KR101275852B1 - Method and apparatus for transmitting/receiving data based on sc-fde using uw - Google Patents

Abstract

PURPOSE: A SC-FDE(Single Carrier-Frequency Domain Equalization) based transceiver using a UW(Unique Word) and a method thereof are provided to improve channel estimation performance and data transmission efficiency. CONSTITUTION: A receiver receives a signal in which two UWs are added to the front end of a data symbol and one UW is added to the rear end of the data symbol. The receiver includes a channel estimator(526) and a frequency domain equalizer(527). The channel estimator estimates a channel by using the second UW of the two added UWs at the front end. The frequency domain equalizer equalizes a signal in which the two UWs at the front end are removed from the received signal in a frequency domain by using the estimated channel. [Reference numerals] (511) Modulator; (512) UW insertion unit; (522) Division unit; (523) Pre-UW removal unit; (524) First FFT unit; (525) Second FFT unit; (526) Channel estimator; (527) Frequency domain equalizer; (AA) Source data; (BB) Estimated signal

Description

Method and apparatus for transmitting / receiving data based on SC-FDE using UW based on SC-FCDE using ＵＷ (ｕｎｉｑｕｅ－ｗｏｒｄ)

The present invention relates to an SC-FDE-based transceiver and method, and more particularly, to an SC-FDE-based transceiver and method using a unique-word (UW).

Cyclic-prefix (CP) based single carrier transmission scheme is an efficient transmission scheme to overcome the effects of multipath frequency-selective fading channel by multipath. In particular, compared to a multi-carrier transmission scheme represented by orthogonal frequency division multiplexing (OFDM) because of the use of a single carrier, in synchronization and channel estimation due to peak-to-average power ratio (PAPR) problems and frequency offset It is robust to possible problems and has the advantage that a simple frequency-domain equalizer can be used at the receiving end due to the cyclic characteristics of the CP. When a transmitter has two antennas, the CP-inserted transmission signal is constructed by copying a portion of the back of the data symbol and attaching it to the front of the data symbol. 1 shows an example of a frame structure of such a transmission signal. In FIG. 1, s (o) denotes a data symbol, P denotes a permutation matrix, and H denotes a Hermitian transpose.

On the other hand, since a faster channel estimation is required in a faster communication situation, a CP-based transmission scheme is used by using a unique word (UW), which is a specific symbol already known to the transceiver, at the position of the CP. While maintaining the advantages, the receiver can easily estimate the channel using a least-square (LS) method using UW.

An object of the present invention is to provide an SC-FDE-based transmitting device and method, and a receiving device and a receiving method that can improve channel estimation performance and increase data transmission efficiency.

In order to solve the above technical problem, SC-FDE-based transmission apparatus according to the present invention, modulating the input data by a predetermined modulation scheme to output a data symbol; And a UW insertion unit for adding two unique words to the front end of the data symbol and one UW to the rear end of the data symbol.

The two UWs and the one UW are the same sequence.

The two UWs and the one UW may each be an M sequence, a Gold sequence, or a CAZAC sequence of a predetermined length.

In order to solve the above technical problem, the SC-FDE-based receiving apparatus according to the present invention receives a signal in which two UWs (unique-word) are added at the front and one UW is added at the rear of the data symbol, A channel estimator for estimating a channel by using a UW of a rear side of the added two front UWs; And a frequency domain equalizer for equalizing a signal from which the two UWs of the front end removed from the received signal in a frequency domain using the estimated channel.

The receiving apparatus may further include a first FFT unit configured to perform fast Fourier transform on a signal from which two UWs of the front end are removed and output the same to the frequency domain equalizer.

The receiving apparatus may further include a second FFT unit configured to perform a fast Fourier transform of a UW at the rear of the two UWs at the front end and output the fast Fourier transform to the channel estimator.

In order to solve the above technical problem, SC-FDE-based data transmission method according to the present invention comprises the steps of generating a data symbol by modulating the input data by a predetermined modulation scheme; And adding two unique-words (UW) to the front end of the data symbol and adding one UW to the rear end of the data symbol.

In order to solve the above technical problem, SC-FDE-based data receiving method according to the present invention, the step of receiving a signal in which two UW (unique-word) is added to the front end of the data symbol and one UW added to the rear end ; Estimating a channel using a rear UW of the added two front UWs; And equalizing, in the frequency domain, the signal from which the two UWs from the front end are removed from the received signal by using the estimated channel.

The data receiving method may further include fast Fourier transforming a signal from which the two UWs of the front end are removed before the equalizing.

The data receiving method may further include fast Fourier transforming the UW of the rear of the two UWs of the front end prior to estimating the channel.

According to the present invention described above, by adding two UWs at the front end of the data symbol and one UW at the rear end of the data symbol, the channel can be estimated using the rear UW of the two UWs at the front end. This has the advantage of improving performance and increasing data transfer efficiency.

