KR100355377B1 - Color temperature deciding method in consideration of surrounding illuminating lights in color display system - Google Patents

Abstract

PURPOSE: A color temperature deciding method in consideration of surrounding illumination lights in a color display system is provided to visually detect the surrounding illumination lights of the color display system and determine color temperature of the display system with respect to the detected surrounding illumination lights. CONSTITUTION: Metamerism color patch sets composed of metamerism pair patches represented in the same color as the color of an arbitrary reference patch are generated. Surrounding illuminating is visually detected from a pair of patches shown to be identical to each other among the metamerism color patch sets. White chrominance of a corresponding display system is re-determined in consideration of the effect of the detected illumination.

Description

Color Temperature Determination Method Considering Ambient Light in Color Display Devices

The present invention relates to a color display device, and more particularly, to a method for visually detecting ambient light of an arbitrary color display device and determining a color temperature of the display device in consideration of the detected ambient light.

Color display devices, for example, CRT (Cathode Ray Tube) or LCD (Liquid Crystal Display) are the 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 accurately reproduce a specific color. colorimetic parameters) are commonly used. 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 CIEXYZ and CIELAB as defined by the Commission Internationale de l'Eclairage.

In order to accurately represent a specific 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. Once the color reproduction characteristics of the display device, i.e., the transfer function of the display device, are known, it is possible to convert an arbitrary specific color into an appropriate voltage value or current value necessary for accurately reproducing the display device using its inverse function. A series of processes for accurately reproducing an arbitrary specific color on one display device is called color correction or color matching. This color matching consists of a process of converting one color to another color, and the accuracy of the color matching as a result depends on the accuracy of the color conversion. Since color conversion is performed using the definition of the color reproduction characteristics of each input / output device, it is necessary to accurately define the color reproduction characteristics. Recently, a color management system (weakly referred to as CMS) has emerged for color matching between various input / output devices (minimum color error), which is used to adjust the color reproduction characteristics of each input / output device for color matching. It requires a profile to define. 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.

In the past, a colorimeter was used to obtain a color temperature or a white chromaticity of a display device, which is advantageous for obtaining an accurate color temperature value of the display device. However, 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 light is excluded, and when the color temperature value is used to define the color reproduction characteristics of the display device as it is, There is a problem that does not reflect properly. 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 there is always an ambient light and observes a reproduced image underneath, 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 determining method for visually detecting ambient light of an arbitrary color display device and determining the color temperature of the display device in consideration of the detected ambient light in order to solve the above-mentioned problem. .

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

A patch set generating step of generating a conditional color patch set consisting of conditional color pair patches that appear in the same color as any reference patch under each illumination light;

Illumination light detection step of visually detecting the ambient illumination light from the pair of patches that look the same in the set of conditional color patch: and

The white chromaticity recrystallization step of re-determining the white chromaticity of the corresponding display device in consideration of the influence of the detected illumination light may be performed.

In the white chromatic recrystallization step, when the white chromaticity of the display device itself is MCTxy, and the chromaticity of the ambient illumination light is VIxy,

Correcting the white chromaticity MCTxy of the display device by a predetermined distance from an MCTxy to an arbitrary point WP opposite to VIxy on a straight line formed by the MCTxy and VIxy; And

Map the corrected point WP to an arbitrary point WP 'on the path of the light source so that the corrected point WP is located on the path of the light source on the chromaticity coordinates, and map the mapped point WP' to the white chromaticity of the display device. It is desirable to have a recrystallization process.

In addition, the distance that the MCTxy is shifted from the MCTxy to any point in the opposite direction of the VIxy on the straight line formed by the MCTxy and VIxy is a change in color that a person feels to be white due to the interaction between the white of the display device and the illumination light. It is preferable that the value is expressed as the ratio of the distance between the two points MCTxy and VIxy in the chromaticity coordinates and the Euclidean distance between the MCTxy and VIxy.

In addition, the position of the mapped point WP 'is a point where the point on the path of the light source meets a straight line perpendicular to the x axis from the WP and is called WPxfix. When the point of meeting is called WPyfix, it is preferable to set the midpoint according to the linearization of the interval between the two points, WPxfix and WPyfix.

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

One color that is recognized by a human is generally standardized to be represented by a 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 reflectance of the object, and the color matching function of the human eye. 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 illumination (illuminant C), O _λ is an inherent reflectivity characteristic of the object (object), Is the color matching function of the standard observer shown in FIG.

