KR100245029B1 - Receiving apparatus of ofdm method - Google Patents

Abstract

According to the present invention, an apparatus using a digital transmission scheme such as a high-definition television can satisfy 8K OFDM scheme having 8K size and 2K OFDM scheme having 2K size according to the size of the FFT symbol.

As described above, the present invention provides quadrature amplitude demodulation means for demodulating the received carrier frequency; Fast Fourier transform means for transforming the demodulated carrier data at high speed into discrete Fourier transform; And a forward error correction decoding means for decoding the Fourier transformed carrier data, comprising: symbol delay means for delaying the carrier data for one symbol period; Correlating means for taking a correlation between the symbol delayed carrier data and current carrier data to obtain a correlation value of symbol period indices input at different sizes; And comparing means for comparing the correlation values of the different symbol periods obtained by the correlation means and providing the result values as control values to the fast Fourier transform means and the forward error correction decoding means.

Accordingly, two 8K OFDM schemes and 2K OFDM schemes may be simultaneously received through one receiver using two different schemes.

Description

Orthogonal Frequency Division Multiplexing Receiver.

The present invention relates to an apparatus for receiving an Orthogonal Frequency Division Multiplexing (OFDM) scheme, and more particularly, to a fast Fourier transform (FFT) in a device using a digital transmission scheme such as a terrestrial high definition television. The present invention relates to an OFDM receiver for enabling simultaneous reception of an 8K OFDM scheme having an 8K size and a 2K OFDM scheme having a 2K size depending on the size of a transformed symbol.

In general, digital television transmission uses a frequency division multiplexing (FDM) transmission scheme, which is a type of multi-carrier modulation scheme.

The frequency division multiplexing (FDM) transmission is a multi-carrier modulation scheme in which data is loaded on several subcarriers in parallel to have a long symbol period while using the same frequency band as that of a single carrier data transmission.

In this case, a frequency division multiplexing (FDM) signal is generated by inverse fast Fourier transform (IFFT) transmission and reception. In this case, each data is carried on a carrier orthogonal to each other and transmitted in parallel.

In other words, the data is transmitted by orthogonal frequency division multiplexing (OFDM).

At this time, the receiver should perform frequency synchronization between the transceivers before performing Fast Fourier Transform (FFT).

In addition, the orthogonal frequency division multiplexing (OFDM) transmission scheme is currently available in terrestrial high-definition television, and has 8K orthogonal frequency division multiplexing (8K) having an 8K size according to the size of the aforementioned fast Fourier transform (FFT) symbol. 2K orthogonal frequency division multiplexing (2K OFDM) has been standardized, and carrier recovery has been developed as a core technology of this transmission.

Also, in recent years, two different 8K OFDM and 2K OFDM receivers are not operated separately according to the size of the symbol. Technology has been developed.

1 is a block diagram showing a conventional orthogonal frequency division multiplexing receiver.

Referring to FIG. 1, a synchronization detector 102 for receiving a synchronization signal from an intermediate frequency signal IFS for a carrier wave received and tuned by a receiver tuner and input through an input terminal 100; Quadrature amplitude demodulator 101 outputs a quadrature amplitude demodulation (Quadrature Ampliture De-Modulation) of the intermediate frequency signal input through the input terminal 100 by the synchronization signal detected by the synchronization detector 102 as a discrete signal ; An analog / digital converter (103) for sampling the discrete signals demodulated by the quadrature amplitude demodulator (101) into digital data according to the synchronization signal of the synchronization detector (102); A fast Fourier transform unit 104 for extracting sampled discrete data by performing discrete Fourier transform on the sampled data at high speed according to the synchronization signal of the synchronization detector 102; And a forward error for correcting the carrier data format converted and inputted by the fast Fourier transform unit 104 based on the surplus information to output errors in a packet unit through the output terminal 106 in order to correct an error caused by interference between adjacent channels. It consists of a correction decoding unit 105.

In the above description, the forward error correction decoding unit 105 is an inner de-interleave 105a distributed to an irregular error to correct a cluster error from carrier data input from the fast Fourier transform unit 104. ); An internal decoding unit 105b that inner-decodes the carrier data distributed by the details insertion unit 105a and corrects an error; An inverse band inserting unit 105c which sequentially takes the carrier data decoded by the internal decoding unit 105b by a predetermined number of bits and combines the data into one data; An outer decoding unit 105d that outer-decodes the carrier data combined by the inverse region insertion unit 105c and corrects an error due to interference between channels; And an inverse random extracting section 105e for restoring the carrier data decoded by the outer decoding section 105d to the original data and outputting the packet data PD through the output terminal 106.

