KR100807476B1 - Apparatus and method for preventing cross color effect - Google Patents

Abstract

The present invention relates to a color interference prevention device and method for preventing color interference that may appear in an image when displaying a black and white image in a broadcast receiver.

The apparatus and method for preventing color interference according to the present invention calculates a probability value that an input composite video signal is a black and white signal in order to prevent color interference from occurring when displaying a black and white image in a broadcast receiver. The color difference signal of the composite video signal is reduced according to the calculated probability value to reduce color interference and to restore the original black and white image as much as possible.

Black-and-white image, color interference, luminance signal, chrominance signal

Description

Apparatus and method for preventing cross color effect}

1 is a block diagram showing a configuration of a luminance / color difference signal separation circuit of a broadcast receiver;

2 is a block diagram showing a configuration of a color interference preventing apparatus according to the present invention;

3 is a flowchart illustrating a method of preventing color interference according to the present invention.

4A and 4B show a black and white image in a broadcast receiver.

* Explanation of symbols for main parts of the drawings

200: color interference prevention device 202: black and white estimating unit

204: color difference signal attenuator

The present invention relates to a color interference preventing device and method for preventing color interference that may appear when displaying a black and white image in a broadcast receiver.

The composite video signal modulation method of the broadcast receiver is divided into NTSC (National Television System Committee) method, PAL (Phase Alternation by Line) method, SECAM (Sequential Couleur a Memorie) method according to the modulation method for transmitting the luminance signal and the chrominance signal. .

For example, the NTSC composite video signal modulation method modulates a sub-carrier having a frequency of 3.58 MHz in a video band using two color difference signals. In addition, the modulated color difference signal is added to the luminance signal in a frequency-integrated manner to generate a composite signal, and the generated composite signal is modulated and transmitted to a carrier having a higher frequency.

The broadcast receiver receives the composite video signal modulated as described above, divides the color image signal into a color difference signal and a luminance signal, and implements an image on the screen.

At this time, when the broadcast receiver fails to completely separate the chrominance component and the luminance component from the received composite video signal, there is a cross luminance phenomenon caused by various dot interference phenomenon or a cross color phenomenon caused by color spreading phenomenon. To prevent the original image from being properly restored. As a result, a problem occurs that the quality of the broadcast video is degraded.

Accordingly, an object of the present invention is to provide an apparatus and method for preventing color interference which can prevent color interference that may appear when displaying a black and white image in a broadcast receiver.

In order to achieve the above object, the apparatus for preventing color interference according to the present invention comprises: a black and white estimator for calculating a probability value of the complex video signal as a black and white signal based on magnitude values of the luminance signal and the color difference signal separated from the complex video signal; And a chrominance signal attenuator for reducing the chrominance signal size of the composite video signal according to the probability value of the monochrome signal calculated by the monochrome estimator.

According to an aspect of the present invention, there is provided a method of preventing color interference, the method comprising: calculating a probability value of a composite image signal as a black and white signal based on magnitudes of luminance signals and color difference signals separated from the composite image signal; And reducing the chrominance signal magnitude of the composite video signal according to the calculated probability value.

Here, the calculation of the probability value that the composite video signal is a black and white signal may include presetting color difference signal magnitude values of at least one or more previously input composite video signals, and magnitude values of luminance signals and color difference signals of the currently input composite video signal. Computing a probability value that the current composite video signal is a black and white signal compared to the set reference values.

In addition, reducing the color difference signal size of the composite video signal maintains the color difference signal size of the composite video signal when the calculated probability value is 0, and the calculated probability value converts the composite video signal into a monochrome signal. When the value corresponds to a probable probability value, the color difference signal magnitude of the composite video signal is reduced to zero.

If the calculated probability value is greater than 0 but does not correspond to a probability value that can be determined as a black and white signal, the magnitude of the color difference signal of the composite video signal is inversely reduced according to the calculated probability value. It is done.

Hereinafter, with reference to the accompanying drawings will be described the present invention in more detail. However, in describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

1 is a block diagram showing a configuration of a luminance / color difference signal separation circuit of a broadcast receiver.

