KR960011167B1 - Apparatus for detecting a time-base error - Google Patents

Abstract

The detector for detecting time base errors to be corrected in Laser Disc Players, includes a level comparator producing a "High" signal when a falling region of a horizontal synch signal is detected, a timing controller generating the 1st and the second "High" signal having a ceratin interval and a start signal, a level storage device sampling the 1st and the second level of the horizontal synch signal according to the two "High" signals, an error detector detecting a time base error corresponding to a difference between gradients of the falling region to display it according to the start signal.

Description

Device for detecting time axis error of video signal

1 is a block diagram showing a time axis error correction apparatus of a general video signal.

2 is a waveform diagram showing examples of an image signal having no temporal error.

3 is a waveform diagram showing a standard of a horizontal synchronization signal.

4 is a waveform diagram showing a time axis error detection description using a horizontal synchronization signal.

5 is a waveform diagram showing slopes that may occur in a horizontal synchronization signal.

6 is a waveform diagram showing error detection of a time axis error according to a change in slope of a horizontal synchronization signal.

7 is a graph for explaining the principle of the present invention.

8 is a block diagram showing an apparatus for detecting a time axis error of an image signal of the present invention.

9 is a waveform diagram relating to a timing controller of the apparatus for detecting time axis error of an image signal of the present invention.

* Explanation of symbols for main parts of the drawings

10: level comparator. 20: timing control unit.

30: level storage unit. 31: First latch.

32: second latch. 40: error detection unit.

41: First subtractor. 42: First divider.

43: Second divider. 44: second subtractor.

45: multiplier. 46: an adder.

47: third latch.

The present invention relates to an apparatus for detecting a time axis error of a video signal which accurately detects a magnitude of the time axis error in correcting a time axis error of a disc video signal in a laser disc player (LDP).

In general, when a video signal recorded on a disk is reproduced by an LDP, color blur similar to a color bar occurs due to a time axis error present in the video signal itself, and color is not emitted. Therefore, in order to obtain a clear color screen, the residual time base error should be reduced to 5 nsec or less.

The time axis error in the video signal means that the interval between the horizontal synchronization signals H is less than or equal to 63.56 μsec, as shown in FIG.

As shown in FIG. 1, the time-base error correction apparatus of a general video signal includes an A / D converter 1 for converting an input analog video signal into a digital signal by a sampling clock, and the A / D converter 1 A video signal memory 2 connected to an output of the video signal memory 2 for storing one horizontal main period, and a digital video signal connected to an output of the video signal memory 2 to a predetermined read clock. D / A converter 3 for converting the time-base error is corrected by the analog video signal, and the time-axis error connected to the output of the A / D converter 1 to detect the time-base error contained in the video signal from the digital video signal A time axis error correction filter 5 connected to the output of the detection device 4, the time axis error detection device 4 to remove a time error detected due to instantaneous noise, and an output of the time axis error correction filter 5 Connected and entered It generates a clock that is variable in response to the time-base error value was composed of an A / D converter 1 and the image signal memory 2 and the time-base error detection device a digital controlled oscillator (6) to be applied to (4).

As shown in FIG. 1, the time axis error correction device of the video signal detects the time axis error in the time axis error detection device 4, and the detected time axis error is digitally controlled through the time axis error correction filter 5. In this case, the digital control oscillator 6 generates a slow clock when the input signal is slow and a fast clock when the input signal is slow, and outputs it to the A / D converter 1.

Therefore, the A / D converter 1 operates in response to the time axis error, and the input video signal is also sampled in response to the time axis error, and is sequentially stored in the image signal memory. Read by the clock and output through the D / A converter 3, resulting in an analog video signal in which the time axis error is corrected.

Here, the conventional time axis error detection device detects the time axis error using a horizontal synchronization signal, and FIG. 3 shows the RS-17OA standard published by the EIA (Electronic Industries Association) for the synchronization signal of the NTSC color image signal. The fall zone (α) of the horizontal synchronization signal corresponds to 0 to 64 levels when 256 levels of the entire video signal are sampled, where a section corresponding to 10% to 90% of the falling section is 140nsec ± 0nsec in time. Able to know.

Therefore, as shown in FIG. 4, a time axis error is detected by sampling one point of the horizontal sync signal falling section of the horizontal sync signal after 63.56 μsec based on 32 levels and comparing the levels. .

FIG. 4 shows that the detection level is detected as A 'or B' for the case where the falling section of the next horizontal synchronization signal enters slowly with respect to the reference signal C (A) and when it enters quickly (B). According to the elevation of this level, it was found how much time axis error occurred in which direction.

