KR940004556B1 - Rgb signal processing circuit - Google Patents

Abstract

The circuit is for simultaneously displaying TV video signal and external color signal on the screen of a double-field digital television. The circuit comprises a band pass filter (11) and a trap circuit (12) for extracting color and brightness signals from TV video signal, three demodulators (13)(14)(15) for extracting RGB signals from the color signal, a matrix circuit (1) for selecting the RGB signal and external color signal alternatively and for producing difference signals, a compositor (4) for producing color signal form the difference signals, balanced modulator (3) for producing composite video signal by combining the color signal and brightness signal.

Description

RGB signal processing circuit

1 is a conventional RGB signal processing circuit.

2 shows an embodiment of an RGB signal processing circuit according to the present invention.

＊ Explanation of symbols on main parts of drawing

1, 15, 16, 17, 18: matrix 2, 3: color difference signal balance modulator

4, 6, 8: synthesizer 5, 11: bandpass filter

7: color carrier generation unit 9: delay circuit

10: D / A converter 12: color trap circuit

13, 14: color demodulation circuit 19: control unit

SW _{1 to} SW ₅ : switch

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double-field digital TV. In particular, the R ', G', and B 'signals from the outside are mixed with an RGB signal made from a composite video signal processed by an IF unit, which is an internal TV signal, and then mixed again. The present invention relates to an RGB signal processing circuit that allows an external RGB input to be mixed with a TV internal signal and displayed by A / D processing.

As can be seen in FIG. 1, the conventional double-field digital TV receives an RGB input signal, a sync signal, and a blanking signal BL to generate an external input terminal B and generate an external input terminal B. In the matrix (1) for generating the color difference signal (BY), (RY) and the luminance signal (Y) from the RGB signal coming from the color carrier, the color carrier generation unit (7) for generating the color subcarrier, and the color carrier generation (7) The color difference signal balance modulator 2 which balances the color difference signal BY by the generated carriers, and the carriers generated by the color carrier generation unit 7 are phase-inverted by 90 ° and -90 ° in every horizontal line. A color signal C by synthesizing the color difference signal balance modulator 3 for balancing the color difference signal RY and the color difference signals BY and RY balanced by the color difference signal balance modulators 2 and 3. And a color signal C from which harmonics components of the color signal C from the synthesizer 4 are removed. A synthesizer which combines the color bandpass filter 5 generating ') and the luminance signal Y from the matrix 1 and the synchronization signal Sync of the external terminal B to produce the synchronization signal and the included luminance signal. (8), a delay circuit 9 for compensating the delay of the color signal C passing through the color band pass filter 5, and a color signal C and a delay passed through the color band pass filter 5; A synthesizer 6 for synthesizing the luminance signal Y passed through the circuit to form a composite video signal CVBS ', an IF unit A for extracting the composite video signal CVBS from the signals from the antenna and the tuner, A switch for outputting the composite video signal CVBS 'coming from the synthesizer 6 or the composite video signal CVBS coming from the IF unit A according to the blanking signal BL from the external input terminal B; SW ₁ ) and an A / D converter 10 for converting the composite video signal output from the switch SW ₁ from analog to digital.

The operation of the conventional circuit having the above-described configuration will be described below.

In the external input mode, when the RGB signal and the synchronization signal Sync enter the external input terminal B, the blanking cancel signal BL is maintained at a high level.

The matrix 1 receives RGB signals from an external input terminal and combines them to form color difference signals BY, RY and luminance signals Y, and then the color difference signals BY, RY and luminance signals Y. Are supplied to the chrominance signal balance modulators 2 and 3 and the synthesizer 8, respectively.

The color difference signal balance modulator 2 balances and modulates the color difference signal BY, which is a basic band, as a color carrier coming from the color carrier generation unit 7, and outputs a color difference modulation signal B'-Y. The modulator 3 phase shifts the color carriers coming from the color carrier generation unit 7 at 90 ° and -90 ° in every horizontal line, and modulates the color difference signal RY to balance the color difference modulated signal R'-Y. Outputs

The color difference modulation signals B'-Y and R'-Y are combined in the synthesizer 4 to form a color signal C, and then pass through the color band pass filter 5 to remove the color signal C '. )

The synthesizer 8 receives the sync signal Y from the matrix 1 and the sync signal Sync from the external input terminal B, synthesizes them, and converts them into a brightness signal having the sync signal. It is supplied to the synthesizer 6. The delay circuit 9 compensates for the delay of the color signal C through the color band pass filter 5.

