KR101130659B1 - apparatus and method for synchronizing OFDM signal - Google Patents

Abstract

The present invention relates to an OFDM signal synchronization apparatus and method for compensating for an error in an FFT window and a sampling frequency in synchronizing an OFDM signal received from an external source.

In addition, the OFDM signal synchronization apparatus of the present invention performs sampling on an Orthogonal Frequency Division Multiplexing (OFDM) signal received from the outside, and includes the sampled copy section and the data section using a fast fourier transform (FFT) window. An OFDM signal synchronization device that removes the copy period from an OFDM signal and performs an FFT on the OFDM signal from which the copy period is removed, wherein the channel estimation is performed on the OFDM signal converted from the time domain to the frequency domain by the FFT. A channel estimator; An impulse response calculator for calculating an impulse response of the channel estimation value obtained by the channel estimator; An FFT window adjuster for adjusting the position of the FFT window by using an impulse response calculated by the impulse response calculator; And a sampling frequency corrector configured to correct the sampling frequency by using an impulse response calculated by the impulse response calculator.

OFDM, sync, sampling, FFT, window, channel estimation, pilot, autocorrelation

Description

Apparatus and method for synchronizing OFDM signal

The present invention relates to an OFDM signal synchronization apparatus and method, and more particularly, to an OFDM signal synchronization apparatus and method for compensating for an error in an FFT window and a sampling frequency in synchronizing an OFDM signal received from the outside.

Orthogonal Frequency Division Mutiplexing (OFDM) is a type of multicarrier modulation that provides excellent performance in multi-path and mobile reception environments. For this reason, attention has been paid to modulation methods suitable for terrestrial digital TV and digital voice broadcasting.

Although OFDM has been mainly studied in the communication field, research and development has been conducted in the broadcasting field as it is adopted as a modulation method of the digital voice broadcasting system proposed by the European Broadcasting Union (EBU).

The performance of an OFDM system, which is a multicarrier system, is sensitive to time and frequency synchronization. The OFDM transmission scheme has a disadvantage in that the signal-to-noise ratio (SNR) is greatly reduced because the orthogonality between the subcarriers of the received signal is lost in the frequency spectrum when there is a carrier frequency offset between the transmitter and the receiver compared to the single carrier transmission scheme. In general, frequency error occurs due to oscillator differences between the transmitter and receiver.

In a packet communication system such as a wireless LAN (IEEE 802.11a), a preamble for initial synchronization is transmitted before transmitting a certain length of data. The preamble is used for symbol synchronization, frequency synchronization, and channel estimation. However, an OFDM broadcasting system such as a digital audio broadcasting system (DAB) or a digital multimedia broadcasting system (DMB) does not have a preamble for initial synchronization, and generally performs system synchronization and channel estimation using a pilot inserted in the middle of data. . In an OFDM broadcasting system in which data is continuously transmitted, frequency error caused by an oscillator of a transmitter and a receiver causes a sampling error, and when it accumulates, a sample is added or dropped and an FFT window pointer is changed. This FFT window change causes Inter Symbol Interference (ISI) and Inter Carrier Interference (ICI) in an OFDM system, resulting in performance degradation.

The digital OFDM receiver performs sampling at a rated periodic interval determined by a sampling frequency in the input continuous OFDM signal. The sampled signal is processed into a digital signal such as a demodulation process through the fast fourier transform (FFT). In such an OFDM receiver, a function of finding an optimal sampling timing or an equalization function of removing distortion components generated by a signal due to sampling frequency error plays an important role.

In general, the sampling frequency error measurement and correction method can be divided into IF (Intermediate Frequency) direct sampling method and baseband conversion method according to the frequency downconversion method of the received signal. It can be divided into structures.

The IF direct sampling method extracts the sample signal directly from the IF received signal, and the baseband conversion method can be classified into two sample structures according to the sampling timing control structure. That is, the synchronous structure estimates the sampling timing error using the PLL to control the timing of the corresponding oscillator. The asynchronous structure performs the free sampling, so the equalizer located at the rear end does not control the sampling timing error without controlling the sampling timing. Compensate for signal distortion caused by

1 is a structural diagram of a sampling frequency control method of a general synchronization structure.

