KR970010396B1 - A color compensation circuit for picture in picture on television screen - Google Patents

Abstract

The sub-screen quality compensating circuit of a TV comprises a sub-screen signal processing unit for converting a sub-screen composite image signal into a luminance and color differential signal, performing a signalling process for it to output a frame blanking pulse, and simultaneously compressing and executing an analog conversion; a mother screen signal processing unit for detecting synthesizing and burst signals from a mother screen composite image signal and converting them into luminance and color differential signal; and a signal synthesizing unit for respectively synthesizing the luminance and color differential signals of the mother screen signal processing unit and the sub-screen signal processing unit in response to the frame blanking pulse of the sub-screen signal processing unit, and compensating an incline of the synthesized luminance signal, combining it with the synthesized color differential signal to output primary color signals.

Description

TV screen quality compensation circuit

1 is a block diagram of a conventional TV screen display circuit.

2 is a block diagram of a sub picture quality compensation circuit of the present invention.

3 is a waveform diagram of each part in FIG.

* Explanation of symbols for main parts of the drawings

1: Sub picture chroma decoder 2: Analog / digital converter

3: sub picture signal processor 4: main synchronization detector

5: Window pulse generator 6: Sync / burst signal detection and switching unit

7: main chroma decoder 8: color killer switching unit

9: color difference signal switching unit 10: luminance modulation unit

11 primary color signal matrix 12 microcomputer

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a TV's sub picture display (PIP) function, and more particularly, to a sub picture quality compensation circuit of a TV for improving a sub picture quality in a large TV or a wide screen TV.

FIG. 1 is a block diagram of a conventional TV screen display device. As shown in FIG. 1, a screen chroma decoder 101 for separating a screen image of a video screen into luminance and color signals and converting the color signal into a color difference signal is shown in FIG. An analog / digital converter 102 for digitally converting the output P _YUV of the sub-screen chroma decoder 101 and a sub-screen signal processor 103 for compressing the output of the analog-digital converter 102. And a combination of the microcomputer 108 for controlling the operation of the sub picture signal processor 103 and the output D _YUN of the sub picture signal processor 103 to output the sub picture primary color signal P _RGB . The mother screen color signal matrix 104, a mother screen chroma decoder 105 for separating the mother screen composite video signal into luminance and color signals, and converting the color signal into a color difference signal, and an output of the mother screen chroma decoder 105 Model by combining (Y, U, V) For the primary color signals (M _RGB) to output the main color signal matrix 106 and the character output of the sub screen color signal matrix of the main color signal matrix 106 according to the frame blanking pulse (FB) of the display signal processor (103) for ( And a color signal switching unit 107 for switching the output of the 104 to output the video signals R, G, and B for the sub picture display.

Referring to the operation of the conventional device as follows.

When the sub picture composite video signal is separated into the luminance signal Y and the color signal C by the sub picture chroma decoder 101, the color signal C is converted into the color difference signals U and V and the analog / digital converter 102 Is printed on

At this time, when the analog / digital conversion unit 102 decodes the output P _YUV of the sub picture chroma decoder 101 and outputs the sub picture signal processor 103 under decimation according to the control of the microcomputer 108. After compression through signal processing such as Decimation, it is output to the sub-screen color signal matrix 104 and at the same time, a frame blanking pulse FB is output to the color signal switching unit 107.

Accordingly, the sub-screen color signal matrix 104 converts the sub-screen signal D _YUV output from the sub-screen signal processor 103 into the main color signal P _RGB for the sub-screen, and then converts the color signal switching unit 107. Will print).

In addition, the mother screen composite video signal is separated into a luminance signal (Y) and a color signal (C) by the main chroma decoder (105), and then the color signal (C) is converted into a color difference signal (U, V), and thus the main color signal matrix (106). Will print).

In this case, the main color signal matrix 106 performs image processing on the output M _YUV of the main chroma decoder 105, converts it into a primary color signal M _RGB , and outputs it to the color signal switching unit 107.