However, in the conventional time axis error detecting apparatus, as the allowable period of the falling section becomes 140 nsec ± 20 nsec, as shown in the horizontal synchronization signal standard of FIG. 3, the falling slope is equal to e and g for the reference signal f of FIG. It is allowed to vary by $ 20nsec, since the direction and magnitude of the time axis error are detected as the level of the point is large and small based on one point of the falling section of the horizontal synchronization signal, that is, the level of the reference point of the falling section. Since the time-base error is detected using only, there is a problem in that there is a problem that the maximum detection of $ 20nsec even if there is no time-base error.

FIG. 6 shows an example of misdetection of time axis error caused by a change in the slope of the horizontal synchronization signal, and f 'is lower than a falling period g' before one horizontal period. If the timebase error by t is indicated, this is given by (YX) If the time axis error of t is detected, but if it is inclined within the range allowed by the EIA standard, as in the case of e ', if the level value is detected at the point t _0, it is detected as Z level, and the time axis error is detected as (ZX). A larger timebase error than that occurred has been misdetected.

An object of the present invention is to consider the change in the slope of the horizontal synchronization signal of the disk image signal, that is, by calculating the difference between the slope of the falling section and the reference horizontal period falling slope of every horizontal period, and then by detecting the time axis error corresponding to the difference Accordingly, an object of the present invention is to provide a time axis error detecting apparatus for an image signal, which can detect a more accurate time axis error.

Hereinafter, the technical configuration of the present invention in detail.

As shown in FIG. 8, the apparatus for detecting time axis error of an image signal includes a level comparator 10 for receiving a video signal and outputting a high signal when a falling section of the horizontal synchronization signal is detected. The first and second high signals of the first and second high signals and the output start signal having a predetermined interval according to the high signal of the < RTI ID = 0.0 >) < / RTI > The slope of the falling section is applied to the level storage unit 30 for sampling the first and second level values of the horizontal synchronization signal at two time points, and the first and second level values of the level storage unit 30. The technical configuration is characterized by an error detection unit 40 configured to detect and store a time axis error corresponding to a difference and then output the signal according to the output start signal of the timing controller 20.

The level storage section 30 includes a first latch 31 having a first high signal of the timing controller 20 connected to a clock terminal CLK and an image signal of an input terminal, and a first latch of the timing controller 20. The second high signal is composed of a second latch 32 which is connected to the clock terminal CLK and an image signal to the input terminal, respectively.

The error detector 40 receives a first subtractor 41 that receives and subtracts first and second level values of the level storage unit 30, and receives an output of the first subtractor 41. A first divider 42 for dividing the interval by two high signals, a second divider 43 for receiving the output of the first divider 42 and dividing it into a predetermined reference value, and a level storing unit 30 A second subtractor 44 that receives a second level value of and subtracts a predetermined reference level value, and a multiplier 45 that multiplies the output of the second subtractor 44 and the second divider 43; And an adder 46 for adding the output of the multiplier 45 and the predetermined reference level value, and an output start signal of the timing controller 20 to the clock terminal CLK. It consists of the 3rd latch 47 connected.

The apparatus for detecting time axis error of the video signal of the present invention performs time axis error detection in consideration of the falling section period of the horizontal synchronization signal, as shown in FIGS. 7 to 9. In other words. After finding the difference between the slope of the falling section of each horizontal period and the slope of the falling of the horizontal reference period, the size of the spot detecting the time-axis error is adjusted according to the difference, thereby detecting the actual time-base error that eliminates the change of the slope. do.

The principle of this is described in detail with reference to FIG. FIG. 7 shows only the level 6.4, which is 10%, from level 57.6, which is 90% of the falling section, in the horizontal synchronous signal specification of FIG. 3, showing 6.4 as the level 0, and the level 25.6, which is the y-intercept value, corresponds to levels 57.6 and 6.4. The slope is a middle point between the levels, where a represents 90% to 10% of the falling section of the standard shown in Fig. 3 for 140 nsec, i.e. for reference slope, and a 'for 140 + 20 nse. In the case, a shows the case of 140-20 nsec.

The principle of the present invention is that when the slope of the falling section of the horizontal synchronization is not a but has a value other than a (here, a is used as an example), the value for detecting the time axis error is converted into a slope. Detecting the time-base error, in order to explain in more detail the equation including the slope a and the slope a is as follows.

y = ax + 25.6 ‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥ ①

y = ax + 25.6 ‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥ ②

If the level values for any one point t ₀ are L and L, respectively,

L = at ₀ +25.6 ‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥ 3

L = at ₀ +25.6 ‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥ 4

④ Find the expression for t ₀ in the equation and substitute it in ③. The following equation is obtained.

