KR960012596B1 - Apparatus for compensating chrominance by means of a luminance level - Google Patents

Abstract

a color compensating memory unit(31) for storing the color compensating data depending on different luminance level and generating the color compensating data responding to a color data input; a switching control unit(33) for controlling the color compensating table memory after comparing the luminance input data with reference luminance levels; and a switching unit(35) for outputting the color compensating data selectively depending on the switching control signal.

Description

Color Correction Device Using Brightness Level

1 is a block diagram of a conventional color compensator.

2 is a block diagram of a color correction system.

3 is a block diagram of a color correction apparatus according to an embodiment of the present invention.

4 is a plan view showing the distribution of reproduction colors with an ideal distribution of colors in the saturation plane.

5 is a block diagram of a color correction device according to another embodiment of the present invention.

6 is a region selection characteristic diagram corresponding to a brightness level region according to three brightness reference values.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color image device, and more particularly, to a color correction device for outputting color reproduction close to an original image by adjusting color components of an image signal including color information.

Recently, a technology for printing and outputting a color image displayed on a monitor from a personal computer and a terminal device has been rapidly developed. For the printing output of the above-described color image, a high color correction technique is required to reproduce the color image displayed by the monitor to a color close to the original color. This is because the three primary colors of the light obtained from the color image are changed into the three primary colors of the color expressed on the recording medium by ink or paint, and there is a distortion of the color of the original image.

FIG. 1 is a block diagram of a conventional color compensator, which receives three signals of red, green, and blue R, G, and B signals. (Lightness: denoted by L below, Saturation: denoted by S below, Hue: denoted by H below) The RGB-HLS conversion unit 10 for converting and correcting the converted H, L, S components, respectively H-Look Up Table (H-LUT) memory, which is a means of storing color correction data, L-LUT Memory, which is a means of storing brightness data, and S-correction table, which is a means of storing data for chroma S-LUT) memory is configured as a color correction table memory 20.

Hereinafter, a conventional color compensator will be described with reference to the configuration of FIG. 1 described above.

First, RGB data R, G, and B of each pixel to be corrected are input to the RGB-HLS converter 10, and output as tri-color attribute data H ', L', and S ', respectively.

The three attribute data (H ', L', S ') of the color may include an H correction table (H-LUT) memory, an L correction table (L-LUT) memory, and an S correction table (S) in the color correction table memory 20. -LUT) are input into the memory and output as corrected H, L, S data stored in advance at the corresponding address.

Thereafter, the H, L, and S data are inversely converted into RGB data, and the corrected RGB data is supplied to the color reproduction recording apparatus.

Here, the corrected H, L, S stored in the H correction table (H-LUT) memory, the L correction table (L-LUT) memory, and the S correction table (S-LUT) memory in the color correction table memory 20, respectively. The data is obtained as follows.

2 is a block diagram of a color correction system. When the input X 'and the output X are known, the transfer function F () of the color correction system can be estimated using a known interpolation method from the correspondence between the input X' and the output X. . In the block diagram of FIG. 2, input X 'is color patch data obtained by reading a color patch (color patch), and output X is color patch generation data input to a printer to construct a color patch. 8-bit binary data with an integer value between 0 and 255.

Therefore, the transfer function F () is composed of a lockup table for outputting a binary F (X ') corresponding to the input of the binary X'. Here, if the inputs H ', L', S 'and the outputs H, L, and S of the color correction table memory 20 are X' and X, respectively, the expressions 1 and 2 can be expressed.

X '= [x'i: i = 1,... , N)… … … … … … … … … … … … … … … … … … … … (One)

X = [xi: j = 1,... , N)… … … … … … … … … … … … … … … … … … … … (2)

In Equations 1 and 2, N is the number of color patches (color samples) used to construct the lockup table.

However, the conventional color correction apparatus and method described above are based on the following two important assumptions.

First assumption: There is a one-to-one correspondence between the elements of output X and input X '. That is, two or more color patch generation data cannot exist for one color patch.