As shown in FIG. 1, a conventional OFDM signal synchronization apparatus is a synchronization structure for estimating a sampling offset using phase rotation of a continuous pilot subcarrier or a distributed pilot subcarrier complex signal among signals output from the FFT 20. The estimated phase offset is used to directly control a voltage control oscillator (VCXO) 50 with a digital phase locked loop (DPLL).

In detail, the conventional OFDM signal synchronization apparatus includes an ADC 10 that performs sampling on an orthogonal frequency division multiplexing (OFDM) signal received from the outside, and an OFDM signal including the sampled copy interval and the data interval using an FFT window. The pilot section 30, which extracts the pilot interval from the signal output from the FFT (20), the signal output from the FFT (20) to remove the copy interval, and converts the OFDM signal from which the copy interval is removed to the frequency domain DPLL 40 for calculating the sampling frequency error using the pilot extracted from the unit 30 and VCXO 50 for correcting the sampling frequency of the ADC 10 using the error value calculated in the DPLL 40. It is done by

2 is a flowchart illustrating a conventional sampling frequency correction method, and FIG. 3 is a frequency spectrum of an OFDM signal passing through an FFT.

First, in step S10, pilots existing at regular intervals different for each standard of the OFDM broadcasting system are extracted.

Next, in step S13, the position and phase change P _m of the pilot present at the negative frequency are calculated.

Next, in step S15, the position and phase change P _p of the pilot present at the positive frequency are calculated.

Next, in step S17, P _m and P _p are observed and accumulated for several symbols to obtain an average value.

 Next, in step S19, the sampling frequency error is calculated using the average value. Then, the sampling frequency of the OFDM signal is corrected using the calculated error value.

This conventional sampling frequency correction method uses a phase shift difference between pilots as described above, and has excellent performance in an additive white gaussian noise (AWGN) channel.

However, since the change in the phase of the pilot has to be observed, there is a problem that the residual frequency error is large and the performance is degraded due to a large phase error in fading and multipath environments due to movement. Also, arctangent is typically used to calculate the position and phase change of the pilot, which is quite complicated to implement.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides an OFDM signal synchronization apparatus and method for stably correcting sampling frequency error of an OFDM signal in an environment that generates fading and frequency error due to multipath, movement, and the like. For the purpose of providing it.

In addition, an object of the present invention is to provide an OFDM signal synchronization apparatus and method having a lower complexity than the conventional method of calculating the position and phase change of the pilot and calculating the sampling frequency error using the same.

In order to achieve the above object, the OFDM signal synchronization apparatus of the present invention performs sampling on an orthogonal frequency division multiplexing (OFDM) signal received from the outside, and uses the sampled copy interval using a fast fourier transform (FFT) window. An OFDM signal synchronization device that removes the copy section from an OFDM signal including a data section and performs an FFT on the OFDM signal from which the copy section is removed, wherein the OFDM signal is converted from a time domain to a frequency domain by the FFT. A channel estimator for performing channel estimation on the apparatus; An impulse response calculator for calculating an impulse response of the channel estimation value obtained by the channel estimator; An FFT window adjustment unit that adjusts the position of the FFT window by using an impulse response calculated by the impulse response calculator; And a sampling frequency corrector configured to correct the sampling frequency by using an impulse response calculated by the impulse response calculator.

Conventionally, the phase shift difference between the pilots is observed and through this, the error of the sampling frequency is corrected. This conventional method exhibits excellent performance in an AWGN environment. However, in an environment where fading and frequency errors due to multipath, movement, and so on, phase performance is large and performance is poor.

According to the present invention, when the impulse response of the channel estimation value is obtained, the position of the FFT window and the number of multipaths can be known, and thus the position of the FFT window is adjusted or the sampling frequency is corrected. And stable performance even in an environment that generates frequency errors.

In general, an OFDM communication system performs initial synchronization through a preamble (consisting of several OFDM symbols commonly known to a transmitter and a receiver), but a broadcast system continuously transmits data without a preamble. For this reason, a broadcast system will be worse than a communication system in an environment that generates multipath, fading due to movement, and frequency error. Therefore, the OFDM signal synchronization device of the present invention is preferably applied to a broadcast system.

The impulse response calculator according to the present invention preferably calculates an impulse response of the channel estimate by performing an FFT or an inverse FFT on the channel estimate obtained by the channel estimator. As is well known, FFT or IFFT is an essential component of an OFDM system. In other words, there is no need to add a new algorithm to obtain the impulse response. Thus, the complexity of the system is considerably lower than in the prior art.