The luminance / color difference signal separation circuit 100 shown in FIG. 1 is a delay circuit unit which is used by the broadcast receiver to separate the received composite video signal YC into the luminance signal Y and the color difference signal C. 102, the first subtraction unit 104, the amplifier 106, the band pass filter 108, and the second subtraction unit 110.

The luminance / color difference signal separation circuit 100 configured as described above filters the received composite image signal YC in the spatial axis direction to separate and output the color difference signal C and the luminance signal Y. Filter function.

The operation of the luminance / color difference signal separation circuit 100 will be described in more detail as follows.

First, the delay circuit unit 102 delays the received composite video signal YC by the time required to scan the horizontal line.

The first subtraction unit 104 subtracts and outputs the current composite image signal YC input from the composite image signal delayed by one horizontal scan line through the delay circuit unit 102. In this case, the component of the luminance signal Y is attenuated and the color difference signal C is output from the composite video signal output from the first subtractor 104.

The color difference signal C is input to the amplifier 103 and the color difference signal C amplified by the amplifier 106 is input to a band pass filter 108 (hereinafter referred to as a BPF) 108. The color difference signal C in the 3.58 MHz band is filtered.

The second subtractor 110 receives the color difference signal C having the 3.58 MHz band and the current composite image signal YC input from the outside, and subtracts the color difference signal C from the received composite image signal YC. Only the luminance signal Y is output.

Accordingly, the luminance / color difference signal separation circuit 100 shown in the figure separates the color difference signal C and the luminance signal Y by using a composite image signal phase inversion phenomenon between two consecutive horizontal scanning lines.

When the luminance signal (Y) and the color difference signal (C) cannot be completely separated in the luminance / color difference signal separation circuit 100 performing the above operation, color interference appears as a color spread phenomenon in the black and white image. Causes the problem to occur.

2 is a block diagram showing the configuration of the color interference prevention apparatus according to the present invention. As shown in the drawing, the color interference prevention apparatus 200 includes a black and white estimator 202 and a color difference signal attenuator 204.

The color interference prevention apparatus 200 is connected to the output terminal of the luminance / color difference signal separation circuit 100 as shown in FIG. 1 and the luminance signal Y and the color difference of the image output from the luminance / color difference signal separation circuit 100 are shown. Receive a signal (C). Then, the probability value of the complex image signal YC is a black and white signal based on the two received signals Y and C, and the magnitude of the color difference signal C is controlled so that color interference does not occur according to the calculated probability value. Characterized in that.

The black-and-white estimator 202 receives the luminance signal Y and the color difference signal C output from the luminance / color difference signal separation circuit 100, and the magnitudes of the received luminance signal Y and the color difference signal C are received. The value is calculated to calculate a probability value BW_Val in which the composite video signal YC is a black and white signal.

In order to calculate the probability value BW_Val in which the complex video signal YC is a black and white signal, the black and white estimator 202 includes the first reference values Y_B1 and C_B1 and the first reference value for each of the luminance signal Y and the color difference signal C. 2 reference values Y_B2 and C_B2 are set in advance.

Here, the first reference value Y_B1 for the luminance signal Y may represent a magnitude value of the luminance signal Y that is black enough, and the second reference value Y_B2 for the luminance signal Y may represent white. The magnitude | size of the luminance signal Y of the magnitude | size enough.

In addition, the first reference value C_B1 for the color difference signal C is a color difference signal C size value that cannot be detected blue and red with the naked eye, and the second reference value C_B2 for the color difference signal C is The color difference signal C may have a magnitude value capable of detecting blue and red color with the naked eye, and the first reference value C_B1 and the second reference value C_B2 for the color difference signal may have a small difference.

The black-and-white estimator 202 compares the magnitude values of the luminance signal Y and the color difference signal C of the input image with the preset reference values Y_B1, Y_B2, C_B1, and C_B2. When (C) has a signal magnitude value equal to or greater than the second reference value C_B2 for a predetermined number of consecutive times, the probability value BW_Val of the composite video signal YC being a monochrome signal is set to zero.

