JP2003218967A - Timing synchronization method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a timing synchronization method capable of enhancing accuracy of timing synchronization. <P>SOLUTION: This method comprises the steps of: obtaining a correlation value between a plurality of synchronization symbols set by a maximum amplitude of a multi-value QAM signal and a predetermined reference symbol for timing synchronization; obtaining a temporary synchronization timing point on the basis of the obtained correlation value; obtaining a variance of a standard value of each synchronization symbol in the temporary synchronization timing point and a variance of a standard value of each synchronization symbol in a plurality of timing points deviated from the temporary synchronization timing point; and obtaining the synchronization timing point from the timing point corresponding to the least variance among a plurality of the obtained variance sets. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital radio receiver, in which a frame contains a synchronization symbol (synchronization word).
The present invention relates to a timing synchronization detection method for inserting symbols to achieve timing synchronization of symbols.

[0002]

2. Description of the Related Art The following is one of the techniques for timing synchronization by receiving a digital modulation signal having a frame structure having a plurality of synchronization symbols at the head. In the case of the 16QAM system, this is shown as a synchronization symbol in FIG.
Symbols SW1 to SW10 set on the maximum amplitude envelope of the constellation diagram shown in FIG. 3 are inserted at the beginning of the frame in the order shown in FIG.
These symbols are held in the receiver in advance as reference symbols for timing synchronization, and the cross-correlation (complex correlation) between the 10 reference symbols for timing synchronization and the 10 received synchronization symbols is calculated, and the correlation This is a method of timing synchronization based on the timing point indicating the peak value.

[0003]

However, the point where there is no intersymbol interference in ordinary PSK and QAM using the roll-off filter is only the midpoint of the symbol, so the timing point must be accurately determined. . In such a system, the correlation of the signal oversampled with respect to the symbol rate (normally about 16 times oversampled during A / D conversion) shows a gentle peak waveform as shown in FIG. Therefore, when noise is included, it is difficult to determine the exact timing point of the peak, and the characteristics are deteriorated.

An object of the present invention is to obtain the timing synchronization detection accuracy by obtaining a timing point at which the variance of a plurality of synchronization symbols is minimized at sampling points which are further shifted after the timing synchronization is tentatively obtained by correlation. It is to improve.

[0005]

The invention according to claim 1 receives a frame including a plurality of synchronization symbols set at the maximum amplitude value of a multilevel QAM signal, and converts the frame into a digital signal by oversampling. In a timing synchronization method for detecting a synchronization timing point from the digitized synchronization symbol, a correlation value between the digitized synchronization symbols and preset timing synchronization reference symbols is obtained and obtained. Obtaining a specific sampling point from the correlation value as a provisional synchronization timing point, the dispersion of the standard value of each synchronization symbol at the provisional synchronization timing point, and the synchronization symbol of each of a plurality of sampling points deviated back and forth from the provisional timing point. The variance of the standard value is calculated, and the variance showing the smallest variance among the obtained variances. And a timing synchronization method characterized by the pulling point and the synchronization timing point.

According to a second aspect of the present invention, in the first aspect of the invention, the standard value is a value obtained by normalizing the synchronization symbols into a predetermined quadrant of the signal point arrangement. The characteristic timing synchronization method was adopted.

The invention according to claim 3 is the invention according to claim 1 or 2.
In the invention according to above, the provisional synchronization timing point is
The timing synchronization method is characterized in that the correlation value among a plurality of sampling points corresponding to a plurality of correlation values exceeding a predetermined threshold is the sampling point showing the maximum peak.

According to a fourth aspect of the present invention, there is provided the timing synchronization method according to the first, second or third aspect, further comprising means for correcting the frequency error of the synchronization symbol based on the correlation value. did.

The invention according to claim 5 relates to claims 1, 2 and
In the invention of 3 or 4, the timing synchronization method is characterized in that the correlation value is obtained by using a predetermined number of sampling points selected from all sampling values of the synchronization symbol.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION In this embodiment, a complex correlation between 10 received synchronization symbols and 10 timing reference symbols in a receiver is obtained, and sampling points at which the absolute value of the correlation shows a peak are determined. First, it is obtained as the provisional synchronization timing point. Then, the frequency error of the synchronization symbol at the provisional synchronization timing point is obtained, and frequency correction and phase synchronization are performed. Then, the synchronization symbol is standardized to a specific quadrant from the positions of the 10 synchronization symbols at the provisional timing point and the signal point arrangement.

For example, the synchronization symbol S shown in FIGS.
Since W1 has I = 3 and Q = 3, the I and Q components (not exactly I = 3 and Q = 3) of the synchronization symbol SW1 received at the provisional synchronization timing point are each divided by 3. , I = Q = 1 to the first quadrant. Since the sync symbol SW2 has I = 3 and Q = -3, it is similarly divided by 3 and -3, respectively, and similarly standardized to the quadrant.
Hereinafter, if SW3 to SW10 are similarly standardized, these standardized 10 symbols SW1 to SW10 are I
= Q = 1 are dispersed and gathered in the first quadrant to which they belong.