The synthesizer 6 receives the delayed luminance signal and the color signal C 'from which the harmonic components are removed and synthesizes the synthesized image signal CVBS'.

As a result, the RGB signal input through the external input terminal B is converted into the composite video signal CVBS '.

Since the blanking signal BL is maintained at a high level while the RGB signal and the synchronization signal Sync are input to the external input terminal B, the switch SW ₁ outputs the composite video signal CVBS ', and A / In the D converter 10, the input composite video signal CVBS 'is converted from analog to digital and then displayed.

On the other hand, when the external input mode, that is, in the internal composite video signal (CVBS) processing mode, since the blanking signal BL coming from the external input terminal B is low, the internal composite video signal CVBS coming from the IF (A) is low. ) Is input to the A / D converter 10 through the switch SW ₁ and then digitally converted and then displayed.

As described above, in the above configuration, the composite video signal processed from the external R ', G', and B 'signals and the composite video signal of the IF unit, which is an internal signal of the TV, are displayed separately so that the R', G ', The signal B 'was not mixed with the composite video signal processed by the IF unit.

Accordingly, the present invention has been made to solve the above-mentioned problems, and the present invention is to mix the RGB signal made from the TV internal signal and the R'G'B 'signal input from the outside to make it into a composite video signal again. It is an object to provide an RGB signal processing circuit which can be processed.

Technical means for achieving the above object of the present invention, by receiving the RGB signal from the external input terminal, the balance modulation after color difference processing, and the color difference signal through the combining means, the delay means, the BPF means and the first switching means A / D A color BPF for extracting a color signal from a composite video signal from an IF processor in an external RGB signal processing circuit displayed after conversion; a color trap circuit for removing a color signal from a complex video signal from the IF processor and extracting a luminance signal; Second color demodulation means for receiving a color signal from the color BPF to produce a color difference signal, second matrix means for generating a third color difference signal by the color demodulation means, from the second matrix means and the external input terminal; A second switching means for switching operation to supply an R'G'B 'signal to the matrix, and a control unit for controlling the operation of the first switching means. As it characterized by the one to be displayed by mixing the R'G'B 'signal from the RGB signal and the external input terminal of the IF processor.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

A first matrix 1 for generating first and second color difference signals and a luminance signal from an R'G'B 'signal from an external input terminal B, a color subcarrier generation unit 7 for generating a color subcarrier, A first color difference signal balance modulator 2 for balancing the first color difference signal by a carrier generated in the color carrier generation unit 7 and a carrier generated in the color carrier generation unit 7 every horizontal line A second color difference signal balance modulator (3) that balances the second color difference signal by inverting the phase at 90 ° and -90 °, and the balance modulated by the first and second color difference signal balance modulators (2) (3). A first synthesizer (4) for receiving the color difference signals and synthesizing them to produce a color signal, a color band pass filter (5) for generating a signal from which harmonic components of the color signal from the first synthesizer (1) are removed, and the first synthesizer (4) The luminance signal received from the matrix 1 and the synchronization signal of the external input terminal B is received. A second synthesizer 8 for generating a signal, a delay circuit 9 for compensating for the delay as the color signal passes through the color bandpass filter 5, and a color signal from the color bandpass filter 5; And a third synthesizer 6 which receives the luminance signals of the delay circuit 9 and synthesizes them to form a composite video signal, an IF unit A which extracts a composite video signal from signals input through an antenna and a tuner, 3 the composite video signal coming from a synthesizer (6) or to the first switch (SW _1), a first said switch (SW ₁₎ of the composite image sinhojung switching operation to pass either a signal coming from the IF section (a) An A / D converter (10) connected to convert a composite video signal from analog to digital, a color band pass (11) for extracting a color signal from the composite video signal from the IF unit (A), and The luminance signal is removed by removing the color signal from the composite video signal from the IF unit A. A color trap circuit 12 for extracting an arc, a first color demodulation circuit 13 for receiving a color signal from the color band pass filter 11 and generating a third color difference signal, and the color band pass filter 11 A second color demodulation circuit 14 that receives a color signal from the second color demodulation circuit 14 and generates a fifth color difference signal by receiving the third and fourth color difference signals from the color demodulation circuits 13 and 14. A second matrix 15, a third matrix 16 for receiving a third color difference signal from the first color demodulation circuit 13 and a luminance signal from the color trap circuit 12, and producing a B signal; A fourth matrix 18 that receives a fourth color difference signal from the two-color demodulation circuit 14 and the luminance signal from the color trap circuit 12 to form a G signal, and a fifth from the second matrix 15; A fifth matrix 17 that receives the color difference signal and the luminance signal from the color trap circuitry to form an R signal, and the third to fifth matrixes 16 to 1; The retrace-clear signal BL coming from the external input terminal B to supply an RGB signal from 8) or an R'G'B 'signal from the external input terminal to the first matrix 1; The _second synthesizer switches any one of the second to fourth switches SW _{2 to} SW ₄ and the luminance signal of the color trap circuit 12 or the synchronization signal of the external input terminal B. consists of the fifth switch (SW ₅₎ and a control unit 19 for controlling the switching operation of the first and the fifth switch (SW _1), (SW ₅₎ for switching operation to the supply (8).

