JP2014150400A - Image processing apparatus, color adjustment system, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image processing apparatus and the like for accurately calculating output image data for changing temperatures of colors of displayed images, and suppressing a change in gradation expression of the images after the change of the color temperature.SOLUTION: An image processing apparatus includes: a color data acquisition unit 213 that acquires color data on an image to be displayed when a color signal for performing color adjustment of a display device is output; a color temperature information acquisition unit 214 that acquires information on a color temperature used in the display device; a first correspondence derivation unit 215 that determines first correspondence between the color signal and the color data; a correction color signal derivation unit 216 that determines a correction color signal that is a color signal adopted when an image is displayed on the display device at the color temperature on the basis of the first correspondence; a color value conversion unit 218 that converts the correction color signal into a color value in a color space different from a color space constituting the color signal to determine a correction color value; and a conversion relation preparation unit 219 that prepares a color conversion table of a color of an image to be displayed on the display device at the color temperature on the basis of the correction color value.

Description

  The present invention relates to an image processing apparatus, a color adjustment system, and a program.

In Patent Document 1, first, input data (r, g, b) to a display having at least one input having a maximum value and a target white chromaticity (x _w , y _w ) is input as video. (R, G, B) are stored as correction data when all are maximum values, and then the luminance level Y _{i at} each input level i is on the luminance curve to be set with reference to the luminance level at the maximum input. adjusted to this brightness level Yi and white chromaticity _{(x w, y} w) 3 stimulus values from the _{(X i, Y i, Z} i) seeking, the tristimulus values _{(X i, Y i,} Z input data (r to the display the obtained closest combination to _i), and g, b) a video input _{(R i,} G _i, the correction data _{(r i} for _{B i),} g _i, and _{b i),} Find this for all input levels i except the maximum input level. Gamma correction circuit which stores this red LUT, green LUT, the three blue LUT Te have been disclosed.

JP 2006-258850 A

  For a display device that displays an image, it is desirable that output image data for changing the color temperature of the image to be displayed is accurately calculated, and the gradation expression of the image after changing the color temperature is less likely to change.

  According to the first aspect of the present invention, when the color signal acquisition unit that acquires a color signal used for color adjustment of the display device and the color signal is output to the display device, the display device A color information acquisition unit that acquires color information of an image to be displayed, a color temperature information acquisition unit that acquires color temperature information used for displaying an image on the display device, and the color signal acquisition unit that acquires the color information A first correspondence derivation unit that obtains a first correspondence that is a correspondence between the color signal and the color information obtained by the color information obtaining unit; and the first correspondence derivation unit that obtains the first correspondence relationship. From a first correspondence relationship, a correction color signal deriving unit for obtaining a correction color signal which is a color signal taken when an image is displayed on the display device at the color temperature acquired by the color temperature information acquisition unit; Obtained by the correction color signal deriving unit The correction color signal is converted into a color value in a color space different from the color space constituting the color signal to obtain a correction color value, and the correction color value obtained by the color value conversion unit And a conversion relationship creating unit that creates a color relationship of an image displayed on the display device at the color temperature.

The invention according to claim 2 is characterized in that the conversion relationship creating unit creates the conversion relationship based on the correction color signal obtained by the correction color signal deriving unit in addition to the correction color value. An image processing apparatus according to claim 1.
According to a third aspect of the present invention, a second correspondence relationship derivation for obtaining a second correspondence relationship, which is a correspondence relationship for associating the color signal with a color value in a color space different from the color space constituting the color signal, is provided. A color space different from a color space constituting the color signal based on the second correspondence obtained by the second correspondence derivation unit. The image processing apparatus according to claim 1, wherein a correction color value is obtained by converting into a color value in the medium.
According to a fourth aspect of the present invention, the correction color signal deriving unit sets color information at the color temperature, converts the set color information into a color signal at the color temperature according to the first correspondence relationship, 4. The correction color signal is obtained by converting a color signal used for adjusting the color so that the converted color signal is a maximum value. It is an image processing apparatus of description.
The invention according to claim 5 is the image processing apparatus according to any one of claims 1 to 4, wherein the color signal includes a red signal, a green signal, and a blue signal.

  According to a sixth aspect of the present invention, when the color signal acquisition unit that acquires a color signal used for color adjustment of the display device and the color signal are output to the display device, the display device A color information acquisition unit that acquires color information of an image to be displayed, a color temperature information acquisition unit that acquires color temperature information used for displaying an image on the display device, and the color signal acquisition unit that acquires the color information A first correspondence derivation unit that obtains a first correspondence that is a correspondence between the color signal and the color information acquired by the color information acquisition unit; and color information at the color temperature is set and set. Based on the color signal at the color temperature obtained by the corrected color signal deriving unit, the corrected color signal deriving unit that converts color information into a color signal at the color temperature according to the first correspondence relationship, To display on the display device An image processing apparatus characterized by comprising a conversion relationship creation unit that creates a color conversion relationship of the image.

  According to a seventh aspect of the present invention, there is provided color conversion means for performing a color conversion process on a color signal created for displaying an image on a display device using a predetermined conversion relationship and outputting the color signal to the display device. A conversion relation creating means for creating the conversion relation used in the color conversion means for performing color adjustment of an image displayed on the display device, the conversion relation creating means comprising: A color signal acquisition unit that acquires a color signal used for color adjustment, and color information that acquires color information of an image displayed on the display device when the color signal is output to the display device An acquisition unit, a color temperature information acquisition unit that acquires information of a color temperature used to display an image on the display device, and the color signal acquired by the color signal acquisition unit and the color information acquisition unit In correspondence with the color information The color temperature acquired by the color temperature information acquisition unit from the first correspondence relationship deriving unit for obtaining the first correspondence relationship and the first correspondence relationship obtained by the first correspondence relationship deriving unit. A correction color signal deriving unit for obtaining a correction color signal which is a color signal taken when an image is displayed on the display device, and a color in a color space different from a color space constituting the color signal. A color value conversion unit for converting to a color value to obtain a correction color value, and a color conversion relationship of an image displayed on the display device at the color temperature based on the correction color value obtained by the color value conversion unit And a conversion relationship creating unit.

  In the invention according to claim 8, the color signal acquired by the color signal acquisition unit of the conversion relationship creating unit is a color used to define the conversion relationship used by the color conversion unit. The color adjustment system according to claim 7, wherein the color adjustment system is a signal.

  According to a ninth aspect of the present invention, there is provided color conversion means for performing a color conversion process on a color signal created for displaying an image on a display device using a predetermined conversion relationship and outputting the color signal to the display device. Conversion relation creating means for creating the conversion relation used in the color conversion means for performing color adjustment of an image displayed on the display device, wherein the conversion relation creating means is a color of the display device. A color signal acquisition unit that acquires a color signal used for adjustment, and color information acquisition that acquires color information of an image displayed on the display device when the color signal is output to the display device A color temperature information acquisition unit that acquires information on a color temperature used for displaying an image on the display device, the color signal acquired by the color signal acquisition unit, and the color information acquired by the color information acquisition unit Correspondence with color information A first correspondence relationship deriving unit that obtains a correspondence relationship of 1 and a correction color signal that sets color information at the color temperature and converts the set color information into a color signal at the color temperature according to the first correspondence relationship And a conversion relationship creating unit that creates a color conversion relationship of an image displayed on the display device at the color temperature based on the color signal at the color temperature obtained by the correction color signal deriving unit. A color adjustment system comprising:

  According to a tenth aspect of the present invention, when a computer obtains a color signal used for color adjustment of a display device and outputs the color signal to the display device, the display device Correspondence relationship between a function for obtaining color information of a displayed image, a function for obtaining color temperature information used for displaying an image on the display device, and the obtained color signal and the obtained color information And a correction color signal which is a color signal taken when an image is displayed on the display device at the obtained color temperature from the obtained first correspondence relationship and the obtained first correspondence relationship. A function for obtaining, a function for obtaining a correction color value by converting the correction color signal into a color value in a color space different from a color space constituting the color signal, and the color temperature based on the obtained correction color value To display on the display A function of creating a color conversion relationship of a program for actualizing.