In detail, the FFT window adjusting unit according to the present invention determines the position of the first output peak in the impulse response calculated by the impulse response calculation unit, and thus, the starting point of the FFT window is located outside the predetermined FFT window starting section. If it is determined, it is recognized that the FFT window has moved due to a sampling frequency offset or the like. In this case, the FFT window adjusting unit moves the FFT window so that the starting point of the FFT window is located at the start section of the FFT window.

The FFT window start section refers to a section adjacent to the data section among the copy sections, and includes a right section adjacent to the data section, a left section farthest from the data section, and an FFT window target section located between these sections. Are distinguished.

In addition, the FFT window adjusting unit according to the present invention, if the number of peaks in the impulse response calculated by the impulse response calculation unit is more than a predetermined threshold, the FFT window movement or the sampling frequency correction through the positioning of the first peak is OFDM It is determined that signal synchronization cannot be performed stably. In this case, the FFT window adjusting unit resets the position of the FFT window based on the result of autocorrelation of the sampled OFDM signal.

The sampling frequency corrector according to the present invention specifically checks the position of the first output peak in the impulse response calculated by the impulse response calculator, and if it is determined that the starting point of the FFT window is located in the right section, the FFT The sampling frequency was increased so that the start point of the window moved to the FFT window target section and the position of the first peak output from the impulse response calculated by the impulse response calculator was determined. If it is determined that the position is located, it may be to lower the sampling frequency so that the starting point of the FFT window is moved to the FFT window target interval.

In addition, the sampling frequency corrector according to the present invention, if it is determined that the starting point of the FFT window is located in the right section as a result of confirming the position of the first output peak in the impulse response calculated by the impulse response calculation unit, the FFT As a result of checking the position of the first output peak in the impulse response calculated by the impulse response calculator, the sampling frequency is increased in proportion to the time taken for the start point of the window to move from the FFT window target section to the right section. If it is determined that the start point of the FFT window is located in the left section, the sampling frequency may be lowered in proportion to the time taken for the start point of the FFT window to move from the FFT window target section to the left section.

Meanwhile, the OFDM signal synchronization method of the present invention performs sampling on an orthogonal frequency division multiplexing (OFDM) signal received from the outside, and includes the sampled copy section and the data section using a fast fourier transform (FFT) window. In the OFDM signal synchronization method of removing the copy period from the OFDM signal, and performing an FFT on the OFDM signal from which the copy period is removed, channel estimation is performed on the OFDM signal converted from the time domain to the frequency domain by the FFT. (A) performing; (B) calculating an impulse response of a channel estimate value that is the result of the channel estimation; And (c) adjusting the position of the FFT window or correcting the sampling frequency by using the calculated impulse response.

The OFDM signal synchronization method of the present invention can be applied to a broadcast system.

In the OFDM signal synchronization method of the present invention, step (b) may be performed to calculate an impulse response of the channel estimate by performing an FFT or an inverse FFT on the channel estimate that is the result of the channel estimation. have.

The copy section may include an FFT window start section divided into a right section adjacent to the data section, a left section located farthest from the data section, and an FFT window target section located between the sections.

In the OFDM signal synchronization method of the present invention, the step (c) is an example, where the starting point of the FFT window is outside the starting point of the FFT window as a result of checking the position of the first output peak in the calculated impulse response. If it is determined that the position is located, the FFT window is moved so that the start point of the FFT window is located at the start section of the FFT window, and after confirming the position of the first output peak in the calculated impulse response, the start point of the FFT window is determined. If it is determined that it is located in the right section, the sampling frequency is increased to move the starting point of the FFT window to the target section of the FFT window, and the starting point of the FFT window is confirmed as a result of confirming the position of the first output peak in the calculated impulse response. Is determined to be located in the left section, the start of the FFT window It may be to lower the sampling frequency so that a point moves to the FFT window target section.

In the OFDM signal synchronization method of the present invention, the step (c) is another example, where the starting point of the FFT window is outside the starting point of the FFT window as a result of checking the position of the first output peak in the calculated impulse response. If it is determined that the position is located, the FFT window is moved so that the start point of the FFT window is located at the start section of the FFT window, and after confirming the position of the first output peak in the calculated impulse response, the start point of the FFT window is determined. If it is determined that it is located in the right section, the sampling frequency is increased in proportion to the time taken for the start point of the FFT window to move from the FFT window target section to the right section, and the peak of the first output peak is calculated from the calculated impulse response. As a result of checking the position, the starting point of the FFT window is located above the left section. If it is determined that the value is determined, the sampling frequency may be lowered in proportion to the time taken for the start point of the FFT window to move from the FFT window target section to the left section.

