KR0122950Y1 - Sub-picture color signal detection stability circuit - Google Patents

Abstract

The present invention relates to a color signal carrier discrimination malfunction prevention circuit. In particular, in an IP system which is processed with a luminance signal and a color signal, the sub-screen color signal detection stabilization to solve the phenomenon that the sub-screen color signal is unstable when the main screen is no signal It is about a circuit.

The conventional sub-screen color signal stabilization circuit is an output of a signal presence detection unit according to the inputted composite video signal (CVBS) of the main screen. When no signal of the main screen is applied, only a bias voltage is applied to the eyepiece switching IC without applying white noise, that is, white noise In this case, the PiPix Switching IC prevents color synch error due to the main screen white noise. However, the output of the synchronous separation unit of the image chroma IC does not output the unstable sync signal when the input signal is unstable. Since the color signal processing part of the chroma IC becomes unstable and the color signal output to the CPT becomes unstable, when white noise is input to the main screen in the PIP system, a malfunction occurs in the sync separation part, resulting in unstable color signal detection output. This happened.

In order to solve such a conventional problem, the present invention applies a synchronization signal of a sub-screen luminance signal to a main screen luminance signal line when a main screen white noise is generated, and inputs a stable luminance signal to the sync separation section, thereby synchronizing separation. This is to prevent the phenomenon that the sub-screen color becomes unstable even when the main screen is no signal by stabilizing the negative output.

Description

Sub-screen color signal detection stabilization circuit

1 is a block diagram of a conventional sub-screen color signal stabilization circuit.

2 is a detailed block diagram of the image chroma IC shown in FIG.

3 is a block diagram of the present invention sub-screen color signal detection stabilization circuit.

* Explanation of symbols for main parts of the drawings

11: signal presence detection unit 12: microcomputer

13: comb filter 14: luminance signal control unit

15: luminance signal switching unit 16: color signal control unit

17: color signal output unit 18: eyepiece switching IC

19: PI signal processing unit 20: image chroma IC

21: synchronization signal separator

The present invention relates to a color signal carrier discrimination malfunction prevention circuit. In particular, in a PIP system processed by a luminance signal and a color signal, a sub-screen for solving a phenomenon in which a sub-screen color signal is unstable when the main screen is no signal The present invention relates to a color signal detection stabilization circuit.

As shown in FIG. 1 and FIG. 2, the conventional sub-screen color signal stabilization circuit is configured to detect a main screen composite video signal CVBS applied thereto, determine whether a signal is present, and output a control signal to the color signal controller 7. The signal presence detection unit 2, the microcomputer 6 for controlling the circuit by receiving and discriminating the signal detected by the signal presence detection unit 2, and the main screen composite video signal CVBS applied to the luminance signal ( A comb filter 1 separating the Y signal and the color signal C, a color signal controller 7 controlling the main screen color signal C by the control signal output from the signal presence detecting unit 2, and the comb The color signal output unit 8 for outputting the main picture color signal C output from the filter 1 by the control signal of the color signal control unit 7, the luminance signal Y and the color signal separated from the comb filter 1. The main screen color signal C output from the output unit 8 and the applied sub-screen color signal C 'are switched to change the color difference signals R-Y' and G-. Y ') and output to the IP signal processing section 4, and the sub picture luminance signal Y' and the color signal C 'processed by the IP signal processing section 19 switch the main screen signal. And sub-screen signal are combined to generate luminance signal (Y Y ') and color signal (C) C ') to output the eyepiece switching IC 3, the color difference signals R-Y' and G-Y 'outputted from the eyepiece switching IC 3, and the luminance signal Y' to be applied. PPI which processes inputted PI signal and outputs luminance signal Y 'and color difference signals R-Y' and G-Y 'of the PPI-processed sub-screen to PPI positioning IC 3 again. The luminance signal Y output from the IP signal processing section 4 and the PI piece switching IC 3. Y ') and color signal (C) C ') is applied to the color demodulation and other image quality changes to the final luminance signal (Y Y ') and color signal (C) C ') is composed of an image chroma IC (5) for outputting.

The image chroma IC 5 is a luminance signal Y output from the eyepiece switching IC 3. The luminance signal Y outputted from the luminance signal processing section 5a and the eyepiece switching IC 3 to process Y '). Y '), a synchronous separation section 5b for separating the synchronous signals included in the horizontal blanking pulse generating section 5c for generating a horizontal blanking pulse, and a synchronous signal separated and output from the synchronous separation section 5b. A burst pulse generator 5d which performs an AND operation on the horizontal blanking pulses applied from the horizontal blanking pulse generator 5c to output a color burst signal, and the color signal from the eyepiece switching IC 3. C Color signal processing unit 5e for receiving color signal processing by the color burst signal output from the burst pulse generating unit 5d and color signal for detecting the color signal output from the color signal processing unit 5e It consists of a detection part 5f.