  According to an eleventh aspect of the present invention, when the computer obtains a color signal used for color adjustment of the display device and outputs the color signal to the display device, the display device Correspondence relationship between a function for obtaining color information of a displayed image, a function for obtaining color temperature information used for displaying an image on the display device, and the obtained color signal and the obtained color information A function for obtaining a first correspondence relationship, a function for setting color information at the color temperature, and converting the set color information into a color signal at the color temperature according to the first correspondence relationship, And a function of creating a color conversion relationship of an image displayed on the display device at the color temperature based on a color signal at the color temperature.

According to the first aspect of the present invention, it is possible to provide an image processing apparatus in which the gradation expression is less likely to change even when the color temperature of the image to be displayed is changed as compared with the case where the present configuration is not provided.
According to the invention of claim 2, the accuracy of color adjustment is further improved as compared with the case where this configuration is not provided.
According to the third aspect of the present invention, it is possible to use a color space suitable for obtaining the correction color value as compared with the case where the present configuration is not provided.
According to the fourth aspect of the present invention, the corrected color signal is obtained using the first correspondence relationship that is the device characteristic considering the image after the color temperature change, as compared with the case where the present configuration is not provided. Can do.
According to the invention of claim 5, the accuracy of color adjustment is further improved in a device that displays an image by additive color mixing, as compared with the case where this configuration is not provided.
According to the sixth aspect of the present invention, a white image at the changed color temperature can be displayed even if the color temperature of the image to be displayed is changed as compared with the case where the present configuration is not provided.
According to the seventh aspect of the present invention, even when the color temperature of the image displayed on the display means is changed, the color conversion process can be performed with higher accuracy than when the present configuration is not provided. Possible color adjustment system can be provided.
According to the eighth aspect of the present invention, the conversion relationship of the color conversion means can be changed more easily than in the case where the present configuration is not provided.
According to the ninth aspect of the present invention, even when the color temperature of the image displayed on the display means is changed, the color conversion process can be performed with higher accuracy than when the present configuration is not provided. Possible color adjustment system can be provided.
According to the tenth aspect of the present invention, compared to the case where the present configuration is not provided, a function that makes it difficult for the gradation expression to change even if the color temperature of the image to be displayed is changed can be realized by a computer.
According to the eleventh aspect of the present invention, compared to the case where the present configuration is not provided, a function capable of displaying a white image at the changed color temperature even if the color temperature of the image to be displayed is changed. It can be realized by a computer.

It is a figure which shows the structural example of the image display system of this Embodiment. It is a figure for demonstrating the state which attached the color setting system to the image display system shown in FIG. It is the figure which showed the hardware constitutions about PC for setting. It is a figure explaining the example of functional composition about PC for setting of this embodiment. FIG. 5 is a diagram illustrating data used or generated in FIG. 4. It is the figure which gave the specific example of the data used or produced | generated in FIG. An example of the white correction RGBLUT when the white correction RGB value is (Rs, Gs, Bs) = (170, 159, 143) is shown. It is the figure which gave the specific example of the data used or produced | generated when not using Lab color space but XYZ color space. It is the flowchart explaining the operation example of PC for setting. (A)-(b) are data groups used to create a multidimensional LUT and input images using the multidimensional LUT in the color processing apparatus according to the first and second embodiments. It is a figure explaining the method to convert data into output image data. It is a figure explaining the example of a function structure about the setting for this Embodiment. It is a figure explaining the data used or produced | generated in FIG.

<Description of overall configuration of image display system>
Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.

FIG. 1 is a diagram illustrating a configuration example of an image display system 10 according to the present embodiment.
The image display system 10 is connected to a network N and has a display PC (Personal Computer) 11 that creates image data (input image data) for display and the like, and a display device 12 that displays an image on a display screen 121. The input image data input from the display PC 11 is subjected to color conversion processing using a color conversion table (conversion relationship), and the obtained image data (display output image data) is output to the display device 12. And a color processing device 13 as an example of color conversion means. The image display system 10 is connected to another image display system, various printers, and the like via the network N.

  In the image display system 10, the display PC 11 and the color processing device 13 are connected via a DVI (Digital Visual Interface), and the color processing device 13 and the display device 12 are also connected via a DVI. Instead of DVI, connection may be made via HDMI (High-Definition Multimedia Interface) or DisplayPort.

  The display PC 11 as an example of a supply device is a so-called general-purpose personal computer. The display PC 11 is configured to generate input image data and the like by operating various application software under the management of the OS.

  Further, the display device 12 is configured by a device having a function of displaying an image by additive color mixing, such as a liquid crystal display for a PC, a liquid crystal television, or a projector. Therefore, the display method in the display device 12 is not limited to the liquid crystal method. In the example shown in FIG. 1, the display screen 121 is provided in the display device 12. However, when a projector is used as the display device 12, for example, the display screen 121 is a screen provided outside the display device 12. It becomes.

  The color processing apparatus 13 includes an output image data creation unit 131 and a color conversion table storage unit 132 as an example of a storage unit.

  The output image data creation unit 131 performs color conversion on the input image data input from the display PC 11 using the color conversion table read from the color conversion table storage unit 132, and the obtained output image for display. Data is output to the display device 12. In the present embodiment, the output image data creation unit 131 receives a red signal (R), a green signal (G), and a blue signal (B) as input image data, and performs color conversion to output red as output image data. A signal (R ′), a green signal (G ′), and a blue signal (B ′) are output.

  The color conversion table storage unit 132 stores a color conversion table used in creating output image data for display by the output image data creation unit 131 described above. Here, examples of the color conversion table include a conversion matrix (matrix), a one-dimensional LUT (Look Up Table), a multi-dimensional LUT, and the like. In this embodiment, the color conversion is performed with higher accuracy. A multidimensional LUT is used. The color conversion table storage unit 132 is configured by a non-volatile memory (for example, a flash memory) that is readable and writable and that can retain stored contents without supplying power.

  Here, the image display system 10 shown in FIG. 1 exemplifies a case where one display device 12 is connected to one display PC 11 via one color processing device 13, but the present invention is not limited thereto. It is not something that can be done. For example, a so-called multi-monitor configuration may be employed in which a plurality of display devices 12 are connected to one color processing device 13 and different continuous images are displayed on each display device 12.

  In the image display system 10 of the present embodiment, the color processing device 13, not the display PC 11, creates output image data for display by performing color conversion processing on the input image data. Here, the color conversion table used in the color conversion processing in the color processing device 13 is created and changed so as to match the color temperature desired for the image displayed on the display device 12 in consideration of the device characteristics of the display device 12. Is done. In the image display system 10, a color conversion table that takes into account the device characteristics of the display device 12 is created and changed in a state where a setting PC 21 described later is externally attached to the image display system 10.

