KR200204883Y1 - Improvement device of picture degradation in a motion detection - Google Patents

Abstract

The present invention relates to a device for improving image quality deterioration by MD (Motion Detection) used in a 100 ㎐ TV. In the past, when a system clock is shaken by jitter and there is a sudden change such as an edge, a sample value of an analog signal is always accurately corrected. If the LSB of the digital image data that is most affected by the MD image is changed when the boundary of the image is unchanged, such as a still image, and the change of two adjacent lines is severe, the image quality due to noise on the 100Hz TV screen is severe. There is a problem that deterioration occurs badly. In other words, if the sampling around the boundary is not accurate, the bright image appears suddenly in the dark area and the image quality of the 100Hz TV is severely deteriorated.

Therefore, in order to solve the above problems, the present invention provides edge detection means for recognizing the boundary surface so as to obtain a sample value of the analog signal at all times by reducing the sampling error while reducing the LSB variation of the digitalized image data at the boundary portion of the image. By constructing a digital processing system that includes an end gate and a switch, the image quality of the still image boundary caused by a sampling error caused by jitter of the system clock in the MD image, which is one of the digital processing of a 100 ㎐ TV, is obtained. In addition to eliminating the deterioration of the digital signal processing, it is possible to use the circuit that finds the boundary at the time of digital signal processing where it is necessary to improve the image quality of the boundary.

Description

Image quality deterioration improvement device by MD

The present invention relates to the improvement of image quality deterioration due to MD (Motion Detection) used in 100 Hz TV, and particularly to the jitter of the system clock in MD image, which is one of the digital processing of 100 Hz TV. The present invention relates to a device for improving image quality deterioration caused by MD, which attempts to eliminate glitters at the boundary of still images caused by sampling errors caused by the sampling.

In general, as shown in FIG. 1, the 100-Hz TV improves the flicker of the screen by displaying each field signal A / A, B / B on the screen once again. Since the field signals (A / A, B / B) are simply displayed once more, a moving object is dragged on the screen in a moving image such as a soccer game.

Therefore, in order to solve such a problem, as shown in FIG. 2, the analog video signals Y, U, and V of 50 Hz are converted into digital video signals UV0 to UV3 (Y0 to Y7) and output. Analog / digital conversion unit 1,

A video processor (2) which performs an MD so that a moving subject of the 50 kHz digital video signals UV0 to UV3 (Y0 to Y7) converted into digital output by the analog / digital conversion unit 1 is not dragged;

Outputting MD detection signal for performing MD and 27M 'digital video signal (Y, U, V) to the video processor (2) while storing 13.5 M㎐ digital video signals (Y, U, V), A video memory (3) for sharing the MD video signals (Y, U, V) with the video processor (2);

The digital video signals UV0 to UV3 (Y0 to Y7) of 50 Hz, which are prevented from dragging a moving subject by the MD of the video processor 2, are converted to the analog video signals UV0 to UV3 (Y0 to Y7) of 100 Hz. The digital / analog converting section 4 which converts and outputs the output to the output is configured.

That is, the 50 kHz analog video signals UV0 to UV3 (Y0 to Y7) input from the analog / digital conversion unit 1 are converted into the digital video signals UV0 to UV3 (Y0 to Y7) according to the above configuration. Is converted to a video processor 2, and the video processor 2 receives 13.5 M㎐ in the video memory 3 so that a moving subject is not dragged in the video signals UV0 to UV3 (Y0 to Y7) that have been digitally changed. Stores digital video signals (Y, U, V).

At this time, the video processor 2 receives a 3-bit MD detection signal from the 13.5 M㎐ digital video signals Y, U, and V stored in the video memory 3, and again the video memory 3 Since the digital video signal (Y, U, V) and MD digital video signal (Y, U, V) of 27M 부터 are received from the video processor (2), the MD video signal (Y, U) is received from the video processor (2). MD is performed through the MD detection signal to prevent dragging of a moving subject, and the MD digital video signals Y, U, and V are stored in the video memory 3 again.

That is, the storage position of the video memory 3 is different from the first stored position, and the digital / analog converting unit 4 which reads the two stored signals at twice the speed that has been read and written to the video memory 3 so far is the last. The analog video signals UV0 to UV3 (Y0 to Y7) of 100 kHz with which the moving subject is prevented from being dragged can be output.

In other words, as shown in FIG. 3, MD is performed by the video processor 2 to implement 100 ms.

As shown in FIG. 4, the MD constructs two new fields A 'and B' by multiplying the values of the first field A and the value of the second field B by different weights. By inserting the fields A 'and B' between the two original fields A and B, the dragging of the moving subject can be prevented and displayed on the screen.