In the OFDM signal synchronization method of the present invention, step (c) is another example. If the number of peaks in the calculated impulse response is equal to or greater than a predetermined threshold, the result of autocorrelation of the sampled OFDM signal is obtained. If the position of the FFT window is adjusted based on a value, and the position of the first peak output from the calculated impulse response is determined, and the start point of the FFT window is determined to be outside the start interval of the FFT window, The FFT window is moved so that the start point of the FFT window is located at the start section of the FFT window, and after confirming the position of the first peak output from the calculated impulse response, it is determined that the start point of the FFT window is located at the right section. If so, the starting point of the FFT window moves to the FFT window target section. Increasing the fling frequency and confirming the position of the first output peak in the calculated impulse response, if it is determined that the starting point of the FFT window is located in the left section, the starting point of the FFT window to the target section of the FFT window It may be to lower the sampling frequency to move.

According to the OFDM signal synchronization device and method of the present invention, by adjusting the FFT window using the impulse response of the channel estimate value and correcting the sampling frequency, OFDM signal synchronization even in an environment that generates fading and frequency error due to multipath, movement, and the like. There is an effect that can achieve the stabilization of.

In addition, the calculation of the impulse response can be done using an existing FFT or IFFT block, so there is no need to add a new algorithm. Therefore, the system has the effect that the complexity is considerably lower than the conventional.

Hereinafter, an OFDM signal synchronization apparatus and method according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail.

4 is a block diagram of an apparatus for synchronizing OFDM signals according to an embodiment of the present invention.

As shown in FIG. 4, the OFDM signal synchronization apparatus of the present invention includes an ADC 110, an FFT 120, a pilot extractor 130, a channel estimator 140, an impulse response calculator 150, and an FFT window. The correction unit 160 may include an autocorrelation unit 170 and a sampling frequency correction unit 180.

The ADC 110 performs sampling on an orthogonal frequency division multiplexing (OFDM) signal received from the outside.

The FFT 120 removes a copy section from the sampling signal using the FFT window and converts the OFDM signal from which the copy section is removed to the frequency domain.

5 is a diagram showing the structure of an OFDM symbol in a broadcasting system.

As illustrated in FIG. 5, an OFDM symbol includes a copy period CP and a data integration period (FFT Integration data). Here, the copy interval is a copy of a portion of the adjacent data interval and is used to overcome the inter-symbol interference (ISI) and the inter-carrier interference (ICI). The data interval means an actual data symbol.

The pilot extractor 130 extracts a pilot from the OFDM signal converted into the frequency domain by the FFT 120. Here, the pilot is a promised signal commonly known at the transmitting end and the receiving end, which is planted between data for channel estimation.

The channel estimator 140 performs channel estimation using a pilot. That is, the channel estimator 140 estimates the information (attenuation, phase shift, time delay, etc.) of the radio channel using the pilot. As channel estimation techniques, least square (LS) and minimum mean-square error (MMSE) are known.

The impulse response calculator 150 calculates an impulse response of the channel estimate by performing an FFT or an inverse FFT on the channel estimate obtained by the channel estimator 140. When the impulse response of the channel estimation value is obtained, the position of the FFT window and the number of multipaths can be known.

The FFT window adjuster 160 adjusts the position of the FFT window by using the impulse response calculated by the impulse response calculator 150. In detail, the FFT window adjuster 160 checks the position of the first output peak in the impulse response calculated by the impulse response calculator 150. Here, the first peak represents the starting position of the FFT window. Therefore, when the position of the first peak is confirmed, if it is determined that the starting point of the FFT window is located outside the predetermined FFT window start section (section 3 adjacent to the data section of the copy section; see FIG. 5), Move the FFT window so that the starting point is in the area (3).

