KR100190040B1 - Fake color signal suppression apparatus - Google Patents

Abstract

The false color signal suppressor is started. A false color signal suppression apparatus for removing an image quality deterioration due to a false color signal in an outline portion or a high luminance portion of an input image, the apparatus comprising: a luminance signal generator for generating a luminance signal from an input image signal; A high brightness detector for detecting a high brightness component; A contour signal detector for detecting a contour signal component; A first coefficient conversion unit for converting the signal output from the high luminance detection unit into a color signal suppression coefficient; A second coefficient converter for converting the signal output from the contour signal detector into a color signal suppression coefficient; An upper coefficient selector for comparing the suppression coefficients respectively output from the first coefficient converting unit and the second coefficient converting unit, and selecting a large result among the compared suppression coefficients to set a false color signal suppression coefficient; A color separation unit that separates the luminance signal Y and the color signals Cr and Cb from the input image signal; A color component matrix and a color difference signal generator for generating R-Y and B-Y from Y, Cr, and Cb output from the color separator; And a color component corrector for correcting the color difference signal output from the color component matrix and the color difference signal generator by the false color signal suppression coefficient output from the upper coefficient selector. Accordingly, by providing the natural color by suppressing the false color signal generated in the color signal processing step by the high luminance and contour components, the image quality is improved.

Description

False signal suppressor

1 is a flowchart for correcting a color signal according to a high luminance component of a luminance signal disclosed in US Patent No. 5,181,105.

2 is a block diagram of a color camera signal processor using a single CCD according to the present invention.

3 is a block diagram of a false color signal suppression apparatus according to the present invention.

4A and 4B are characteristic diagrams for generating a high color signal suppression coefficient of a high luminance detector and an edge in each luminance signal.

5 is a characteristic diagram of the relationship between the false color signal suppression coefficient detected and converted by the high luminance and contour components and the color signal correction attenuation rate for the color difference signals of R-Y and B-Y.

6A and 6B show the signal form before and after suppressing the false color signal in the contour portion of the luminance signal.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a false color signal suppression apparatus, and in particular, a false color signal for improving unnaturalness due to a fake color signal generated in a color signal processing process in a contour portion and a very bright portion of a luminance signal in an image signal. It is about a suppressor.

By suppressing the color signal at an appropriate ratio with respect to the contour portion of the luminance signal and the pixel corresponding to the high luminance, the false color signal is eliminated for the natural reproduction of the color.

In the camera signal processing system employing a single CCD for the cause of the false color signal, the signal passed through the low pass filter in color signal separation and color difference signal generation in color signal processing is used as luminance signal. Since the color signal matrix and the color difference signal are generated using this luminance signal, the pixel having the high luminance portion or the contour component exists as a false color signal in which the original color component is emphasized. In addition, due to the structure of the CCD, the presence of a false color signal is intensified by the effects of blooming, smear, interference with adjacent pixels, and the like in the high luminance portion and contour components. This phenomenon occurs in the signal processing system using the composite video signal according to the system, the false color signal is caused by various factors due to the luminance signal.

The color signal suppression technique in the high luminance portion according to the prior art is disclosed in US Patent No. 5, 181, 105, which separates the luminance signal and the chrominance signal for each channel of the color color components R, G, and B, and the high luminance portion of the luminance signal. In this case, the color difference signals of RY and BY are corrected using a ROM table.

1 is a flowchart for correcting a color signal according to a high luminance component of a luminance signal disclosed in US Patent No. 5,181,105.

Referring to FIG. 1, the high luminance component is detected (step 100), and the color difference signal in the high luminance component is corrected (step 102) by the exact amount of the color difference signal.

As described above, the conventional technique has a problem that the color component suppression effect is limited by using a method of controlling the color component corresponding to the high luminance of the luminance signal by the ROM table to remove the false color signal.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to suppress the deterioration of the image quality due to the false color signal in the contour portion or high luminance portion of the image to suppress the natural color signal to obtain a natural image In providing a device.

