KR20060003670A - Method and apparatus for auto-reporting a result of self-test - Google Patents

Abstract

Disclosed are a frame and symbol time synchronization detection apparatus and a detection method. According to the present invention, by obtaining a correlation value of a phase reference symbol of a frame of an orthogonal frequency division multiplex (OFDM) modulated digital signal, a starting point of a frame in a time domain before performing a fast Fourier transform (FFT) Symbol timing compensation (STR). In addition, the size of the hardware can be remarkably reduced by obtaining the correlation value by obtaining only the sign of the phase reference symbol, and thus a device for detecting frame synchronization and symbol timing synchronization with low power can be implemented.

OFDM, frame synchronization, phase reference symbol, PRS, symbol timing compensation, STR

Description

Frame and symbol time synchronization detection apparatus and detection method {Method and apparatus for auto-reporting a result of self-test}

1 is a diagram showing the structure of a digital data frame of the COFDM method;

2 is a block diagram of a frame and symbol time synchronization detection device of the present invention;

3 is a view showing the output of the correlation filter unit according to the present invention, and

4 is a flowchart provided to explain the operation of the frame and symbol time synchronization detection apparatus according to the present invention.

      The present invention relates to a digital receiving system, and more particularly, a frame and a symbol for detecting synchronization of a digital broadcast data frame and an orthogonal frequency division multiple symbol received in an orthogonal frequency division multiplex (OFDM) scheme. A time synchronization detection device and a detection method.

Currently, terrestrial digital radio broadcasting systems are available in European, American, and Japanese styles, all using OFDM. EUREKA-147, a European DAB (Digital Audio Broadcasting) method, uses digitally modulated COFDM (Coded OFDM) for robust multipath fading in terrestrial waves. Digital Multimedia Broadcasting (DMB), a Korean digital multimedia broadcasting service, is also based on European DAB and provides CD (Compact Disk) level sound quality, various data services, and excellent mobile reception quality.

1 is a diagram showing the structure of a digital data frame of the COFDM method. Referring to FIG. 1, there are 76 OFDM symbols after a null symbol a, and the first OFDM symbol is a phase reference symbol (PRS) b. There are valid data symbols c after the phase reference symbol b. The null symbol (a) section and the phase reference symbol (b) form a synchronization channel of the frame. Each symbol has a signal (e) of an OFDM subcarrier in the time domain, followed by a guard interval (GI) d. A portion of the time domain OFDM signal e is inserted in the guard period d to cope with ghost disturbances generated on the channel.

The phase reference symbol (b) is known data from both the transmitting side and the receiving side, and provides a phase reference for differential modulation of the next OFDM symbol. It is also used to detect time synchronization of frames and symbols.

Conventionally, a technique that is widely used as a synchronization detection algorithm of OFDM has a structure using the correlation between the guard period and a structure using the unit response of the channel.

Although the symbol time synchronization algorithm using the guard interval d has a simple structure, the stability varies greatly depending on the characteristics of the channel. In fact, the stability is good in Gaussian channel, but in channel with multipath characteristics such as Rayleigh channel and lysian channel, synchronization error is more than one symbol and not stable.

The structure using the unit response of the channel is more stable than the structure using the guard interval (d), but consumes a lot of power in the actual implementation, which is not suitable for developing a synchronous detection algorithm for low power. This is because low power is another concern in DAB or DMB that is highly mobile.

Accordingly, an object of the present invention is to provide a frame and symbol time synchronization detecting device and a detection method having excellent stability according to low power and channel characteristics in detecting time synchronization of a frame and a symbol using a phase reference symbol (PRS). .

In order to achieve the above object, a frame and symbol time synchronization detection apparatus for a digital signal modulated by an orthogonal frequency division multiplex (OFDM) method of a frame structure including a phase reference symbol according to the present invention is a predetermined time. A correlation filter unit for obtaining a correlation value between a local phase reference symbol, which is a phase reference symbol of a region, and the received signal, and a maximum value detection unit for detecting a position of the highest value of an output of the correlation filter unit;

And a frame synchronizing unit for finding a starting point of the received frame from the position of the highest value and a symbol timing synchronizing unit for synchronizing symbol timing of the received frame from the position of the highest value.

Preferably, the apparatus further includes a frequency error compensator for compensating for the frequency error by removing the frequency component that changes with time from the received signal and outputting the frequency error to the correlation filter.

Preferably, the frequency error compensation unit, a delay unit for delaying the received signal for one sampling time, a conjugate complex unit for obtaining a conjugate complex value of the delayed signal and a value obtained by multiplying the conjugate complex value and the received signal It includes a first multiplier for outputting.

