KR930011973B1 - Chroma signal compensation apparatus - Google Patents

Abstract

The circuit consists of an IF detector which amplifies the sensitivity and selectivity from an image IF signal, a BPF which bandpasses the color signal from the amplified image signal, a video processor which detects the IF detector output and outputs brightness signal, a chroma processor which detects the BPF output and outputs color difference signal, a matrix part which combines the brightness signal and color difference signal to output original signal, a buffer which buffers and amplifies the color signal of the BPF, a color compensation part which detects and low pass filters the phase of the color signal to output color compensated signal, and a CRT driver which output the color compensated image signal to CRT.

Description

Color correction circuit of video signal receiver

1 is a conventional circuit diagram.

2 is a circuit diagram of the present invention.

3 is a detailed view of the CRT drive unit 40 in FIG.

* Explanation of symbols for main parts of the drawings

20: matrix portion 30: color correction portion

40: CRT drive section

The present invention relates to a color correction circuit of an image signal receiving apparatus, and more particularly, to a color correction circuit of an image signal receiving apparatus capable of automatically correcting color by detecting color characteristics of a received color image signal.

In general, the color (Tint) of the color image signal is a very sensitive part of the human visual characteristics, and the color level may be different from the original signal level due to noise of the transmission process and the reception process.

Therefore, for example, if the color level of the original signal is red, this is adjusted through the color correction stage in order to prevent the screen from appearing in orange, which is shown in FIG.

1 is a conventional color correction circuit diagram. An IF detector 1 for amplifying sensitivity and selectivity by inputting an image intermediate frequency signal applied from a tuner to an input terminal TN, and the IF detector 1 The Y / C processing unit 2 for detecting the output of the input signal and outputting the luminance signal and the chrominance signal, and inputs the luminance signal and the chrominance signal of the Y / C processing unit 2 to the original image on the CRT 4. It consists of the CRT drive part 3 which applies a signal.

Briefly describing the prior art based on the structure of the conventional color correction circuit described above, the luminance signal (-Y) is output to the output terminal A of the Y / C processing unit 2 and the color difference signal to the output terminal (B). (RY, GY, BY) are output, respectively. If color degradation occurs on the CRT 4, the color signals are corrected by adjusting the variable resistors VR1 and VR2 of the Y / C processing unit 2. Of course, at this time, the user manually adjusted by judgment.

That is, the variable resistor VR1 is a color correction stage, and the variable resistor VR2 is a color correction stage.

Therefore, the color is instantaneously corrected by the variable resistors VR1 and VR2, but there is a problem because it is always necessary to adjust it whenever the electric field strength of the received signal changes.

In addition, the disadvantage of not being able to watch the screen in the optimal color naturally occurs.

Therefore, in the prior art, color correction was manually performed by a variable resistor, which caused troublesome deterioration of image quality and user's use.

Accordingly, an object of the present invention is to provide a color correction circuit of an image signal receiving apparatus capable of automatically correcting color by detecting color characteristics of a received color image signal in view of the above problems.

Another object of the present invention is to provide a color correction circuit of a video signal receiving apparatus which can reduce the user's trouble and can watch an optimum picture quality.

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

2 is a circuit diagram of the present invention, an IF detector 10 for amplifying and outputting sensitivity and selectivity by inputting an image intermediate frequency signal applied from a tuner to an input terminal TN, and an amplified image of the IF detector 10. BPF 12 for inputting a signal and band-passing the color signal, a video processor 14 for detecting the output of the IF detector 10 and outputting a luminance signal, and detecting the output of the BPF 12. A chroma processor 18 for outputting a color difference signal, a matrix unit 20 for synthesizing luminance signals and color difference signals of the video processor 14 and the chroma processor 18, and outputting a primary color signal, and the BPF A buffer 16 for input buffering, amplifying and outputting the color signal of (12), a color correction unit 30 for outputting a corrected color signal by phase detection and low pass filtering of the amplified color signal of the buffer 16, and the matrix unit 20, primary color A correction color signal input of the output and the color correction section 30, synthesis consists of a CRT drive unit 40 for outputting the video signal to compensate color CRT (50).

FIG. 3 is a detailed diagram of the CRT drive unit 40 of the second diagram, and includes voltage application resistors R1, R2, and R3 connected to primary color signal output terminals R, G, and B of the matrix unit 20, respectively. Driving transistors (TR1, TR2, TR3) for outputting a color-compensated image signal to the CRT (50) to the collector, respectively, the bases of which are connected to the resistors (R1, R2, R3) and the color correcting unit; A voltage application resistor (R4, R5, R6) connected to the corrected color signal output terminals (R ', G', B ') of (30), and a respective base is connected to the resistors (R4, R5, R6); Collector is connected to the emitters of the driving transistors TR1, TR2, and TR3, respectively, and the signal applying transistors TR4, TR5, TR6 for synthesizing the primary color signal and the corrected color signal, and the driving transistors T R1, TR2. And current limiting resistors R7, R8, and R9 respectively connected to the emitter of TR3.