The false color signal suppressor for achieving the above object is a false color signal suppressor for removing an image quality deterioration due to a false color signal in an outline portion or a high luminance portion of an input image. A luminance signal generation unit for generating a luminance signal at a high luminance detector for detecting a high luminance component from a signal output from the luminance signal generation unit, a contour signal detector for detecting a contour signal component from a signal output from the luminance signal generation unit, and A first coefficient converter for converting a signal output from the high luminance detector into a color signal suppression coefficient, a second coefficient converter for converting a signal output from the contour signal detector into a color signal suppression coefficient, the first coefficient converter and a second coefficient Compare the suppression coefficients respectively output from the converter and set the comparison signal to set the false color suppression coefficients. An upper coefficient selector for selecting a large result among the suppressed suppression coefficients, a color separation unit for separating the luminance signal Y and the color signals Cr and Cb from the input video signal, and RY from Y, Cr, and Cb output from the color separation And correct the color difference signal output from the color component matrix and color difference signal generator, the color component matrix and color difference signal generator, and the color component matrix and color difference signal generator by the false color signal suppression coefficient output from the upper coefficient selector. And a color component corrector.

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

2 is a block diagram of a color camera signal processor using a single CCD according to the present invention.

In FIG. 2, reference numeral 200 is a single CCD, 202 is a Correlative Double Sampling (CDS) unit, 204 is an analog / digital signal conversion unit, 206 is a luminance signal processing unit, and 208 is a color signal processing unit. 210 denotes an encoder and 212 denotes a digital / analog signal converter.

The image signal captured by the single CCD 200 is used as an input of a digital camera signal processor (not shown) via the double correlation sampling unit 202 and the analog / digital signal conversion unit 204. The input of the digital camera signal processor is converted into a video signal according to the broadcast standard by the encoder 210 through the luminance signal processor 206 and the color signal processor 208. The luminance signal processing unit 206 generates the color signal suppression coefficient according to the high luminance and the contour component, and removes the false color signal by having a constant correction attenuation rate of the color component using the color signal suppression coefficient for the color difference component processed by the color signal processing unit 208. Done.

3 is a block diagram of a false color signal suppression apparatus according to the present invention.

In FIG. 3, reference numeral 300 denotes a luminance signal generator, 302 a color separator, 304 a luminance signal processor, 306 a color component matrix and a color difference signal generator, 308 a high luminance detector, and 310 a contour. 312 is a first coefficient converter, 314 is a second coefficient converter, 316 is an upper coefficient selector, and 318 is a color component compensator.

The result obtained by generating the luminance signal once from the camera signal input, converting it into the color signal suppression coefficient by the first coefficient converter 312 using the result obtained from the high luminance detector 308 of the luminance signal, and obtained by the contour signal detector 310 The second coefficient converting unit 314 converts the color signal suppression coefficients by using. The higher coefficient selector 316 compares the high luminance obtained from the first coefficient converting unit 312 and the second coefficient converting unit 314 and the suppression coefficient by the contour signal to select a result having a large suppression coefficient. This is used as data for suppressing false color signals. Selecting a large number from the suppression coefficient between the high luminance and the contour signal effectively suppresses the false color signal according to the shape of the image. In addition, the color separator 302 outputs a Cr signal of the red system, a Cb signal of the blue system, and a luminance signal Y1 for color signal processing. The color separated signal components output the R-Y and B-Y signals through the color signal matrix and the color difference signal generator 306. This color difference signal includes a false color signal component in the previous color signal processing. The color difference signal is corrected in the color component compensator 318 by using the color signal suppression coefficient by the high luminance and contour components of the luminance signal processing unit 304. The color difference component corrected for the false color signal in the color component compensator 318 may obtain an camera signal having improved image quality through an encoder (not shown).

In FIG. 3, the false color signal suppression coefficients for the high luminance and contour components of the luminance signal may be used depending on the system. In other words, even if the suppression coefficient of the false color signal is used by using only one parameter among high luminance and contour components, the effect of improving the false color signal can be obtained. Therefore, when selecting to use either the coefficient of the color signal suppression component of the high luminance component, the coefficient of the color signal suppression component of the contour component, or the suppression coefficient having a larger value among the two suppression coefficients by selection from the outside. User adjustment is possible according to the characteristics of the system.

4A and 4B are characteristic diagrams for generating a high color signal suppression coefficient of a high luminance detector and an edge in each luminance signal.