Next, a description will be given of a color setting system attached to the image display system 10 in creating a color conversion table used in the color processing device 13.
FIG. 2 is a diagram for explaining a state in which the color setting system 20 is attached to the image display system 10 shown in FIG.

  The color setting system 20 according to the present embodiment includes a setting PC 21 connected to the color processing device 13 of the image display system 10 and a display screen 121 connected to the setting PC 21 and on the display device 12 of the image display system 10. And a colorimeter 22 for measuring the color of the displayed image.

  In this color setting system 20, the setting PC 21 and the colorimeter 22 are connected via a USB (Universal Serial Bus) or RS-232C. Further, the setting PC 21 in the color setting system 20 and the color processing device 13 in the image display system 10 are connected via a USB.

  In the color setting system 20, the setting PC 21 is a so-called general-purpose personal computer, which will be described later in detail. For example, a notebook PC having excellent portability is used. The setting PC 21 is also configured to operate various application software under the management of the OS.

  The colorimeter 22 is a sensor that measures the color of the image displayed on the display screen 121 by being arranged in contact with or non-contacting the display screen 121 provided in the display device 12 of the image display system 10. I have. In this example, the size of the measurement area by the sensor provided in the colorimeter 22 is set to be equal to or smaller than the size of the display screen 121. The colorimeter 22 is configured not to perform color measurement on the entire area of the display screen 121 but to perform color measurement on a predetermined partial area of the entire area.

  Here, the color setting system 20 shown in FIG. 2 exemplifies a case where one colorimeter 22 is connected to one setting PC 21, but is not limited thereto. For example, a plurality of colorimeters 22 can be connected to one setting PC 21.

  In the present embodiment, the setting PC 21 provided in the color setting system 20 creates a color conversion table, and performs color conversion on the color conversion table storage unit 132 provided in the color processing device 13 of the image display system 10. It is possible to write a table. In the present embodiment, the setting PC 21 can be regarded as a conversion relationship creating means (image processing device) for creating a color conversion table used in the color processing device 13.

  The image display system 10 according to the present embodiment normally performs color conversion on the input image data created by the display PC 11 with the color processing device 13 in a state where the color setting system 20 is not attached. An image (display image) based on the obtained output image data for display is displayed on the display screen 121 of the display device 12. On the other hand, the image display system 10 is based on the colorimetric output image data created by the color processing device 13 with the color setting system 20 attached when the color conversion table is created or changed. An image (color measurement image, color patch) is displayed on the display screen 121 of the display device 12.

<Hardware configuration example of setting PC>
Next, the hardware configuration of the setting PC 21 will be described.
FIG. 3 is a diagram illustrating a hardware configuration of the setting PC 21.
The setting PC 21 is realized by a personal computer or the like as described above. As shown in the figure, the setting PC 21 includes a CPU (Central Processing Unit) 41 as a calculation means, a main memory 42 as a storage means, and an HDD (Hard Disk Drive) 43. Here, the CPU 41 executes various programs such as an OS (Operating System) and application software. The main memory 42 is a storage area for storing various programs and data used for execution thereof, and the HDD 43 is a storage area for storing input data for various programs, output data from various programs, and the like.

  Further, the setting PC 21 includes a communication interface (hereinafter referred to as “communication I / F”) 44 for performing communication with the outside, a video memory, a display, etc., a monitor 45 for displaying images, a keyboard, and the like. And an input device 46 such as a mouse.

<Functional configuration example of setting PC>
[First Embodiment]
As a functional configuration of the setting PC, first, the first embodiment will be described.
FIG. 4 is a diagram illustrating an example of a functional configuration of the setting PC 21 according to the present embodiment. FIG. 5 is a diagram illustrating data used or generated in FIG. FIG. 6 is a diagram showing a specific example of data used or generated in FIG.
Hereinafter, the functional configuration of the setting PC 21 will be described with reference to FIGS. 4, 5, and 6.

  The setting PC 21 illustrated in FIG. 4 includes a color signal acquisition unit 211, a color signal output unit 212, a color data acquisition unit 213, a color temperature information acquisition unit 214, a first correspondence relationship derivation unit 215, and a correction. A color signal deriving unit 216, a second correspondence relationship deriving unit 217, a color value converting unit 218, and a conversion relationship creating unit 219 are provided.

  The color signal acquisition unit 211 acquires a red signal (Rin), a green signal (Gin), and a blue signal (Bin) as input color signals from the color conversion table storage unit 132 of the color processing device 13. Rin, Gin, and Bin are stored in the color conversion table storage unit 132, unlike the red signal (R), green signal (G), and blue signal (B) as input image data input from the display PC 11. Each grid point data of the multidimensional LUT. The input color signals Rin, Gin, and Bin are red, green, and blue color signals used for color adjustment of the display device 12, and the values of Rin, Gin, and Bin are In other words, the values of the red signal, the green signal, and the blue signal that are used to define the multi-dimensional LUT as the conversion relationship can also be described.

For example, when the image is displayed with 256 gradations on the display device 12, Rin, Gin, and Bin are any integer values from 0 to 255. In the example shown in the first column of FIG. 6, Rin, Gin, and Bin take values set every 64, and are any one of five values of 0, 64, 128, 192, and 255. Therefore, there are a total of 5 ³ = 125 pairs of Rin, Gin, and Bin. Therefore, a data group composed of 125 sets is configured by combinations of Rin, Gin, and Bin values. In the present embodiment, hereinafter, a data group composed of a set of Rin, Gin, and Bin may be referred to as an RGB data group. This RGB data group is illustrated as an RGB data group D3 in FIG. 5 and is a data group illustrated in the first column of FIG.

The color signal output unit 212 actually transmits Rin, Gin, and Bin acquired by the color signal acquisition unit 211 to the display device 12.
In the display device 12, an image of a colorimetric image is displayed based on Rin, Gin, and Bin transmitted from the color signal output unit 212. The color of the colorimetric image displayed on the display device 12 is read by the colorimeter 22. Then, the colorimeter 22 transmits color information (color data) acquired by reading the image of each colorimetric image to the setting PC 21. At this time, the color data output from the colorimeter 22 is, for example, an X value, a Y value, and a Z value in an XYZ color space.

  The color data acquisition unit 213 is an example of a color information acquisition unit, and acquires the color data transmitted from the colorimeter 22. That is, the color data acquisition unit 213 acquires color data of an image displayed on the display device 12 when Rin, Gin, and Bin are output to the display device 12.

  This color data is composed of a set of X, Y, and Z. Since the display device 12 displays images of colorimetric images for all 125 sets of Rin, Gin, and Bin acquired by the color signal acquisition unit 211, a set of X, Y, and Z as acquired color data. Will be 125 sets. In the present embodiment, hereinafter, a data group composed of the set of X, Y, and Z may be referred to as an XYZ data group. This XYZ data group is a data group illustrated in the second column of FIG.

  The color temperature information acquisition unit 214 acquires color temperature information used for displaying an image on the display device 12. More specifically, the color temperature information acquisition unit 214 acquires color temperature setting information when displaying a white image on the display device 12. This color temperature is not the color temperature set for the display device 12 at this time, but the color temperature that the display device 12 wants to newly set. For example, the color temperature information is displayed on a monitor 45 (see FIG. 3) on a setting screen that prompts the user to set the color temperature, and the operator operates the input device 46 (see FIG. 3) such as a keyboard or a mouse. It can be obtained by entering the numerical value of.

