KR0165316B1 - Computer controlled monitor system - Google Patents

Abstract

In the display device having a color correction function according to the present invention, a color signal is added to an existing CCMS, and thus a video signal in which an input color system is determined according to a user's selection, that is, a full picture as well as a still picture made by existing software. There is an advantage that accurate color correction for.

Description

Display device with color correction

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

FIG. 2 is a detailed block diagram of the color compensator shown in FIG.

3 is a detailed block diagram of the color conversion unit shown in FIG.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to color display devices, and more particularly to a computer controlled monitor system (hereinafter referred to as CCMS) having a color correction function for correcting the color of a reproduced image.

In CCMS, color reproduction is generally performed by additive color mixing of R, G, and B which are primary primary colors. In this case, the color reproduction characteristics are based on colorimetric or chromaticity parameters, such as chromaticity coordinate values of three primary colors and white points. Recently, with the development of multimedia, more attention has been paid to accurate color matching, and some software researches on color reproduction using the color reproduction characteristics of CCMS have been actively conducted.

Currently, devices capable of displaying full-motion video on a CCMS include overlay boards for displaying VTR, LD, and television signals on the CCMS, and MPEG for displaying MPEG signals output from the CD on the CCMS. Play boards, etc. These signals use a specific color system, such as the NTSC system. However, depending on the signal output from such a device, the color displayed on the screen is reproduced in a different color than the originally intended color. This is because the color reproduction characteristics determined by the primary colors and the white points of the actual output device in most cases have their own color system, and are different from the input color system. This difference causes color reproduction errors.

On the other hand, as information such as letters, figures, sounds, and colors are frequently transmitted between devices, distortion of information in information transmission between each other has emerged as a big problem. Among them, the transmission of color information is more and more, and the accurate delivery of color information has become an important problem. In an effort to minimize such errors in information transmission, a proposed technique is colorimetric color-matching. The need to accurately reproduce the signal of one color system as intended by a device using another color system is a trend in the field of DTP and graphics. Recently, according to the demand for accurate color reproduction, softwares for achieving accurate matching when transmitting color signals between a variety of color devices such as CMS (Color Management System) have emerged. CMS can be said to have great utility value when processing still images mainly used in DTP and graphics fields. However, this does not consider the case of moving images, and the existing CCMS has a disadvantage in that it cannot accurately reproduce itself.

Following the conventional CCMS, the image processing unit is indicated by reference numeral 100 in FIG. 1, and the image signals 1R, 1G, and 1B (in this case, 2R, 2G, and 2B) output from the image signal generator 90 of the host computer are It is first amplified by the image preamplifier 40 by the gain adjustment signal Gain-ctl of the microcomputer 80 to 3R, 3G, and 3B, and the image is output by the offset adjustment signal Offset-ctl of the microcomputer 80. Secondary amplification in the main amplifier 50 results in 4R, 4G, and 4B for driving the CRT. These 4R, 4G and 4B are applied to each electron gun of the CRT 60 to finally determine the color to be output by adjusting the beam current.

The image processing of the conventional CCMS does not have accurate color reproduction in mind, but merely transforms the data supplied from the image signal generator 90 into a signal required to drive a display device.

Accordingly, an object of the present invention is to provide a display device having a color correction function for reproducing accurate colors when displaying a still picture or a complete moving picture in order to solve the above problems.

In order to achieve the above object, a display device having a color correction function according to the present invention is a display device for signal processing and displaying a video signal supplied from a host computer or an external video signal source. A color correction circuit for color-correcting and outputting an image signal; And an image processing unit for amplifying the image signal corrected by the color correction unit or an image signal supplied from the host computer or an external image signal source so as to be displayed on the screen.

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

1 is a block diagram showing a display device having a color correction circuit according to the present invention, which includes an image signal generator 90 of a host computer, an image processing unit 100 of a known CCMS element, and a color correction circuit 200. It consists of.

In addition, the image processor 100 includes an image preamplifier 40, an image main amplifier 50, a CRT 60, and a microcomputer 80.

In addition, the color correction circuit 200 may include a first switch 10 for selecting one of two output lines for one input signal, a color compensator 20, and one for outputting one of two input signals. It consists of two switches 30 and a clock generator 70.

FIG. 2 is a detailed block diagram of the color compensator 20 shown in FIG. 1, which includes an analog / digital converter 21, a gamma lookup table (LUT) 22, a color converter 23, and a digital / analog converter. 24).