Preferably, the correlation filter unit comprises: a local phase reference symbol unit for obtaining a conjugate complex value of the local phase reference symbol, a second multiplier and a multiplier for multiplying an output signal of the frequency error compensation unit and a conjugate complex value of the local phase reference symbol unit; And an integral part for accumulating and adding the result of the multiplier for a predetermined time.

Preferably, the local phase reference symbol unit obtains a conjugate complex value for half of the valid data of the local phase reference symbol, and the integrator calculates the result of the multiplier for a half of the effective data of the local phase reference symbol. Accumulate and add.

Preferably, the first code unit for obtaining the positive and negative signs of the received signal and

The size of the hardware for obtaining the correlation value is further reduced by further including a second coder for obtaining the positive and negative signs of the output of the local phase reference symbol unit.

Preferably, the first coder and the second coder output 1 if the obtained code value is positive and 0 for negative.

In addition, the frame and symbol time synchronization detection method of a digital signal modulated by an Orthogonal Frequency Division Multiplex (OFDM) method of a frame structure including a phase reference symbol according to the present invention, a phase reference symbol of a predetermined time domain Obtaining a correlation value between an internal phase reference symbol and the received signal, detecting a position of the highest value of the output of the correlation filter unit, finding a starting point of the received frame from the position of the highest value, and Matching symbol timing synchronization of the received frame from the position of the highest value.

Advantageously, the step of obtaining a correlation value further comprises compensating for a frequency error by removing a frequency component that changes over time in the received signal.

Preferably, the step of making the direct current comprises: calculating a conjugate complex value of the signal delaying the received signal for one sampling time, and outputting a value obtained by multiplying the conjugate complex value by the received signal. Include.

Preferably, the calculating of the correlation value comprises: calculating a conjugate complex value of the local phase reference symbol, multiplying the output signal of the outputting step by a conjugate complex value of the local phase reference symbol, and for a predetermined time period. Accumulating and adding the result of the multiplication.

Preferably, the step of obtaining the conjugate complex value obtains a conjugate complex value for half of the valid data of the local phase reference symbol.

Preferably, the adding step accumulates and adds the result of the multiplying step for half of the valid data of the local phase reference symbol.

Preferably, the multiplying step obtains and multiplies the sign value of the conjugate complex value of the local phase reference symbol with the output of the outputting step.

Hereinafter, the present invention will be described in detail with reference to the drawings.

2 is a block diagram of a frame and symbol time synchronization detection device of the present invention.

The detection apparatus 200 of the present invention is provided in a DAB / DMB (Digital Audio Broadcasting / Digital Multimedia Broadcasting) receiver and receives digital broadcast data modulated in an Orthogonal Frequency Division Multiplex (OFDM) scheme to synchronize the frame. Compensate for errors in Frame Synchronization and Symbol Timing Recovery (STR).

The detection apparatus 200 of the present invention operates in the time domain before the fast Fourier transform (FFT), thereby correcting the fast Fourier transform located at the rear end of the detection apparatus 200 of the present invention with accurate frame synchronization and fast Fourier transform. Let's do it with a starting point.

Referring to FIG. 1, the signal input to the detection apparatus 200 according to the present invention is a signal modulated by an orthogonal frequency division multiplexing scheme of a frame structure including a phase reference symbol (b), and an analog-to-digital converter (ADC). Through digital converter (not shown), it is sampled by a certain unit of time and converted into digital data. The complex digital data is input to the detection apparatus 200 by being divided into a real number and an imaginary number through an in-phase / quadature-phase (I / Q) unit (not shown).

Preferably, the type of digital data frame received has the frame structure shown in FIG. When the received digital data is the transmission mode 1 (Tx 1: Transmission mode 1) of the DAB, the guard interval d consists of 504 samples and the valid data part e consists of 2048 samples. The following description is made in the Tx 1 mode.

Referring to FIG. 2, the detection apparatus 200 of the present invention includes a frequency error compensator 210, a correlation filter 230, a maximum value detector 250, a frame synchronizer 270, and a symbol timing synchronizer 290. ).

The frequency error compensator 210 compensates for a carrier frequency error included in the digital signal input to the correlation filter 230. The frequency error included in the digital signal prevents the correlation value from the correlation filter 230.

The frequency error compensator 210 includes a delay unit 211, a conjugate complex unit 213, and a first multiplier 215.

The delay unit 211 sequentially delays the received OFDM modulated digital signal by one sample. This value is transferred to the conjugate complex portion 213.

The conjugate complex unit 213 obtains a conjugate complex value of the digital signal divided into a real number and an imaginary number received from the delay unit 211.

The first multiplier 215 multiplies the delayed signal output from the conjugate complex unit 213 with the received digital signal without delay. This signal is input to the correlation filter unit 230. As a result of the first multiplier 215, the frequency component that changes with time disappears.

