KR100335618B1 - Color display device having color temperature conversion function and method of changing color temperature - Google Patents

Abstract

PURPOSE: A color display device having a color temperature conversion function and a method of changing a color temperature are provided to prevent colors from being distorted to maintain high picture-quality video information. CONSTITUTION: A color display device includes a white selection panel(14), a data storage(15,16), a microcomputer(17), a factor driver(18), and a white converter(19). The white selection panel displays color temperatures and judges a color temperature value selected by a viewer. The data storage stores basic color temperature values, a look-up table having chrominance data value, transform matrix factor values for transforming input color signals from an RGB space into a standard color space, and a transform matrix factor values for transforming the color signals from the standard color space into the RGB space. The microcomputer calculates a white transform matrix with respect to the color temperature value selected by the viewer with reference to the transform matrix factor values stored in the data storage. The factor driver converts the factor values of the white transform matrix into analog signals. The white converter converts an input color signal into a color signal having the color temperature selected by the viewer according to amplification factor corresponding to the signal output from the factor driver.

Description

Color display device with color temperature change function and color temperature change method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color display apparatus and a color temperature changing method capable of converting a color temperature into a white (color temperature) which can be arbitrarily set according to the color sense characteristic of a viewer in a color monitor or color television receiver.

NTSC, PAL, SECAM, the broadcasting standard, defined all colors as three primary colors and white. Especially, white is based on D65 lighting with a color temperature of 6504˚K, which was established by the International Lighting Commission (CIE). Also, broadcasting stations transmit broadcasting signals in the same standard. However, manufacturers of television sets and monitors manufacture products according to different standards, and it has been shown that TV receivers are usually manufactured or corrected within a color temperature range of 5700 degrees K to 13700 degrees K. In particular, viewers generally prefer white above 9300˚K (see 1993 IS & T / SID article). This is because most viewers prefer the color of the color image to blue rather than red or yellow, and because each person has a different preferred color, TV receivers prefer not to express colors focusing on only one white color. It would be desirable to provide a suitable white color.

White color in the color image is defined by the maximum value that can represent the primary colors (R, G, B) of the color display device, depending on where the white is located in the color coordinates the color of the color image changes. However, the color of the image varies depending on the lighting, TV receiver, and viewer used when shooting the broadcast camera.

In the conventional color TV receiver, the viewer can obtain the color of the input image by adjusting the control panel (luminance, color, density) mainly attached to the TV receiver, and this adjustment is inconvenient and optimized due to color adjustment of the non-expert. There arises a problem of shifting the parameters of the TV receiver.

The conventional method for solving this problem is disclosed in US Pat. No. 5,257,096. First, when a desired white value (CIEXYZ unit) and a luminance value are input, a chromaticity value of an RGB phosphor of a color CRT is known in advance. The RGB luminance value is obtained, and the amount of current flowing through the cathode of the CRT is calculated using the RGB luminance value. The amount of the CRT driving voltage is adjusted by comparing the calculated current amount with the actual amount of current flowing through the cathode. That is, the technique adjusts the white color of the TV receiver by adjusting the RGB current amount of the CRT with respect to the input white value.

However, the above method is not clear in terms of visual perception of the white color-enhanced ambient color by varying the RGB current range in the device-dependent RGB region, and also excessively exceeds the range of the amount of CRT current set to the optimal state according to the definition of white. Beyond that, there is a problem of shortening the life of the CRT. Therefore, white adjustment must be performed within the adjustment range of the display device in which the current limit value of the CRT cathode is optimized, and the conversion of the ambient colors during the white conversion is also defined in the standard color space for accurate white conversion.

Accordingly, an object of the present invention is to solve the above-mentioned problems, the viewer to select the preferred color based on the color temperature, the color signal conversion based on the color temperature selected on the standard color space representing the visual characteristics of the human input To provide a color display device and a color temperature changing method having a color temperature changing function for performing the above.