Therefore, the color signal switching unit 107 synthesizes the output of the sub-screen color signal matrix 104 and the output of the main color signal matrix 106 according to the frame blanking pulse FB of the sub-screen signal processor 103, thereby outputting the TV. The screen of the sub screen displays an image of the sub screen.

However, since the resolution and image quality of the magnetic screen are conventionally determined by the performance of the analog / digital (A / D) converter and the PIP processor employed to perform the magnetic screen display function, when trying to improve the resolution and image quality of the magnetic screen. There is a problem that the manufacturing cost increases by using an expensive device.

In addition, since the resolution and the image quality of the sub picture itself are inevitably deteriorated on a large screen, there is a problem in that it is disadvantageous to apply to a TV that is gradually enlarged.

In order to solve this problem, the present invention stabilizes the synchronization by using the synchronization signal and the burst signal of the video signal for the mother screen when there is no mother screen video signal, and corrects the slope of the composite luminance signal of the mother screen and the mother screen. Therefore, a TV screen image compensating circuit of a TV is developed to improve the screen quality of the TV screen, which will be described in detail with reference to the accompanying drawings.

In order to achieve the above object, the present invention processes a sub picture composite video signal, converts it into a luminance and color difference signal, compresses the sub picture signal, and generates a frame blanking pulse. When processing the parent screen composite video signal by detecting the sync and burst signals, if the parent screen composite video signal is no signal, the mother screen signal outputs the luminance and color difference signals by extracting the sync signal and the burst signal from the subscreen composite video signal. And the luminance means and color difference signal of the mother screen signal processing means and the sub picture signal processing means are synthesized according to the frame blanking pulse of the sub picture signal processing means to correct the inclination of the synthesized luminance signal, and then the synthesis is performed. Signal synthesizing means for outputting the primary color signal for sub-screen display in combination with the color difference signal It is characterized by one.

2 is a block diagram of an embodiment of the present invention. As shown in FIG. 2, the sub-screen composite video signal is divided into luminance (Y) and color signal (C), and the color signal (C) is converted into color difference signals (U, V). The subscreen chroma decoder 1 to be converted, the analog / digital converter 2 for digitally converting the output P _YUV of the subscreen chroma decoder 1, and the output of the analog / digital converter 2 And a sub picture signal processor 3 for outputting a frame blanking pulse FB, a micro computer 12 for controlling the operation of the sub picture signal processor 3, and synchronization with a mother screen composite video signal. a main sync detector 4 for detecting the signal, is the high signal window pulse generator 5 for (D _S), the active is generating a window pulse (W _P) in the main synchronization detection unit 4, the main motivation According to the output D _S of the detector 4, the mother screen or the mother screen composite video signal is selected. Sub screen composite image when the signal is selected the window pulse generator (5) output (W _P) synchronizing signal and a burst signal is synchronous / burst signal is detected, and a switching unit (6), the sync / burst signal to extract in accordance with the The main chroma decoder 7 which separates the output V ₁ of the detection and switching unit 6 into luminance Y and color C signals and then converts the color signals C into color difference signals U and V. And a color killer switching unit 8 that outputs a switching signal in accordance with the output V ₂ of the main chroma decoder 7 and an output of the sub-screen signal processor 3 in accordance with the frame blanking pulse FB. D _YUV ) and a chrominance signal switching unit 9 for combining the output M _YUV of the main chroma decoder 7 and a luminance for processing the luminance signal Y of the chrominance signal switching unit 9 to correct the slope. The output Y 'and the color difference of the luminance modulator 10 according to the modulator 10 and the output Y ₂ of the color killer switching unit 8. A primary color signal matrix 11 for outputting primary color signals R, G, and B by combining the outputs U and V of the signal switching section 9 is configured.

Referring to the operation and effect of the present invention configured in this way in detail as follows.

First, the sub picture chroma decoder 1 receiving the sub picture composite video signal is separated into a luminance signal Y and a color signal C, and then converts the color signal C into a color difference signal U and V. The digital conversion unit 2 converts the digital signal into a digital signal and outputs it to the sub picture signal processor 3.