The correlation filter unit 230 includes a local phase reference symbol unit 233, a second multiplier 237, an integration unit 239, a first code unit 231, and a second code unit 235. A correlation value between a phase reference symbol (PRS) of a digital signal frame and a 'local phase reference symbol', which is a phase reference symbol already known and stored in the correlation filter unit 230, is obtained.

The correlation filter 230 multiplies the conjugate reference value of the phase reference symbol of the received frame by the local phase reference symbol of the time domain to obtain a correlation value by accumulating for a predetermined time.

The first coder 231 obtains the sign (positive or negative) of the sample value of the frame data input to the correlation filter unit 230 and outputs it to the second multiplier 237. By doing so, only one bit can be used without using a plurality of bits to use the value of the actual data to obtain the correlation value.

The local phase reference symbol unit 233 obtains a conjugate complex value of the local phase reference symbol in the time domain composed of real and imaginary numbers. Therefore, the local phase reference symbol unit 233 converts the local phase reference symbol in the frequency domain into an inverse fast fourier transform (IFFT), and then obtains a conjugate complex value. The local phase reference symbol unit 233 obtains a conjugate complex value of the sample value of the valid data portion (n = 2048) or half (n = 1024) of the local phase reference symbol.

The second coder 235 obtains a sign (positive or negative) of the conjugate complex value output from the local phase reference symbol unit 233 and outputs the sign to the second multiplier 237.

The first coder 231 and the second coder 235 may respectively output 1 and 0 when the sign of each sample is positive and negative.

The second multiplier 237 multiplies the value output from the first coder 231 by the value output from the second coder 235 and outputs the multiplier 239 to the integrator 239. The second multiplier 237 sequentially multiplies the valid data portion of the phase reference symbol or half of the valid data portions.

The second multiplier 237 multiplies the quantity (1) and the quantity (1) by 1 when the first and second codes output values of 1 and 0, respectively, for positive and negative signs. If you multiply (1) by negative (0), you can output 0, and multiply by negative (0) and negative (0).

The integrator 239 sequentially adds values output from the second multiplier 237 for a predetermined time to obtain a correlation value. Preferably, the cumulative addition is performed for one valid data period (n = 2048), or the cumulative addition for half (n = 1024).

The correlation filter unit 230 may obtain a correlation value for the valid data section (2048 samples) of each phase reference symbol. Preferably, the correlation filter 230 may obtain a correlation value for the half section (1024 samples) of the valid data. Even by this, accurate frame synchronization and symbol timing synchronization can be obtained.

The correlation filter 230 may obtain a correlation value by multiplying an actual sample value without the first coder 231 and the second coder 235. However, the hardware size of the second multiplier 237 and the integrator 239 increases.

Preferably, the correlation filter 230 multiplies and accumulates only the symbols of the phase reference symbol and the local phase reference symbol received through the first and second coders 231 and 235 to obtain a correlation value. Can be. Accordingly, the size of the hardware for representing 1024 or 2048 samples of the phase reference symbol can be reduced to the size representing the sign, and thus the hardware size of the second multiplier 237 can be reduced.

The maximum value detector 250 obtains the position of the maximum value of the correlation value output from the correlation filter 230.

3 is a diagram illustrating an output of the correlation filter unit 230 according to the present invention. Referring to Fig. 3, it is shown that the highest value f of the correlation values appears at half of the valid data. The highest value detector 250 outputs the position of the highest value f to the frame synchronizer 270 and the symbol timing synchronizer 290.

The frame synchronizer 270 finds a frame start point through the position of the highest value of the correlation value detected by the highest value detector 250. The information is transmitted to a fast Fourier transform unit (not shown) located at the rear end of the detection apparatus 200 of the present invention.

The symbol timing synchronization unit 290 performs symbol timing compensation (STR) for obtaining an accurate starting point of the fast Fourier transform based on the highest position of the correlation value detected by the highest value detection unit 250. The output of the symbol timing synchronization unit 290 is transmitted to a fast Fourier transform unit (not shown) located at the rear end of the detection apparatus 200 of the present invention.

4 is a flowchart provided to explain the operation of the frame and symbol time synchronization detection apparatus according to the present invention.

When receiving the OFDM modulated digital signal (S401), the detection apparatus 200 compensates for a carrier frequency error that may be included in the first received signal. To this end, the delay unit 211 of the frequency error compensator 210 delays the received signal by one sample, and calculates a conjugate complex value of the delayed signal through the conjugate complex unit 213. The digital signal received through the first multiplier 215 and the delayed signal output from the conjugate complex unit 213 are multiplied and output to the correlation filter unit 230 (S403).