1 shows an example of a frame structure of a transmission signal in which a CP is inserted.
2 shows an example of a network model including one relay.
3 shows an example of a frame structure of a UW-based transmission signal.
4 shows a frame structure of a UW-based transmission signal according to an embodiment of the present invention.
5 is a block diagram of a UW-based transmitting device and a receiving device according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. In the following description and the accompanying drawings, substantially the same components are denoted by the same reference numerals, and redundant description will be omitted. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In order to facilitate understanding of the present invention, first, problems that may occur in the existing UW-based transmission scheme will be described.

2 shows an example of a network model including one relay. Referring to FIG. 1, S denotes a transmitting end, D denotes a receiving end, and R denotes a relay. In timeslot 1, signals are sent from S to R and D. In timeslot 2, signals are sent from S and R to D. In this case, the path from S to D causes the previous symbol to interfere with the next symbol due to the transmission of a continuous signal. This phenomenon is called inter-block interference (IBI). IBI occurs because paths h1, h2, h3 are multipath frequency selective fading channels. h1, h2, and h3 have lengths of L1, L2 and L3, respectively, as follows.

라 하고, 이것의 UW를

이라고 하자. 마찬가지로 타임슬롯 2에서 전송할 데이터 심볼과 이것의 UW를 각각

와

라고 하자. d와 u는 각각 길이 M과 K의 시퀀스이며, 아래와 같이 표현할 수 있다.In timeslot 1, the jth data symbol of the transmitting end is transmitted.

And UW of this

. Similarly, the data symbol to be transmitted in timeslot 2 and its UW

Wow

Let's say. d and u are sequences of lengths M and K, respectively.

이고,

은 컨벌루션(convolution) 성질에 의해

으로 결정된다. 이때 UW 기반 전송 신호의 프레임 구조는 도 3과 같이 나타낼 수 있다.here,

ego,

Is due to the convolution nature

Is determined. In this case, the frame structure of the UW-based transmission signal may be represented as shown in FIG. 3.

,

의 회색으로 처리된 부분은 이전 신호로부터 받는 IBI를 나타낸다. 이와 같은 전송 프레임 구조에 의하면, 데이터 심볼의 앞쪽에 위치하는 UW에 IBI가 미치게 되므로, 데이터 심볼의 손실을 막을 수는 있지만, 수신단에서는 데이터 검출에 앞서 IBI의 영향을 받은 UW를 이용하여 채널 추정을 해야 하기 때문에 채널 추정 성능이 열화된다. Referring to Figure 3,

,

The grayed part of indicates the IBI received from the previous signal. According to such a transmission frame structure, since the IBI extends to the UW located in front of the data symbol, the loss of the data symbol can be prevented, but the receiver uses the UW affected by the IBI prior to data detection to perform channel estimation. Channel estimation performance is degraded.

In addition, according to the above-described transmission frame structure, when using the LS channel estimation, the length of the UW should be more than twice the effective channel length to remove the IBI, resulting in a reduction in the data rate. In addition, if the channel estimation is performed after removing a portion of the UW by the channel length to remove the IBI, the excellent characteristics inherent to the UW sequence may be lost, resulting in an increase in the channel estimation error.

In order to solve the above problems, in the transmission frame structure according to an embodiment of the present invention, two UWs are disposed at the front of the data symbol and one UW is disposed at the rear of the data symbol. 4 shows a transmission frame structure according to an embodiment of the present invention. Referring to FIG. 4, d ₁ ^j and d ₂ ^j represent data symbols corresponding to the j th block, u ₁ represents UW added to the data symbol d ₁ ^j , and u ₂ is added to the data symbol d ₂ ^j . UW. The length K 'of each UW may be half of the length K of the existing UW (FIG. 3). In Fig. 4, the grayed portion shows the IBI received from the previous signal. The front UW of the two UWs in front of the data symbol is affected by the IBI, but the rear UW is not affected by the IBI. Therefore, the receiving end discards the front UW of the two UWs in front of the data symbol to remove the influence of the IBI, and the rear UW is not affected by the IBI. Equalization is possible in the frequency domain with the data symbol except the UW (the rear UW of the two UWs before the data symbol) used for channel estimation and the UW after the data symbol. Because two UWs are placed at the front of the data symbol, the circulant characteristics of the data are maintained even after the removal of one IW-affected front UW, so the receiver uses a simple frequency domain equalizer. This becomes possible.

5 is a block diagram of a UW-based transmitting device and a receiving device according to an embodiment of the present invention. The transmitter and the receiver according to the present embodiment represent a system of a single carrier-frequency domain equalization (SC-FDE) scheme.

Referring to FIG. 5, the transmission apparatus according to the present embodiment includes a modulator 511 and a UW inserter 512.