In order to achieve the above object, a color display device having a color temperature changing function according to the present invention includes: a white selection panel for displaying a color temperature so that a viewer can select a color temperature, and for determining a color temperature value selected by the viewer;

A look-up table having an inherent basic color temperature value of the color display device, a corresponding color data value on the basic color temperature value to the standard color space within a displayable color temperature range, and converting the input color signal from the RGB space to the standard color space. A data storage unit for storing a transform matrix coefficient value and a transform matrix coefficient value for converting the color signal from the standard color space to the RGB space;

A microcomputer for calculating a white conversion matrix for a color temperature value selected by the viewer through the white selection panel with reference to the conversion matrix coefficient values stored in the data storage unit;

A coefficient driver for converting coefficient values of the white conversion matrix output as the calculated result of the microcomputer into analog signals and continuously outputting the analog values; And

And a white conversion unit for converting the input color signal into a color signal having a color temperature selected by the viewer according to the amplification degree, and outputting the signal output from the coefficient driver to the CRT.

In order to achieve the above object, a color temperature changing method according to the present invention is a color display device having a color temperature changing function.

Reading an RGB / standard color space conversion matrix coefficient value, an xy chromaticity data value corresponding to a basic color temperature value, and an xy chromaticity data value corresponding to a color temperature value selected by the viewer from the data storage unit;

Calculating a white ratio between the basic color temperature and the color temperature selected by the viewer in a standard color space;

Reading a standard color space / RGB transformation matrix coefficient value from the data storage unit;

Calculating a matrix product of the RGB / standard color space transform matrix coefficient value, the white ratio and the standard color space / RGB transform matrix coefficient values; And

And multiplying the input color signal by the matrix product to convert the color signal into a color signal having a desired color temperature.

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

Fig. 1 is a block diagram showing a color display device having a color temperature change function according to the invention of the ball, which is an example of a color TV receiver.

The color display device shown in FIG. 1 includes a tuner (not shown), a Y / C separator (not shown), and a demodulator (11). It consists of a CRT driver 12, a CRT 13, a white selection panel 14, a RAM 15, a ROM 16, a microcomputer 17, a coefficient driver 18 and a white converter 19.

FIG. 2 is a conceptual diagram of the white conversion unit 19 shown in FIG. 1 and includes an RGB / standard color space converter 112, a white point converter 113, and a standard color space / RGB converter 114.

FIG. 3 is a detailed block diagram of the coefficient driver 18 and the white converter 19 shown in FIG. 1, and the coefficient driver 18 converts the coefficient values of the white conversion matrix calculated by the microcomputer 17 into analog values. A digital converter (121) and an analog voltage driving circuit (122) for continuously setting an amplification degree in the amplifier (124) in the white converter (19) using the converted analog coefficient values. 19 consists of three level amplifiers 123, nine gain controllable amplifiers 124 and three adders / buffers 125.

4 is a flow chart for explaining the method of changing the color temperature according to the present invention. The white conversion matrix for the color temperature selected by the viewer is shown.

A process (steps 41 to 47) and a process of amplifying and outputting an input color signal using the coefficient values of the white conversion matrix (step 49).

FIG. 5 is an operation flowchart of the microcomputer 17 shown in FIG. 1, which corresponds to the RGB / standard color space conversion matrix coefficient value, the xy chromaticity data value corresponding to the basic color temperature value, and the color temperature value selected by the viewer from the data storage unit. Reading the xy chromaticity data value (steps 51 to 53), calculating the ratio of the basic color temperature and the viewer-selected color temperature in the standard color space (step 54), and the standard color space / RGB from the data storage unit. Reading the transform matrix coefficient value (step 55), calculating the RGB / standard color space transform matrix coefficient value, and calculating a matrix product for the white ratio and the standard color space / RGB transform matrix coefficient values (step 56). .

On the other hand, the operation and effects of the present invention will be described with reference to FIGS. 1 to 5 as follows.

In FIG. 1, the radio wave received from the color TV receiver is input to the demodulator 11 via a tuner (not shown) and a luminance / color signal (Y / C) separation unit (not shown), thereby providing reference phases P1 and P2. One luminance signal and two chrominance signals or RGB signals are output using the two signals, and these signals are input to the CRT driver 12 to drive the CRT 13.

