).

이고 홀수번째 타임 슬롯과 마찬가지로 짝수 번째 타임 슬롯에서도 수신신호는 ISI와 IRI성분을 포함한다. 때문에 이러한 간섭성분들을 신호검출 전에 제거해 주어야 한다. 수신부에서의 IRI성분은 이전 타임슬롯에서 중계기로부터 수신한 신호와 동일하므로 채널정보만 완벽하다면 수신부에서 완벽히 제거할 수 있다. 홀수 번째 수신한 신호에 포함된 IRI성분은 다음의 수학식 9 내지 수학식 11과 같이 제거될 수 있다. here

And the received signal includes ISI and IRI components even in the even-numbered time slot as in the odd-numbered time slot. Therefore, these interference components must be removed before signal detection. Since the IRI component in the receiver is the same as the signal received from the repeater in the previous time slot, if the channel information is perfect, the receiver can completely remove it. The IRI component included in the odd-numbered received signal can be removed as shown in the following Equations (9) to (11).

는 IRI제거 후 잔존하는 잡음으로써 다음의 수학식 10과 같이 표현된다.here

Is the remaining noise after IRI removal and is expressed as Equation (10).

  The IRI component existing in an even-numbered received signal can also be removed using the same principle as Equation (9). The even-numbered timeslot reception signal with IRI removed is expressed by Equation (11).

이다. here

to be.

It can be seen from Equations (9) and (11) that the signal received from the S? Ri? D (i = 1, 2) link based on the signal received from the S? D link after the IRI removal is equal to the ISI. Conversely, to detect the signal received from the repeater link, the signal received by the direct link must first be removed. As a result, residual ISI after IRI should be removed. For this, a forward-and-backward successive interference cancellation and maximal ratio combining (FB-SIC-MRC) In the FB-SIC-MRC scheme, after all the received signals are stacked by the dual repeater, after the exchange of information is completed, successive interference cancellation (SIC) is performed in the forward direction and the reverse direction, Separate the signal. Then, MRC maximizes the received SNR to detect the signal.

However, in order to remove IRI and ISI from the receiving unit from the above Equations (9) and (11), the SD link, the S-R1-D link, the S-R2-D link, the R1- It can be seen that the channel information of the -D link and the R2-D link is needed, but knowing all of these channel information is a very complicated task.

The present invention proposes a signal processing method capable of efficient channel estimation for interference cancellation in a system using dual repeaters.

According to an aspect of the present invention, there is provided a signal processing method performed in a first repeater for channel estimation in a dual repeater system including first and second repeaters, Lt; _{RTI ID} = 0.0 > u2 < / RTI _> (A) receiving a signal including at least one of training sequence or u ₃ training sequence from a second repeater and performing predetermined signal processing; (B) adding at least one training sequence of a u ₂ training sequence or a u ₃ training sequence to a signal processed in a predetermined mode in a transmission mode, and transmitting the u ₂ training sequence to a u ₁ training Wherein the u ₃ training sequence is a training sequence which is cyclically shifted by a predetermined 2Ks with respect to the u ₁ training sequence and the u ₁ training sequence has an autocorrelation characteristic A signal processing method is provided.

The u ₁ training sequence has a periodic peak value based on the Ks interval.

Wherein the step (a) comprises receiving, from the second repeater in the first time slot, a signal including a u ₂ training sequence, a signal including the u ₃ training sequence, and a signal including the u ₁ training sequence from the transmission unit Step a1); And a step (a2) of separating a signal from a transmitter link using an autocorrelation characteristic of the u ₁ training sequence in a first time slot.

Further comprising: in step (a), the third time slot receives a signal including a training sequence u ₁ from the transmitting and receiving a signal comprising a training sequence u ₂ from the second repeater (a3); After performing the reverse cyclic shift as Ks for the signal received in the step (a3) it includes the step (a4) to separate the signal of the second relay link through the auto-correlation of the training u ₁ columns.

Wherein step (b), the step of sending by adding a training sequence u ₂ to a signal with a separate transmission link in said step (a1) in the second timeslot (b1); And in the fourth time slot and a step (b2) for transmitting a signal, each addition of a signal, and u3 training sequence added to u ₂ training sequence in the signal of the second relay link was separated in said step (a4).