Here, in order to realize the analog video signals UV0 to UV3 (Y0 to Y7) of 100 Hz, the analog video signal must be sampled according to the system clock, and the condition that the system clock must be stable at all times is necessary in order to always obtain accurate sample values. do.

However, in the conventional digital processing unit for performing MD, when the system clock is shaken by jitter and there is a sudden change such as an edge, as shown in FIG. 5, the sample value of the analog signal is not always accurately obtained and the adjacent value is obtained. Therefore, the least significant bit (LSB) of the digitalized image data that is most affected by the MD image is changed when the boundary of the image is unchanged, such as a still image, while 100 Hz TV is used when the change between two adjacent lines is severe. This caused a problem of severe image quality deterioration due to noise such as a star shining on the screen.

In other words, the change of one line in the image information can be very small except for the boundary surface, but if the sampling around the boundary is not accurate in the sudden motion image, the bright spots appear suddenly in the dark areas, and vice versa. As a result, the deterioration of the image quality of the 100 Hz TV occurred.

Therefore, in order to solve this problem, the present invention reduces the sampling error while reducing the least significant bit (LSB) change of the digitalized image data at the edge of the edge, and always recognizes the edge to recognize the edge of the analog signal. Noise in the boundary of still picture caused by sampling error caused by jitter of system clock in MD image, which is one of the digital processing of 100Hz TV, comprising digital processing system including detection means, end gate and switch The purpose is to get rid of glitter without degrading the overall picture quality.

Another object of the present invention is to employ a circuit for detecting a boundary at the time of digital signal processing so that it can be used where an image quality improvement at the boundary is required.

1 is a field configuration diagram of a conventional 100 Hz TV.

2 is a block diagram showing the configuration of a digital processing apparatus of a conventional 100 Hz TV.

3 is a field configuration diagram of a 100 Hz TV using a conventional MD.

4A to 4D are respective line waveform diagrams of two fields obtained by MD according to the related art.

5A and 5B are field waveform diagrams showing a sampling error state caused by jitter of a conventional system clock.

Figure 6 is a block diagram showing the configuration of a device for improving image quality deterioration by MD used in the present invention 100 GHz TV.

Figure 7 is a block diagram showing the configuration of the edge detector in the image quality deterioration improvement device by the present invention MD.

8 is a signal waveform diagram according to the operation state of the edge detection unit of the present invention, a is a waveform diagram of the MD image signal (Y7), b is a system clock waveform diagram, c is an output waveform diagram of the control terminal signal (CON).

Referring to Figures 6 and 7 attached to the configuration of the image quality deterioration improving device according to the present invention for achieving the above object is as follows.

First, in a 100Hz TV which displays an analog image of 100Hz by performing MD so that a moving subject of an image signal is not attracted.

The reference signal of the MD signals Y0 to Y7 input from the video memory 3 according to the user control to detect the boundary of the MD image signals Y0 to Y7 and reduce the sampling error. An edge detector 10 outputting a control terminal signal CON of the switching unit 30 according to the change of the selected reference signal Y7 after selecting Y7);

An end gate (AND gate) 20 for outputting a value Y'0 obtained by performing a logical AND on only the boundary portions of the MD video signals Y0 and Y1 input from the video memory 3;

The MD video signal Y0 output by the video memory 3 and the logic value Y'0 output by the end gate 20 and the control terminal signal CON output by the edge detector 10. A switching unit 30 which switches to determine an image signal 27 MHz Y, U, V input from the video memory 3 to the video processor 2 according to the present invention; It consists of.

In addition, the edge detector 10 includes a switch 11 for switching to output the image signals Y0 to Y7 that have been digitally converted by the analog / digital converter 1 and controlled by the user. ;

A flip-flop (12) for selecting a reference signal (Y7) among the MD video signals (Y0 to Y7) output during the switching operation of the switch (11) according to the input system clock;

The control terminal of the switching unit 30 after calculating the MD video signals Y0 to Y7 outputted during the switching operation of the switch 11 and the reference signal Y7 selected by the flip-flop 12 with an exclusive logical sum. An exclusive X-OR gate 13 which outputs a signal CON; It was configured to include.

The operation of the apparatus for improving image quality deterioration by the present invention MD configured as described above will be described with reference to FIGS. 6 to 8.

First, the 50 kHz analog video signals UV0 to UV3 (Y0 to Y7) input from the analog / digital converter 1 are converted into digital video signals UV0 to UV3 (Y0 to Y7) to convert the video processor into a video processor. 2), the video processor 2 outputs a 13.5 M㎐ digital video signal Y, to the video memory 3 so that the moving subject of the digitally changed video signals UV0 to UV3 (Y0 to Y7) is not attracted. U, V) are stored.