In addition, the FFT window adjuster 160 checks the number of peaks in the impulse response calculated by the impulse response calculator 150. Here, the number of peaks represents the number of multipaths. If the number of peaks is greater than or equal to the threshold, it is determined that the OFDM signal synchronization cannot be stably performed due to the FFT window movement through the positioning of the first peak or the sampling frequency correction described later due to the multipath fading. Therefore, if the number of peaks is greater than or equal to the threshold, the FFT window adjusting unit 160 resets (initializes) the position of the FFT window based on the result of autocorrelation of the sampling signal.

6 illustrates timing synchronization of an OFDM signal.

In general, an OFDM signal synchronization apparatus performs timing synchronization by autocorrelating a sampled OFDM signal. As shown in FIG. 6, when the autocorrelation unit 170 performs autocorrelation with respect to the sampled OFDM signal, since the copy section is a copy of the rear part of the adjacent data section, a boundary point between the copy section and the data section is shown. The peak occurs at. When the sampled OFDM signal is auto-correlated, the copy period and the data period can be distinguished.

As described above, in the broadcasting system, the frequency error causes a sampling error, and when this accumulates, a sample is added or dropped, and thus the starting point of the FFT window changes from time to time. Therefore, the above-described FFT window adjustment alone cannot achieve stabilization of OFDM signal synchronization.

The sampling frequency corrector 180, together with the FFT window adjuster 160, is a means for stabilizing OFDM signal synchronization. The sampling frequency corrector 180 corrects the sampling frequency by using the impulse response calculated by the impulse response calculator 150. Specifically, the position of the first output peak in the impulse response calculated by the impulse response calculation unit 150 is checked. As a result of checking the position of the first peak, if it is determined that the starting point of the FFT window is located in the right section c (see FIG. 5), the sampling frequency is increased to move the FFT window starting point to the target section b (see FIG. 5). . On the other hand, if it is determined that the starting point of the FFT window is located in the left section (a; see FIG. 5) as a result of confirming the position of the first peak, the sampling frequency is lowered so that the starting point of the FFT window moves to the target section (b).

In addition, in adjusting the sampling frequency, the sampling frequency correction unit 180 considers the time taken to move from the target section to the right section or the left section. Specifically, when the starting point of the FFT window moves from the target section (b) to the right section (c), the sampling frequency is increased in proportion to the moving time. For example, if the travel time is 10 ms and 5 ms, then the adjusted sampling frequency values would be 5 Hz and 2.5 Hz, respectively. On the contrary, when the starting point of the FFT window moves from the target section (b) to the left section (a), the sampling frequency is lowered in proportion to the moving time.

7A and 7B are flowcharts illustrating an OFDM signal synchronization method according to an embodiment of the present invention, and FIG. 8 is a diagram illustrating a frequency spectrum of an OFDM signal passing through an FFT in the OFDM signal synchronization device according to the present invention. 9 shows an impulse response of a channel estimate value.

First, in step S101, channel estimation is performed on an OFDM signal (see FIG. 8) converted into the frequency domain by the FFT 120.

Next, in step S103, an impulse response of the channel estimate value is calculated by performing FFT or IFFT on the channel estimate value (see FIG. 9).

Next, in step S105, the position and number of peaks are searched for in the impulse response.

Next, in step S107, it is determined whether the number of searched peaks is 20 or more.

As a result of the determination in step S107, if the number of peaks is 20 or more, the flow advances to step S109 to perform autocorrelation on the sampled OFDM signal. Then, the flow advances to step S111 to readjust the FFT window based on the autocorrelation value.

On the other hand, if it is determined in step S107 that the number of peaks is less than 20, the process proceeds to step S113 to determine whether the first peak (FFT window start point) is located in the region (2) (see FIG. 5).

As a result of the determination in step S113, when the first peak is located in the area (2), the flow advances to step S115 to move the FFT window forward.

On the other hand, if the first peak is not located in the area (2) as a result of the determination in step S113, the flow advances to step S117 to determine whether the first peak is located in the area (1) (see FIG. 5).

As a result of the determination in step S117, when the first peak is located in the area (1), the flow advances to step S119 to move the FFT window backward.

On the other hand, as a result of the determination in step S117, if the first peak is not located in the area (1), the process proceeds to step S121 to determine whether the first peak has moved from (b) to (a).

As a result of the determination in step S121, when the first peak has moved from (b) to (a), the flow advances to step S123 to reduce the sampling frequency in proportion to the time taken to move from (b) to (a). Then, the flow advances to step S125 to initialize the counter (t = 0).