The operation of the conventional sub-screen color signal stabilization circuit, which is performed in this way, first, when there is a signal in the input main screen composite video signal CVBS, the output of the signal presence detection unit 2 becomes low, and thus the color signal controller 7 The transistor Q1 is turned off, and the comb filter 1 separates the input composite video signal CVBS of the main screen into a luminance signal Y and a color signal C so that the luminance signal Y is an eyepiece switching IC. When outputted to (3) and the color signal C is output to the base of the transistor Q2 of the color signal output section 8, since the transistor Q1 is turned off, the main screen color signal C input to the base of the transistor Q2 ) Voltage is not changed and transistor B3 is turned off and transistor Q2 is turned on so that the main screen color signal C is turned on since voltage B + becomes higher than the voltage divided by voltage divided by resistors R3 and R4. It is applied to the eyepiece switching IC 3.

Thereafter, the eyepiece switching IC 3 converts the sub-screen color signal c 'applied to the color difference signals R-Y' and G-Y 'and outputs it to the IP signal processing section 4, and then the PI signal. The processing unit 4 receives the sub-screen color difference signals R-Y 'and G-Y' outputted from the eyepiece switching IC 3 and the sub-screen luminance signal Y 'applied to process the P-P signal. When the color difference signals R-Y 'and G-Y' together with the sub-screen luminance signal Y 'are outputted to the eyepiece switching IC 3 again, the eyepiece switching IC 3 outputs the main screen luminance signal Y. ) And the luminance signal Y synthesized by combining the color signal C, the sub-screen luminance signal Y 'and the color signal C'. Y ') and color signal (C) C ') is printed.

At this time, since the eyepiece switching IC 3 detects that there is a color sync signal, the main screen color sync signal is output as it is, and the luminance signal Y obtained by combining the main screen and the sub-screen on which the main screen color sync signal is carried is Y. Y ') and color signal (C) C ') is outputted, and the luminance signal Y output from the eyepiece switching IC 3 from the image chroma IC 5. Y ') and color signal (C) C ') after the color demodulation and other image quality changes, the final luminance signal (Y) Y ') and color signal (C) C ') will print

The luminance signal Y applied by the luminance signal processing section 5a of the image chroma IC 5 Y ') is processed and output to the CPT driving circuit, and the synchronous separation section 5b applies the applied luminance signal Y. The synchronization signal included in the Y ') is separated and output to the burst pulse generator 5d.

Thereafter, the burst pulse generator 5d performs an AND operation on the horizontal blanking pulse output from the horizontal blanking pulse generator 5c and the synchronization signal output from the sync separator 5b, and outputs a color burst signal.

In the color signal processing section 5e, the color signal C applied from the eyepiece switching IC 3 is applied. C ') is signal-processed based on the color burst signal output from the burst pulse generator 5d as a reference, and detected by the color signal detector 5f and output to the CPT driving circuit.

When the main screen is no signal, the output of the signal presence detection unit 2 becomes high to turn on the transistor Q1. When the transistor Q1 is turned on, the output of the comb filter 1 is output to the transistor Q2. Bypassing the bias voltage of the main picture color signal C inputted to the base of the transistor, divides the applied B + voltage by the resistors R3 and R4 to make it lower than the voltage inputted to the base of the transistor Q3. ) Is turned off, and the transistor Q3 is turned on.

When the transistor Q2 is turned off and the transistor Q3 is turned on, the main picture color signal C, that is, white noise is not applied to the eyepiece switching IC 3, and only a bias voltage is applied to the eyepiece switching IC 3. In (3), the image chroma IC is loaded with the sub-screen luminance signal Y 'and the color signal C' and the sub-screen color synchronizing signal synthesized with the main screen signal. When applied to (5), the image chroma IC 5 performs color demodulation in the same manner as described above to produce the final luminance signal Y ') and color signal (C) Will print C ').

In this way, the signal presence detecting unit 2 according to the composite video signal CVBS of the main screen is input. When no signal of the main screen is input, the color signal C, that is, white noise is not applied to the eyepiece switching IC 3. By applying only the bias voltage, the color synchronization malfunction due to the main picture white noise does not occur in the piafswitching IC 3, so that the sub picture comes out of color even when no signal of the main picture occurs.

However, when the input signal is unstable, the output of the synchronization separator 5b outputs the synchronization signal in an unstable state. Accordingly, the output of the burst pulse generator 5d is also horizontally output from the horizontal blanking pulse generator 5c. Although it is AND operation with the blanking signal, it may be temporarily unstable.