FIG. 3 is a detailed block diagram of the color conversion unit 23 shown in FIG. 2, which includes a multiplier 25 including nine multipliers 25a to 25i and three adders 26a to 26c. 26).

Next, the operation of the present invention will be described with reference to FIGS. 1 to 3.

Referring to FIG. 1, the analog image signals 1R, 1G, and 1B output from the image signal generator 90 pass through the color correction unit 20 by turning on / off the color correction control terminal CCC attached to an external control panel. It is decided whether or not to do so. When the CCC is off, it operates in the same manner as the existing general CCMS, and the description of the operation in this case will be omitted. Meanwhile, when the CCC is turned on by the user, the microcomputer 80 activates the 'RES-SEL' signal and the 'SEL' signal according to the signal.

The microcomputer 80 determines the display resolution of the current input signal according to the horizontal and vertical synchronous signals Sync (H, V) supplied from the image signal generator 90, and sends 'RES' to the clock generator 70 to generate a suitable clock. Apply the -SEL 'signal. In addition, the 'SEL' signal is generated so that the first and third switches 10 and 30 are connected to the color compensator 20. The color compensator 20 will be described in more detail with reference to FIG. 2.

The signal 'Fq' generated from the clock generator 70 is applied to the analog / digital converter 21 and the digital / analog converter 24 to operate at a sampling frequency. The signals 1R, 1G, and 1B output from the video signal generator 90 are converted into digital signals in units of pixels, which are color correction processing units, in accordance with the sampling frequency Fq by the analog / digital converter 21.

The output signals dR, dG, and dB of one pixel of the analog / digital converter 21 serve as addresses of the gamma lookup table 22 to output corresponding signals nR, nG, and nB. The gamma lookup table 22 calculates a relationship between the input video signal of each of the R, G, and B channels and the output intensity of the CRT to be used to obtain a value to be corrected, and stores a value corresponding to the input in advance. The gamma lookup table 22 is configured for each of R, G, and B channels, and its size 2 ^N is determined according to the number of bits N of dR, dG, and dB. Normally, dR, dG, and dB are quantized to 8 bits, in which case the size of the lookup table of each channel is 256 bytes. The nR, nG, and nB output from the gamma lookup table 22 are applied to the color conversion unit 23 and calculated as a matrix of the following first equation together with the parameters input from the prestored microcomputer 80.

In Formula 1, A ₁₁ to A ₃₃ are obtained through colorimetry using a colorimeter as elements determined by phosphorsets and driving circuits used in manufacturing CRT. These parameters are obtained by excluding the color correction circuit 20. These parameters are obtained at the time of manufacture and stored and used in the memory of the microcomputer 80.

DR ', dG', and dB 'are output as a result of the matrix operation as in Equation 1, and dR', dG ', and dB' are analog video signals 2R, 2G, and 2B corrected by the digital-to-analog converter 24. Becomes

As described above, in the display device having the color correction function according to the present invention, by adding a color correction circuit to the existing CCMS, a video signal in which an input color system is determined according to a user's selection, that is, a still image made by existing software In addition, there is an advantage that accurate color correction for a complete moving picture is possible.

Claims (1)

A display apparatus for processing a video signal supplied from a host computer or an external video signal source and displaying the same on a screen, wherein the display device switches the video signal supplied from the host computer or an external video signal source according to a user's color correction intention. A first switch for outputting; An analog / digital converter for converting the video signal switched by the first switch into a digital signal at a predetermined clock frequency; Obtain a value to be corrected by obtaining a relationship between an input video signal of each of the R, G, and B channels and the output intensity of the screen used, and use the address as a digital signal for one pixel output from the analog / digital converter as an address. A gamma lookup table for outputting corresponding R, G, and B data values; A memory unit for storing color conversion parameters determined according to a phosphor set and a driving circuit used in manufacturing the screen; A color conversion unit configured to read out the parameters stored in the memory and multiply the R, G, and B data values output from the gamma lookup table, and add the output signal for each R, G, and B signal to perform color conversion; A digital / analog converter for converting the output force signal of the color conversion unit into an analog signal; A second switch for switching and outputting the color-converted analog video signal output from the digital / analog converter according to a user's color correction intention; And an image processing unit for amplifying the video signal switched by the second switch or the video signal supplied from the host computer or an external video signal source so as to be displayed on the screen. One display device.