The first correspondence relationship deriving unit 215 obtains a first correspondence relationship that is a correspondence relationship between Rin, Gin, and Bin acquired by the color signal acquisition unit 211 and the color data acquired by the color data acquisition unit 213.
This first correspondence relationship is a correspondence relationship between the above-described Rin, Gin, Bin (RGB data group) and X, Y, Z (XYZ data group). That is, it is a correspondence relationship with the color displayed on the display device 12 when an image is displayed on the display device 12 based on Rin, Gin, and Bin. This first correspondence relationship can be rephrased as the correspondence relationship between the input image data input to the display device 12 and the color actually displayed on the display device 12, and is a device characteristic of the display device 12.

  In FIG. 5, this first correspondence relationship is illustrated as a device characteristic T1. In FIG. 6, this first correspondence relationship can be illustrated as a correspondence relationship between each pair of Rin, Gin, and Bin in the first column and each pair of X, Y, and Z in the second column.

When the correction color signal deriving unit 216 displays an image on the display device 12 at the color temperature acquired by the color temperature information acquiring unit 214 from the first corresponding relationship obtained by the first corresponding relationship deriving unit 215. A correction color signal, which is a color signal used in the above, is obtained.
Here, the correction color signal deriving unit 216 first sets X, Y, and Z values (represented as Xs, Ys, and Zs here) at the color temperature acquired by the color temperature information acquisition unit 214. Specifically, the Xs value and the Zs value are uniquely determined by the color temperature, and when the color temperature is 6500K, for example, (Xs, Zs) = (95, 85). However, since Ys (luminance) can take various values, Ys = 100 (100 cd / m ² ) is selected here. This is a numerical value in accordance with the usage status actually displayed on the display device 12. That is, when a white image is displayed on the display device 12, the value is normally around Yh = 100. As a result, (Xs, Ys, Zs) = (95, 100, 85) is set in the present embodiment.
This is illustrated as Xs, Ys, and Z value D1 in FIG.

Next, the correction color signal deriving unit 216 uses prediction calculations such as a linear regression model, multiple regression analysis, and a neuro model using the first correspondence relationship obtained by the first correspondence relationship deriving unit 215, and Xs , Ys, and Zs are converted into R, G, and B values. That is, the R, G, and B values after the Xs, Ys, and Zs values are converted using the first correspondence relationship are displayed on the display device 12 at the color temperature acquired by the color temperature information acquisition unit 214. Thus, the color signal (input image data) is input when a white image is displayed. In the present embodiment, R, G, and B after conversion are expressed as Rs, Gs, and Bs, respectively, and these are called white correction RGB values.
Here, the value obtained by converting (Xs, Ys, Zs) = (95, 100, 85) using the first correspondence relationship is (Rs, Gs, Bs) = (170, 159, 143). ).

  Note that the process of converting Xs, Ys, and Zs into Rs, Gs, and Bs using the first correspondence relationship is performed by converting the Xs, Ys, and Z values D1 into white correction RGB values D2 using the device characteristics T1 in FIG. This is illustrated as processing to be performed.

  Then, the correction color signal deriving unit 216 creates a white correction RGBLUT for performing white correction of Rin, Gin, Bin (RGB data group) based on the white correction RGB values (Rs, Gs, Bs). This white correction RGBLUT is a one-dimensional LUT for correcting each of Rin, Gin, and Bin of the RGB data group with the white correction RGB value (Rs, Gs, Bs) as a maximum value. The white correction RGBLUT is illustrated as white correction RGBLUT D4 in FIG.

FIG. 7 shows an example of the white correction RGBLUT when the white correction RGB values are (Rs, Gs, Bs) = (170, 159, 143).
In the illustrated one-dimensional LUT, 0-170 is connected with a straight line for the red (R) signal. Similarly, for a green (G) signal, 0-159 is connected by a straight line, and for a blue (B) signal, 0-143 is connected by a straight line. In addition, it is not restricted to the case where it connects with a straight line, You may connect with curves, such as a quadratic curve and a cubic curve.
Then, Rin, Gin, Bin (RGB data group) having a maximum value of 255 by the one-dimensional LUT set in this way is set as a white correction RGB value (Rs, Gs, Bs) = (170, 159, 143). Can be converted into an RGB data group having a maximum value.

The correction color signal deriving unit 216 converts Rin, Gin, and Bin (RGB data group) using the white correction RGBLUT illustrated in FIG. Here, Rin after conversion, Gin after conversion, and Bin after conversion are expressed as Rh, Gh, and Bh, respectively, and a data group constituted by each set of Rh, Gh, and Bh is a white correction RGB data group. Call it.
This white correction RGB data group is a correction color signal which is a color signal that can be taken when the display device 12 displays an image at the color temperature acquired by the color temperature information acquisition unit 214 here. That is, Rh takes an integer value of 0 to 170. Similarly, Gh takes an integer value of 0 to 159, and Bh takes an integer value of 0 to 143.

  Note that the process of converting Rin, Gin, Bin (RGB data group) into Rh, Gh, Bh (white correction RGB data group) using white correction RGBLUT uses RGB correction data D3 in FIG. 5 using white correction RGBLUT D4. This is illustrated as processing for conversion into the white correction RGB data group D5. In FIG. 6, this conversion process can be exemplified as a process of converting each set of Rin, Gin, and Bin in the first column into each set of Rh, Gh, and Bh in the fourth column.

The second correspondence relationship deriving unit 217 performs color values in a color space different from the input color signals Rin, Gin, Bin (RGB data group) and the color space (RGB color space) constituting Rin, Gin, Bin. Is obtained as a second correspondence relationship.
In the present embodiment, for example, a Lab color space which is a device-independent color space is used as a color space different from the color space (RGB color space) constituting Rin, Gin, and Bin. Therefore, the second correspondence relationship is such that Rin, Gin, and Bin (RGB data group) are associated with color values (L ^* , a ^* , b ^* ) in the Lab color space.
To obtain the second correspondence, first, X, Y, Z (XYZ data group) acquired by the color data acquisition unit 213 is converted into color values (L ^* , a ^* , b ^* ) in the Lab color space. . This conversion can be performed by a known mathematical formula. On the other hand, Rin, Gin, Bin (RGB data group) and X, Y, Z (XYZ data group) are already known from the first correspondence. Therefore, Rin, Gin, Bin (RGB data group) can be associated with color values (L ^* , a ^* , b ^* ) in the Lab color space. Here, each set of color values (L ^* , a ^* , b ^* ) associated with each set of Rin, Gin, Bin is denoted as L ^* in, a ^* in, b ^* in, and L ^* in, a ^A data group composed of each set of ^* in and b ^* in is called a Lab data group. This second correspondence relationship can be rephrased as a correspondence relationship between the input image data input to the display device 12 and the value that the color actually displayed on the display device 12 is expressed in the Lab color space. This is one of the device characteristics of the device 12.

In FIG. 5, this second correspondence relationship is illustrated as a device characteristic T2. In FIG. 6, this second correspondence relationship is illustrated as a correspondence relationship between each pair of Rin, Gin, Bin in the first column and each pair of L ^* in, a ^* in, b ^* in in the third column. it can.