Therefore, when the output of the burst pulse generating unit 5d is unstable, the color signal processing unit 5e becomes unstable and the color signal output to the CPT becomes unstable. Therefore, when white noise is input to the main screen in the PIP system, the synchronization separator ( In 5b), a malfunction occurs, which causes a problem that the color signal detection output becomes unstable.

In order to solve such a conventional problem, the present invention applies a synchronization signal of a sub-screen luminance signal to a main screen luminance signal line when a main screen white noise is generated, and inputs a stable luminance signal to the sync separation section, thereby synchronizing separation. It is intended to prevent the phenomenon that the sub-screen color appears unstable by stabilizing the negative output. Referring to the accompanying drawings, the configuration and operation effects will be described below.

As shown in FIG. 3, the configuration of the sub-screen color signal detection stabilization circuit according to the present invention detects an applied main screen composite video signal (CVBS), determines whether there is a signal, and outputs a control signal. And the microcomputer 12 for controlling the circuit by receiving and detecting the signal detected by the signal presence detecting unit 11, and applying the main screen composite video signal CVBS to the luminance signal Y and the color signal C. A comb filter 13 to be separated, a luminance signal controller 14 for controlling the main screen luminance signal Y by the control signal output from the signal presence detection unit 11, and an output from the comb filter 13 The luminance signal switching unit 15 for outputting the luminance signal by switching the main screen luminance signal Y by the control signal of the luminance signal control unit 14, and the color signal C output from the comb filter 13 Color signal to be output controlled by the control signal output from the signal presence detection unit 11 The control unit 16, the color signal output unit 17 for outputting the color signal C according to the signal output from the color signal control unit 16, and the main screen luminance signal Y output from the luminance signal switching unit 15. And the main screen color signal C output from the color signal output unit 17 and the applied sub-screen color signal C 'are converted into color difference signals R-Y' and G-Y 'to convert the PI signal processing unit. And a sub-screen luminance signal Y 'and a color signal C' which have been processed by an IP signal processing unit 19 to synthesize a main screen signal and a sub-screen signal, thereby combining the luminance signal ( Y Y ') and color signal (C) C ') outputs the eyepiece switching IC 18, the color difference signals R-Y' and G-Y 'outputted from the eyepiece switching IC 18, and the luminance signal Y' applied thereto. PIP signal processing, PIP signal processing, and the luminance signal (Y ') and the color difference signals (R-Y', G-Y ') of the PPI-processed sub-screen are again used. P signal processing unit 19 for outputting to the P, and the luminance signal (Y) output from the PPI positioning IC (18) Y ') and color signal (C) C ') is applied to the color demodulation and other image quality changes to the final luminance signal (Y Y ') and color signal (C) The sub-screen synchronization signal separator 21 for separating the image chroma IC 20 outputting the C ') and the synchronization signal of the applied sub-screen luminance signal Y' and outputting it to the luminance signal switching unit 15. It consists of.

In addition, the luminance signal controller 14 is switched on and off by the control signal output from the signal presence detection unit 11 to control the output of the luminance signal (Y) output from the comb filter 13 ( Q4), and the luminance signal switching unit 15 switches on and off according to on and off switching of the transistor Q4 to output the luminance signal Y output from the comb filter 13. (Q5), the resistors R9 and R10 for dividing the applied B + voltage and outputting them to the base of the transistor Q6, and the transistors receiving the voltages divided by the resistors R9 and R10 as a base and switching on and off. It consists of (Q6).

Referring to the operation of the inventive sub-screen color signal detection stabilization circuit configured as described above, when there is a signal in the main screen composite video signal CVBS inputted first, the output of the signal presence detection unit 2 becomes low and the luminance signal controller The transistor Q4 of (14) is turned off, and the comb filter (1) separates the composite video signal (CVBS) of the input main screen into a luminance signal (Y) and a color signal (C), respectively. ) And the color signal controller 16.

Thereafter, as the transistor Q4 of the luminance signal control unit 14 is turned off, the voltage of the luminance signal Y of the transistor Q5 of the luminance signal switching unit 15 does not change at all and resists the applied B + voltage. Since the voltage is higher than the divided voltage divided by R9 and R10, the transistor Q6 is turned off, the transistor Q5 is turned on, and the main screen luminance signal Y is applied to the eyepiece switching IC 18.

In addition, the main screen color signal C output from the comb filter 13 is applied to the eyepiece switching IC 18 through the color signal output unit 17 under the control of the color signal controller 16.