The modulator 511 modulates the input source data by a predetermined modulation method and outputs data symbols. As the modulation method of the modulator 511, for example, QAM modulation, QPSK modulation, or the like may be used.

The UW inserting unit 512 adds two UWs to the front of the data symbol and one UW to the rear of the data symbol, as shown in FIG. 4, for the data symbols output from the modulator 511. . The three additional UWs are the same sequence. Each UW may be an M sequence or a Gold sequence or a Constant Amplitude Zero AutoCorrelation (CAZAC) sequence of a predetermined length. The CAZAC sequence is known to exhibit excellent channel estimation performance in the SC-FDE system which estimates the channel in the frequency domain because the power distribution is constant in the time and frequency domain.

After UW addition, the data symbols transmitted through the antenna go through channel h (n) and noise w (n) is added.

Referring to FIG. 5, the receiving apparatus according to the present embodiment includes a splitter 522, a pre-UW remover 523, a first FFT unit 524, a second FFT unit 525, and a channel estimator 5526. ), And a frequency domain equalizer 527.

The receiving device receives a signal in which two UWs are added at the front end of the data symbol, and a data symbol having one UW added at the rear end of the data symbol goes through the channel h (n) and noise w (n) is added.

The divider 522 divides the received signal into two UW portions at the front end and the remaining portion, that is, the data symbol and the UW at the rear end are combined. The portion of the data symbol combined with the rear end UW is output to the first FFT unit 524, and the two front UW parts are input to the pre-UW removal unit 523. As a result, the first FFT unit 524 receives a signal from which the two UWs of the preceding stage are removed from the received signal.

The pre-UW removal unit 523 removes the front UW portion from the two UW portions at the front end, and outputs the rear UW portion (the portion not affected by the IBI) to the second FFT portion 523. As a result, a signal corresponding to the rear UW of the two UWs in the front end is input to the second FFT unit 525.

The first FFT unit 524 performs fast Fourier transform on a signal from which two UWs from the front end are removed from the received signal, and outputs the fast Fourier transform to the frequency domain equalizer 525.

The second FFT unit 523 converts a signal corresponding to the rear UW of the two UWs of the front end into a frequency domain signal by performing fast Fourier transform, and outputs the signal to the channel estimator 526. For example, if the signal transmitted from the transmitting side is a signal as shown in Fig. 4, as a result, the signal output from the second FFT unit 523 is u1 (or u2) passing through the channel h (n) and the noise w (n). This added signal (more precisely this is a fast Fourier transformed signal).

The channel estimator 526 estimates a channel using a signal corresponding to the rear UW of the two front UWs from the second FFT unit 525. As described above, since the UW sequence added by the transmitting end is already known by the receiving end, it is possible to simply estimate the channel.

The frequency domain equalizer 527 uses a channel estimated by the channel estimator 526 to perform a fast Fourier transform on a signal obtained by fast Fourier transforming a signal obtained by removing the first two UWs from the first FFT unit 524. Equalize and output the estimated signal.

The above-described embodiments of the present invention can be embodied in a general-purpose digital computer that can be embodied as a program that can be executed by a computer and operates the program using a computer-readable recording medium. The computer-readable recording medium includes a storage medium such as a magnetic storage medium (e.g., ROM, floppy disk, hard disk, etc.), optical reading medium (e.g., CD ROM,

So far I looked at the center of the preferred embodiment for the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

Claims (10)

delete delete delete In the SC-FDE-based receiving device,
The receiving device receives a signal in which two unique words (UW) are added at the front end and one UW at the rear end, wherein the two UWs and the one UW are the same sequence, and
A channel estimating unit estimating a channel by using a UW of a rear side of the added two UWs of the front end; And
And a frequency domain equalizer for equalizing a signal from which the two UWs in the front end removed from the received signal in a frequency domain using the estimated channel. 5. The method of claim 4,
And a first FFT unit for fast Fourier transforming the signal from which the two UWs of the front end is removed and outputting the same to the frequency domain equalizer. 5. The method of claim 4,
And a second FFT unit configured to perform fast Fourier transform on the rear UW among the two UWs of the front end and output the fast Fourier transform to the channel estimator. delete In the SC-FDE-based data receiving method,
Receiving a signal in which two unique words (UW) are added at the front of the data symbol and one UW at the rear, where the two UWs and the one UW are the same sequence;
Estimating a channel using a rear UW of the added two front UWs; And
Equalizing in a frequency domain a signal obtained by removing the two previous UWs from the received signal using the estimated channel. 9. The method of claim 8,
And performing fast Fourier transform on the signal from which the two UWs from the front end are removed before the equalizing. 9. The method of claim 8,
And performing fast Fourier transform of a UW at the rear of the two UWs at the front end before the estimating of the channel.

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