KR100968207B1 - Fft windows position recovery, receiver for digital radio mondiale comprising the same and method therefor - Google Patents

Abstract

According to an embodiment of the present invention, an FFT unit for fast Fourier transforming an effective data section of an OFDM symbol according to a position of an FFT window, and averaging phase shift values of a plurality of reference cells included in the fast Fourier transformed OFDM symbol are used. And an FFT window position correction unit for calculating a position offset estimate. According to the present invention, the position of the FFT window is corrected based on the calculated position offset estimate. Therefore, it is possible to restore the position of the FFT window that is changed due to the error of the sampling frequency between the transmitter and receiver.

Description

FFT WINDOWS POSITION RECOVERY DEVICE, RECEIVER FOR DIGITAL RADIO BROADING AND FFT WINDOWS POSITION RECOVERY METHOD {FFT WINDOWS POSITION RECOVERY, RECEIVER FOR DIGITAL RADIO MONDIALE COMPRISING THE SAME AND METHOD THEREFOR}

The present invention relates to an FFT window position restoration apparatus, a digital radio broadcast reception apparatus having the same, and an FFT window position restoration method. Specifically, an FFT window position restoration apparatus based on an OFDM transmission scheme, a digital radio broadcasting reception apparatus having the same, and an FFT A method for restoring window position.

Digital radio broadcasting system (Digital Radio Mondiale) is a digital broadcasting system using a frequency band of long wave (LF), medium wave (MF), short wave (HF) of 30MHz or less, and is defined by the ETSI standard.

Such digital radio broadcasting systems include digital television broadcasting systems and digital audio broadcasting systems in a broad sense. In this case, the digital audio broadcasting system generally refers to a digital audio broadcasting that mainly provides an audio (or sound) service by being distinguished from a digital television broadcasting system having a video as a main medium. That is, the digital radio broadcasting system refers to digital audio broadcasting that can replace the existing analog AM (Amplitude Modulation) and FM (Frequency Modulation) radio broadcasting. Currently, most digital radio broadcasting systems developed around the world provide high quality audio services at the CD level using the latest voice coding scheme with high compression rate.

As such, the digital radio broadcasting system is strongly resistant to the effects of multipath fading, which is one of the characteristics of the transport channel in order to provide various services stably even when moving, and can be received without degrading orthogonal frequency-division. Multiplexing) transmission method is used.

Such a digital radio broadcasting system can implement a single frequency network (SFN) by using the OFDM transmission scheme as described above. As a result, a broadcasting service can be performed without using a local boundary using a single carrier frequency. .

However, when there is a carrier frequency offset between the transmitter and the receiver, the OFDM transmission scheme loses orthogonality between subcarriers of a received signal on a frequency spectrum, thereby causing a signal-to-noise ratio; SNR) is greatly reduced. In addition, the OFDM transmission scheme is sensitive to carrier frequency offset, frame synchronization, and sampling synchronization.

In particular, in the OFDM transmission scheme, when the error of the sampling frequency between the transmitter and the receiver accumulates differently from the packet communication, a phenomenon of missing or adding a sample occurs at the receiver, and as a result, the position of the FFT window is changed. Variation of the position of the FFT window causes inter-OFDM interference and carrier interference.

As a result, performance degradation of the entire digital live broadcasting system using the OFDM transmission scheme occurs. Therefore, restoration of the FFT window position is essentially required in a digital live broadcasting system using an OFDM transmission scheme.

Accordingly, an object of the present invention is to provide an FFT window position restoration apparatus capable of restoring the FFT window position, a receiving device for digital radio broadcasting having the same, and a method for restoring the FFT window position.

In order to achieve the above object, the FFT window position recovery apparatus of the present invention includes a reference cell extracting unit for extracting complex values of reference cells included in the OFDM symbol among fast Fourier transformed signals, and based on the extracted complex values. A phase extractor for extracting phase values of the reference cells, an average value calculator for averaging phase shift values of the extracted reference cells, and generating an averaged phase shift value as an estimate of a position offset of the FFT window; And an FFT window controller for moving the position of the FFT window based on the position offset estimate.

In order to achieve the above object, a digital radio broadcasting receiver according to the present invention removes a guard interval and performs a fast Fourier transform on an effective data interval of an OFDM symbol according to the position of an FFT window, and the fast Fourier transform. A FFT window position correction unit for calculating a position offset estimate of the FFT window by averaging phase shift values of a plurality of reference cells included in an OFDM symbol, and correcting the position of the FFT window based on the calculated position offset estimate. do.

In order to achieve another object as described above, the FFT window position restoration method of the present invention is as follows.