The PI piece switching IC 18 converts the sub-screen color signal C 'applied to the color difference signals R-Y' and G-Y 'and outputs it to the PI signal processing unit 19, and the PI signal processing unit ( In 19), the sub picture is processed by receiving the sub picture color difference signals R-Y 'and G-Y' and the sub picture luminance signal Y 'applied from the eyepiece switching IC 18 to process the picture signal. When the color difference signals R-Y 'and G-Y' together with the luminance signal Y 'are outputted to the eyepiece switching IC 18 again, the eyepiece switching IC 18 receives the main screen luminance signal Y and The luminance signal Y synthesized by combining the color signal C, the sub-screen luminance signal Y 'and the color signal C'. Y ') and color signal (C) C ') is printed.

At this time, the eyepiece switching IC 18 detects that there is a color sync signal, and outputs the main screen color sync signal as it is, and the luminance signal Y obtained by combining the main screen and the sub-screen on which the main screen color sync signal is loaded. Y ') and color signal (C) When C ') is outputted, the luminance signal Y output from the Pia Api positioning IC 18 from the image chroma IC 20. Y ') and color signal (C) C ') after demodulation and other image quality changes Y ') and color signal (C) C ') will print

The image chroma IC 20 performs the same operation as the operation of the process described with reference to FIG. 2 of the related art.

Next, when the main screen is no signal, the output of the signal presence detecting unit 2 becomes high to turn on the transistor Q4 of the luminance signal control unit 14, and when the transistor Q4 is on, the comb filter 13 is turned on. Bypass the bias voltage of the main screen luminance signal (Y) output from the input to the transistor Q5 base of the luminance signal switching unit 15, and divides the applied B + voltage by the resistors (R9, R10) When the transistor Q5 is turned off by making it lower than the voltage input to the base of Q6, the transistor Q6 is switched on.

As described above, since the transistor Q5 is turned off, the white noise is not transmitted to the eyepiece switching IC 18, and the transistor Q6 is switched on, so that the negative signal output from the synchronization signal separation unit 21 is performed. The synchronization signal of the screen luminance signal Y 'is applied to the main screen luminance signal Y terminal of the eyepiece switching IC 18 to perform the following operation by the operation described above.

As described above, when the main screen is no signal, when the synchronization signal of the sub-screen luminance signal Y 'is outputted to the main screen luminance signal Y, the signal input to the image chroma IC 20 even during white noise. Is applied as a stable signal, and as shown in FIG. 2, the luminance signal inputted to the synchronization separator 5b of the image chroma IC 20 is stabilized, and the synchronization outputted from the synchronization separator 5b is performed. Since the output of the burst pulse generator 5d outputting the color burst on the basis of the signal is stabilized, the color signal output from the color signal detector 5f is output as a stable signal.

As described above, the luminance signal Y applied to the image chroma IC 20 at the time of no main screen signal is displayed. As the color signal is unstable as Y ') becomes unstable, the sub-screen luminance signal Y' is loaded on the main screen luminance signal Y line when the main screen is no signal. Luminance signal input to Y By stabilizing Y '), the sub-screen color is prevented from becoming unstable.

Claims (2)

Sub-screen color signal that detects the applied main screen composite video signal (CVBS) to determine the presence of a signal and controls the main screen color signal (C) according to the presence of the main screen signal to prevent color synchronization malfunctions generated when no main screen signal is present. In the stabilization circuit, a luminance signal control unit 14 for controlling the main screen luminance signal Y by the control signal output from the signal presence detecting unit 11, and the main screen luminance signal (Y) to the luminance signal control unit 14 Outputs the luminance signal by switching under the control of the control signal), and outputs the color signal C output from the comb filter 13 by the signal output from the signal presence detection unit 11. The synchronization signal of the color signal controller 16 to be controlled, the color signal output unit 17 to output the color signal C by the signal output from the color signal controller 16, and the sub-screen luminance signal Y 'applied. And output to the luminance signal switching unit 15 To the sub-screen synchronous signal separator 21, a stabilization sub-screen color signal detector, comprising a step of including in the circuit components to be The luminance signal control unit 14 controls the output of the luminance signal Y output from the comb filter 13 by switching on and off by a control signal output from the signal presence detecting unit 11. The luminance signal switching unit 15 is switched on and off according to the on and off switching of the transistor Q4 to convert the luminance signal Y output from the comb filter 13. The transistor Q5 to be outputted, the resistors R9 and R10 for dividing the applied B + voltage and outputting them to the base of the transistor Q6, and the voltages divided by the resistors R9 and R10 are inputted to the base. Sub-screen color signal detection stabilization circuit comprising a transistor (Q6) for switching off as a component