The color value conversion unit 218 uses the second correspondence relationship obtained by the second correspondence relationship deriving unit 217 to convert the correction color signal obtained by the correction color signal deriving unit 216 into a color space constituting Rin, Gin, and Bin. A color value in a color space different from (RGB color space) is converted to obtain a corrected color value.
That is, by using the correspondence between the second correspondence Rin, Gin, Bin (RGB data group) and L ^* in, a ^* in, b ^* in (Lab data group), Rh, Gh, Bh ( The white correction RGB data group) is converted into a correction color value composed of L ^* , a ^* , and b ^* values. Here ^L * associated Rh, Gh, each set of Bh ^is, a *, denoted ^{b *} of each pair ^L * ^h, a * ^h, and ^{b * h, L * h,} a * h, b ^{* A} data group consisting of each set of h is called a white correction Lab data group.

The process of converting Rh, Gh, Bh (white correction RGB data group) into L ^* h, a ^* h, b ^* h (white correction Lab data group) using the second correspondence relationship is shown in FIG. The correction RGB data group D5 is illustrated as a process of converting into a white correction Lab data group D6 using the device characteristic T2. In FIG. 6, this conversion process can be exemplified as a process for converting each set of Rh, Gh, Bh in the fourth column into each set of L ^* h, a ^* h, b ^* h in the fifth column.

  The conversion relation creating unit 219 uses a multidimensional LUT as a color conversion table (conversion relation) of the colors of images displayed on the display device 12 at the acquired color temperature based on the corrected color value obtained by the color value conversion unit 218. Create

The procedure for creating a multidimensional LUT by the conversion relationship creation unit 219 is as follows. The following procedure is processing when the Lab color space is used as a device-independent space.
(1) First, Rin, Gin, and Bin (RGB data group) are converted into color values in the Lab color space by a known mathematical formula (for example, a mathematical formula for converting the sRGB color space into the Lab color space). A data group consisting of this set of color values is assumed to be an sLab data group.
(2) Next, the sLab data group and the white correction Lab data group are compared, and further compared with the white correction RGB data group, a set of color values constituting the sLab data group is set as a white correction RGB data group. . That is, conversion is performed from sLab data group → white correction Lab data group → white correction RGB data group. In this case, the numerical value of each set constituting the sLab data group is compared with the numerical value of the white correction Lab data group in the fifth column in FIG. Will be compared. Actually, since there are few places where the numerical values match, a known method such as a linear regression model, a high-order polynomial approximation model, or a neuro model is used to calculate the numerical values. Further, Rin, Gin, and Bin data to be used are lattice points of a multidimensional LUT, and conversion with higher accuracy can be performed with a larger number of lattice points.

Note that the same processing can be performed using, for example, an XYZ color space instead of the Lab color space described above. In this case, using the first correspondence relationship, the correction color signal obtained by the correction color signal deriving unit 216 is defined as an XYZ color space in a color space different from the color space (RGB color space) constituting Rin, Gin, and Bin. The correction color value is obtained by converting to the color value at.
That is, Rh, Gh, Bh (white correction RGB data group) using the correspondence relationship between Rin, Gin, Bin (RGB data group) and X, Y, Z (XYZ data group) as the first correspondence relationship. Are converted into corrected color values composed of X, Y, and Z values. Here, each set of X, Y, Z associated with each set of Rh, Gh, Bh is expressed as Xh, Yh, Xh, and a data group consisting of each set of Xh, Yh, Zh is a white correction XYZ data group Say.

  FIG. 8 is a diagram showing a specific example of data specifically used or generated at this time. In the example illustrated in FIG. 8, the first correspondence relationship can be exemplified as the correspondence relationship between each pair of Rin, Gin, and Bin in the first column and each pair of X, Y, and Z in the second column. The process of converting Rh, Gh, Bh (white correction RGB data group) into Xh, Yh, Zh (white correction XYZ data group) is performed by converting each set of Rh, Gh, Bh in the third column to Xh in the fourth column. , Yh, and Zh can be exemplified as a process of conversion.

  In order to create a multi-dimensional LUT by the conversion relationship creation unit 219, a set of color values constituting the RGB data group is converted into a set of white correction RGB data group by comparing the XYZ data group and the white correction XYZ data group. Can be done.

  As described above, Rin, Gin, Bin (RGB data group) can be converted into Rh, Gh, Bh (white correction RGB data group). Rh, Gh, and Bh (white correction RGB data group) are output as output color signals. In the present embodiment, the output color signal is stored as each grid point data of a multidimensional LUT as a color conversion table stored in the color conversion table storage unit 132. That is, the multidimensional LUT stored in the color conversion table storage unit 132 by the series of processes described above is changed to a multidimensional LUT that displays the image after the color temperature change on the display device 12.

  In the setting PC 21 shown in FIG. 3, the HDD 43 stores a program for realizing each function shown in FIG. Then, this program is loaded into the main memory 42, and processing based on this program is executed by the CPU 41, whereby these functions are realized.

  Specifically, in the setting PC 21, for example, an input color signal (Rin, Gin) with the color processing device 13 via the communication I / F 44 according to an instruction given by the CPU 41 based on a program prepared as application software or the like. , Bin) and output color signals (Rh, Gh, Bh). Similarly, color signals (Rin, Gin, Bin) and color data (X, Y, Z (XYZ data) are exchanged with the colorimeter 22 via the communication I / F 44 in accordance with instructions issued by the CPU 41 based on the program. Group)). Similarly, a color temperature setting screen or the like is displayed on the monitor 45, and the color temperature information is acquired via the input device 46. Further, the first correspondence relationship, X, Y, Z values (Xs, Ys, Zs), white correction RGB values (Rs, Gs, Bs), white correction at the color temperature acquired by the color temperature information acquisition unit 214 Calculation of RGBLUT, white correction RGB data group (Rh, Gh, Bh), second correspondence, white correction RGB data group (Rh, Gh, Bh), multidimensional LUT, etc. is realized by the CPU 41 performing calculations. can do.

<Description of operation of setting PC>
FIG. 9 is a flowchart illustrating an operation example of the setting PC 21.
Hereinafter, the operation of the setting PC 21 will be described with reference to FIGS.

  First, the color signal acquisition unit 211 acquires Rin, Gin, Bin (RGB data group) as input color signals from the color conversion table storage unit 132 of the color processing device 13 (step 801). As described above, Rin, Gin, and Bin are grid point data of the multidimensional LUT stored in the color conversion table storage unit 132 of the color processing device 13 in the present embodiment.

  Next, the color signal output unit 212 actually transmits the input color signals Rin, Gin, and Bin acquired by the color signal acquisition unit 211 to the display device 12 (step 802). In the display device 12, an image of a color measurement image is displayed based on Rin, Gin, and Bin transmitted by the color signal output unit 212, and the color is read by the colorimeter 22. The colorimeter 22 transmits the color data acquired by reading each colorimetric image to the setting PC 21.

Then, the color data acquisition unit 213 acquires X, Y, Z (XYZ data group) as the color data transmitted from the colorimeter 22 (step 803).
On the other hand, the color temperature information acquisition unit 214 acquires information on the color temperature used for displaying an image on the display device 12 (step 804).

  Next, the first correspondence relationship deriving unit 215 obtains a first correspondence relationship between Rin, Gin, Bin and color data (step 805). This first correspondence relationship is a correspondence relationship between the above-described Rin, Gin, Bin (RGB data group) and X, Y, Z (XYZ data group).