First, a DRM (Digital Radio Mondiale) transmission frame consisting of a plurality of OFDM symbols is received through a multipath fading channel. Then, it is determined whether the currently received OFDM symbol is the first OFDM symbol among the plurality of OFDM symbols. Subsequently, when the currently received OFDM symbol is the first OFDM symbol, reference cells included in the first OFDM symbol are extracted as a complex value. Subsequently, the correlation between the position and the phase of each reference cell is calculated using the extracted complex values of the reference cells. Then, the position offset estimate of the FFT window is estimated from the calculated correlation. Thereafter, the position of the FFT window is restored by changing the position of the FFT window according to the estimated position offset of the FFT window.

According to an embodiment of the present invention, an FFT unit for fast Fourier transforming an effective data section of an OFDM symbol according to a position of an FFT window, and averaging phase shift values of a plurality of reference cells included in the fast Fourier transformed OFDM symbol are used. And an FFT window position correction unit for calculating a position offset estimate. According to the present invention, the position of the FFT window is corrected based on the calculated position offset estimate. Therefore, it is possible to restore the position of the FFT window that is changed due to the error of the sampling frequency between the transmitter and receiver.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 illustrates an FFT window offset due to a sampling frequency error accumulated in an OFDM symbol.

Referring to FIG. 1, an OFDM signal transmitted from a transmitting side is composed of a plurality of OFDM symbols configured in a stream form. For each OFDM symbol, an OFDM symbol is inserted between symbols to prevent interference between symbols and an effective data interval (DAT) generated by an inverse fast fourier transform (IFFT) performed at a transmitting side. It consists of a guard interval (CP) with G sample lengths. That is, the transmitter transmits one symbol consisting of (G + N) samples by copying the N complex values generated by the IFFT and the last G of them.

In addition, each OFDM symbol includes a plurality of data cells and a plurality of reference cells. The plurality of reference cells include a time reference cell (hereinafter referred to as TRC), a gain reference cell (hereinafter referred to as GRC), and a frequency reference cell (hereinafter referred to as FRC). It may include at least one. Here, GRC and FRC exist in each symbol, but TRC exists only in the first symbol in one frame. The FRC is a reference cell used by the DRM receiver to detect the presence of the DRM signal and to estimate the frequency offset. The GRC is a reference cell used to estimate the coherent demodulation and the channel response. Since the DRM receiver and the DRM transmitter know both the size and phase of these reference cells, and use them as a pilot signal to perform synchronization and channel estimation, the reference cells are also called "pilot cells."

In the DRM receiver of the present invention, symbol timing synchronization is performed to find the starting point of the FFT window 10 of the OFDM symbol using the reference cells together with the detection of the OFDM signal.

If the start point of the OFDM symbol sampled at the receiving end is incorrectly determined, a phase shift of the received OFDM signal and inter-symbol interference occur after the fast fourier transform (FFT) performed at the receiving end.

As shown in FIG. 1, since the guard period CP exists only at the front of the symbol, a phase shift occurs when the point preceding the valid data period DAT is determined as the start point of the FFT window 10. On the receiving side, the number of abnormal samples ((N + G + 1)) to which the number of samples is added is obtained, not the number of samples included in one OFDM symbol ((N + G)) (FIG. See 1 (a)).

In addition, if the point delayed from the start point of the valid data interval DAT is determined as the start point of the FFT window 10, the inter-symbol interference and the inter-carrier interference occur with phase shift. In this case, on the receiving side, the number of samples included in one OFDM symbol is not the number of normal samples ((N + G)) but the number of abnormal samples ((N + G-1)) in which the number of samples is missing. Is obtained (see FIG. 1A).

As described above, in the DRM transmitting / receiving system using the OFDM transmission scheme, due to the difference in sampling frequencies between the transmitting side and the receiving side, the receiver cannot acquire a total of (N + G) samples through one OFDM symbol (N + G + 1). Alternatively, since (N + G-1) samples are acquired, a position error of the FFT window 10 occurs.

Accordingly, in the present invention, by correcting (or 'restoring') the position error of the FFT window 10 as described above, a sample may be missing from a specific symbol or another sample may be added to the specific symbol from an adjacent symbol. Preventive measures are provided.

Hereinafter, the DRM receiver of the present invention for correcting the position of the FFT window 10 will be described in detail with reference to FIGS. 2 to 3.

2 is a block diagram of a DRM receiver according to an embodiment of the present invention.

Referring to FIG. 2, the DRM receiver 100 according to an embodiment of the present invention includes an ADC unit 110, an FFT unit 120, and an FFT window position correction unit 130.