Hereinafter, the operation of the present invention will be described in detail with reference to the accompanying drawings.

In the case of the external input mode in FIG. 2, when the R'G'B 'signal and the synchronization signal Sync enter the external input terminal B, the blanking cancel signal BL is maintained at a high level.

Accordingly, the displayed signal, that is, the signal input to the A / D converter 10 is an R'G'B 'signal coming from the external input terminal B.

Accordingly, the second, third and fourth switches SW ₂ , SW ₃ , and SW ₄ select the external input signal R'G'B '.

The signal R "G" B "selected by the second, third and fourth switches SW ₂ , SW ₃ , and SW ₄ is supplied to the first matrix 1, and the first matrix The first matrix 1 is formed of the color difference signals B "-Y, (R" -Y) and the luminance signal Y 'of the selection signals R ", G", and B ", and the first color difference signal equilibrium is respectively obtained. To the modulator (2), the second color difference signal balance modulator (3), and the second synthesizer (8).

The first color difference signal balance modulator 2 balances the first color difference signal B ″ -Y by color carriers from the color carrier generation unit 7, and the second color difference signal balance modulator 3 The second color difference signal R " -Y is balanced by modulating the color carriers generated by the color carrier generation unit 7 by inverting the phases alternately by 90 degrees and -90 degrees every horizontal line.

The signals modulated by the first and second chrominance signal balance modulators 2 and 3, respectively, are synthesized in the first synthesizer 4 to form a color signal C 'and then go to the color bandpass filter 5 to harmonic. It is a signal from which components are removed.

The second synthesizer 8 has a luminance signal Y from the first matrix 1 and a synchronization signal Sync from an external input terminal B selected by the fifth switch SW ₅ by the controller 19. ) Is synthesized, the luminance first signal having the synchronization signal is produced, and supplied to the third synthesizer 6 via the delay circuit 9.

Then, the third synthesizer 6 receives the delayed luminance signal and the color signal C 'from which the harmonic components are removed and synthesizes the synthesized image signal CVBS'. Since the control unit 19 maintains the high level, the switch SW ₁ passes the composite video signal CVBS 'to the A / D converter 10.

As a result, only the R'G'B 'signal coming through the external input terminal B is applied to the A / D converter 10 and then digitally converted and displayed.

Now, the case in which the external input signal R'G'B 'coming from the external input terminal B is mixed with the output signal CVBS of the IF unit A, which is an internal TV signal, is displayed on the screen.

The blanking clear signal BL coming from the external input terminal B becomes a high level state only when there is an R'G'B 'signal, and is a signal that is quickly switched to a low level when there is no R'G'B' signal. This is a signal that repeats "high" or "low" many times depending on the presence or absence of the R'G'B 'signal in the horizontal line.