The microcomputer 17 reads the setting values of the white selection panel 14 attached to the color TV receiver and uses the white conversion matrix for the corresponding values with reference to the values stored in the ROM 15 and the RAM 16. The coefficient values of the calculated white conversion matrix are applied to the white conversion unit 19 through the coefficient driver 18.

The operation of the white conversion unit 19 will be briefly described with reference to FIG. 2 first. In the RGB / standard color space converter 112, the white in the RGB space is converted into the standard color space, and in the white point converter 113, The white point of the white color in the standard color space is converted, and the standard color space / RGB converter 114 converts the white color of the converted white color point into the RGB space again.

Here, the coefficient driver 18 and the white converter 19 will be described in detail with reference to FIG. 3.

First, the input voltage signal is input to each of the three level amplifiers 123 inside the white converting unit 19 to be converted into a voltage signal of an appropriate level. Here, nine gain controllable amplifiers 124 and three adders / buffers 125 are examples of a multiplication of a 3 × 3 matrix. That is, the final output of the white conversion unit 19 is expressed as the weighted sum of each of the three input color components.

On the other hand, the coefficient driver 18 converts the coefficient values of the white conversion matrix output as the calculation result of the microcomputer 17 into analog signals by the digital / analog converter 121, and continuously through the analog voltage driving path 123. The amplification degree of the amplifier 124 in the white conversion unit 19 is output.

The white selection panel 14 converts and displays a white color of a section preferred by the viewer into a color temperature, and when the viewer selects a random color temperature, the microcomputer 17 can detect the value.

The gap 16 includes data necessary for obtaining a white conversion matrix coefficient using this value when a color temperature desired by a viewer is selected, that is, chromaticity information of a CRT 13 phosphor or chromaticity information of an NTSC RGB primary color, and a basic chromaticity of a white CRT. Information or chromaticity information of an NTSC "C" light source (white), RGB (Y, RY, BY or YIQ) / standard color space (CIEXYZ or basic LMS) conversion matrix coefficients, and standard color space / RGB conversion matrix coefficients.

The method of changing the color temperature according to the present invention with reference to the overall flow diagram shown in FIG. 4 is as follows.

When the white selection panel 14 is selected in step 41, the microcomputer 17 reads a settable color temperature range, for example, 5000 ° K to 13000 ° K from the gap 16 and displays it on the screen (step 43). ). In the 45th step, it is determined whether the viewer selects an arbitrary color temperature body and selects 8000 ° K. If the viewer does not select any color temperature, the process returns to the 45th step and waits until the viewer selects the arbitrary color temperature. When the viewer selects a random color temperature, the microcomputer 17 calculates the conversion matrix coefficient value for the selected color temperature (step 47), and transmits the calculated matrix coefficient value to the white conversion unit 19 through the coefficient driver 18. The nine gain-adjustable amplifiers 124 are applied to the respective amplification degrees (step 49). Here, the amplification degree applied to the white conversion unit 19, that is, the coefficient for white conversion may use a conversion matrix of the NTSC broadcast standard, but if the NTSC RGB signal is corrected for the TV receiver, the conversion of the CRT primary color of the TV receiver is performed. You can also use matrices.

On the other hand, the principle of changing the color temperature on the standard color space is as shown in Figure 5 represented by the formula as follows. First, the relation between the RGB color space and the international standard color space (CIEXYZ) is expressed by the following equation (1). This corresponds to the operation principle of the RGB / STD 112 in FIG.

In the formula (1), M, which is a 3 × 3 matrix, is an RGB / standard color space conversion matrix obtained under chromaticity coordinates of the NTSC RCB (or TV CRT phosphor RGB) primary color and the standard light source “C” (or white of the TV CRT). For reference, the white color of the TV CRT is obtained when R = G = B = maximum.

When arbitrary color values (X ₁ , Y ₁ , Z ₁ ) are defined by a predetermined light source (or white) in the standard color space, these values are defined as color values (X ₂ , Y ₂ , Z ₂ ) under another light source (or white). The relational expression is as shown in the following (2). This corresponds to the operation principle of the white point converter 113 in FIG.