On the other hand, as a result of the determination in step S121, if the first peak has not moved from (b) to (a), the flow advances to step S127 to determine whether the first peak has moved from (b) to (c).

As a result of the determination in step S127, if the first peak has moved from (b) to (c), the flow advances to step S129 to increase the sampling frequency in proportion to the time taken to move from (b) to (c). Then, the flow advances to step S131 to initialize the counter (t = 0).

On the other hand, if the first peak is located at (b) as a result of the determination in step S127, the flow advances to step S133 to update the movement period (t ++).

The OFDM signal synchronizing apparatus and method of the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

1 is a structural diagram of a sampling frequency control method of a general synchronization structure.

2 is a flowchart illustrating a conventional sampling frequency correction method.

3 is a frequency spectrum of an OFDM signal passing through an FFT.

4 is a block diagram of an apparatus for synchronizing OFDM signals according to an embodiment of the present invention.

5 is a diagram showing the structure of an OFDM symbol in a broadcasting system.

6 illustrates timing synchronization of an OFDM signal.

7A and 7B are flowcharts illustrating an OFDM signal synchronization method according to an embodiment of the present invention.

8 is a view showing a frequency spectrum of the OFDM signal passing through the FFT in the OFDM signal synchronization device of the present invention.

9 illustrates an impulse response of a channel estimate value.

*** Explanation of symbols for the main parts of the drawing ***

110: ADC 120: FFT

130: pilot extractor 140: channel estimator

150: impulse response calculation unit 160: FFT window correction unit

170: autocorrelation unit 180: sampling frequency correction unit

Claims (15)