Next, the corrected color signal deriving unit 216 sets X, Y, and Z values (Xs, Ys, Zs) at the color temperature acquired by the color temperature information acquiring unit 214 (step 806).
Then, the correction color signal deriving unit 216 converts each value of Xs, Ys, and Zs into each value of R, G, and B (Rs, Gs, Bs) using the first correspondence relationship (step 807).
Further, the correction color signal deriving unit 216 creates a white correction RGBLUT for performing white correction of Rin, Gin, Bin (RGB data group) based on the white correction RGB values (Rs, Gs, Bs) (step 808). . The white correction RGBLUT is, for example, as illustrated in FIG.
Further, the correction color signal deriving unit 216 converts Rin, Gin, Bin (RGB data group) into Rh, Gh, Bh (white correction RGB data group) as correction color signals using the white correction RGBLUT (step 809). ).

Next, the second correspondence relationship deriving unit 217 calculates Rin, Gin, Bin (RGB data group) and color values in the Lab color space (L ^* in, a ^* in, b ^* in (Lab data group)). A second correspondence relationship to be associated is obtained (step 810).

The color value conversion unit 218 then converts Rh, Gh, Bh (white correction RGB data group) as correction color signals into color values (L ^* h) in the Lab color space, which are correction color values, from the second correspondence relationship. , A ^* h, b ^* h (white correction Lab data group)) (step 811).

Next, the conversion relationship creation unit 219 creates a multidimensional LUT as a color conversion table used when displaying an image at a color temperature on the display device 12 based on the corrected color value obtained by the color value conversion unit 218. (Step 812).
Further, the conversion relationship creating unit 219 outputs the created Rh, Gh, Bh (white correction RGB data group) as an output color signal (step 813). The output color signal is stored as grid point data of a multidimensional LUT that is a color conversion table stored in the color conversion table storage unit 132 of the color processing device 13.

[Second Embodiment]
Next, a second embodiment will be described as a functional configuration of the setting PC.
The configuration shown in FIGS. 4 to 9 is the same in the second embodiment. That is, also in the second embodiment, as shown in FIG. 4, the setting PC 21 includes a color signal acquisition unit 211, a color signal output unit 212, a color data acquisition unit 213, and a color temperature information acquisition unit 214. The first correspondence relationship deriving unit 215, the correction color signal deriving unit 216, the second correspondence relationship deriving unit 217, the color value converting unit 218, and the conversion relationship creating unit 219 are provided.
Also in the second embodiment, data as shown in FIG. 5 is used or generated, and a specific example thereof is as shown in FIG. 6. In the correction color signal deriving unit 216, 1 as shown in FIG. A dimension LUT is created.
Further, also in the second embodiment, the operation of the setting PC 21 is as described with reference to FIG.

On the other hand, in the second embodiment, the procedure for creating a multidimensional LUT in the conversion relationship creating unit 219 is partially different. That is, the processes (1) to (2) described above are as follows.
(1 ′) First, Rin, Gin, and Bin (RGB data group) are converted into color values in the Lab color space by a known mathematical expression (for example, a mathematical expression that converts the sRGB color space into the Lab color space). A data group consisting of this set of color values is assumed to be an sLab data group. The steps so far are the same as those in the first embodiment.
(2 ′) Next, the sLab data group and the white correction Lab data group are compared, and further compared with the RGB data group, the set of color values constituting the sLab data group is set as the RGB data group. That is, conversion is performed from sLab data group → white correction Lab data group → RGB data group. In this case, the numerical value of each set constituting the sLab data group is compared with the numerical value of the white correction Lab data group in the fifth column in FIG. 6, and further compared with the numerical value of the RGB data group in the first column in FIG. I will do it. Actually, since there are few places where the numerical values match, a known method such as a linear regression model, a high-order polynomial approximation model, or a neuro model is used to calculate the numerical values.

10A and 10B show data groups used to create a multidimensional LUT and a multidimensional LUT in the color processing apparatus 13 according to the first embodiment and the second embodiment. It is a figure explaining the method to convert input image data into output image data.
Among these, Fig.10 (a) is based on 1st Embodiment. Here, the white correction RGB data group and the white correction Lab data group are used to create a multidimensional LUT by the setting PC 21 as described in the above (1) and (2). It can also be said that the conversion relationship creation unit 219 creates a multidimensional LUT based on the white correction RGB data group obtained by the correction color signal deriving unit 216 in addition to the white correction Lab data group.
Further, by using the created multidimensional LUT, the output image data creation unit 131 of the color processing device 13 can directly convert the input image data into the output image data.

On the other hand, FIG. 10B is according to the second embodiment. Here, the RGB data group and the white correction Lab data group are used to create the multidimensional LUT by the setting PC 21 as described in the above (1 ′) to (2 ′).
Further, when the created multi-dimensional LUT is used, the maximum value of the converted gradation is 255. To display the image after changing the color temperature on the actual display device 12, for example, in FIG. Using the white correction RGBLUT as described above, it is necessary to further convert, for example, to an RGB value having (R, G, B) = (170, 159, 143) as a maximum value. The data after the two conversions is output image data.
Therefore, the output image data creation unit 131 of the color processing device 13 converts the input image data with the created multidimensional LUT, and further converts it with the white correction RGBLUT to convert it into output image data.

  As described above, in the present embodiment, the color conversion table stored in the color conversion table storage unit 132 of the color processing device 13 is changed when the color temperature of the image displayed on the display device 12 is changed. The multidimensional LUT used as the color conversion table reflects the device characteristics of the display device 12. Therefore, even if the display device 12 has nonlinear device characteristics, a multidimensional LUT is created in a form incorporating this nonlinearity. Therefore, even if the change in the color temperature of the image displayed on the display device 12 is changed, a change in gradation expression such as a decrease in the number of gradations hardly occurs, and more accurate color adjustment can be performed. In the case of the prior art, when the display device 12 has non-linear device characteristics, the gradation expression is particularly likely to change, and it is difficult to perform more accurate color adjustment.

  In this embodiment, Rin, Gin, and Bin (RGB data group) as colorimetric images are output to the colorimeter 22, and the colorimetric image by the colorimeter 22 is measured to obtain X, After obtaining Y and Z (XYZ data group), a color conversion table can be created by obtaining color temperature information. That is, if X, Y, and Z (XYZ data group) are acquired once as color data, the colorimetric image using the colorimeter 22 can be changed even if the color temperature of the image displayed on the display device 12 is changed again thereafter. The color conversion table after changing the color temperature can be created without performing the above measurement again.

[Third Embodiment]
Next, a third embodiment will be described as a functional configuration of the setting PC.
FIG. 11 is a diagram for explaining a functional configuration example of the setting PC 21 according to the present embodiment. FIG. 12 is a diagram illustrating data used or generated in FIG.

  The setting PC 21 shown in FIG. 11 includes a color signal acquisition unit 211, a color signal output unit 212, a color data acquisition unit 213, a color temperature information acquisition unit 214, a first correspondence relationship derivation unit 215, and a correction. A color signal deriving unit 216 and a conversion relationship creating unit 219 are provided. Here, the operations of the color signal acquisition unit 211, the color signal output unit 212, the color data acquisition unit 213, the color temperature information acquisition unit 214, and the first correspondence relationship deriving unit 215 are the same as those described with reference to FIG.