Although the two objects (Object 1 and Object 2) have different spectral reflectances, as shown in Figure 1, if the resulting X, Y, Z values are the same, then humans perceive the colors of the two objects as the same. do. This phenomenon is called conditional colorism, and the color of two objects causing such conditional coloration is called a metameric pair.

The present invention comprises a patch set for inducing such a conditional orange phenomenon and a method for re-determining the color temperature of the ambient light detection and display device using the same.

FIG. 2 shows a set of conditional color patches used to detect illumination light, wherein the set of conditional color patches consists of reference patches represented by "ref." And a plurality of "meta." Consists of conditional orange pair patches. A, F2, F8, D65, F5, F7 and the like indicated on the left side of the patch indicate illumination light. The reference patches are the same for each illumination light with one particular color. That is, Aref, F2ref, F8ref, D65ref, F5ref, and F7ref patches are the same color. In each of the indicated illumination lights, the conditional orange pair patch corresponding to each reference patch is a conditional orange pair that appears under the illumination light in the same color as the reference patch. Under one illumination beam, only a pair of reference patches and a pair of conditional color pair patches appear the same color.

For example, if a patch "F5ref" and a patch "F5meta" look the same in some viewing environment, the main illumination light is "F5". It is possible to find out the ambient illumination light of the display device by using the conditional orange phenomenon. Shown in FIG. 2 is an example, and more conditional pairs may be used to detect more illumination. The conditional color patch set is manufactured using ink or paint, and the conditions of the production are as follows.

"Aref" and "Ameta" patch pairs are made to look the same color under standard illumination A (associated color temperature: 2856 ° K), and "F2ref" and "F2meta" patch pairs are used for standard illumination F2 (associated color temperature; 4200 ° K) ), "F8ref" and "F8meta" patch pairs are made to look the same color under standard lighting F8 (associated color temperature, 5000 ° K), and "D65ref" and "D65meta" patch pairs Made to look the same color under standard lighting D65 (Associated color temperature: 6500 ° K), "F5ref" and "F5meta" patch pairs are made to look the same color under standard lighting F5 (Associated color temperature; 6350 ° K), "F7ref" and "F7meta" patch pairs are made to look the same color under standard illumination F7 (associated color temperature; 6500 ° K). At this time, only one patch pair is manufactured to look the same color under each illumination. In addition, each patch is fabricated to have the same concentration and the same gloss.

On the other hand, lighting is one of the important operating environment of the system for the purpose of color matching, and greatly affects 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 illumination light. The method of obtaining such ambient illumination light is as shown in FIG.

Referring to FIG. 3, a conditional color patch set is used to obtain illumination light under a given environment. At this time, a reference patch and a conditional patch pair that look the same in the conditional color patch set are found. Illumination light can be detected simply from pairs of patches that look the same in a set of conditional color patches. This is because the information of the illumination light is displayed on the left side of the patch.

Next, a method of determining the color temperature of the monitor according to the detected illumination light will be described.

Another way of expressing color temperature is to express it as white chroma on the xy chromaticity diagram. Characterization of the actual display device, that is, data required for profiling to detect and file various chromaticity parameters for the color reproduction characteristics of the display device, is based on the white CIEXYZ stimulus (X, Y, Z) value.

When the white chromaticity of the display device is called MCTxy and the chromaticity of the ambient light is VIxy, the MCTxy is obtained by measuring the white chromaticity of the display device using a colorimeter, or determined by the setting of the display device. . At present, some monitor sets can be selected to correspond to several color temperatures by themselves. VIxy, on the other hand, is determined by detection of ambient illumination light using a set of conditional color patches, as shown in FIG. In the human eye, the light emitted from the screen of the display device and the ambient illumination light enter at the same time, and the feeling of white is changed by the interaction of these lights. The following equation (2) shows the conversion ratio for white generated by the interaction of two lights.

In Equation (2), APSR represents a change in color that a person feels as white depending on the interaction between white and illumination light of the display device as a ratio of the distance between two points MCTxy and VIxy on the chromaticity coordinate. α is 1.237 in the ambient light of normal brightness (about 60 cd / m 2), and changes depending on the brightness of the ambient illumination light, and becomes 0 when no ambient light exists. TVdist represents the Euclidian distance between MCTxy and VIxy. For example, when the coordinates of MCTxy are xt and yt, and the coordinates of VIxy are xv and yv, TVdist can be expressed as the following expression (3).

According to the interaction between the white light of the display device and the illumination light, a change in color (indicated by AP ′ in FIG. 4) that a person feels white occurs from the MCTxy to the VIxy direction. According to the human eye adaptation, the change of the white point of the display device occurs in the opposite direction to the direction of the color change that the person feels as white, that is, the APSR * TVdist from VIxy to MCTxy.