In Equation (2), the transformation matrix W may be expressed as Equation (3) using a visual model.

In Equation (3), LMS is referred to as a fundamental tristimulus value reflecting the physiological characteristics of the human eye.

On the other hand, the conversion from the standard color space to the RGB space can be easily obtained using the inverse of the matrix M as shown in Equation (4). This corresponds to the operating principle of the standard color space / RGB converter 114 in FIG.

Formula (1), (2) (or (3)) and (4) can be expressed by the matrix multiplication by taking the matrix product.

Therefore, by obtaining the matrix coefficient CO of the above equation (5), it is possible to convert the specific white input RGB signal into R ', G', B 'signals having a white color temperature desired by the viewer. When the color temperature value setting of white is changed in Equation (5), only the matrix W is changed. Matrix M has no change. Thus, the inverse coefficients of the matrices M and M are stored in the gap 16.

When the white color, i.e., the color temperature is set from the viewer, the xy coordinate values in CIExyY for the arbitrary color temperature can be obtained by calculation, but the process is complicated. It is convenient to store. Table 1 below shows an example of a lookup tabled use period.

On the other hand, XYZ tristimulus values for the xy chromaticity value can be easily obtained as in the following equation (6).

As described above, the color display apparatus and the color temperature changing method having the color temperature changing function according to the present invention can be implemented by adding the coefficient driving unit and the white conversion unit to the existing color display device circuit, and the color temperature preferred by the viewer can be changed. The color signal conversion is performed based on the selected color temperature based on the color temperature selected on the standard color space representing human visibility, so that color distortion of the remaining colors due to white conversion can be prevented to maintain high quality image information. have.

1 is a block diagram showing a color display device according to the present invention.

FIG. 2 is a conceptual diagram of a white conversion unit shown in FIG.

FIG. 3 is a detailed block diagram of the white converter and coefficient driver shown in FIG.

4 is a flowchart for schematically illustrating a method of changing a color temperature according to the present invention.

5 is a flowchart illustrating the operation of the microcomputer shown in FIG.

* Explanation of symbols for main parts of the drawings

11 ... demodulator 12 ... CRT drive

13 ... CRT 14 ... White Selection Panel

15 ... RAM 16 ... ROM

17 ... micom 18 ... counter

19 ... white conversion unit

Claims (2)

A white selection panel for displaying a color temperature so that the viewer can select a color temperature, and for determining a color temperature value selected by the viewer; A look-up table having an inherent basic color temperature value of the color display device, a corresponding color data value on the basic color temperature value to the standard color space within a displayable color temperature range, and converting the input color signal from the RGB space to the standard color space. A data storage unit for storing a transform matrix coefficient value and a transform matrix coefficient value for converting the color signal from the standard color space to the RGB space; A microcomputer for calculating a white conversion matrix for a color temperature value selected by the viewer through the white selection panel with reference to the conversion matrix coefficient values stored in the data storage unit; A coefficient driver for converting coefficient values of the white conversion matrix output as the calculated result of the microcomputer into analog signals and continuously outputting the analog values; And And a white conversion unit for converting the input color signal into a color signal having a color temperature selected by the viewer according to the amplification degree and outputting the signal output from the coefficient driver to a CRT according to the amplification degree. Color display device having a. In the color display device having a color temperature changing function as described in claim 1, Reading an RGB / standard color space conversion matrix coefficient value, an xy chromaticity data value corresponding to a basic color temperature value, and an xy chromaticity data value corresponding to a color temperature value selected by the viewer from the data storage unit; Calculating a white ratio between the basic color temperature and the color temperature selected by the viewer in a standard color space; Reading a standard color space / RGB transformation matrix coefficient value from the data storage unit; Calculating a matrix product of the RGB / standard color space transform matrix coefficient value, the white ratio and the standard color space / RGB transform matrix coefficient values; And And multiplying the input color signal by the matrix product and converting the color signal into a color signal having a color temperature desired by the viewer.