First, the composite video signal CVBS, which is an internal TV signal, is output from the IF unit A and then input to the color band pass filter 11 and the color trap circuit 12. The signal output through the color band pass filter 11 is only the color signal C, and on the contrary, the signal output through the color trap circuit 12 is the luminance signal Y. The color signal C, which is an output signal of the color band pass filter 11, is input to the first and second color demodulation circuits 13 and 14 to be changed into color difference signals B-Y and R-Y, respectively.

The first and second color demodulation circuits 13 and 14 generate a color difference signal G-Y in the second matrix 15. These color difference signals BY, RY, and GY are supplied to the third to fifth matrices 16, 17, 18, which are corresponding matrices, together with the luminance signal Y of the color trap circuit 12, respectively. do.

In addition, the third to fifth matrices 16, 17, and 18 are connected to the corresponding second to third switches SW ₂ , SW ₃ , and SW _4, respectively, so that the color signal C and the luminance are the same. A mixed signal of the signal Y is received.

In this case, the second to fourth switches SW ₂ (SW ₃ ) and SW ₄ are each R'G'B when the R'G'B signal is received from the external input terminal B, so that R 'is the high level. When the G'B signal is output and there is no R'G'B signal from the external input terminal B, the blanking cancellation signal BL is at a low level, so the RGB signal is output.

The signal R "G" B "output from the first to third switches SW ₁ (SW ₂ ) and SW ₃ is supplied to the first matrix 1.

The following operations are the same as described above. However, since the fifth switch SW ₅ is at a high level, the synchronization signal Sync is output from the external terminal B, and the first switch SW ₁ is also in a high state. The video signal CVBS 'is outputted.

Here, the composite video signal CVBS 'is obtained by mixing an R'G'B' signal input through an external input terminal B with an RGB signal generated from the composite video signal CVBS which is an output of the IF unit A. It is a signal.

Therefore, the mixed signal obtained by mixing the RGB signal made from the composite video signal CVBS which is the TV internal signal and the R'G'B 'signal input from the external input terminal B through the first switch SW ₁ is A / D. It is input to the transducer 10 and is displayed after being digitally processed.

When not in the external input mode, i.e., in the internal signal processing mode, the signal of the control unit 9 is at a low level, and in the fifth switch SW ₅ , the composite video signal CVBS, which is the output of the IF unit A, is output. It is input to the A / D converter 10. Therefore, at this time, the internal composite video signal CVBS is input to the A / D converter 10 and is displayed after being digitally processed.

As described above, in the circuit according to the present invention, in a double-field digital TV, an analog signal before A / D processing, that is, an RGB signal made from a 50Hz TV internal signal and an R'G'B 'signal of an external input of 50Hz After the mixer, A / D treatment was performed to allow 100 Hz scanning.

Claims (4)

In an external RGB signal processing circuit which receives an RGB signal from an external input terminal and balances it after color difference processing, and displays the color difference signal after A / D conversion through a combining means, a delay means, a BPF means, and a first switching means. A color BPF 11 for extracting a color signal from the composite video signal from the processing unit A, a color trap circuit 12 for removing a color signal from the composite video signal from the IF processing unit and extracting a luminance signal; Second color demodulation means for receiving a color signal from a color BPF to produce a second color difference signal, matrix means for generating a third color difference signal by said second color demodulation means, and R 'from said matrix means and said external input terminal; And a second switching means for switching operation to supply a G'B 'signal to the matrix (1), and a control portion (9) for controlling the operation of the first switching means. 2. The first color demodulation circuit according to claim 1, wherein said second color demodulation means receives a color signal from said color BPF (11) and produces a BY signal, and a second color demodulation circuit (14) produces an RY signal. Circuit characterized in that consisting of. 3. The matrix circuit according to claim 1 or 2, wherein the matrix means receives a signal from the second color demodulation means and generates a GY signal, and a third matrix circuit receives the BY signal and generates a B signal. And a fifth matrix circuit (17) for receiving the RY signal and producing an R signal, and a fourth matrix circuit (18) for receiving the GY signal and producing a G signal. The circuit according to claim 1, further comprising a third switching means for switching the luminance signal from the color trap circuit (12) and the synchronization signal from the external input terminal (B) to supply to the combining means.