Therefore, the standardized 10 synchronizations
The variance of the symbols SW1 to SW10 is calculated. Ci as standard
The in-phase component, Cq is the normalized quadrature component,
The normalized results of SW1 to SW10 are Ci (1) and Cq (1),
Ci (2) and Cq (2), ..., Ci (10) and C
If q (10), then the variance S is S = 1 / N ・ Σ_{x = 1} ^N(Ci (x)-* ci)²+ (Cq (x)-* cq)
² Can be found at. However, * ci is Ci (1) to Ci (1
The average of 0) and * cq are the average of Cq (1) to Cq (10). Also
In this embodiment, the number of synchronization symbols is 10.
Therefore, N = 10.

In the same manner, ten sync symbols SW1 to SW10 are standardized for each sampling point shifted by several sampling points before and after the sampling point which is the temporary synchronization timing point, and its variance is obtained. . Among the variances of the plurality of sampling points thus obtained, the sampling point corresponding to the variance having the smallest value is determined as the final synchronization timing.

At this time, the frequency error is obtained based on the correlation at the temporary synchronization timing point.
The effect can be ignored in the short sync symbols from 1 to SW10. For the data symbols after the synchronization symbol in the frame, the frequency error is recalculated based on the finally determined synchronization timing point, and frequency correction and phase correction are performed. Alternatively, the pilot symbols are inserted at appropriate intervals, and the phase is corrected at that time to deal with the problem.

When obtaining the peak value for obtaining the provisional synchronization timing point in the correlation calculation, the peak value may be obtained by obtaining the correlation using sampling points that are appropriately thinned out. For example, in the case of 16 oversampling, when the correlation is obtained by using every other sampling data, the correlation output is reduced to 1/2 of the data in FIG. By doing so, the calculation time and the hardware scale for obtaining the provisional synchronization timing point can be simplified.

FIG. 1 is a block diagram of a demodulation circuit according to one embodiment of the present invention. Reference numerals 1 and 2 are multipliers, and when a received signal is input thereto, a baseband signal is extracted by quadrature demodulation (quasi-coherent detection) that is multiplied with a local frequency signal oscillated by the local oscillator 3. Since the multiplier 1 multiplies the local frequency, the baseband signal of the in-phase component is output therefrom, and the multiplier 2 multiplies the local frequency by 90 degrees by the phase shifter 4, so that the baseband of the quadrature component is output therefrom. The signal is output. Reference numerals 5 and 6 are low-pass filters that remove high-frequency components from these in-phase component and quadrature-component baseband signals. An A / D converter for converting into a digital signal, and 9 is a memory in which digitized sampling data of the in-phase component and the quadrature component is written.

Reference numeral 10 is a complex correlator, which is a reference symbol for timing synchronization input from the reference synchronization signal source 11 (see FIG. 3).
(The same as the synchronization symbols SW1 to SW10) and the reception synchronization symbol are multiplied to calculate the complex correlation. 12 calculates the absolute value from the obtained in-phase component and quadrature component of the correlation value and also determines whether or not the threshold value set by the threshold value setting unit 13 is exceeded. Reference numeral 14 denotes a provisional timing generator that determines a peak value from a plurality of correlation absolute values equal to or greater than a threshold value input from the absolute value conversion circuit 12 and generates a provisional synchronization timing point.

Reference numeral 15 is a frequency error detector for detecting the frequency error of the received signal from the in-phase component and the quadrature component of the correlation value obtained from the complex correlator 10, and 16 and 17 are the frequency errors obtained by the frequency error detector 15. It is a multiplier that performs frequency correction and phase correction of the quadrature component and the in-phase component of the baseband signal based on. Reference numeral 18 denotes an identification circuit, which inputs the quadrature component and the in-phase component whose frequency and phase have been corrected,
It identifies which of the 16 positions of the signal point arrangement shown in FIG. 2 the received symbol corresponds to.

Reference numeral 19 denotes a variance minimum value detector, which is a multiplier 1
From the received symbols output from 6 and 17, and the identification result of the identification circuit 18, the received symbol is standardized in a specific quadrant, and the variance is calculated for the standardized 10 symbols,
The minimum value of the obtained plurality of variances is detected. Reference numeral 20 is a decoder for converting the received symbol into 4-bit data from the position of the signal point arrangement obtained by the discrimination circuit 18.

Reference numeral 21 denotes a control unit, which is a signal A indicating that the absolute value has exceeded the threshold value in the absolute value conversion circuit 12, a signal B in which the temporary timing is detected by peak detection in the temporary timing generation circuit 14, and a variance minimum value detection. The signal C or the like in which the detector 19 has detected the minimum variance is fetched, and the address control signal a of the memory 9, the control signal b of the frequency error detector 15, the control signal c of the minimum variance detector 19 and the control signal d of the discrimination circuit 18 are taken. And so on.