In Fig. 4A, the horizontal axis represents the magnitude of the luminance signal and the vertical axis represents the magnitude of the false color signal suppression coefficient. In Fig. 4B, the horizontal axis is the luminance contour signal, and the vertical axis is the magnitude of the false color signal suppression coefficient.

A suppression coefficient according to the luminance signal is generated from a portion that is equal to or greater than a certain component with respect to the luminance signal. At this time, the number of bits of the coefficient to be used is determined according to the characteristics of the system. Consider three bits as an example of the present invention. The generation of the high luminance suppression coefficient for this luminance signal is as shown in FIG. 4A. The coefficient is '0' up to a constant level of luminance, and is linearly constant from the reference level (HLref) to the maximum value (Ymax.) Of the luminance. In the case of converting the coefficients from '1' to '7' by dividing the interval, in addition to the linear separation method mentioned above, the luminance signal in the preprocessing step of the gamma signal processing should be divided by the inverse gamma characteristic. 4b is a characteristic diagram for generating a false color signal suppression coefficient by the contour component of the luminance signal. Since the contour component is output in the form of a signal having a sign, it should be generated with the same false signal suppression coefficient for the magnitude of the positive part and the negative part. do. Similar to the false color signal suppression coefficient at high luminance, it has an externally adjustable contour component reference level (EGref) and linearly separates and transforms a section from the reference level to the maximum contour component level (EGmax).

5 is a characteristic diagram of the relationship between the false color signal suppression coefficient detected and converted by the high luminance and contour components and the color signal correction attenuation rate for the color difference signals of R-Y and B-Y.

The color component corrector 318 of FIG. 3 has the characteristic diagram as shown in FIG.

If the false color signal suppression coefficient selected by the high luminance or contour component corresponds to '0', it is regarded as a normal color signal and is directly output without suppressing the color difference signal in a manner that the color signal correction attenuation rate is 0%. When the suppression coefficients correspond to '1' to '3', the color difference processed by the RY and BY color difference signals with correction attenuation of 12.5%, 25% at '4', 62.5% at '5' and 87.5% at '6' Suppresses the signal In addition, when the suppression coefficient is '7', the color component itself is completely removed by outputting '0' at a correction rate that reduces the color difference component to 100%, which is due to the fact that there is almost no color component in the very bright part. This characteristic can also be adjusted according to the system specifications.

6A and 6B show the signal form before and after suppressing the false color signal in the contour portion of the luminance signal.

FIG. 6A shows the unnaturalness of the color components in the contour portion before applying the color signal suppression, and FIG. 6B shows the signal shape after removing the false color signal to remove the phenomenon of FIG. 6A.

The present invention as described above provides the effect of improving the image quality by suppressing the false color signal generated in the color signal processing step by the high luminance and contour components to obtain a natural color.

Claims (2)

A false color signal suppression apparatus for removing an image quality deterioration due to a false color signal in an outline portion or a high luminance portion of an input image, wherein the luminance signal generating unit generates a luminance signal from the input image signal, and the luminance signal. A high brightness detector for detecting a high luminance component from a signal output from a generator, a contour signal detector for detecting a contour signal component from a signal output from the luminance signal generator, and a signal for converting a signal output from the high luminance detector into a color signal suppression coefficient A first coefficient converter, a second coefficient converter for converting the signal output from the contour signal detector into a color signal suppression coefficient, and a suppression coefficient output from the first coefficient converter and the second coefficient converter, respectively, A higher coefficient selector for selecting a larger result of the compared suppression coefficients to set a suppression coefficient, A color separator for separating the luminance signal Y and the color signals Cr and Cb from the output image signal, a color component matrix and a color difference signal generator for generating RY and BY from Y, Cr and Cb output from the color separator, and the color component And a color component correcting unit for correcting the color difference signal output from the matrix and the color difference signal generating unit by the false color signal suppression coefficient output from the upper coefficient selector. The method of claim 1, wherein when the first coefficient converting unit and the second coefficient converting unit allocate n bits, the coefficient is set to '0' to a predetermined level of luminance, and is linear from a predetermined reference level or more to a maximum value. False color suppressor, characterized in that for outputting a suppression coefficient of '1 to 2 ⁿ -1' by dividing a predetermined interval.