KR20110077316A - Fast synchonizing method of ofdm digital broadcasting system - Google Patents

Abstract

PURPOSE: A fast synchronization, a digital broadcasting system and an OFDM method thereof are provided to performing a frame synchronization and an integer frequency error after symbol synchronization. CONSTITUTION: An OFDM symbol synchronization and a fraction time frequency error estimation operate. A FFT(Fast Fourier Transform) operates. A correlation diagram, an existing tone on the pilot location of a receive symbol with all possible integrals and of an OFDM symbol pilot and possible are obtained among one of the OFDM signal frame at all symbols(S40g). An index of an integral frequency error that has a maximum correlation diagram and the index of a pertinent symbol estimate respectively a frame synchronization and an integral error(S40l).

Description

Fast synchonizing method of OFDM digital broadcasting system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fast synchronization method of an OFDM digital broadcasting system. In particular, in decoding an OFDM digital broadcasting signal, an integer multiple frequency error and a frame synchronization are simultaneously performed after OFDM symbol synchronization. The present invention relates to a fast synchronization method of an OFDM type digital broadcasting system capable of shortening the transmission delay by the time required.

Unlike analog broadcasting system, digital broadcasting system has many advantages such as providing various additional data services as well as providing better image quality and sound quality. In such a digital broadcasting system, an OFDM scheme, which is a multi-carrier system, is adopted. Orthogonal Frequency Division Multiplexing (OFDM) is an orthogonal frequency division modulation scheme that multiplexes a high-speed transmission signal into a plurality of orthogonal narrowband carriers. Say.

On the other hand, such an OFDM signal is composed of a frame unit, each frame is composed of a plurality of symbols, each symbol is composed of a plurality of samples again. Furthermore, the first symbol of each frame contains a pilot signal known in advance.

1 is a flowchart illustrating a problem of a conventional synchronization method of an OFDM digital broadcasting system. As shown in FIG. 1, in a receiver of a conventional OFDM digital broadcasting system, OFDM symbol synchronization, cyclic prefix removal (CP), fast fourier transform (FFT), integer frequency error estimation, and frame synchronization are used to demodulate an OFDM signal. In addition, wireless channel estimation and compensation, channel demuxing and control channel, service information channel, and data channel decoding process are performed.

As described above, in the OFDM digital broadcasting system, when decoding a broadcast signal, the OFDM symbol and frame synchronization, that is, the starting point thereof, must be accurately found, but the transmission delay caused by operating the buffer in decoding the signal is set aside. Even so, it takes a lot of time to find the synchronization of the broadcast signal. Depending on the scheme, a transmission delay of up to six seconds may occur. In addition, the transmission delay in the synchronization process is mainly generated in the above-described OFDM symbol synchronization, integer frequency error estimation and frame synchronization.

However, in the conventional OFDM digital broadcasting system, since the integer frequency error estimation is performed first and then frame synchronization is performed, that is, a separate process, the transmission delay is increased by adding the time required to perform each process. There was a problem that occurred.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problem, and in decoding an OFDM type digital broadcast signal, the integer frequency error and the frame synchronization are simultaneously performed after the OFDM symbol synchronization. It is an object of the present invention to provide a fast synchronization method of an OFDM digital broadcasting system so as to reduce a transmission delay.

In accordance with another aspect of the present invention, a fast synchronization method of an OFDM digital broadcasting system is performed during OFDM demodulation of a broadcast signal received in an OFDM digital broadcasting system. (A) performing frequency error estimation; (B) performing an FFT, and (c) simultaneously performing frame synchronization and integer frequency error estimation.

In the above-described configuration, the step (c) is a two-dimensional operation of obtaining the correlation between the pilot of the OFDM symbol in all symbols of one frame of the OFDM signal and the tone present at the pilot position of the received symbol having all possible integer frequency errors. After arranging, the index of the integer frequency error having the maximum correlation and the index of the symbol are estimated by the integer frequency error and frame synchronization, respectively.

In addition, when the maximum correlation does not meet the integer frequency error and the reference value for estimating frame synchronization, the correlation between the previously obtained correlation after obtaining the correlation and re-initializing the symbol index for the next frame until the reference value is exceeded It is preferable to repeat the accumulation.