As a result of the comparison, the luminance signal Y has a signal magnitude value indicating black or white, that is, the luminance signal Y has a signal magnitude value less than or equal to the first reference value Y_B1 or a signal greater than or equal to the second reference value Y_B2. With the magnitude value, the color difference signal C increases the probability value BW_Val when the composite video signal YC is a monochrome signal when the magnitude difference signal C has a signal magnitude value less than or equal to the first reference value C_B1.

As a result of the comparison, when the color difference signal C has a signal magnitude value greater than the first reference value C_B1 and smaller than the second reference value C_B2, the monochrome image estimator 202 has a composite image signal YC. If the probability value BW_Val is a black and white signal, and the probability value BW_Val is 0, the probability value BW_Val is zero without further decreasing the value.

The black-and-white estimator 202 thus measures the color difference signal C magnitude values of at least one or more previously input composite image signal YC, and the luminance signal Y and the color difference signal (C) of the current composite image signal YC. C) The probability value BW_Val of calculating the probability that the composite video signal YC is a black and white signal is compared with the reference values Y_B1, Y_B2, C_B1 and C_B2.

The color difference signal attenuator 204 reduces the color difference signal magnitude of the composite image signal YC according to a probability value BW_Val in which the composite image signal YC calculated by the monochrome estimation unit 202 is a monochrome signal.

Accordingly, the color difference signal attenuator 204 checks the probability value BW_Val in which the composite image signal YC calculated by the black and white estimator 202 is a black and white signal, and determines the probability value of the black and white signal. If applicable, the color difference signal magnitude of the composite video signal YC is reduced to zero.

In addition, the color difference signal attenuator 204 has a probability value BW_Val when the composite video signal YC is a black and white signal, but the probability value BW_Val is greater than 0 but does not correspond to a probability value that can be determined as a black and white signal. ), The magnitude of the color difference signal C of the composite video signal YC is inversely reduced.

When the probability value BW_Val of the composite video signal YC is a black and white signal, when the probability value BW_Val is 0, the color difference signal attenuator 204 maintains the color difference signal C of the composite video signal YC without decreasing the normal color. Allow the image to be displayed.

3 is a flowchart illustrating a method of preventing color interference according to the present invention.

According to the present invention, the broadcast receiver separates the received broadcast composite video signal (YC) into a luminance signal (Y) and a color difference signal (C), and the magnitude values of the separated luminance signal (Y) and the color difference signal (C). The probability value BW_Val of the complex video signal YC as a black and white signal is calculated through S300.

Here, when calculating the probability value BW_Val where the composite video signal YC is a black and white signal, the broadcast receiver calculates the color difference signal C of at least one or more previous composite video signals YC.

Accordingly, the broadcast receiver may predetermine magnitude values of at least one previous composite image signal YC together with luminance values Y and color difference signals C of the composite image signal YC currently received. Compare the set reference values (Y_B1, Y_B2, C_B1, C_B2). Based on the comparison result, the probability value BW_Val of the current composite video signal YC is a black and white signal. Here, the preset reference values Y_B1, Y_B2, C_B1, and C_B2 are the same as already mentioned in the description of FIG.

As a result of the comparison, when the color difference signal C has a signal magnitude value greater than or equal to the second reference value C_B2 for a predetermined number or more consecutive times, the broadcast receiver sets the probability value BW_Val as 0 to the monochrome video signal YC. .

As a result of the comparison, the luminance signal Y of the current composite video signal YC has a signal magnitude value indicating black or white, that is, the luminance signal Y has a signal magnitude value less than or equal to the first reference value Y_B1, or When the color difference signal C has a signal magnitude greater than or equal to the second reference value Y_B2 and the color difference signal C has a signal magnitude less than or equal to the first reference value C_B1, the probability value BW_Val of the composite image signal YC is a black and white signal. Let's do it.