As described above, in the conventional orthogonal frequency division multiplexing receiving apparatus configured, when the intermediate frequency signal for the carrier is input through the input terminal 100 after being tuned in the receiver tuner, the synchronization detecting unit 102 synchronizes from the input intermediate frequency signal. The signal is detected and input to the quadrature amplitude demodulator 101 and the analog / digital converter 103 and the fast Fourier transform 104 which will be described later.

The quadrature amplitude demodulator 101 amplitude-modulates and outputs a quadrature modulated intermediate frequency signal inputted through the input terminal 100.

The intermediate frequency signal for the quadrature amplitude demodulated carrier is digitized by the analog / digital converter 103 in accordance with the synchronization signal of the synchronization detector 102 and input to the fast Fourier transformer 104.

The fast Fourier transform unit 104 extracts sampled discrete data by performing fast Fourier transform on the input carrier data according to the synchronization signal of the synchronization detector 102.

Discrete Fourier transformed data through the fast Fourier transform unit 104 is corrected by the error generated by interference between adjacent channels in the forward error correction decoding unit 105 is output terminal 106 as the original packet data (PD) Is output via

That is, the forward error correction decoding unit 105 is known as a history insertion unit 105a, an internal decoding unit 105b, an inverse region insertion unit 105c, an outer decoding unit 105d, and an inverse random extraction unit 105e. ) Is included.

Accordingly, the details insertion unit 105a is distributed to an irregular error to be provided to the internal decoding unit 105b in order to correct the clustering error from the sampled discrete data inputted by the discrete Fourier transform.

The internal decoding unit 105b decodes the data distributed by the detail insertion unit 105a to correct an error, and the inverse extrapolation unit 105c sequentially takes the decoded data by a predetermined number of bits and then transmits one data. It is combined to provide to the outer decoding unit 105d.

The outer decoding unit 105d decodes the data input through the inverse band inserting unit 105c to correct an error due to interference between channels, and the corrected decoded data is originally obtained through the inverse random extracting unit 105e. The data is recovered to the data of the packet and output through the output terminal 106 as packet data PD.

However, in the apparatus for receiving the conventional orthogonal frequency division multiplexing scheme, as is well known, 8K OFDM and 2K OFDM schemes having different sizes are received according to the size of a fast Fourier transform symbol. In order to simultaneously accommodate both schemes, there is an economic problem that a separate receiver for receiving 2K OFDM and 8K OFDM schemes should be provided.

Accordingly, in view of the problems of the prior art orthogonal frequency division multiplexing receiver, the present invention provides a fast discrete Fourier transform in a device using a digital transmission scheme such as a terrestrial high definition television. SUMMARY OF THE INVENTION An object of the present invention is to provide an orthogonal frequency division multiplexing receiver for enabling simultaneous reception of two different OFDM schemes according to the size of a (FFT) symbol.

In another aspect of the present invention, an object of the present invention is to determine before receiving the first start of a data frame to be processed first to determine which of two different orthogonal frequency division multiplexing methods is received.

1 is a block diagram showing a conventional orthogonal frequency division multiplexing receiver;

Figure 2 is an embodiment block diagram showing an orthogonal frequency division multiplexing receiver according to the present invention.

3A illustrates a data frame structure of an orthogonal frequency division multiplexing scheme.

3B illustrates a pilot carrier included in a data frame format in an orthogonal frequency division multiplexing scheme.

* Explanation of symbols on the main parts of the drawings *

201: Quadrature amplitude demodulator 202: Synchronous detector

203: analog-to-digital converter 204: symbol delay unit

205: correlation unit 206: comparison unit

207: fast Fourier transform unit 208: forward error correction decoder

Orthogonal frequency division multiplexing receiving apparatus according to an aspect of the present invention for achieving the above object, orthogonal amplitude demodulation means for orthogonal amplitude demodulation of the received carrier frequency; Fast Fourier transform means for performing discrete Fourier transform on the demodulated and sampled carrier data at high speed; And forward error correction decoding means for correcting and decoding errors generated between channels from the Fourier transformed carrier data, comprising: symbol delay means for delaying the sampled carrier data for one symbol period; Correlation means for taking a correlation between the symbol-delayed carrier data and the currently received sampled carrier data to obtain correlation values of symbol period indices input at different sizes; And comparing means for comparing the correlation values of the different symbol periods obtained by the correlation means and providing the result values as control values to the fast Fourier transform means and the forward error correction decoding means.