Meanwhile, the chromaticity change of the display device is determined through the following process.

In the first step, the white point WP is moved from the MCTxy to the opposite direction of the VIxy by the size of APSR * TVdist on the straight line formed by the MCTxy and VIxy, and in the second step, the white point WP is moved from the light source on the chromaticity coordinate. A path, for example, is mapped to a point WP 'on the path of the light source to be located on the daylight locus. The mapped point WP 'is the white chromaticity of the recrystallized display device. This is shown schematically in FIG.

The process of determining the white chromaticity of the display device changed by the influence of ambient illumination light is shown using the coordinate values of the points shown in FIG. 4 and the coordinate values mentioned in Equations (2) and (3) as follows.

Next, the point that meets the path of the light source when the straight line perpendicular to the x axis from the WP is called WPxfix, and the point close to the WP from the point where the line parallel to the x axis from the WP meets the path of the light source is called WPyfix. The process of finding the coordinates of the points is as follows. These points are one point of the path of the light source, and the path of the light source can be expressed by the following equation (4).

Next, the coordinates x, y of the WPxfix can be expressed by the following equations (5) and (6).

On the other hand, the coordinates x, y of the WPyfix can be expressed by the following equations (7), (8) and (9).

From the above equations (7) to (9), the chromaticity coordinate value of WP 'is determined by the following equation (10) for selecting an intermediate point according to the linearization of the intervals of the two coordinates WPxfix and WPyfix.

In other words, the white chromaticity of the display device changes from MCTxy to WP 'in consideration of the ambient light. This is used to describe the white chromaticity in the characterization of the display device.

As described above, in the color temperature determination method according to the present invention, in the color display device, the ambient light is visually detected using a conditional orange color patch set, and the color temperature of the display device is re-determined in consideration of the influence of the detected ambient light. When generating a profile of a display device required by a color matching system such as the above, the color temperature of the display device in consideration of the influence of ambient light, that is, white chromaticity information may be provided. Therefore, when a white chromaticity, which is one of chromaticity parameters, is obtained using the method proposed in the present invention when generating a profile of a display device, a color temperature obtained by simply using a colorimeter in various application software or the like that is intended to achieve color matching using a CMS or the like. In the display device set which can select the color temperature, it is possible to achieve visually more accurate color matching than when using the white chromaticity determined by the user's selection.

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

2 shows a set of conditional color patches used for the detection of illumination light in the present invention.

3 is a diagram illustrating visual illumination light detection according to the present invention.

4 is a graph showing a change in the white chromaticity of the display device according to the present invention.

Claims (5)

A patch set generating step of generating a conditional color patch set consisting of conditional color pair patches that appear in the same color as any reference patch under each illumination light; An illumination light detection step of visually detecting ambient illumination light from a pair of patches that appear identical among the conditional orange color patch sets; And And a white chromaticity recrystallization step of re-determining the white chromaticity of the display device in consideration of the influence of the detected illumination light. The method of claim 1, wherein the white chromatic recrystallization is performed when the white chromaticity of the display device itself is MCTxy, and the chromaticity of the ambient illumination light is VIxy. Correcting the white chromaticity MCTxy of the display device by a predetermined distance from the MCTxy to an arbitrary point WP opposite to VIxy on a straight line formed by the MCTxy and VIxy: The transferred point WP is mapped to an arbitrary front WP 'on the path of the light source so that the transferred point WP is located on the path of the light source on the chromaticity coordinate, and the mapped point WP' is re-determined as the white chromaticity of the display device. In the color display device characterized in that consisting of a process for determining the color temperature considering the ambient illumination light. The distance between the MCTxy and any point in the opposite direction of the VIky on the straight line formed between the MCTxy and VIxy is that a person feels white due to the interaction between the white light of the display device and the illumination light. The method of determining color temperature in consideration of ambient illumination light in a color display device, wherein the change in color is expressed as the product of the ratio of the distance between the two points MCTxy and VIxy on the chromaticity coordinates and the Euclidean distance between the MCTxy and VIxy. . The position of the predetermined point (WP ') is a meeting point on the path of the light source and a straight line perpendicular to the x-axis from the WP is called WPxfix, and a straight line lowered perpendicularly to the y-axis from the WP A color temperature determining method in consideration of ambient illumination light in a color display device, characterized in that when the point on the path of the light source meets WPyfix, it is set to an intermediate point according to the linearization of the two points WPxfix and WPyfix. 5. The method of claim 4, wherein the path of the light source uses a trajectory of daylight.