The ADC unit (Analog-to-Digital Converter) 110 outputs a sampling signal yi [] obtained by sampling the OFDM signal OFDM-S through the multipath fading channel 2.

The FFT unit 120 performs fast Fourier transform on the sampling signal yi [] sampled by the ADC unit 110. At this time, the FFT unit 120 corrects the position of the FFT window based on the FFT window position correction value C provided from the FFT window position correction unit 130. In addition, the FFT unit 120 performs fast Fourier transform by selecting only the valid data section (DAT in FIG. 1) of the sampling signal yi [] according to the corrected FFT window position, and performs the fast Fourier transformed valid data section. (DAT in FIG. 1) is generated as an output signal Yi [].

The FFT window position correction unit 130 detects the first received OFDM symbol among the plurality of sampled symbols and estimates the position offset of the FFT window using the detected first OFDM symbol. Thereafter, the FFT window position correction unit 130 outputs a correction value C based on the estimated value of the position offset of the estimated FFT window. The output FFT window position correction value C is provided to the FFT unit 120, and the FFT unit 120 moves the position of the FFT window based on the correction value C.

3 is a block diagram illustrating an example of a configuration of the FFT window position correction unit illustrated in FIG. 1.

Referring to FIG. 3, the FFT window position corrector 130 includes a reference cell extractor 132, a phase extractor 134, an average value calculator 136, and an FFT window controller 138.

The reference cell extracting unit 132 extracts complex values Xi [] e ^[] of reference cells included in the first OFDM symbol among the output signals Yi [] output from the FFT unit 120, respectively. The extracted complex value Xi [] e ^[] is equal to the rightmost term in Equation 1 below.

Here, xi () is an OFDM signal transmitted from the transmitting side, y _{i (n)} is an OFDM signal sampled through the ADC unit 110 shown in FIG. 2, ↔ represents a Fourier transform, and idx _RC [ 0, k] is the position value (or index) of the kth reference cell of the first OFDM symbol, N is the size of the FFT, that is, the total number of samples included in the first symbol, m is changed according to the sampling frequency error The position value (or index) of the k-th reference cell.

The phase extractor 134 calculates a correlation between the positions and phases of the reference cells by using the complex value Xi [] e ^[] extracted from the reference cell extractor. To this end, the phase extractor 134 calculates the phase value φ [] of the k-th reference cell, which is changed according to the sampling frequency error, as shown in Equation 2 below.

Where * is a conjugate complex value.

Meanwhile, in Equation 2, the relationship between the position value and the phase of the reference cell has no linear characteristic. That is, the phase of each reference cell rotates (or increases) by a predetermined multiple of the position value (or index value) of the corresponding reference cells only within the range of -p ~ + p. Therefore, in order to calculate the correlation between the position value and the phase value of the reference cell, the relationship between the position value and the phase of the reference cell must maintain a linear characteristic.

The phase extractor 134 maintains a linear characteristic between the position value and the phase of the reference cell through an operation performed by Equation 3 below.

Here, k is the 2≤k≤k _max, k _max is the total number of the reference cell included in the first OFDM symbol, φidx _RC [0, k] and _{φidx RC [0, k-1} ] is -Π or + It is the phase of reference cells adjacent to each other with π in between.

According to Equation 3, if the phase difference between the phase (φidx _RC [0, k]) of the k-th reference cell and the phase (φidx _RC [0, k-1]) of the k-1th reference cell is + π or more, The phase (φidx _RC [0, k]) of the k-th reference cell is summed to -2, and the phase of the k-th reference cell (φidx _RC [0, k]) and the phase of the k-th reference cell (φidx _RC [ If the phase difference between 0, k-1]) is less than or equal to -π, 2? Is added to the phase (? Idx _RC [0, k]) of the k-th reference cell. By doing so, a linear characteristic is maintained between the position value and the phase of the reference cell.

)로서 생성한다. 상기 평균값 계산부(136)로부터 생성된 상기 FFT 윈도우의 위치 옵셋의 추정치(

)는 아래의 수학식 4로 나타낼 수 있다. Subsequently, the average value calculator 136 averages the phase value variation of each reference cell through Equations 1 to 3, and calculates the averaged phase value variation of the position offset of the FFT window.

To generate. Estimated value of the position offset of the FFT window generated from the average value calculator 136 (

) May be represented by Equation 4 below.

는 샘플링 주파수의 오차에 의한 위상 변동의 기울기값의 총합과 같다. Here, ＾ means an estimation function, _{Δφ idxRC} [,] means the amount of phase variation due to the error of the sampling frequency, Δidx _RC [,] means the amount of position variation of the reference cell due to the error of the sampling frequency. do. Thus, the above

Is equal to the sum of the slope values of the phase fluctuations due to the error of the sampling frequency.