Accordingly, the sub picture signal processor 3 which receives the output of the analog / digital converter 2 performs signal processing under the control of the microcomputer 12 to perform a frame blanking pulse as shown in FIG. FB) is output and at the same time, the luminance and color difference signals are compressed to fit the size of the sub picture through decimation and the like, and then the analog conversion is performed to output to the color difference signal switching unit 9.

When the mother screen composite image signal is input, the main synchronization detector 4 detects the synchronization signal and the color burst signal to control the window pulse generator 5 and the synchronization / burst signal detection and switching unit 6. When the mother screen composite video signal has a synchronization signal and a color burst signal, the window pulse generator 5 is deactivated by outputting a low signal D _S , and the synchronization / burst signal detection and switching unit 6 simultaneously. A screen composite video signal is selected and output to the main chroma decoder 7.

In addition, the main screen the composite video signal has no signal (i.e., noise) when the synchronization signal detecting section 4 is a high signal (D _S), the outputs and deactivates a window pulse generator (5) at the same time synchronous / burst signal is detected, and The switching unit 6 enters a switching mode to alternately select input terminals of the parent screen and the sub picture composite video signal.

At this time, the synchronization / burst signal detection and switching unit 6 is switched according to the output W _P of the window pulse generator 5 as shown in FIG. After extracting the signal and synthesizing each other by extracting noise components from the parent picture composite video signal, the signal V ₁ as shown in FIG. 3 (f) is output to the main chroma decoder 7.

Here, the extraction of the synchronization signal and the color burst signal from the sub-screen composite video signal when the mother screen composite video signal does not have the synchronization signal and the color burst signal is the main chroma decoder without the synchronization signal and the color burst signal. This is because not only the own screen itself is not displayed in color but also the mother screen is caused by synchronous instability when it is displayed on the screen after it is input as it is and is signal processed.

Accordingly, the main chroma decoder 7 which receives the output V ₁ of the synchronization / burst signal detection and switching unit 6 separates the luminance signal Y and the color signal C, and then divides the color signal C into the color difference signal. Separated by (U, V) and output to the color difference signal switching section (9).

At this time, the main chroma decoder 7 outputs a low signal V ₂ to the color killer switching unit 8 to activate the switching signal which is high when the main screen composite image signal having the synchronization signal and the color burst signal is input. The output signal is output to the primary color signal switching unit 11, and when the mother-screen composite video signal which is no signal is input and synthesized with the synchronization signal and the color burst signal of the sub-screen composite video signal, the high signal V ₂ is transmitted to the color switching unit ( 8) to be deactivated to output a low switching signal to the primary color signal switching unit 11.

Here, when the color killer switching unit 8 outputs a low switching signal, the sub-screen signal operates regardless of the color killer.

When the luminance and color difference signal D _YUV of the mother screen is output by the magnetic screen signal processor 3 and the luminance and color difference signal MYUV of the mother screen is output by the main chroma decoder 7 by the above operation, the color difference signal is output. The switching unit 9 synthesizes the frame blanking pulse FB of the sub picture signal processor 3 to output the luminance signal Y to the luminance modulator 10, and the chrominance signals U and V are primary colors. It is output to the signal switching unit 11.

Here, when the signals of the mother screen and the mother screen are synthesized by the color difference signal switching unit 9, the signals are output as shown in FIG. 3E. The color difference signals U and V are directly or after a predetermined time delay, and then the primary color signals. It is output to the switching part 11.

At this time, the luminance modulator 10 improves contrast and sharpness by performing first and second derivatives on the luminance signal Y of the chrominance signal switching unit 9 to improve contrast and sharpness. Output to the switching unit 11.

Accordingly, the primary color signal switching unit 11 outputs the luminance signal Y 'of the luminance modulator 10 and the color difference signals U and V of the color difference signal switching unit 9 according to the output of the color killer switching unit 8. By combining), the child screen is displayed on the TV screen where the mother screen is displayed by outputting the primary color signal.

As described in detail above, the present invention extracts a synchronization signal and a color burst signal from a sub-screen composite video signal when the non-signal parent screen composite video signal is input, and synthesizes the sub-signal to prevent synchronous instability, thereby eliminating screen shake. In addition, it is possible to improve the image quality and the resolution of the sub picture by performing a tilt correction on the composite luminance signals of the main picture and the sub picture.