Hereinafter, the present invention will be described in detail with reference to FIGS. 2 and 3 based on the above-described configuration. By combining with the signal, you get a compensated color.

In FIG. 2, an image signal input from a tuner is input to the IF detector 10 and becomes an image signal of which a sensitivity and selectivity are amplified and output, which are output to the BPF 12 and the video processor 14, respectively. do.

The video signal input to the video processor 14 is output only to the output terminal A of the luminance signal (-Y) of the components of the composite video signal, the video signal input to the BPF 12 is a Only color signals of the components are output and input to the buffer 16 and the chroma processor 18, respectively.

The color signal input to the buffer 16 is input to the color corrector 30 after buffering, and the color signal input to the chroma processor 18 is synthesized and detected to output RY, GY and BY signals, which are color difference signals. Is output as (B).

The matrix unit 20 combines the -Y signal, which is the output luminance signal of the video processor 14, and RY, GY, BY, which are the output color difference signals of the chroma processor 18, to form the R, G, B color signals, which are the primary color signals. Outputs something like this:

That is, the signal R is R-Y-(-Y) = R, the signal G is G-Y-(-Y) = G, and the signal B is B-Y-(-Y) = B.

On the other hand, the color signal inputted to the color corrector 30 is outputted by the first phase detector 30a and the first low pass filter 30d, R ′, which is a corrected color signal, and the second phase detector 30b and The second low-pass filter 30e outputs the corrected color signal G ', and the third phase detector 30c and the third low-pass filter 30f output the corrected color signal B' to output the CRT drive unit 40. ) Is entered.

Since the corrected color signals of R ', G', and B 'are low-pass filtered by the low pass filter after the color feature signals of the color carrier reference phase contrast characteristics are detected, they have a DC level voltage.

That is, the corrected color signals of R ', G', and B 'are DC levels of color components to be compensated for.

Therefore, the CRT drive unit 40 outputs the color-compensated image signal to the CRT 50 by combining the R, G, and B signals, which are the primary color signals, and the R, G, and B signals, which are the corrected color signals, respectively. do.

Referring to FIG. 3 for the detailed description of the CRT drive unit 40, the R, G, B signals are input to the base of the driving transistors TR1, TR2, TR3 and output to the collector. Since the collector outputs of the signal applying transistors TR4, TR5 and TR6 are connected to the respective emitters of the driving transistors TR1, TR2 and TR3, the collectors of the driving transistors TR1, TR2 and TR3 compensate for the color. The video signal level is automatically adjusted and output according to the input.

Therefore, the user can watch the color-compensated video signal automatically on the screen of the CRT 50 without the user's color adjustment.

As described above, the present invention has the advantage of automatically correcting the color by detecting the color characteristics of the received color image signal, thereby eliminating user's hassle and viewing the optimal image.

Claims (2)

In the color correction circuit of the image signal receiving apparatus, an IF detector 10 for amplifying and outputting sensitivity and selectivity by inputting an image intermediate frequency signal applied from a tuner to an input terminal TN, and amplifying the IF detector 10. The BPF 12 for band-passing the color signal by inputting the video signal, the video processor 14 for detecting the output of the IF detector 10 and outputting the luminance signal, and the output of the BPF 12. A chroma processor 18 for synthesizing detection and outputting a color difference signal, a matrix unit 20 for synthesizing luminance signals and color difference signals of the video processor 14 and the chroma processor 18, and outputting a primary color signal; A buffer 16 for input buffering, amplifying and outputting the color signal of the BPF 12, a color correction unit 30 for outputting a corrected color signal by phase detection and region filtering the amplified color signal of the buffer 16, and matrix Color correction, characterized in that consisting of the CRT drive unit 40 for outputting the color-compensated image signal to the CRT (50) by combining the primary color signal output of the unit 20 and the corrected color signal of the color correction unit 30 Circuit. The voltage applying resistor (R1, R2, R3) of the CRT drive unit 40 is connected to the primary color signal output terminals (R, G, B) of the matrix unit (20), and the resistance ( The driving transistors TR1, TR2, and TR3 connected to respective bases of R1, R2, and R3 to output the color-compensated image signal to the CRT 50 to the collector, and the color correcting unit 30. Voltage-applying resistors R4, R5, and R6 connected to the corrected color signal output terminals R ', G', and B ', respectively, and bases connected to the resistors R4, R5, and R6, respectively, and the driving transistors TR1, Collectors of emitters of TR2 and TR3 are connected to each other so that the signal applying transistors TR4, TR5 and TR6 for synthesizing the primary color signal and the corrected color signal, and the emitters of the driving transistors TR1, TR2 and TR3. And a current limiting resistor (R7, R8, R9) respectively connected to the color correction circuit of the image signal receiving apparatus.

Images