According to another aspect of the present invention, a signal processing method performed in a second repeater for channel estimation in a dual relay system including a first and a second repeater, the signal comprising a u _one training sequence from the transmitter in the receive mode, and From the first repeater u ₂ (A) receiving a signal including at least one of training sequence or u ₃ training sequence from a first repeater and performing predetermined signal processing; (B) adding at least one training sequence of a u ₂ training sequence or a u ₃ training sequence to a signal processed in a predetermined mode in a transmission mode, and transmitting the u ₂ training sequence to a u ₁ training Wherein the u ₃ training sequence is a training sequence which is cyclically shifted by a predetermined 2 Ks for the u ₁ training sequence, and the u ₁ training sequence is a training sequence which is cyclically shifted by Ks A processing method is provided.

The u ₁ training sequence has a periodic peak value based on the Ks interval.

Wherein step (a), receiving a signal including a training u ₁ time slot 10-2, from the transmitting and receiving a signal comprising a training sequence u2 from the first repeater (a1); And a step (a2) of removing training sequences for the signals received in step (a1) in a second timeslot.

Wherein said step (a) comprises: receiving, in a fourth time slot, a signal comprising a u ₁ training sequence from said transmitter and a signal comprising a u ₂ training sequence and a signal comprising a u ₃ training sequence from a first repeater (A3); And the u ₁ training sequence, reverse-cyclically shifts the signal received in step (a 3) by 2 Ks, and then performs autocorrelation with the u ₁ training sequence, And separating the signal with the link (a4).

Wherein step (b), the method comprising: in a first time slot, transmit a signal including the signal and u ₃ u ₂ training sequence including a training sequence (b1); And a step (b2) of adding a u2 training sequence to the signal from which the training sequence is removed in the step (a2) and transmitting it in the third time slot.

According to the present invention, channel estimation can be efficiently performed for interference cancellation in a system using dual repeaters.

1 shows a dual repeater system with dual paths to which the present invention is applied;
2 is a diagram illustrating a structure of a transmission signal according to an embodiment of the present invention;
3 is a graph illustrating the characteristics of a training sequence according to an embodiment of the present invention.
Figure 4 illustrates operation in a first timeslot according to an embodiment of the present invention.
Figure 5 illustrates operation in a second timeslot according to an embodiment of the present invention.
6 illustrates operations performed in a third timeslot according to an embodiment of the present invention.
7 illustrates operations performed in a fourth timeslot according to an embodiment of the present invention.

Hereinafter, a signal processing method for channel estimation in a dual repeater system according to the present invention will be described in detail with reference to the accompanying drawings.

The signal processing technique for channel estimation proposed in the present invention performs preprocessing in each repeater so as to effectively separate channels and transmits a pre-processed training sequence to a receiver D.

It is assumed that the transmission unit S, the repeaters R1 and R2, and the reception unit D know this protocol.

In the present embodiment, a signal processing procedure at each relay during four time slots is proposed, and it is assumed that the channel does not change during the four time slots.

2 is a diagram illustrating a structure of a transmission signal according to an embodiment of the present invention.

1, a transmission signal according to an embodiment of the present invention includes a training sequence 100, a first cyclic prefix (CP) extension unit 102 added before and after the training sequence 100, a data 106, And a second CP extension 104 that is added before and after the second CP extension. In Figure 1, the training sequence length is K and K = 3Ks. Here, it is assumed that Ks is equal to or greater than the maximum channel length between the nodes.

3 is a graph illustrating the characteristics of a training sequence according to an embodiment of the present invention.

Referring to FIG. 3, the autocorrelation of the training sequence has a periodic peak based on the Ks interval as shown in FIG.

The training sequence applied to the present invention must have a constant size with autocorrelation properties, and a Chu sequence can be used as one of training sequences satisfying these characteristics.

The following equation (12) is a mathematical expression that defines a Chu sequence.

이고,

는

에 대한 서로소이다. In the above equation (12)

ego,

The

For each other.

According to the embodiment of the present invention, after the CP is removed from each repeater, a repeater performs a cyclic shift as much as Ncs symbols to utilize the autocorrelation characteristic of the Chu sequence. Hereinafter, The signal processing method of the repeater will be described in detail.

The description of the operation of removing and re-adding the CP in the operation in the following four time slots is omitted. That is, in each time slot, each repeater removes the CP, performs signal processing, adds the CP again, and transmits the signal.

4 is a diagram illustrating operations performed in a first timeslot according to an embodiment of the present invention.

As described above, the first repeater R1 and the second repeater R2 alternately operate in a reception mode or a transmission mode, and in the first time slot, the first repeater R1 operates in the reception mode and the second repeater R1 R2 operate in the transmission mode.

In the first timeslot, the transmitter S transmits data with u ₁ training sequences. The second repeater (R2) operating in the transmission mode transmits data having the u ₂ training sequence and data having the u ₃ training sequence, respectively. Here, u ₂ is u ₁ Is a training sequence cyclically shifted by a preset Ks in comparison with the training sequence, u ₃ is u ₁ Is a training sequence cyclically shifted by 2 Ks compared with the training sequence.