Sampling is performed on an Orthogonal Frequency Division Multiplexing (OFDM) signal received from the outside, and removes the copy section from the copy section and the data section of the OFDM signal subjected to the sampling using a fast fourier transform (FFT) window, In the OFDM signal synchronization apparatus for performing FFT on the OFDM signal from which the copy period is removed, A channel estimator for performing channel estimation on the OFDM signal converted from the time domain to the frequency domain by the FFT; An impulse response calculator for calculating an impulse response of the channel estimation value obtained by the channel estimator; An FFT window adjuster for adjusting the position of the FFT window by using an impulse response calculated by the impulse response calculator; And It includes a sampling frequency correction unit for correcting the frequency used to perform the sampling by using the impulse response calculated by the impulse response calculation unit, When the FFT window adjusting unit determines the position of the first peak output from the impulse response calculated by the impulse response calculator, and determines that the start point of the FFT window is outside a predetermined FFT window start section, the FFT window And move the FFT window such that a start point of the FFT window is located at a start interval of the FFT window. The method of claim 1, And the OFDM signal synchronizing device is used in a broadcasting system. The method of claim 1, wherein the impulse response calculation unit, And calculating an impulse response of the channel estimate by performing an FFT or an inverse FFT on the channel estimate obtained by the channel estimator. delete The method of claim 3, wherein the FFT window adjustment unit, If the number of peaks in the impulse response calculated by the impulse response calculation unit is greater than or equal to a predetermined threshold value, the position of the FFT window is adjusted based on a result obtained by autocorrelation of the sampled OFDM signal. OFDM signal synchronization device characterized in that. The method of claim 3, wherein the FFT window start interval, And an interval adjacent to the data interval among the copy intervals. The method of claim 6, wherein the FFT window start section is a right section adjacent to the data section, a left section farthest from the data section, and a left section located farthest from the right section and the data section adjacent to the data section. FFT window target zones located between the zones, The sampling frequency correction unit, When the position of the first output peak is determined from the impulse response calculated by the impulse response calculator, and it is determined that the starting point of the FFT window is located in the right section adjacent to the data section, the starting point of the FFT window is determined by the FFT. Increase the frequency used to perform sampling to move to the window target interval, As a result of checking the position of the first output peak in the impulse response calculated by the impulse response calculator, if it is determined that the starting point of the FFT window is located in the left section farthest from the data section, the starting point of the FFT window is determined. OFDM frequency synchronization device, characterized in that for lowering the frequency used to perform the sampling to move to the FFT window target interval. The method of claim 6, wherein the FFT window start section is a right section adjacent to the data section, a left section farthest from the data section, and a left section located farthest from the right section and the data section adjacent to the data section. FFT window target zones located between the zones, The sampling frequency correction unit, When the position of the first output peak is determined from the impulse response calculated by the impulse response calculator, and it is determined that the starting point of the FFT window is located in the right section adjacent to the data section, the starting point of the FFT window is determined by the FFT. The frequency used for performing sampling is increased in proportion to the time taken to move from the window target section to the right section adjacent to the data section. As a result of checking the position of the first output peak in the impulse response calculated by the impulse response calculator, if it is determined that the starting point of the FFT window is located in the left section farthest from the data section, the starting point of the FFT window is determined. And a frequency used to perform sampling is reduced in proportion to the time taken to move from the FFT window target section to the left section farthest from the data section. Sampling is performed on an Orthogonal Frequency Division Multiplexing (OFDM) signal received from the outside, and removes the copy section from the copy section and the data section of the OFDM signal subjected to the sampling using a fast fourier transform (FFT) window, In the OFDM signal synchronization method for performing an FFT on the OFDM signal from which the copy period is removed, (A) performing channel estimation on the OFDM signal converted from the time domain to the frequency domain by the FFT; (B) calculating an impulse response of a channel estimate value that is the result of the channel estimation; And (C) adjusting a position of the FFT window or correcting a frequency used to perform the sampling using the calculated impulse response, In the step (c), when it is determined that the starting point of the FFT window is located outside the starting section of the FFT window as a result of confirming the position of the first output peak in the calculated impulse response, the starting point of the FFT window is determined. And moving the FFT window to be located at a window start section. The method of claim 9, The OFDM signal synchronization method is used in a broadcast system. The method of claim 9, wherein step (b) comprises: And calculating an impulse response of the channel estimation value by performing an FFT or an inverse FFT on the channel estimation value that is a result of the channel estimation. 10. The method of claim 9, wherein the copy section, the right section adjacent to the data section, the left section farthest from the data section and the right section neighboring the data section and the left section farthest from the data section Including an FFT window start interval separated by an FFT window target interval located between, In step (c), As a result of confirming the position of the first output peak in the calculated impulse response, if it is determined that the starting point of the FFT window is located in the right section adjacent to the data section, the starting point of the FFT window is moved to the FFT window target section. To increase the frequency used for sampling, As a result of checking the position of the first output peak in the calculated impulse response, if it is determined that the starting point of the FFT window is located in the left section farthest from the data section, the starting point of the FFT window is the target section of the FFT window. OFDM frequency synchronization method characterized in that to lower the frequency used to perform the sampling to move to. 10. The method of claim 9, wherein the copy section, the right section adjacent to the data section, the left section farthest from the data section and the right section neighboring the data section and the left section farthest from the data section Including an FFT window start interval separated by an FFT window target interval located between, In step (c), As a result of confirming the position of the first output peak in the calculated impulse response, if it is determined that the starting point of the FFT window is located in the right section adjacent to the data section, the starting point of the FFT window is determined in the FFT window target section. The frequency used to perform sampling is increased in proportion to the time taken to move to the right section adjacent to the data section. As a result of checking the position of the first output peak in the calculated impulse response, if it is determined that the starting point of the FFT window is located in the left section farthest from the data section, the starting point of the FFT window is the target section of the FFT window. OFDM frequency synchronization method characterized in that to reduce the frequency used to perform the sampling in proportion to the time taken to move to the left section located farthest from the data interval. 10. The method of claim 9, wherein the copy section, the right section adjacent to the data section, the left section farthest from the data section and the right section neighboring the data section and the left section farthest from the data section Including an FFT window start interval separated by an FFT window target interval located between, In step (c), If the number of peaks in the calculated impulse response is greater than or equal to a predetermined threshold, the position of the FFT window is adjusted based on a result obtained by autocorrelation the OFDM signal on which the sampling is performed, As a result of confirming the position of the first output peak in the calculated impulse response, if it is determined that the starting point of the FFT window is located in the right section adjacent to the data section, the starting point of the FFT window is moved to the FFT window target section. To increase the frequency used for sampling, As a result of checking the position of the first output peak in the calculated impulse response, if it is determined that the starting point of the FFT window is located in the left section farthest from the data section, the starting point of the FFT window is the target section of the FFT window. OFDM frequency synchronization method characterized in that to lower the frequency used to perform the sampling to move to. A computer-readable medium having recorded thereon a program for executing the method of synchronizing the OFDM signal according to any one of claims 9 to 14.

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