At this time, the video processor 2 receives a 3-bit MD detection signal from the 13.5 M㎐ digital video signals Y, U, and V stored in the video memory 3, and again the video memory 3 Since the digital video signal (Y, U, V) and MD digital video signal (Y, U, V) of 27M 부터 are received from the video processor (2), the MD video signal (Y, U) is received from the video processor (2). MD is performed through the MD detection signal to prevent dragging of a moving subject, and the MD digital video signals Y, U, and V are stored in the video memory 3 again.

On the other hand, the edge detection unit 10 built in the video processor 2 detects the boundary of the MD video signals Y0 to Y7 and reduces the sampling error to the video memory 3 according to the user's control. After selecting the reference signal Y7 among the MD signals Y0 to Y7 inputted from the control unit, the control terminal signal CON is output to the switching unit 30 according to the change of the selected reference signal Y7.

That is, in the switch 11 included in the edge detector 10, a switching operation is performed under the control of a user to flip-flop the image signals Y0 to Y7 that are converted into digital by the analog / digital converter 1 and are MD. And outputs to (12), so that the flip-flop 12 selects the reference signal Y7 among the MD video signals Y0 to Y7 as shown in FIG. 8A according to the system clock input as shown in FIG. 8B. Will be.

At this time, the X-OR gate 13 included in the edge detector 10 is selected by the MD video signals Y0 to Y7 and the flip-flop 12 output during the switching operation of the switch 11. After the reference signal Y7 is calculated using the exclusive OR, the control terminal signal CON is output to the switching unit 30 as shown in FIG. 8C.

For example, the switching unit outputs a control terminal signal CON recognized as a boundary when the reference signal Y7 selected by the flip-flop 12 changes from 0 to 1 or 1 to 0. At 30, the switching operation is performed according to the input control terminal signal CON to determine the video signals 27MHz Y, U, V input from the video memory 3 to the video processor 2.

That is, since the video processor 2 shares the MD video signals Y, U, and V with the video memory 3, the video memory 3 ends with the MD video signals Y0, Y1. And outputs the MD video signal Y0 to the switching unit 30, so that only the boundary portion of the MD video signals Y0 and Y1 input from the end gate 20. After calculating by the AND, the value Y'0 is output to the switching unit 30.

In the switching unit 30, the MD image signal Y0 output from the video memory 3, the logic value Y′0 output from the end gate 20, and the edge detection unit 10 are output. The video signal (27MHz Y, U, V) input from the video memory 3 to the video processor 2 is determined according to the control terminal signal CON outputted by the control terminal signal CON, thereby sampling only at the boundary of the digitalized video signal. By reducing the error, it is possible to eliminate the noise (gliding) generated during MD without deteriorating the overall image quality.

As described above, the present invention has edge detection means and end for recognizing the boundary so that the sampling error of the digitalized image data is reduced while reducing the sampling error while reducing the least significant bit (LSB) change of the digital data at the boundary of the image. By constructing a digital processing system that includes a gate and a switch, noise (blinking) at the edge of a still picture caused by a sampling error caused by jitter of the system clock in an MD image, which is one of the digital processing of a 100 ㎐TV, While eliminating the deterioration of the overall image quality, the circuit for detecting the boundary portion in the processing of the digital video signal is employed in the place where the image quality improvement of the boundary portion is required.

Claims (2)

In a 100Hz TV which displays an analog image of 100Hz by performing MD so that a moving subject of an image signal is not attracted. Selecting the reference signal among the MD signals input from the video memory according to the user's control to detect the boundary of the digitalized video signal and reducing the sampling error, and then outputs the control terminal signal of the switching unit according to the change of the selected reference signal. An edge detector; An end gate which calculates and outputs only the boundary of the MD video signal input from the video memory by logical AND; A switching operation for determining a video signal input from the video memory to the video processor according to the digitalized video signal output by the video memory, the logic value output by the end gate, and the control terminal signal output by the edge detector. part; Apparatus for improving image quality deterioration, characterized in that consisting of. The display apparatus of claim 1, wherein the edge detector comprises: a switch configured to perform a switching operation to output an image signal converted into digital by an analog / digital converter according to a user's control; A flip-flop for outputting a digitalized video signal output during the switching operation of the switch according to an input system clock; An exclusive oal gate configured to output a control terminal signal of the switching unit after calculating the digitalized video signal output during the switching operation of the switch and the video signal output to the system clock by the flip-flop with an exclusive logical sum; Apparatus for improving image quality degradation by the MD, characterized in that configured to include.