According to the present invention, according to the fast synchronization method of an OFDM digital broadcasting system, an integer multiple frequency error is estimated by simultaneously performing an integer frequency error and a frame synchronization after OFDM symbol synchronization in decoding an OFDM digital signal. By reducing the time required for at least one frame, it is possible to reduce user's discomfort and provide a higher quality broadcasting service.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail with respect to a preferred embodiment of a fast synchronization method of an OFDM digital broadcasting system.

2 is a flowchart illustrating a fast synchronization method of an OFDM digital broadcasting system according to the present invention. As shown in FIG. 2, in performing OFDM demodulation by receiving OFDM digital broadcasting, OFDM symbol synchronization is first performed in step S10. Such OFDM symbol synchronization is a cyclic protection interval during signal transmission. CP) and the front part of the OFDM symbol are made through cross-correlation calculation using the same feature. Usually, the point where the correlation is maximized by accumulating for more than a few dozen symbols rather than one or two symbols becomes the start point of the OFDM symbol.

Next, since the OFDM scheme is a multicarrier scheme, it is very sensitive to timing synchronization and frequency synchronization, and a frequency error inevitably occurs due to the difference between the oscillators of the transmitter and receiver of the broadcast signal. This frequency error can be divided into integer multiple error and prime multiple error. In the case where the frequency error is 2.3, for example, the integer frequency error becomes 2 and the prime frequency error becomes 0.3. Similarly, if the frequency error is 1.8, for example, the integral frequency error is 2 and the prime frequency error is -0.2. That is, the prime frequency error is given as a value between -0.5 and 0.5. Here, the frequency error (e _f ) is a normalized frequency error (and therefore unitless), which is the actual frequency error Δf as an interval between subcarriers (tones) Δf _t as shown in Equation 1 below. Can be obtained by dividing.

On the other hand, in estimating the frequency error, the prime frequency error is estimated first, and the prime frequency error is performed together with the OFDM symbol synchronization.

 2, in step S20, a cyclic protection interval (CP), which is an overlapping portion of the digital broadcast signal of the OFDM scheme, is removed, and in step S30, an FFT (FFT) converting the time domain signal into a frequency domain signal by Fourier transform Fast Fourier Transform).

Next, in step S40, the integer frequency error estimation and the frame synchronization are performed at the same time. In general, the integer frequency error is estimated through the phase change of the pilot at a fixed position. At this time, an integer multiple frequency error, that is, an integer multiple frequency error of the tone interval is estimated through observation for several symbols for correct signal detection. In more detail, in the OFDM type digital broadcast signal, a pilot position is generally changed for each OFDM symbol. In an OFDM digital broadcasting system having such a feature, a correlation between a pilot inserted in a frequency domain and a pilot position of a received FFT signal for several symbols is calculated by calculating a correlation between a pilot of the first symbol of every frame and every received symbol. The integer frequency error is estimated based on the correlation of the symbols. Since the pilot position is usually repeated in the frame half, the integer frequency error is estimated by observing for a minimum number of times the number of symbols per frame.

Next, in steps S50 and S60, wireless channel estimation and compensation are performed to estimate and compensate for distortion of a channel generated during signal amplification or transmission, and in step S70, each channel included in the signal, for example, a control channel. By decompressing the service information channel and the data channel, it is possible to finally decode the image data and the audio data.

FIG. 3 is a flowchart illustrating a process of performing integer frequency error estimation and frame synchronization in FIG. 2. First, in step S40a, the first symbol of the frame is received, and again in steps S40b and 40c, it is assumed that there is no integer frequency error n (n = 0), and the tone existing at the pilot position of the pilot and the received symbol of the OFDM symbol Obtain the correlation with and store it in a two-dimensional array as shown in Equation 2 below.

Next, in steps S40d and 40e, the integer frequency error n is increased by one while the pilot positions of the corresponding OFDM symbols and the pilot positions of the received symbols +1, +2,... , Correlation with tones existing at + max is continuously obtained and stored as 2D array. In step S40d, it is determined whether the integer multiple frequency error n for which the current correlation is to be calculated is greater than the positive maximum integer multiple frequency error max. If it is small, the process returns to step S40c, whereas in the large case, the steps S40f and S40g are large. After assuming that the current integer frequency error (n) is -1, the correlation between the pilot of the first OFDM symbol of the frame and the tone present at pilot position-1 of the received symbol is calculated and stored in a two-dimensional array. .