The transmitter (S) transmits the data signal (u ₁ signal hereinafter) including a u1 training sequence, and relays the data signal (hereinafter, including u _2, and u ₃ training sequence each u ₂ signal, and u ₃ signal ).

A first repeater operating in the reception mode (R1) performs the auto-correlation of the received signals after receiving the signal u1 from the transmitting and receiving u ₂ and u ₃ signal from the second repeater (R2).

At this time, u ₂ and u ₃ is the auto-correlation result of zero because the cyclic shift by Ks and 2Ks can separate only the S-link signal R1.

Reception unit (D) is the second repeater (R2) R1-R2-D link channel estimate for S-R2-D link channel using the u ₂ signal, and using the u ₃ signal which is transmitted from the first time slot .

The receiving unit D receives the u ₁ signal from the transmitting unit S and estimates the SD link channel using the u ₁ signal.

5 is a diagram illustrating operations performed in a second timeslot according to an embodiment of the present invention.

In the second time slot, the first repeater R1 operates in the transmission mode and the second repeater R2 operates in the reception mode.

In the second time slot, the transmitter S transmits a u ₁ signal. Also, the first repeater R1 operating in the transmission mode broadcasts the u- ₂ training sequence added to the S-R1 link signal separated in the first time slot. The first repeater 1 (R1) uses the training sequence u ₂ is to remove the SD link and R1-S-D link when receiving u ₁ and u ₂ at the receiver (D).

The second relay R2 receives the u1 signal and u2 signal from the transmitter S and the first relay R1, respectively, and discards the train train from the received signal.

The receiving unit D also receives the u1 signal from the transmitting unit S and receives the u2 signal from the first repeater R1. The u ₁ and u ₂ signals have different training sequences so that each link signal can be separated. The u1 signal is used to estimate the channel of the SD link, and the u2 signal is used to estimate the channel of the S-R1-D link.

6 is a diagram illustrating operations performed in a third timeslot according to an embodiment of the present invention.

In the third time slot, the first repeater R1 operates in the reception mode and the second relay R2 operates in the transmission mode.

In the third time slot, the transmitter S transmits a u ₁ signal. In addition, the second repeater R2 operating in the transmission mode transmits a signal by adding u2 training to the signal which discards the train train in the second time slot. That is, in the third time slot, the transmitter S transmits the u ₁ signal and the second relay R 2 transmits the u ₂ signal.

A first repeater (R1) operating in the receive mode receives the signals u ₁ from the transmitter (S) and receives the signal from the second repeater u2.

The first repeater R1 performs a reverse cyclic shift of the received signal by Ks and then performs a correlation operation with the training sequence u1. It is possible to separate only the u ₂ signal which is the signal from the second repeater R 2 because the autocorrelation is performed after the reverse cyclic shift.

On the other hand, u ₁ signal from the transmission unit (S) is zero by the correlation operation of the first repeater (R1).

Receiving (D) receives the signal u ₁ from the transmitter (S) and receives the signal u2 from the second repeater (R2). The u ₁ signal received from the transmitter S is used to estimate the channel of the SD link and the u ₂ signal received from the second relay is used to estimate the channel of the R 2 -D link.

7 is a diagram illustrating operations performed in a fourth time slot according to an embodiment of the present invention.

In the fourth time slot, the first repeater R1 operates in the transmission mode and the second repeater R2 operates in the reception mode.

The transmitting unit S transmits the u1 signal, the first repeater R1 copies the separated R2-R1 link signal in the third time slot into two signals, and one of the two signals transmits the u2 training train And the u3 training sequence is added to the other signal.

The second repeater (R2) is receiving the signal u ₁ from the transmitter (S) and receives the signal u ₂ and u ₃ signal from the first repeater.

The second repeater R2 copies the sum of the received u1, u2, and u3 signals and performs parallel processing on the signals.

In the first parallel processing process, a sum of the received u1, u2, u3 signals is subjected to autocorrelation with u1 to separate signals of the S-R2 link. Also, in the second parallel processing process, a reverse cyclic shift is performed on the sum of the received signals u1, u2, u3 by 2 Ks, and then autocorrelation is performed with u1 to separate signals of the R1-R2 link.

The signal of the S-R2 link separated in the second repeater and the signal of the R1-R2 link are broadcast with u2 and u3 training sequences added in the next time slot (first time slot), respectively.