In the orthogonal frequency division multiplexing receiver according to the present invention, it is preferable that the correlation means take correlation of the data frame including the guard interval in the carrier data frame to obtain correlation values of different symbol periods.

In the orthogonal frequency division multiplexing receiver according to the present invention, the comparing means selects one having a larger value from the correlation value of the 8K symbol period index and the correlation value of the 2K symbol period index obtained by the correlation means. desirable.

In the orthogonal frequency division multiplexing receiver according to the present invention, the comparison means comprises 8K fast Fourier transform means and forward error correction decoding means, respectively, according to the correlation value of the 8K symbol period index and the correlation value of the 2K symbol period index. It is desirable to generate a control value for determining whether to drive at 2K or at 2K.

As a result, it can be seen that two different OFDM schemes can be simultaneously received by taking the correlation between the received carrier data and the previous one symbol delayed carrier data and determining and selecting the largest correlation value.

Therefore, in a device using a digital transmission method such as a terrestrial high-definition television, the 8K OFDM method having an 8K size and the 2K OFDM method having a 2K size can be simultaneously received through one receiver according to the size of a fast discrete Fourier transform. There is a possible advantage.

And, there may be a plurality of embodiments of the present invention, hereinafter will be described in detail for the preferred embodiment. Through this preferred embodiment, it is possible to better understand the objects, features and advantages of the present invention.

Hereinafter, exemplary embodiments of an OFDM transmission method receiver according to the present invention will be described in detail with reference to the accompanying drawings.

2 is an embodiment block diagram showing an orthogonal frequency division multiplexing receiver according to the present invention.

According to the present embodiment, a synchronization detection unit 202 for receiving a synchronization signal from an intermediate frequency signal (IFS) for a carrier wave received by the receiver tuner and input through the input terminal 200; A quadrature amplitude demodulation unit 201 of a digital demodulation method for performing quadrature amplitude demodulation of the intermediate frequency signal input through the input terminal 200 as a discrete signal based on the synchronization signal detected by the synchronization detection unit 202; An analog / digital converter (203) for sampling the discrete signals demodulated by the quadrature amplitude demodulator (201) into digital data according to the synchronization signal of the synchronization detector (202); A symbol delay unit 204 for delaying and outputting the sampled carrier data obtained by the analog / digital converter 203 by one symbol; 8K OFDM symbol period index input having different magnitudes by taking correlation between symbol data delayed by the symbol delay unit 204 and current sampled carrier data input through the analog / digital converter 203; A correlator 205 for obtaining correlation values 8Xk and 2Xk of 2K OFDM symbol period indices; And a comparison unit 206 for comparing the correlation values 8Xk and 2Xk of the different symbol periods obtained by the correlation unit 205, selecting one having a larger value, and outputting the selected index. A fast Fourier transform unit 207 which receives the index obtained by the comparison unit 206 as a control value and extracts sampled discrete data by performing fast Fourier transform in accordance with the OFDM scheme; And a forward error correction decoding unit 208 which reconstructs the corresponding carrier data converted and input by the fast Fourier transform unit 207 according to the OFDM scheme according to the index input from the comparison unit 206.

3A illustrates a data frame structure in an orthogonal frequency division multiplexing scheme, and FIG. 3B illustrates a pilot carrier provided in a data frame format in an orthogonal frequency division multiplexing scheme.

Hereinafter, with reference to the accompanying Figures 2 and 3 will be described a preferred embodiment according to the present invention through the following.

First, the difference between the 8K OFDM scheme and the 2K OFDM scheme is that only the symbol size of the discrete Fourier transform in the fast Fourier transform unit 104 of FIG. 1 differs from the detail inserter 105a of the forward error correction decoder 105. Has a structure.

Therefore, if the difference is appropriate, 8K OFDM and 2K OFDM can be simultaneously received.

In addition, the structure of a data frame transmitted by the OFDM scheme includes a reference symbol and data as shown in FIG. 3A.

In addition, the carrier is a file included in the data frame as shown in Figure 3b

In Fig. 3B, the symbol "o" indicates valid data (number of symbols), the symbol "o" is a scattering pilot signal included in the data format, and the symbol "o" is a continuous pilot signal, and the symbol "o" is displayed. Denotes a signal in which a scattered pilot signal and a continuous pilot signal are superimposed, and "-"

As is well known, in order to simultaneously receive two 8K OFDM and 2K OFDM schemes, it is first to determine which OFDM scheme, which is determined prior to hitting the first start of a data frame to be processed as shown in FIG. 3A.