)로서 생성한다.As a result, the amount of phase shift of the reference cells is averaged by dividing the sum of the slope values of the phase shifts by the total number of reference cells (k _max −1) included in the first OFDM sample. In this way, the average value calculator 136 calculates the position offset estimate of the FFT window using the value calculated through the division operation.

To generate.

)에 근거하여 보정값(CP)을 생성한다. The FFT window controller 136 may estimate the position offset of the generated FFT window (

To generate a correction value CP.

)가 -1 샘플(-1 sample, 도 1에 도시됨)보다 작으면, FFT 윈도우(10, 도 1에 도시됨)의 시작 시점을 1샘플 뒤로 이동시키고, FFT 윈도우(10) 위치 옵셋 추정치(

)가 +1 샘플(+1 sample)보다 크면 FFT 윈도우(10)의 시작시점을 1 샘플 앞으로 이동시킨다.The FFT unit 120 (shown in FIG. 2) corrects the position of the FFT window based on the generated FFT window position correction value CP. For example, the position offset estimate of the FFT window 10 (

) Is less than -1 sample (-1 sample, shown in FIG. 1), moves the start time of the FFT window 10 (shown in FIG. 1) behind one sample, and estimates the FFT window 10 position offset estimate (

If is greater than +1 sample, the start point of the FFT window 10 is moved forward by 1 sample.

4 is a flowchart for describing a method of correcting a position of an FFT window according to an embodiment of the present invention.

4, first, the receiving side receives a DRM transmission frame composed of a plurality of OFDM symbols, and determines whether the currently received OFDM symbol is the first OFDM symbol (S410). As described above, the first OFDM symbol of the DRM transmission frame may include at least one reference cell of TRC, FRC, and GRC. However, TRC exists only in the first OFDM symbol. When TRC, FRC, and GRC are present in the first OFDM symbol, each reference cell has a position (or index) and a phase determined within 4.5 kHz from the center frequency.

Next, the receiver extracts reference cells from the first OFDM symbol (S420). That is, a complex value of each reference cell is calculated.

)를 추정한다(S440). Subsequently, the receiver calculates a correlation between the position and phase of each reference cell using the calculated complex values of the reference cells (S430). Subsequently, the receiving side estimates the position offset of the FFT window from the calculated correlation.

) Is estimated (S440).

)에 따라 FFT 윈도우의 위치를 변경하고(S450), 변경된 FFT 윈도우의 위치에 따라 수신 신호를 구성하는 각 OFDM 심볼들의 보호구간(CP)을 제거하고, 보호구간(CP)이 제거된 수신신호를 고속 푸리에 변환한다(S460). Then, the estimated position offset of the FFT window (

Change the position of the FFT window according to (S450), remove the guard interval (CP) of each OFDM symbol constituting the received signal according to the changed position of the FFT window, and remove the received signal from which the guard interval (CP) has been removed. Fast Fourier transform (S460).

5 is a flowchart illustrating step 430 shown in FIG. 4 in more detail.

Referring to FIG. 5, phase values are extracted from the extracted plurality of reference cells. At this time, the extracted phase values are calculated through the algorithm as described above (S510). In this case, since there is no linearity between the position and the phase of the reference cells, a linear characteristic between the position and the phase of the reference cells is secured through an algorithm that performs the calculation process of Equation 3 described above.

)로서 FFT 윈도우의 위치를 복원하는데 이용된다.Subsequently, the calculated phase values of each of the reference cells are summed (S520), and the average value of the phase variation values of the reference cells is calculated through division association that divides the summed phase values by the total number of reference cells included in the first OFDM symbol. (S530). The average value of the phase shift value is calculated through an algorithm such as Equation 4 described above. The average value of the calculated phase shift value is a position offset estimate of the FFT window (

Is used to restore the position of the FFT window.

As described above, anyone of ordinary skill in the art to which the present invention pertains can variously change the preferred embodiment of the present invention without departing from the spirit and scope of the present invention. Accordingly, various modifications may be made to the invention without departing from the spirit of the invention as claimed in the claims.

FIG. 1 illustrates an FFT window offset due to a sampling frequency error accumulated in an OFDM symbol.

2 is a block diagram of a DRM receiver according to an embodiment of the present invention.

3 is a block diagram illustrating an example of a configuration of the FFT window position correction unit illustrated in FIG. 1.

4 is a flowchart for describing a method of correcting a position of an FFT window according to an embodiment of the present invention.