Second assumption: The three components, H, L, and S, are independent of each other, and neither component or two components can have any effect on the other components.

In the above assumption, the first assumption is expressed as a matter of fact, but in reality, since the three components of H, L, and S are not mutually independent, there is no one-to-one correspondence between the input X 'and the output X. That is, a change in any one of the three components H, L, and S affects the other components. Therefore, there was a problem that a plurality of work correspondence. In addition, the data of the input X 'area is processed by the statistical method, and the color correction lockup table is created by one-to-one correspondence with the output X area data. There was a problem that good results could not be obtained in the required color correction.

Accordingly, an object of the present invention is to provide a color correction apparatus using a brightness level capable of performing accurate color correction only by color correction according to the brightness level.

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

3 is a block diagram of a color compensator according to an embodiment of the present invention, which stores different color correction data according to brightness data L 'and corresponds to input of color data H' to correct color data H1-H4. 1-4H correction table (1-4H-LUT) memory for outputting the H correction memory unit 31 and the first correction in the H correction memory unit 31 corresponding to the brightness data L 'input. Switching control means 33 for outputting a switching control signal for selecting an output of a 1-4 H-LUT memory, and a control input from the switching control means 33; And a switching unit 35 for receiving the output data of the first-fourth correction table (first-fourth H-LUT) memory in the H correction memory unit 31 and selectively outputting the output data in response to the switching control signal. do.

The H correction memory unit 31 may include at least two H correction table (H-LUT) memories in another embodiment according to the present invention.

4 is a plan view showing the distribution of reproduction colors with an ideal distribution of colors in the saturation plane.

6 is a region selection characteristic diagram corresponding to a brightness level region according to three brightness reference values.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 2, 4, and 6 based on the configuration of FIG. 3.

The block diagram of the color correction system according to the invention can also be represented in the second diagram as conventionally.

In one embodiment of the present invention, the transfer function F () is obtained using only the input H 'and the output H. First, the first H-LUT selects an ideal six colors with saturation S = 255 and brightness as a predetermined reference value, i.e., H = 0, 43, 85, 127, 171, 212, to obtain input H 'and output H. do. Thereafter, the sample color is printed through a color recording apparatus for color correction, and then read by a scanner to convert each RGB data into a H'L'S 'coordinate system to obtain H'.

The process of obtaining the transfer function F () is performed by dividing the H region into six regions of R-Y, Y-G, G-C, C-B, B-M, and M-R.

The first region supplies R and Y, H 'and H, of the two colors R and Y as inputs and outputs to the color correction system of FIG. When the H 'and H are represented by the X and Y axes of the X-Y plane, the two colors R and Y become two points on the plane. The transfer function F () in the first region is obtained by linear interpolation between the two points. The transfer function F () is also obtained in the second, third, fourth, fifth, and sixth regions. After all transfer functions F () are found in six areas, the transfer functions F () are combined to form an H-LUT.

In order to obtain the second H-LUT, the reference value of the shaving L is changed and designated, and the saturation S = 255 is designated, and the color H is the same as the method of obtaining the first H-LUT described above, H = 0, 43, 85, The procedure is repeated by selecting six sample colors of 127, 171, and 212.

As in the prior art, the F-4 H correction table memory has an arrangement in which F (H ') = H is outputted when H' is input to the H correction table memory using an integer value of 0 to 255 as an address.

First, the three-attribute data H ', L', S 'of the color output from the RGB-HLS conversion unit (not shown in FIG. 3) is output, and the brightness data L' of the data is converted into switching control means ( 33), the switching control means outputs a switching control signal corresponding to the magnitude of the brightness data L '. In this case, the switching control signal corresponds to the brightness level according to the predetermined brightness reference value illustrated in FIG. 6.

The H correction memory 31 outputs respective color correction data H1-H4 from the 1-4 H correction table H-LUT memory in response to the input of the color data H '.

The switching unit 35 receives four color correction data H1-H4 from the H correction memory 31 and outputs one color correction data H in response to an input of a switching control signal.