Claims (8)

When the main screen composite video signal is converted into a luminance and chrominance signal, the signal is processed, the frame blanking pulse is output, simultaneously compressed, and the analog screen is processed. Mother screen signal processing means for converting the brightness and color difference signals, and the brightness and color difference signals of the mother screen signal processing means and the sub picture signal processing means, respectively, according to the frame blanking pulses of the sub picture signal processing means, and synthesizing them; And a signal synthesizing means for outputting a primary color signal in combination with the synthesized color difference signal after correcting the slope of the luminance signal. 2. The mother screen signal processing unit of claim 1, wherein the mother screen signal processing unit extracts a synchronization signal and a color burst signal of the mother screen composite video signal when the mother screen composite video signal is no signal, and then combines the mother screen video signal to output luminance and color difference signals. TV screen quality compensation circuit, characterized in that. The magnetic screen chroma processing apparatus according to claim 1, wherein the magnetic screen signal processing means separates the magnetic screen composite video signal into luminance (Y) and color signal (C) and converts the color signal (C) into color difference signals (U, V). Decoder 1, an analog / digital converter 2 for digitally converting the output P _YUV of the sub-screen chroma decoder 1, and an output of the analog / digital converter 2 are processed to blank the frames. The sub picture signal processor 3 which outputs the pulse FB to the signal synthesizing means, compresses it, and then converts the analog signal to output the luminance and color difference signals D _YUV to the signal synthesizing means. A television screen image compensating circuit for a TV, comprising: a microcomputer 12 for controlling the operation of 3). 2. The mother screen signal processing means according to claim 1, wherein the mother screen signal processing means is activated by a main synchronization detector 4 for detecting a synchronization signal in the mother screen composite video signal, and an output D _S of the main synchronization detector 4 to generate a window pulse ( A window pulse generator 5 for generating W _P ) and a sync / burst signal detection and switching unit for selecting and outputting a parent image composite video signal when the main synchronization detector 4 detects a synchronization signal and a color burst signal. (6) and the output of the synchronization / burst signal detecting and switching section 6 are separated into luminance (Y) and color (C) signals, and then the color signal (C) is converted into color difference signals (U, V). The main chroma decoder 7 outputs to the signal synthesizing means, and the color killer switching unit 8 outputs the switching signal V ₂ to the signal synthesizing means in accordance with the output of the main chroma decoder 7. TV screen quality compensation circuit. The method of claim 4 wherein the output of the sync / burst signal detector (6) is the window pulse generator (5), as when the active output of the main synchronization detection unit 4, the parent screen and a child screen, select the composite video signal (W _P ), By synthesizing the parent screen and the sub picture composite video signal alternately, synthesizing the synchronization signal and the color burst signal of the extracted sub picture signal and the non picture parent picture composite video signal, and then converting the luminance signal and the color difference signal to the signal synthesizing means. TV screen quality compensation circuit, characterized in that the output. The TV according to claim 4, wherein the main chroma decoder (7) activates the color killer switching unit (8) when only the parent image composite video signal is input from the synchronization / burst signal detection and switching unit (6). Sub picture quality compensation circuit. 2. The signal synthesizing means according to claim 1, wherein the signal synthesizing means synthesizes the output P _YUV of the sub picture signal processing means and the output M _YUV of the mother screen signal processing means in accordance with the frame blanking pulse FB of the sub picture signal processing means. A chrominance signal switching section 9, a luminance modulation section 10 for receiving the luminance signal Y of the chrominance signal switching section 9, and correcting the slope, and an output V ₂ of the ambiguity signal processing means. According to the primary color signal matrix for outputting the primary color signal (R, G, B) by combining the output (Y ') of the luminance modulator 10 and the output (U, V) of the color difference signal switching unit (9) 11) TV screen quality compensation circuit, characterized in that consisting of. The image display compensation of TV according to claim 7, wherein the luminance modulator 10 corrects the inclination by performing the first and second derivatives of the luminance signal Y of the color difference signal switching unit 9. Circuit.