When the in-phase component and the quadrature component of the received symbol are written in the memory 9, the complex correlation operation in the complex correlator 10, the absolute value conversion and the threshold value in the absolute value conversion circuit 12 are performed on the in-phase component and the quadrature component. Compare with. Then, when the obtained absolute value does not exceed the threshold value, it is considered that the synchronization symbol has not been received yet, and the writing to the memory 9 is sequentially updated.

When the correlation absolute value exceeds the threshold value by repeating the above operation each time the memory 9 is updated, it is assumed that the synchronization symbol to be received has arrived, and the peak value of the correlation absolute values of the symbols received thereafter is shown. The provisional timing generation circuit 14 determines the provisional synchronization timing point from the sampling points. The frequency error detector 15 detects the frequency error of the synchronization symbol based on the provisional synchronization timing point thus obtained. Next, the ten sync symbols corresponding to the provisional sync timing point are read again from the memory 9, and the frequency error correction and the phase error correction are performed in the multipliers 16 and 17 based on the detected frequency error. Then, the discrimination circuit 18 discriminates the 10 synchronization symbols that have been subjected to the frequency error correction and the phase error correction, and the discrimination result and the received symbol are taken into the variance minimum value detector 19 to standardize the 10 synchronization symbols. And distributed calculation.

Next, for each of a plurality of sampling points deviated from the position of the provisional synchronization timing point in the front-rear direction, 10 synchronization symbols are read from the memory 9, and the multipliers 16 and 17 perform the frequency error correction and the phase correction. Done,
Similar to the above, the discrimination is performed by the discrimination circuit 18, and the variance minimum value detector 19 calculates the variance. When the variance showing the minimum value is obtained from the obtained plurality of variances, the sampling point corresponding to this is finally determined as the optimum synchronization timing point.

After that, the symbol at the synchronization timing point of this final decision is read out and the normal processing is performed.

[0025]

As described above, according to the present invention, the sampling timing corresponding to the minimum variance of the variances of the standard values of the synchronization symbols at the provisional synchronization timing point and the sampling points before and after the provisional synchronization timing point is synchronized with the synchronization timing. Since it is determined as a point, the accuracy of timing synchronization performed by receiving the oversampled synchronization symbol is significantly improved,
The error rate characteristic is improved.

[Brief description of drawings]

FIG. 1 is a block diagram of a demodulation circuit according to an embodiment of the present invention.

FIG. 2 is a 16QAM signal point arrangement diagram.

FIG. 3 is an explanatory diagram of a synchronization symbol inserted at the beginning of a frame.

FIG. 4 is a correlation output characteristic diagram of 16QAM synchronization symbols (16 oversampling).

[Explanation of symbols]

1, 2: Multiplier, 3: Local oscillator, 4: 90 degree phase shifter, 5, 6: Low pass filter, 7, 8: A / D converter, 9: Memory, 10: Correlator, 11: Reference synchronization Signal source, 12: absolute value conversion circuit, 13: threshold value setting device, 14: provisional timing generator, 15: frequency error detector, 16,
17: multiplier, 18: identification circuit, 19: minimum variance detector, 20: decoder, 21: controller.

Claims (5)

[Claims] 1. A frame including a plurality of synchronization symbols set at the maximum amplitude value of a multilevel QAM signal is received, the frame is converted into a digital signal by oversampling, and the synchronization timing point is converted from the digitized synchronization symbol. In the timing synchronization method for detecting, the correlation value between the plurality of digitized synchronization symbols and a plurality of preset reference symbols for timing synchronization is determined, and a specific sampling point is determined from the obtained correlation value as a provisional synchronization timing point. And the variance of the standard value of each sync symbol at the provisional sync timing point and the variance of the standard value of each sync symbol at a plurality of sampling points deviated from the provisional timing point before and after Use the sampling point that shows the smallest variance among the variances as the synchronization timing point. Timing synchronization method characterized by. 2. The standard value according to claim 1, wherein each synchronization symbol has a predetermined value of 1 in a signal point constellation.
A timing synchronization method characterized in that the values are obtained by standardization collected in one quadrant. 3. The sampling point according to claim 1 or 2, wherein the provisional synchronization timing point is a sampling point at which a correlation value among a plurality of sampling points corresponding to a plurality of correlation values exceeding a predetermined threshold has a maximum peak. A timing synchronization method characterized by: 4. The timing synchronization method according to claim 1, further comprising means for correcting a frequency error of the synchronization symbol based on the correlation value. 5. The timing synchronization according to claim 1, 2, 3 or 4, wherein the correlation value is obtained using a predetermined number of sampling points selected from all sampling values of the synchronization symbol. Method.