  In the present embodiment, the second correspondence derivation unit 217 and the color value conversion unit 218 are not provided as compared with the setting PC 21 shown in FIG. When FIG. 12 is compared with FIG. 5, the process up to the creation of the white correction RGBLUT D4 is performed. In other words, in the present embodiment, the correction color signal deriving unit 216 sets the X, Y, and Z values (Xs, Ys, Zs) at the color temperature acquired by the color temperature information acquisition unit 214. Then, white correction RGB values (Rs, Gs, Bs) are created based on the X, Y, and Z values (Xs, Ys, Zs). Further, the conversion relationship creating unit 219 creates a white correction RGBLUT D4 from the corrected RGB values (Rs, Gs, Bs). The white correction RGBLUT D4 becomes a color conversion table stored in the color conversion table storage unit 132 of the color processing device 13. The white correction RGBLUT D4 is the same as that shown in FIG.

  Even if the color conversion table stored in the color conversion table storage unit 132 of the color processing apparatus 13 is used for the white correction RGBLUT D4 in the present embodiment, it reflects the device characteristics of the display apparatus 12, and therefore the color temperature change Even later, the gradation expression of the display device 12 hardly changes. However, the accuracy of color adjustment is better when the multidimensional LUT described in the first embodiment and the second embodiment described above is used.

<Description of color adjustment system>
In the first embodiment and the second embodiment, the above-described color processing device 13 and setting PC 21 have predetermined input image data created to display an image on the display device 12. In order to adjust the color of the image displayed on the display device 12, the color processing device 13 that performs color conversion processing using the color conversion table and outputs it to the display device 12, and the color conversion table used in the color processing device 13. A setting signal PC 21 to be created, and the setting PC 21 has a color signal acquisition unit 211 for acquiring an input color signal (Rin, Gin, Bin) used for color adjustment of the display device 12, and a display device A color data acquisition unit 213 that acquires color data (X, Y, Z) of an image displayed on the display device 12 when an input color signal (Rin, Gin, Bin) is output to the display device 12; 12, acquired by the color temperature information acquisition unit 214 that acquires information of the color temperature used for displaying the image, and the input color signals (Rin, Gin, Bin) acquired by the color signal acquisition unit 211 and the color data acquisition unit 213. A first correspondence relationship deriving unit 215 that obtains a first correspondence relationship that is a correspondence relationship with the obtained color data (X, Y, Z), and a first correspondence relationship that is obtained by the first correspondence relationship deriving unit 215 From the relationship, a correction color signal deriving unit 216 for obtaining a correction color signal (Rh, Gh, Bh) that is a color signal taken when an image is displayed on the display device 12 at the color temperature acquired by the color temperature information acquisition unit 214. Then, the correction color signals (Rh, Gh, Bh) obtained by the correction color signal deriving unit 216 are converted into color values in a predetermined uniform color space, and the correction color values (L ^* h, a ^* h, b) are converted. color to determine the ^* h, etc.) A converting unit 218, the correction color values obtained by the color value conversion unit ^{218 (L * h, a *} h, b * h , etc.) based on the color of the image to be displayed on the display device 12 by the acquired color temperature And a conversion relationship creating unit 219 that creates a color conversion table of the color conversion table.

  In the third embodiment, the color processing device 13 and the setting PC 21 described above use input color data created for displaying an image on the display device 12 using a predetermined color conversion table. A color processing device 13 that performs color conversion processing and outputs it to the display device 12, and a setting PC 21 that creates a color conversion table used by the color processing device 13 for color adjustment of an image displayed on the display device 12. The setting PC 21 includes a color signal acquisition unit 211 that acquires input color signals (Rin, Gin, Bin) used for color adjustment of the display device 12, and an input color signal toward the display device 12. (Rin, Gin, Bin) is used to display the color data (X, Y, Z) of the image displayed on the display device 12 when it is output, and the display device 12 is used to display the image. A color temperature information acquisition unit 214 for acquiring information on the color temperature to be input, an input color signal (Rin, Gin, Bin) acquired by the color signal acquisition unit 211 and a color data (X, A first correspondence relationship deriving unit 215 that obtains a first correspondence relationship that is a correspondence relationship with Y, Z), and X, Y, and Z values (Xs, Ys, Zs) at the acquired color temperature are set. A correction color signal deriving unit 216 that converts the set values of X, Y, and Z (Xs, Ys, Zs) into color signals (Rs, Gs, Bs) at this color temperature according to the first correspondence relationship; Based on the color signals Rs, Gs, and Bs) at this color temperature obtained by the correction color signal deriving unit 216, a conversion for creating a color conversion table for the colors of images displayed on the display device 12 at this color temperature A relationship creating unit 219 It can be considered as a color adjustment system characterized by and.

  In the image display system 10 according to the present embodiment, the color processing device 13 is arranged separately from the display PC 11 and the display device 12 between the display PC 11 and the display device 12. However, it is not limited to this. For example, the function of the color processing device 13 may be built in the display PC 11 or may be built in the display device 12.

  In the present embodiment, the setting PC 21 is separate from the display PC 11, but the display PC 11 may have the function of the setting PC 21. In this case, the display PC 11 functions as an image processing apparatus (conversion relation changing unit).

<Description of the program>
The processing performed by the setting PC 21 in the present embodiment described above is prepared as a program such as application software as described above.

Therefore, in the first embodiment and the second embodiment, the processing performed by the setting PC 21 uses the input color signals (Rin, Gin, Bin) used for color adjustment of the display device 12 to the computer. A function of acquiring, and a function of acquiring color data (X, Y, Z) of an image displayed on the display device 12 when an input color signal (Rin, Gin, Bin) is output to the display device 12; Correspondence between the function of acquiring the color temperature information used for displaying the image on the display device 12 and the acquired input color signal (Rin, Gin, Bin) and the acquired color data (X, Y, Z) A correction color signal (Rh) that is a color signal taken when an image is displayed on the display device 12 at the acquired color temperature from the function for obtaining the first correspondence relationship that is a relationship and the obtained first correspondence relationship. , Gh, Bh) Obtains a corrected color signals (Rh, Gh, Bh) correction color values converted to color values in the different color space is a color space that constitutes a color signal ^{(L * h, a * h} , b * h , etc.) A function and a function of creating a color conversion table for the color of an image displayed on the display device 12 at the acquired color temperature based on the obtained correction color value (L ^* h, a ^* h, b ^* h, etc.) It can also be understood as a program that realizes

  In the third embodiment, the processing performed by the setting PC 21 includes a function of acquiring input color signals (Rin, Gin, Bin) used for color adjustment of the display device 12 in the computer, and a display device. 12, when the input color signal (Rin, Gin, Bin) is output to the display device 12, the display device 12 acquires the color data (X, Y, Z) of the image, and the display device 12 A first correspondence that is a correspondence relationship between the function of obtaining the color temperature information used for display and the obtained input color signal (Rin, Gin, Bin) and the obtained color data (X, Y, Z). A function for obtaining a relationship and each value (Xs, Ys, Zs) of X, Y, Z at the acquired color temperature are set, and each set value of X, Y, Z (Xs, Ys, Zs) is set. The color signal at this color temperature (R , Gs, Bs) and the color conversion table of the color of the image displayed on the display device 12 at this color temperature based on the obtained color signals (Rs, Gs, Bs) at this color temperature. It can also be understood as a program that realizes

  The program for realizing the present embodiment can be provided not only by communication means but also by storing it in a recording medium such as a CD-ROM.