Next, in steps S40h and S40g, the pilot frequency of the first OFDM symbol of the frame and the pilot positions-2, -3, ... of the received symbol are reduced by decreasing the integer frequency error n by one. , Correlation with tones in -max is obtained continuously and stored in 2D array. In step S40i, it is determined whether the integer multiple frequency error n for which the current correlation is to be calculated is smaller than the maximum negative integer frequency error max. If large, the process returns to step S40g, whereas if small, the process proceeds to step S40j. It is determined whether all correlation calculations to the last OFDM symbol are completed.

As a result of the determination in step S40j, when the correlation calculation to the last OFDM symbol is not completed, the process proceeds to step S40k after receiving the next OFDM symbol and repeats steps S40c or less, whereas when it is completed, step S40l. The OFDM symbol having the maximum correlation and the integer frequency error are estimated by the start synchronization of the frame and the corresponding integer frequency error, respectively.

Here, it can be known in advance by the specification of the maximum integer frequency error oscillator, for example, if the tone interval is 100 kHz (1 integer frequency error = 100 kHz) and the maximum possible frequency error is 300 kHz Max = 3 And -Max = -3. In this case, for each symbol in the two-dimensional array, that is, the number of correlation calculations in one dimension is seven times, that is, a total of seven up to 0, +1, +2, +3, -1, -2, and -3. It is time.

As above, the above steps are performed (-Max ~ + Max) times for every symbol reception and stored in a two-dimensional array. In this case, the number of OFDM symbols to be observed should be an integer multiple of the number of symbols per frame for frame synchronization. If the maximum correlation is less than the integer frequency error and the reference value for the frame synchronization, the correlation is obtained by re-initializing the symbol index for the next frame. It is desirable to add to the cumulative accumulation.

4 is a graph illustrating a fast synchronization method of an OFDM digital broadcasting system according to the present invention. The maximum possible integer frequency error max (X axis) is 13 and the number of OFDM symbols per frame (Y axis) is shown in FIG. Is 15, it is a graph comparing the correlation (Z-axis) of the calculated two-dimensional array in order to estimate the integral frequency error and perform frame synchronization simultaneously.

In the example of FIG. 4, the one-dimensional value of the maximum correlation is when -4 in the frequency domain, which means that there is an integer multiple frequency error of -4 times. In addition, the two-dimensional value of the maximum correlation is when the OFDM symbol index is 5, which means that the fifth received OFDM symbol is the start symbol of the frame.

As such, when all of the steps of FIG. 3 are performed during the OFDM symbol to be observed, the position of the maximum correlation is found in the stored two-dimensional array, and the one-dimensional index at the position of the found maximum correlation is corresponding integer multiple frequency error. It can be estimated that the two-dimensional index is the position of the start symbol of the frame.

The present invention of the present invention is not limited to the embodiment described above, and the fast synchronization method of the digital broadcasting system of the OFDM method can be modified in various ways within the scope of the technical idea of the present invention.

1 is a flowchart illustrating a problem of a conventional synchronization method of an OFDM digital broadcasting system;

2 is a flowchart illustrating a fast synchronization method of an OFDM digital broadcasting system according to the present invention;

3 is a flowchart illustrating a process of performing integer frequency estimation and frame synchronization in FIG. 2;

4 is a graph for explaining a fast synchronization method of an OFDM digital broadcasting system according to the present invention.

Claims (4)

In the process of OFDM demodulating a broadcast signal received in an OFDM digital broadcasting system, (A) performing OFDM symbol synchronization and fractional frequency error estimation; (B) performing an FFT and And (c) performing simultaneous integer frequency error estimation and frame synchronization at the same time. The method of claim 1, In the step (c), the correlation between the pilot of the OFDM symbol and the tone existing at the pilot position of the received symbol having all possible integer frequency errors in all symbols of one frame of the OFDM signal is obtained and then correlated two-dimensionally. A method of fast synchronization in an OFDM digital broadcasting system, characterized by estimating an index of an integer multiple frequency error and an index of a corresponding symbol with integer multiple frequency error and frame synchronization, respectively. The method of claim 2, If the maximum correlation does not meet the integer frequency error and the reference value for estimating the frame synchronization, the symbol index is reinitialized for the next frame until the reference value is exceeded, and the correlation is calculated and accumulated. A fast synchronization method of an OFDM digital broadcasting system, characterized in that it is repeated. A computer-readable recording medium having a program for executing any one of claims 1 to 3.

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