The correlation filter 230 obtains a correlation value between the input signal and the local phase reference symbol. First, the sign of each sample value of the signal input from the first coder 231 to the correlation filter 230 is detected. The local phase reference symbol unit 233 obtains the conjugate complex value of half (n = 1024) of the effective data portion of the local phase reference symbol, and the second code unit 235 obtains only the 1024 samples of the conjugate complex value. Output The signals output from the first coder 231 and the second coder 235 are multiplied by the second multiplier 237 and accumulatively added by half an interval (n = 1024) of valid data in the integrator 239. Obtain the correlation value (S405)

The maximum value detector 250 obtains the position of the highest value among the correlation values obtained by the correlation filter 230 (S407). From this position, the frame synchronization unit 270 finds the starting point of the frame, and the symbol timing synchronization unit 290 finds the exact starting point of the fast Fourier transform (S409).

As such, the operation of the frame and symbol time synchronization detection apparatus according to the present invention is performed by the process.

As described above, according to the present invention, the fast Fourier transform can be stably performed with accurate frame synchronization in the time domain and the starting point of the Fast Fourier transform before the fast Fourier transform (FFT). By performing the process of obtaining the correlation value for only half of the valid data or only by performing the sign thereof, the size of the hardware can be significantly reduced, and thus a device for detecting frame synchronization and symbol timing synchronization with low power can be implemented.

In addition, while the above has been shown and described with respect to preferred embodiments of the present invention, the present invention is not limited to the specific embodiments described above, the technology to which the invention belongs without departing from the spirit of the invention claimed in the claims Various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (14)

An apparatus for detecting frame and symbol time synchronization of a digital signal modulated by an orthogonal frequency division multiplex method of a frame structure including a phase reference symbol, A correlation filter unit obtaining a correlation value between a local phase reference symbol, which is a phase reference symbol in a preset time domain, and the received signal; A highest value detection unit for detecting a position of the highest value of the output of the correlation filter unit; A frame synchronization unit for finding a starting point of the received frame from the position of the highest value; And And a symbol timing synchronizing unit for synchronizing the symbol timing of the received frame from the position of the maximum value. The method of claim 1, And a frequency error compensator for compensating for a frequency error by removing a frequency component that changes with time from the received signal and outputting the frequency error to the correlation filter. The method of claim 2, The frequency error compensation unit, A delay unit delaying the received signal for one sampling time; A conjugate complex unit for calculating a conjugate complex value of the delayed signal; And And a first multiplier outputting a value obtained by multiplying the conjugate complex value by the received signal. The method of claim 2, The correlation filter unit, A local phase reference symbol unit for obtaining a conjugate complex value of the local phase reference symbol; A second multiplier multiplying the output signal of the frequency error compensation unit by the conjugate complex value of the local phase reference symbol unit; And And an integral part accumulating and adding the result of the multiplier for a preset time. The method of claim 4, wherein The local phase reference symbol unit obtains a conjugate complex value of half of the valid data of the local phase reference symbol, And the integrating unit accumulates and adds the result of the multiplier to half of the valid data of the local phase reference symbol. The method according to claim 4 or 5, A first coder which obtains a positive and negative sign of the output signal of the frequency error compensator and outputs it to a second multiplier; And And a second coder for obtaining a positive and negative sign of the output of the local phase reference symbol unit and outputting the negative code to a second multiplier. The method of claim 6, And the first coder and the second coder output 1 when the obtained code value is positive and 0 when the obtained code value is positive. In the frame and symbol time synchronization detection method of a digital signal modulated by an Orthogonal Frequency Division Multiplex method of a frame structure including a phase reference symbol, Obtaining a correlation value between a local phase reference symbol, which is a phase reference symbol in a preset time domain, and the received signal; Detecting a position of the highest value of the correlation value; Finding a starting point of the received frame from the position of the highest value; And And aligning symbol timing synchronization of the received frame from the position of the highest value. The method of claim 8, Obtaining the correlation value, Compensating for the frequency error by removing a frequency component that changes over time in the received signal. Frame and symbol time synchronization detection method further comprising. The method of claim 9, The step of making a direct current, Calculating a conjugate complex value of the signal delaying the received signal for one sampling time; And And outputting a value obtained by multiplying the conjugate complex value by the received signal. The method of claim 9, Obtaining the correlation value, Obtaining a conjugate complex value of the local phase reference symbol; Multiplying the output signal of the outputting step by a conjugate complex value of the local phase reference symbol; And And accumulating and adding the multiplied result for a preset time period. The method of claim 11, The calculating of the conjugate complex value comprises obtaining a conjugate complex value for half of the valid data of the local phase reference symbol. The method of claim 12, And the adding step comprises accumulating and adding the result of the multiplying step for half of the valid data of the local phase reference symbol. The method according to claim 11, wherein In the multiplying step, the output of the outputting step is obtained by multiplying a sign value of a conjugate complex value of the local phase reference symbol.

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