L = a / a (L-25.6) +25.6 ‥‥‥‥‥‥‥‥‥‥‥‥‥‥‥ ⑤

That is, after calculating the level L value of the falling section slope a and the time axis error detection point t ₀ of the input horizontal synchronization signal, and subtracting the case where the slope is a using the equation ⑤, the L value from which the influence of the slope is removed is eliminated. Can be obtained to detect an accurate time axis error.

8 is a configuration diagram for realizing the above principle, and its operation relationship will be described in detail as follows.

When the digital video signal including the time axis error is input to one terminal b of the level comparator 10, the level comparator 10 is connected to the sampling signal SAM of FIG. 9 when the input video signal value is 57.5 level or less. As described above, the high signal is output to the input terminal SAM of the timing controller 20. The reason why the level comparator 10 detects 57.5 levels or less is that when the maximum value of the video signal is quantized to 256 levels, 90% of the falling section of the horizontal synchronization signal corresponds to 57.5 levels.

As such, when the SAM signal is input from the level comparator 10 to the timing controller 20, the timing controller 20 firstly and firstly separates the first and second high signals FIR and SED at predetermined intervals. And the first and second level values at two points in the falling section of the horizontal synchronization signal are applied to the clock terminal CLK of the second latch 32. The clock input to the timing controller 20 uses a frequency four times the frequency of the burst signal of the video signal.

Here, the horizontal synchronization signals stored in the first and second latches 31 and 32 are inputted to the first subtractor 41 to obtain a difference, and are then sent to the first divider 42 to obtain the first and second high signals. The interval value is divided by 70 μsec, which is one cycle of CLK in FIG. In this way, the slope of the falling section of the input horizontal sync signal is obtained, which corresponds to the slope a in the equation (5).

In addition, a, which is an output of the first divider 42, is input to the second divider 43, is calculated with a predetermined reference value, that is, a falling slope of the reference horizontal period, and a / a is executed. Is input to multiplier 45.

Meanwhile. The value of the second latch 32, which is a sampling value for detecting the time axis error in the horizontal synchronization signal falling section, becomes a value corresponding to L in the equation ⑤, which is inputted to the second subtractor 44 to provide a predetermined reference level value. The 25.6 level is subtracted (L-25.6), and the result is sent to the multiplier 45, whereby the result of the calculation of a / a (L-25.6) is obtained at the output of the multiplier 45.

Finally, the adder 46 adds 25.6, which is a predetermined reference level value, to the output of the multiplier 45, thereby finally obtaining the result of equation (5). This result is applied to the third latch 47, which is triggered and stored at the rising edge of the output start signal of the timing controller 20, and this stored value becomes a result value in consideration of the change in the slope of the horizontal synchronization signal. By using the value in consideration of the gradient change as the time axis error, the time axis error can be more accurately corrected.

As described above, the time-axis error detection apparatus of the video signal of the present invention is horizontal so that the change in the slope of the horizontal synchronization signal of the disk video signal is considered in the error detection unit receives two level values of the level storage unit according to the signal of the timing controller. After calculating the difference between the falling section slope of the period and the reference horizontal period falling slope, it is useful to be able to correct the error by detecting the correct time axis error corresponding to the difference.

Claims (3)

A level comparator for outputting high when a falling section of the horizontal synchronization signal is detected and a timing controller for generating first and second high signals having a predetermined interval and an output start signal according to a high signal of the level comparator; A level storage unit receiving the video signal and sampling the first and second level values of the horizontal synchronization signal at two points in time according to the first and second high signals of the timing controller; and the first and second storage units of the level storage unit. And an error detector for detecting and storing a time axis error corresponding to a difference in slope between the falling sections after receiving a level value, and outputting the detected error signal based on an output start signal of the timing controller. The display device of claim 1, wherein the level storage unit comprises: a first latch in which a first high signal of the timing controller is connected to a clock terminal and an image signal to an input terminal; and a second high signal of the timing control unit to a clock terminal. And a second latch connected to the input terminal, respectively. The method of claim 1, wherein the error detecting unit receives a first subtractor for receiving and subtracting first and second level values of the level storing unit, and an interval between the first and second high signals receiving an output of the first subtractor. A first divider dividing by a value, a second divider receiving an output of the first divider and dividing a predetermined reference value, and a second divider receiving a second level value of the level storing unit and subtracting a predetermined reference level value A second subtractor, a multiplier for multiplying the outputs of the second subtractor and the second divider, an adder for adding the output of the multiplier and the predetermined reference level value, and an output of the adder, the timing controller An apparatus for detecting time axis error of an image signal, characterized in that the output start signal comprises a third latch connected to a clock terminal.