5 is a flowchart illustrating step 430 shown in FIG. 4 in more detail.

Claims (11)

In the receiving device for a digital radio broadcasting (Digital Radio Mondiale) receiving an OFDM symbol consisting of a guard interval and a valid data interval in units of frames, An FFT unit for fast Fourier transforming the OFDM symbol according to a position of an FFT window; And A time reference cell, a gain reference cell for estimating a frequency offset, and a coherent that are present only in the first symbol of a frame included in the OFDM symbol A phase offset of the frequency reference cell for estimating coherent demodulation and channel response is averaged to calculate a position offset estimate of the FFT window, and based on the calculated position offset estimate of the FFT window. Receiving apparatus for a digital radio broadcasting system (Digital Radio Mondiale) comprising a FFT window position correction unit for correcting the position. delete The receiver of claim 1, wherein the valid data section includes audio information and data information. The method of claim 1, wherein the FFT window position correction unit, A reference cell extracting unit for extracting complex values of reference cells included in the OFDM symbol among the fast Fourier transformed signals by the FFT unit; A phase extracting unit extracting phase values of the reference cells based on the extracted complex value; An average value calculator for averaging phase shift values of the extracted reference cells and generating the averaged phase shift value as an estimate of a position offset of the FFT window; And And an FFT window control unit for moving the position of the FFT window based on the position offset estimate. The method of claim 4, wherein An estimate of the position offset of the FFT window (

),

Defined as Here, ＾ means an estimation function, _{Δφ idxRC} [,] means the amount of phase variation due to the error of the sampling frequency, Δidx _RC [,] means the amount of position variation of the reference cell due to the error of the sampling frequency. And k _max is the total number of the reference cells and is two or more real numbers. An ADC unit for receiving and sampling an OFDM symbol including a guard period and a valid data period in units of frames; An FFT unit for removing the guard interval and performing fast Fourier transform on the valid data interval of the OFDM symbol according to a position of an FFT window; And Calculating phase shift values of a plurality of reference cells included in the OFDM symbol, An FFT window position correction unit configured to correct the position of the FFT window by using the calculated phase shift value, The FFT window position correction unit, A time reference cell existing only in a first symbol of a frame included in the OFDM symbol among the fast Fourier transformed signals by the FFT unit, a gain reference cell for estimating a frequency offset, and a coherent A reference cell extracting unit extracting a complex value of a frequency reference cell for estimating coherent demodulation and channel response; A phase extracting unit extracting phase values of the reference cells based on the extracted complex value; An average value calculator for averaging phase shift values of the extracted reference cells and generating the averaged phase shift value as an estimate of a position offset of the FFT window; And And an FFT window control unit for moving the position of the FFT window based on the position offset estimate. The receiver of claim 6, wherein the reference cells are determined in phase and position within a range of 4.5 kHz from a center frequency. Receiving an OFDM symbol consisting of a guard interval and a valid data interval in units of frames, and according to the position of the FFT window of the receiver for digital radio broadcasting (Digital Radio Mondiale) to output the fast Fourier transform In the FFT window position restoration device, Of the fast Fourier transformed signal, a time reference cell existing only in a first symbol of a frame included in the OFDM symbol, a gain reference cell for estimating a frequency offset, and coherent demodulation A reference cell extracting unit extracting a complex value of a frequency reference cell for estimating a channel response; A phase extracting unit extracting phase values of the reference cells based on the extracted complex value; An average value calculator for averaging phase shift values of the extracted reference cells and generating the averaged phase shift value as an estimate of a position offset of the FFT window; And And an FFT window controller for moving the position of the FFT window based on the position offset estimate. Receiving a Digital Radio Mondiale (DRM) transmission frame consisting of a plurality of OFDM symbols over a multipath fading channel; Determining whether a currently received OFDM symbol is the first OFDM symbol of the plurality of OFDM symbols; When the currently received OFDM symbol is the first OFDM symbol, a time reference cell existing only in a first symbol of a frame included in the first OFDM symbol, a gain reference cell for estimating a frequency offset And extracting, as a complex value, a frequency reference cell for estimating coherent demodulation and channel response; Calculating a correlation between a position and a phase of each reference cell using the complex values of the extracted reference cells; Estimating a position offset estimate of the FFT window from the calculated correlation; And Restoring the position of the FFT window by changing the position of the FFT window according to the estimated position offset of the FFT window. The method of claim 9, wherein calculating the correlation comprises: Calculating phase values of the respective reference cells; Summing the calculated phase values; And And dividing the sum of the summed phase values by the sum of the reference sets to calculate an average value of the phase values. delete

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