As a result of the comparison, when the color difference signal C has a signal magnitude value greater than the first reference value C_B1 and smaller than the second reference value C_B2 continuously for a predetermined number of times or more, the probability value of the composite image signal YC is a monochrome signal ( BW_Val is decreased, and when the probability value BW_Val is 0, the probability value BW_Val is set to 0 without further decreasing the value.

The broadcast receiver calculates a probability value that the composite video signal YC is a black and white signal according to the above-mentioned method, and when the calculated probability value BW_Val is 0, the color difference signal C of the composite video signal YC. It is maintained as it is without reducing the size (S302, S304).

If the probability value BW_Val of the composite video signal YC is a black and white signal is greater than 0 but does not correspond to a probability value that can be determined as a black and white signal, that is, less than a predetermined value (a), the probability value The color difference signal C of the corresponding composite video signal YC is reduced in proportion to (S306, S308).

When the calculated probability BB_Val of the composite video signal YC is a black and white signal corresponds to a probability value that can determine the complex video signal YC as a black and white signal, that is, the predetermined value (a) or more The color difference signal C of the composite video signal YC is reduced to 0 (S310 and S312).

If the probability value BW_Val of the complex video signal YC is a black and white signal does not correspond to any of the above conditions, the probability value BW_Val of the complex video signal YC is a black and white signal is initialized to 0, and the corresponding complex video signal is The color difference signal magnitude of (YC) is maintained as it is (S314, S316).

The broadcast receiver maintains or changes the color difference signal size of the composite video signal in this way, performs signal processing together with the luminance signal, and displays an image on the screen (S318).

The above process is repeated until the image display is stopped (S320).

4A and 4B are diagrams showing a black and white image in a broadcast receiver. FIG. 4A is an example of a screen displayed when a black and white image is displayed in a broadcast receiver. FIG. 4B is a view illustrating a black and white image in a broadcast receiver. An example of a screen displayed when displaying a black and white image.

As shown in the figure, it can be seen that less color interference occurs in the black and white image of FIG. 4a in FIG. 4b.

Although the present invention has been described in detail with reference to exemplary embodiments above, those skilled in the art to which the present invention pertains can make various modifications to the above-described embodiments without departing from the scope of the present invention. I will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

The present invention calculates a probability value that an input composite video signal is a black and white signal in order to prevent color interference from occurring when displaying a black and white image in a broadcast receiver. The color difference signal of the composite video signal is reduced according to the calculated probability value, thereby reducing the possibility of color interference.

Accordingly, the present invention allows the original black and white image to be reconstructed as much as possible without color interference, thereby improving the image quality of the image.

Claims (4)

A black and white estimator configured to calculate a probability value of the complex video signal as a black and white signal based on magnitude values of the luminance signal and the chrominance signal separated from the complex video signal; And When the probability value calculated by the black and white estimator is 0, the color difference signal size of the composite video signal is maintained as it is, and the calculated probability value corresponds to a probability value that can determine the complex video signal as a black and white signal. When the color difference signal size of the composite video signal is reduced to 0, and the calculated probability value is greater than 0 but does not correspond to a probability value that can be judged as a black and white signal, And a color difference signal attenuator which inversely reduces a color difference signal size of the composite video signal. delete Color difference signal magnitude values of at least one or more previously input composite video signals through magnitude values of the luminance signal and the color difference signal separated from the composite video signal, and magnitude values of the luminance signal and the color difference signal of the currently input composite video signal. Calculating a probability value that the current composite video signal is a black and white signal by comparing the preset reference values; And And reducing a color difference signal size of the composite video signal according to the calculated probability value. Calculating a probability value of the composite video signal as a black and white signal based on magnitude values of the luminance signal and the chrominance signal separated from the composite video signal; And When the calculated probability value is 0, the color difference signal size of the composite video signal is maintained as it is, and when the calculated probability value corresponds to a probability value that can determine the complex video signal as a black and white signal. The color difference signal size of the composite video signal is reduced to 0, and when the calculated probability value is greater than zero but does not correspond to a probability value that can be determined as a black and white signal, the composite image according to the calculated probability value Reducing the chrominance signal magnitude of the signal in inverse proportion.

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