The receiving unit S receives the u1 signal from the transmitting unit S, receives the u2 and u3 signals from the first repeater, and uses the received u1 signal for estimation of the S-D link channel. Also, the receiving unit S uses the u2 signal for R2-R1-D link estimation.

As described above, during four time slots, the transmitter transmits a signal including a predetermined training sequence, and each repeater transmits a cyclic-shifted signal by Ks or 2Ks when in the transmission mode, and the autocorrelation It is possible to efficiently perform channel estimation for a plurality of links at a receiving end through separation of a specific link signal.

As described above, the present invention has been described with reference to particular embodiments, such as specific elements, and specific embodiments and drawings. However, it should be understood that the present invention is not limited to the above- And various modifications and changes may be made thereto by those skilled in the art to which the present invention pertains. Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, belong to the scope of the present invention .

Claims (10)

A signal processing method performed in a first repeater for channel estimation in a dual repeater system including first and second repeaters,
Receiving from the second repeater a signal including at least one of a u ₁ training sequence from the transmitter and a u ₂ training sequence or u ₃ training sequence from the second repeater in the receiving mode and performing a predetermined signal processing a);
(B) adding at least one training sequence of a u ₂ training sequence or a u ₃ training sequence to a signal processed in a predetermined manner in a transmission mode, and transmitting the added training sequence,
The u ₂ training sequence is u ₁ is preset Ks as cyclic shifted training sequence for training the column, the u ₃ training sequence is a predetermined 2Ks as cyclic shifted training sequence for a column wherein u ₁ training, the u ₁ Wherein the training sequence has autocorrelation properties. The method according to claim 1,
Wherein the u ₁ training sequence has a periodic peak value based on a Ks section. 3. The method of claim 2,
The step (a)
The method comprising: receiving respectively a signal including a training u1 10-1 time slot from the signal and a signal and the transmission unit that includes the training sequence u ₃ u ₂ including a training sequence from the second repeater (a1); And
And a step (a2) of separating a signal from a transmitter link using autocorrelation characteristics of the u ₁ training sequence in a first time slot. The method of claim 3,
The step (a)
Receiving a signal including a u ₁ training sequence from the transmitter in a third time slot and receiving a signal including a u ₂ training sequence from the second relay;
Characterized in that after performing the above step (a3) a signal Ks by reverse cyclic shift on the received in a step (a4) to separate the signal of the second relay link through the autocorrelation of u ₁ trained column and further . 5. The method of claim 4,
The step (b)
Comprising the steps of: transmitting, in addition to the training sequence u ₂ to a signal with a transmission link, separate from the step (a1) in the second timeslot (b1); And
Article characterized in that it comprises a step (b2) for transmitting a signal, each addition of a signal, and u3 training sequence added to u ₂ training sequence in the signal of the second relay link was separated in said step (a4) in four time slots . A signal processing method performed in a second repeater for channel estimation in a dual repeater system including first and second repeaters,
Receiving from the first repeater a signal including at least one of a u ₁ training sequence from the transmitter and a u ₂ training sequence or u ₃ training sequence from the first repeater in the receiving mode and performing a predetermined signal processing a);
(B) adding at least one training sequence of a u ₂ training sequence or a u ₃ training sequence to a signal processed in a predetermined manner in a transmission mode, and transmitting the added training sequence,
The u ₂ training sequence is u ₁ is preset Ks as cyclic shifted training sequence for training the column, the u ₃ training sequence is a predetermined 2Ks as cyclic shifted training sequence for a column wherein u ₁ training, the u ₁ Wherein the training sequence has autocorrelation properties. The method according to claim 6,
Wherein the u ₁ training sequence has a periodic peak value based on a Ks section. 8. The method of claim 7,
The step (a)
Receiving a signal including a training u ₁ time slot 10-2, from the transmitting and receiving a signal comprising a training sequence u2 from the first repeater (a1); And
(A2) in the second timeslot, removing training sequences for the signals received in step (a1). 9. The method of claim 8,
The step (a)
Receiving a signal including a training sequence u ₁ receives a signal including a training sequence signal, and u ₃ u ₂ including a training sequence from a first repeater in the fourth time slot, from the transmitting unit (a3); And
a first relay link through the autocorrelation of u ₁ trained column and then through the auto-correlation calculation of u ₁ trained column and separating a signal of the transmission link, and wherein the step (a3) of the received signal cyclic by reverse 2Ks in shift (A4) of separating the signal with the signal. 10. The method of claim 9,
The step (b)
The method comprising: in the first time slot, transmit a signal including the signal and u ₃ u ₂ training sequence including a training sequence (b1); And
And a step (b2) of adding a u2 training sequence to the signal from which the training sequence is removed in the step (a2) in the third time slot.

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