Looking at the embodiment of the present invention described above, the present invention does not correct the brightness and saturation. The reason for this is because the effect of brightness on the reproduction color can be corrected by correcting the color change according to the brightness change through a plurality of color corrections created separately according to the brightness level.

In addition, as can be seen from the plan view of FIG. 4 showing the distribution of the reproduction color with the ideal color distribution in the HS plane, color correction by + dH when A 'is mapped to A to compensate the reproduction color A' to the original color A In addition, saturation compensation of + dS is achieved.

Therefore, when the H correction table H-LUT is created according to the present invention, the H correction table H-LUT includes an element for correcting the influence of saturation, and thus does not affect the reproduction color without a separate saturation correction.

FIG. 5 is a block diagram of a color compensator according to another embodiment of the present invention, and includes four reference brightness levels La, 127, and Lb to set four brightness areas, and corresponds to the brightness L 'input. A brightness level detection circuit 51 for outputting two-bit data (brightness data) representing a brightness level area, and receiving the two-bit data as the upper two bits and specifying the color H input as the lower address and outputting it as output selection data. An address decoder 53 and a 1-4 H correction table (1-4 H-LUT) memory for storing different color correction data according to the brightness data L ', and including the first 2 bits of the output selection data. Correspondingly, an H correction table memory (1-4 H-LUT) is selected, and is composed of an H correction memory section 55 for outputting color correction data H in correspondence with a lower address.

Hereinafter, another embodiment of the present invention will be described in detail with reference to the data characteristic diagram of FIG. 6 based on the configuration of FIG. 5 described above.

First, the brightness level detection circuit 51 outputs 2-bit data b0, b1: 00, 01, 10, 11 corresponding to the brightness level shown in FIG.

The address decoder 53 receives the H 'input and outputs the output selection data to the H correction memory section 55 by designating the 2-bit data as an upper address and the H' input as a lower address. At this time, the H correction memory unit 55 corresponds to the upper address of the output selection data, such as 00: 1H-LUT, 01: 2H-LUT, 10: 3H-LUT, and 11: 4H-LUT. The memory of the calibration table will be selected. The color correction data in the corresponding address of the selected H correction table memory is then output corresponding to the lower address of the output selection data.

Therefore, as described above, the present invention uses a correlation between hue, brightness, and saturation, which are three attributes of color, to variably correct color according to a change in brightness level, thereby obtaining faithful color correction.

In addition, the present invention simplifies the configuration of the color correction apparatus because the color correction is variably performed corresponding to the brightness level to shorten the three processes of hue, brightness, and saturation correction.

Claims (3)

A color correction device comprising: a color correction memory unit including at least two color correction table memories for storing different color correction data in brightness levels and outputting color correction data in response to input of color data, and a predetermined reference brightness level; A switching control means having a value, receiving brightness data, comparing the reference brightness value with the reference brightness value, and outputting a switching control signal for controlling output of the color correction table memories in the color correction memory unit according to the comparison result; Color correction data of the color correction table memories in the color correction memory unit, and a color correction unit for selectively outputting the color correction data in response to a switching control signal input to the switching control means Device. A color correction apparatus comprising: a brightness level detection circuit having a predetermined reference brightness level value and outputting brightness data representing a corresponding brightness level area in response to input of brightness data; An address decoder which receives data as a lower address and outputs the output selection data, and a color correction table memory for storing different color correction data according to at least two brightness levels, and corresponding to an upper address of the output selection data. And a color correction memory unit for selecting a color correction table memory and outputting color correction data corresponding to a lower address. 3. The brightness level detecting device according to claim 2, wherein said brightness level detecting circuit comprises three reference brightness levels, sets four brightness areas, and outputs two bits of brightness data representing corresponding brightness level areas in response to input of brightness data. And a first to fourth color correction table memory configured to store different color correction data according to brightness data. The first and second color correction table memories correspond to upper addresses of output selection data. And a color correction memory unit for selecting and outputting color correction data corresponding to the lower address.