KR100335619B1 - Method for determining color temperature in color display device - Google Patents

Abstract

PURPOSE: A method for determining a color temperature in a color display device is provided to visually detect an illumination component and visually obtain a color temperature of a display device using the detected illumination component. CONSTITUTION: The first patch set composed of a plurality of patches that express gray color under each illumination component is generated. The second patch set composed of a plurality of patches, which are produced to become metameric paris with spectral power distribution of each illumination component constructing the first patch set, is generated. A patch having the same color as the color of a patch having equivalent energy spectral reflectivity of the first patch set is selected from the first patch set, to visually detect surrounding illumination components. The color temperature of an output device is determined from the second patch set using the detected illumination components(46).

Description

Determination of Color Temperature in Color Display Devices

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for detecting the color temperature of a display device that affects the accuracy of color conversion and determines the overall color in a system for accurately reproducing any particular color on a color display device. The present invention relates to a color temperature determining method for detecting an illumination component and visually obtaining a color temperature of a corresponding display device using the same.

Color display devices using a CRT (Cathode Ray Tube) or LCD (Liquid Crystal Display) are most widely used as a medium for transmitting graphic information. In applications such as graphic arts, advertising, textile design, automotive design, and the like, color display devices are required to display specific colors with specific colorimetic parameters. In addition, the same chromaticity parameters are used to reproduce these colors in other media such as ink, dyes or paint. These parameters include the well-known XYZ tristimulus, as defined by the Commission Internationale de l'Eclairage.

In order to express a certain color (a color having a specific chromaticity parameter or a point in the XYZ color space) on one color display device, it is necessary to first understand the color reproduction characteristics of the display device. Any specific color is converted into a voltage value necessary to be reproduced in the display device according to the color reproduction characteristics of the display device. In the case of such color conversion, the accuracy depends on the accuracy of the transform formulas, that is, the definition of the color reproduction characteristics of each display device. For color conversion with minimal color errors between various input and output devices, a color management system (CMS) has been proposed, which requires a profile containing the definition of the exact color reproduction characteristics of each device for color conversion. . In this case, the chromaticity of the white point of the display device, that is, the color temperature, is one of the important chromaticity parameters when creating a profile of the CMS.

Conventionally, a colorimeter is used to obtain a color temperature of a display device, which is advantageous for obtaining accurate chromaticity coordinate values of the display device. The color temperature value of the display device obtained by using the colorimeter is the color temperature value of the pure display device itself in which the ambient lighting component is excluded. However, this color temperature value does not reflect the ambient lighting component. This will be described in more detail as follows.

In most cases, the user does not immediately see the reproduced image in the dark room, so the environment of observing the reproduced image is quite different from the environment obtained by using a colorimeter. That is, since the ambient light always exists and the reproduction image is observed under the eye, the eye is adapted to the light source of the ambient light and the display device, and the color temperature of the display device is different from the value obtained by the colorimeter. Therefore, it is impossible to achieve the desired color registration without considering the difference between the colorimeter and the visual angle for the color temperature.

Accordingly, an object of the present invention is to provide a color temperature determination method for visually detecting an illumination component in a color display device and visually obtaining a color temperature of the display device by using the same to solve the above problems.

Color temperature determination method according to the present invention in a color display device to achieve the above object

A patch set I generation step consisting of a plurality of patches that appear gray under each illumination component;

A patch set II generation step consisting of a plurality of patches made to be a spectral power distribution and a conditional orange pair of each illumination component constituting the patch set I;

An illumination component detection step of visually detecting an ambient lighting component by selecting a patch having the same color as the patch having the equivalent energy spectral reflectivity of the patch set I in the patch set I:

And a color temperature determination step of determining a color temperature of the display device from the patch set II using the detected illumination component.

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

One color recognized by a human is generally standardized as represented by the CIE 1931 XYZ 3 stimulus as shown in FIG. This is determined by the product of the spectral power distribution (SPD) of the light source, the stimulus spectrum or reflectivity of the object, and the color matching function of human vision. Looking at the process diagrammatically is shown in Figure 1, it can be expressed as formula (1) below.

In the formula (1), S _λ is the SPD of the illuminant C, O _λ is the inherent reflectivity characteristic of the object, and x _λ , y _λ , z _λ is the standard observer of FIG. Color matching function.

Although the two objects (0bject 1 and Object 2) have different spectral reflectances as shown in Figure 1, if the resulting X, Y, and Z values are the same, then the human is the same color. To be recognized. These phenomena are called metameric phenomena, and the colors of two objects that cause such phenomena are called conditional orange pairs.

The present invention has a configuration in which a patch set for inducing such a conditional color phenomenon and a color temperature of an illumination detection and display device using the same are obtained.

FIG. 2 shows a first patch set used for illumination component detection, wherein the gray patches indicated by the respective diagonal lines in the patch set are manufactured using ink or paint as follows.

The E patch is made to have a constant reflectance over the wavelength of the entire visible region, the A patch is made to look gray under standard illumination A (associated color temperature; 2856 ° K), and the F11 patch is made of standard illumination F11 (associated color temperature). ; 4000 ° K) to make it look gray, F2 patch is made to look gray under standard lighting F2 (Associated color temperature: 4200 ° K), D5O patch is made to be standard light ) D55 patch is made gray when viewed under standard lighting D55 (Associated color temperature; 5500 ° K), D65 patch is made gray when viewed under standard illumination D65 (Associated color temperature: 6500 ° K) The D75 patch is designed to look gray under standard lighting A (associated color temperature; 7500 ° K), and the D95 patch is gray when viewed under light with a color temperature of 9500 ° K. Is produced. In Figure 2, the BLK is the part where no color is painted.