  Although the present embodiment has been described above, the technical scope of the present invention is not limited to the scope described in the above embodiment. It is clear from the description of the scope of the claims that various modifications or improvements added to the above embodiment are also included in the technical scope of the present invention.

DESCRIPTION OF SYMBOLS 10 ... Image display system, 11 ... Display PC, 12 ... Display apparatus, 13 ... Color processing apparatus, 20 ... Color setting system, 21 ... Setting PC, 211 ... Color signal acquisition part, 212 ... Color signal output part, 213 ... color data acquisition unit, 214 ... color temperature information acquisition unit, 215 ... first correspondence relationship derivation unit, 216 ... corrected color signal derivation unit, 217 ... second correspondence relationship derivation unit, 218 ... color value conversion unit, 219 ... Conversion relation creation part, N ... Network

Claims (11)

A color signal acquisition unit for acquiring a color signal used for color adjustment of the display device;
A color information acquisition unit that acquires color information of an image displayed on the display device when the color signal is output to the display device;
A color temperature information acquisition unit for acquiring information of a color temperature used for displaying an image in the display device;
A first correspondence derivation unit for obtaining a first correspondence that is a correspondence between the color signal acquired by the color signal acquisition unit and the color information acquired by the color information acquisition unit;
It is a color signal taken when an image is displayed on the display device at the color temperature acquired by the color temperature information acquisition unit from the first correspondence relationship obtained by the first correspondence relationship deriving unit. A correction color signal deriving unit for obtaining a correction color signal;
A color value conversion unit for converting the correction color signal obtained by the correction color signal deriving unit into a color value in a color space different from the color space constituting the color signal and obtaining a correction color value;
Based on the corrected color value obtained by the color value conversion unit, a conversion relationship creating unit that creates a color conversion relationship of an image displayed on the display device at the color temperature;
An image processing apparatus comprising:   The image processing apparatus according to claim 1, wherein the conversion relationship creating unit creates the conversion relationship based on the correction color signal obtained by the correction color signal deriving unit in addition to the correction color value. . A second correspondence derivation unit that obtains a second correspondence that is a correspondence that associates the color signal with a color value in a color space different from the color space that constitutes the color signal;
The color value conversion unit converts the corrected color signal into a color value in a color space different from the color space constituting the color signal based on the second correspondence obtained by the second correspondence relation deriving unit. The image processing apparatus according to claim 1, wherein the correction color value is obtained by conversion.   The correction color signal deriving unit sets color information at the color temperature, converts the set color information into a color signal at the color temperature according to the first correspondence relationship, and sets the converted color signal as a maximum value. 4. The image processing apparatus according to claim 1, wherein the correction color signal is obtained by converting a color signal used for adjusting the color so that the color is adjusted.   The image processing apparatus according to claim 1, wherein the color signal includes a red signal, a green signal, and a blue signal. A color signal acquisition unit for acquiring a color signal used for color adjustment of the display device;
A color information acquisition unit that acquires color information of an image displayed on the display device when the color signal is output to the display device;
A color temperature information acquisition unit for acquiring information of a color temperature used for displaying an image in the display device;
A first correspondence derivation unit for obtaining a first correspondence that is a correspondence between the color signal acquired by the color signal acquisition unit and the color information acquired by the color information acquisition unit;
A correction color signal deriving unit that sets color information at the color temperature and converts the set color information into a color signal at the color temperature according to the first correspondence relationship;
Based on the color signal at the color temperature obtained by the correction color signal deriving unit, a conversion relationship creating unit that creates a color conversion relationship of an image displayed on the display device at the color temperature;
An image processing apparatus comprising: Color conversion means for performing color conversion processing on a color signal created for displaying an image on a display device using a predetermined conversion relationship and outputting the color signal to the display device;
Conversion relation creating means for creating the conversion relation used in the color conversion means for performing color adjustment of an image displayed on the display device;
With
The conversion relationship creating means includes:
A color signal acquisition unit for acquiring a color signal used for color adjustment of the display device;
A color information acquisition unit that acquires color information of an image displayed on the display device when the color signal is output to the display device;
A color temperature information acquisition unit for acquiring information of a color temperature used for displaying an image in the display device;
A first correspondence derivation unit for obtaining a first correspondence that is a correspondence between the color signal acquired by the color signal acquisition unit and the color information acquired by the color information acquisition unit;
It is a color signal taken when an image is displayed on the display device at the color temperature acquired by the color temperature information acquisition unit from the first correspondence relationship obtained by the first correspondence relationship deriving unit. A correction color signal deriving unit for obtaining a correction color signal;
A color value conversion unit for converting the correction color signal into a color value in a color space different from a color space constituting the color signal and obtaining a correction color value;
Based on the corrected color value obtained by the color value conversion unit, a conversion relationship creating unit that creates a color conversion relationship of an image displayed on the display device at the color temperature;
A color adjustment system comprising:   The color signal acquired by the color signal acquisition unit of the conversion relationship creating unit is a color signal used to define the conversion relationship used by the color conversion unit. Item 8. The color adjustment system according to Item 7. Color conversion means for performing color conversion processing on a color signal created for displaying an image on a display device using a predetermined conversion relationship and outputting the color signal to the display device;
Conversion relation creating means for creating the conversion relation used in the color conversion means for performing color adjustment of an image displayed on the display device;
With
The conversion relationship creating means includes:
A color signal acquisition unit for acquiring a color signal used for color adjustment of the display device;
A color information acquisition unit that acquires color information of an image displayed on the display device when the color signal is output to the display device;
A color temperature information acquisition unit for acquiring information of a color temperature used for displaying an image in the display device;
A first correspondence derivation unit for obtaining a first correspondence that is a correspondence between the color signal acquired by the color signal acquisition unit and the color information acquired by the color information acquisition unit;
A correction color signal deriving unit that sets color information at the color temperature and converts the set color information into a color signal at the color temperature according to the first correspondence relationship;
Based on the color signal at the color temperature obtained by the correction color signal deriving unit, a conversion relationship creating unit that creates a color conversion relationship of an image displayed on the display device at the color temperature;
A color adjustment system comprising: On the computer,
A function for acquiring a color signal used for color adjustment of the display device;
A function of acquiring color information of an image displayed on the display device when the color signal is output to the display device;
A function of acquiring color temperature information used to display an image on the display device;
A function for obtaining a first correspondence which is a correspondence between the acquired color signal and the acquired color information;
A function for obtaining a correction color signal, which is a color signal taken when an image is displayed on the display device at the obtained color temperature, from the obtained first correspondence relationship;
A function of converting the correction color signal into a color value in a color space different from a color space constituting the color signal and obtaining a correction color value;
A function of creating a color conversion relationship of an image displayed on the display device at the color temperature based on the obtained correction color value;
A program that realizes On the computer,
A function for acquiring a color signal used for color adjustment of the display device;
A function of acquiring color information of an image displayed on the display device when the color signal is output to the display device;
A function of acquiring color temperature information used to display an image on the display device;
A function for obtaining a first correspondence which is a correspondence between the acquired color signal and the acquired color information;
A function of setting color information at the color temperature and converting the set color information into a color signal at the color temperature according to the first correspondence relationship;
A function of creating a color conversion relationship of an image displayed on the display device at the color temperature based on the obtained color signal at the color temperature;
A program that realizes

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