2, when the intermediate frequency signal IFS is input to the carrier from the input terminal 200, the synchronization detector 202 detects the synchronization signal from the input intermediate frequency signal to form a quadrature amplitude. Input to demodulator 201.

The quadrature amplitude demodulator 201 demodulates and outputs an intermediate frequency signal inputted by quadrature amplitude modulation through the input terminal 200.

The intermediate frequency signal of the demodulated carrier is digitized by the analog / digital converter 203 in accordance with the synchronization signal of the synchronization detector 202 and input to the correlation unit 205 and the symbol delay unit 204. .

The symbol delay unit 204 delays data having different periods as shown in FIG. 3A input from the analog / digital converter 203 for one symbol to provide the correlation unit 205.

The correlation unit 205 takes a correlation between the carrier data delayed for one symbol period by the symbol delay unit 204 and the current carrier data input from the analog / digital converter 203, and has different magnitudes according to the correlation. The correlation value (8Xk) at the input 8K OFDM symbol period (8K) index and the correlation value (2Xk) at the 2K OFDM symbol period (2K) index are obtained and provided to the comparator 206 such as a differential amplifier. .

In other words, the data input from the analog / digital converter 203 has a different symbol period. As is well known, it is 896 μs in the 8K OFDM scheme and 224 μs in the 2K OFDM scheme.

Therefore, the frame synchronization can be obtained by taking the correlation of the data frame including the guard interval in the data frame from the correlator 205 and determining the largest correlation value. Since the 8K and 2K systems have different symbol periods, the correlation values with signals separated by different symbol periods must also be considered.

Therefore, by selecting a symbol period that has a large correlation, it is determined whether the 8K OFDM scheme or the 2K OFDM scheme is used. It is provided to a comparator 206 such as an amplifier.

Accordingly, the comparison unit 206 compares the correlation value (8Xk) in the 8K OFDM symbol period index input from the correlation unit 205 and the correlation value (2Xk) in the 2K OFDM symbol period index to have a large value. Page is selected, and the selected value index is provided as a control value to the detail inserter of the fast Fourier transform 207 and the forward error correction decoder 208, respectively, to determine whether to drive at 8K or 2K. Given.

The fast Fourier transform unit 207 performs Fourier transform according to a control value selected by the comparator 206, that is, an index, in an 8K or 2K manner, and provides a detail insertion unit of the forward error correction decoder 208. In this case, the forward error correction decoding unit 208 corrects an error from carrier data received according to the 8K OFDM scheme or the 2K OFDM scheme according to the control value input from the comparator 206 to restore the original data. do.

As described above, in the embodiment of the present invention, the correlation between the received current carrier data and the previous one symbol delayed carrier data is taken to determine a value having the largest correlation to select different 8K or 2K symbol periods. Two different 8K OFDM and 2K OFDM schemes can be simultaneously received through one receiver.

In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the present invention may be variously modified and implemented by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments should fall within the appended claims of the present invention.

The present invention is based on the difference between the 8K OFDM method having 8K size and the 2K OFDM method having 2K size according to the size of the fast discrete Fourier transform in the device using a digital transmission method such as terrestrial high-definition television. Since it can receive simultaneously through one receiver, there is an effect that can improve the compatibility and economical operability.

Claims (4)

Quadrature amplitude demodulation means for orthogonal amplitude demodulation of the received carrier frequency; Fast Fourier transform means for performing discrete Fourier transform on the demodulated and sampled carrier data at high speed; And forward error correction decoding means for correcting and decoding an error generated between channels from the Fourier transformed carrier data. Symbol delay means for delaying the sampled carrier data for one symbol period; Correlation means for taking a correlation between the symbol-delayed carrier data and the currently received sampled carrier data to obtain correlation values of symbol period indices input at different sizes; And And a comparison means for comparing correlation values of different symbol periods obtained by the correlation means and providing them to the fast Fourier transform means and the forward error correction decoding means as control values. The method of claim 1, And the correlation means takes the correlation of the data frame including the guard interval in the data frame to obtain correlation values of different symbol periods. The method of claim 1, And the comparing means selects one having a larger value from a correlation value of an 8K symbol period index and a correlation value of a 2K symbol period index obtained by the correlation means. The method of claim 3, wherein The comparison means sets a control value for determining whether to drive the fast Fourier transform means and the forward error correction decoding means at 8K or 2K according to the correlation value of the 8K symbol period index and the correlation value of the 2K symbol period, respectively. Orthogonal frequency division multiplexing receiver characterized in that for generating.

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