Each gray patch is fabricated to have a constant density and arranged as in FIG. 2, which is referred to as patch set I for detecting illumination components. To get more detailed lighting, you can make more patches in Patch Set I.

3 shows an example of patch set II used for determining the color temperature of the display device, wherein patches indicated by diagonal lines in the patch set are produced as follows.

The A patch is designed to be a pair of gray and conditional pairs of medium brightness emitted by standard light A under a given light (specific lighting), and the F11 patch is produced of medium brightness emitted by standard light F11 under a given light (detected light). The F2 patch is designed to be a gray and conditional light pair under a given light (specific light), and the D5O patch is a standard light under a given light (specific light). Lighting D5O is designed to be a medium-bright gray and conditional light pair, and under the given lighting (specific light), the D55 patch is designed to be a medium-light gray and conditional-light pair emitted by a standard light D55 Under lighting (specific lighting), the standard light D65 produces a medium-bright gray and conditional light pair. It is designed to be a pair of medium light gray and condition light emitted by the standard light D75 under dark lighting, and the D95 patch is made of medium light gray and condition light emitted by the standard light D95 under a given light (specific light). It is manufactured to be a pair. Here, the white part is a part which is not painted with any color and is made of a transparent film.

The patch set II is made for each illumination, for example A, F11, F2, D5O, D55, D65, D75, D95.

Lighting is one of the important operating environment of the system for the purpose of color matching, and has a great influence on the recognition characteristics of the person. The color reproduced on the display device is necessarily recognized as a value different from the value obtained by using a colorimeter in the process of being actually recognized by the influence of ambient light. As such, it is necessary to perform color processing in consideration of the situation in which the actual index expression occurs, so it is very important to detect the lighting component.

FIG. 4 is a flowchart for detecting an illumination component and determining a color temperature of a display device, wherein the illumination component detection step (steps 41 to 42) for visually detecting an ambient illumination component and the detected illumination component are performed. And a color temperature determination step (steps 43 to 46) for determining the color temperature of the display device.

Referring to the operation of the present invention by the flow chart shown in Figure 4 as follows.

In step 41, all control terminals of the display device are set to obtain color reproduction characteristics, and in step 42, the lighting component is detected using patch set I as shown in FIG. This lighting component detection process will be described in more detail with reference to FIG.

In FIG. 5, patch set I is used to obtain an illumination component under a given environment, where an E patch of patch set I is selected, that is, a patch having the same color as the patch having equivalent energy spectral reflectivity. In this case, the selected patch informs the current lighting condition. In other words, the name given to each patch is the lighting component. For example, if the E patch and the F2 patch look the same color (gray), then the lighting component is F2, and the rest of the patches have different colors.

In step 43, the patch set II corresponding to the illumination component detected in step 42 is selected, and then the patch set II is attached onto the screen of the display device (step 44). In the 45th step, gray is displayed on the transparent portion of the patch set II attached to the display device, and the contrast of the display device is adjusted to have a brightness similar to that of the surrounding gray patches. In step 46, one patch of patch set II having the color closest to gray displayed on the display device is selected, and accordingly, the color temperature of the display device is determined. This color temperature determination process will be described in more detail with reference to FIG. 5 followed by FIG. 6.

In FIG. 6, the patch set II fabricated to correspond to the illumination F2 detected in FIG. 5 is selected and attached to the screen of the display, wherein the display displays the background in 50% gray color, and the patch The part where is attached is grayed out so that the brightness of the patch is similar to that of the patch. Next, the contrast terminal of the display device is adjusted such that the brightness of the gray of the display device visible through the transparent window portion of the patch set II and the brightness of the surrounding patches are constant. At this time, since the chromaticity of the display device does not change according to the adjustment of the contrast terminal, it is possible to readjust and use it properly in actual use. In this case, the patch having the color closest to the color of the display device seen through the transparent window is selected. For example, when the selected patch is D65, the color temperature of this display device is D65.

As described above, in the color temperature determining method according to the present invention in the color display device, the color temperature of the display device is determined in consideration of the ambient lighting components without using a colorimeter, thereby providing color temperature information when generating a profile of a device required by the CMS. Can be. Therefore, in the various application software which wants to achieve color registration using CMS, etc., it is possible to achieve visually more accurate color registration than color matching processing by color temperature obtained by using a colorimeter.

1 shows a schematic representation of color perception and conditional color pairs.

2 is a diagram showing a patch set I used for illumination component detection in the present invention.

3 is a diagram showing patch set II used for color temperature determination of a display device in the present invention.

4 is a flowchart for a color temperature determining method according to the present invention in a display device.

5 is an exemplary view of visual illumination component detection according to the present invention.

6 is an exemplary view of determining color temperature of a display device according to the present invention.

Claims (2)

A patch set I generation step consisting of a plurality of patches that appear gray under each illumination component; A patch set II generation step consisting of a plurality of patches manufactured to be a spectral power distribution and a conditional orange pair of each illumination component constituting the patch set I; An illumination component detection step of visually detecting an ambient lighting component by selecting a patch having the same color as the patch having the equivalent energy spectral reflectivity of the patch set I in the patch set I; And And a color temperature determination step of determining a color temperature of the display device from the patch set II by using the detected illumination component. The method of claim 1, wherein the color temperature determining step Selecting a patch set II corresponding to the detected illumination component and attaching the selected patch set II to the screen of the corresponding display device; Displaying gray on the transparent portion of the patch set II attached to the display device, and adjusting the contrast of the display device to have a brightness similar to that of the surrounding gray patches; And Selecting a patch of patch set II having the color closest to that displayed on the display device, and determining the color temperature of the display device by the selected patch.