JP5906880B2 - COLOR ADJUSTMENT DEVICE, COLOR ADJUSTMENT SYSTEM, AND PROGRAM - Google Patents

Description

  The present invention relates to a color adjustment device, a color adjustment system, and a program.

In Patent Document 1, when mapping the color gamut of an input signal to a color gamut of a narrower device, a common area of the input signal and the color gamut of the device is extracted, and the color gamut of the input signal is extracted from the device. A color processing device is disclosed that maps a non-common area obtained by removing a common area from a color gamut of an input signal to an area obtained by removing the common area from a color gamut of a device when mapping to a color gamut.
Further, in Patent Document 2, a color conversion parameter is obtained in advance from a color space obtained by subtracting a value on the black color space displayed by the first and second image output means, and is output to the first image output means. The black color displayed on the second image output means is obtained by subtracting the value on the black color space represented by the first image output means from the image data on the color space and performing color conversion using the color conversion parameters. A color correction processing method for performing color conversion of image data by adding values in the color space is disclosed.
Further, in Patent Document 3, since the color data of the input device is mapped to the color data of the output device by using the entire color reproduction region of each output device, the mapped color reproduction region can be reduced. No image processing method is disclosed.

JP2003-153020A JP 2001-36758 A JP 2011-155696 A

  Here, when images are displayed on a plurality of image display devices, it is desirable that the respective color representations are closer.

  The invention according to claim 1 is acquired by a color value acquisition unit that acquires a color value when a predetermined image is displayed on a plurality of image display devices that display images, and the color value acquisition unit. A characteristic value deriving unit for deriving a predetermined characteristic value of the image display device from the obtained color value, and correcting the input image signal from the characteristic values derived by the characteristic value deriving unit. Characteristic values other than the first input image signal correction item and the first input image signal correction item, which are common correction items for color adjustment of the image of the image display device, and the input image signal A correction item selection unit that selects a second input image signal correction item, which is a common correction item for color-adjusting the image of each of the plurality of image display devices, and the correction item selection The first input image selected by the section Target characteristic value setting for setting a target characteristic value, which is a characteristic value that is a common target when the image is color-adjusted by the plurality of image display devices, for the correction item for the signal and the correction item for the second input image signal A correction coefficient deriving unit for deriving a correction coefficient for correcting the characteristic value to the target characteristic value set by the target characteristic value setting unit, and a correction coefficient derived by the correction coefficient deriving unit. And a conversion relationship creating unit that creates a conversion relationship for converting the input image signal for each image display device in order to perform color adjustment of the images of the plurality of image display devices. It is.

According to a second aspect of the present invention, a color gamut when the input image signal is corrected by the first input image signal correction item and the input image signal are corrected by the second input image signal correction item. The color adjustment device according to claim 1, further comprising a color gamut matching unit that matches the current color gamut.
According to a third aspect of the present invention, the target characteristic value setting unit sets the target characteristic value by weighting reflecting the frequency of use of the image display device. The color adjusting device according to claim 1.
According to a fourth aspect of the present invention, the correction item selection unit has a luminance when a black image is displayed on the image display device as the first input image signal correction item. Color temperature when displaying a white image, color gamut shape of the image display device, luminance when a white image is displayed on the image display device, and black image displayed on the image display device 4. The color adjusting apparatus according to claim 1, wherein at least one of hue and saturation is selected.
According to a fifth aspect of the present invention, the color value acquisition unit displays a color value when a white image is displayed on the image display device as a color value when a predetermined image is displayed. 5. The color value when a black image is displayed on the apparatus and the color value of the main color when the main color is displayed on the image display apparatus are acquired. 6. The color adjusting device according to claim 1.

  The invention according to claim 6 is a plurality of image display devices that display images, a color value acquisition unit that acquires color values when a predetermined image is displayed on the plurality of image display devices, A characteristic value deriving unit for deriving a predetermined characteristic value of the image display device from the color value acquired by the color value acquiring unit, and an input from among the characteristic values derived by the characteristic value deriving unit Other than the first input image signal correction item and the first input image signal correction item, which are common correction items for color-adjusting the images of the plurality of image display devices by correcting the image signal A correction item that is a characteristic value and selects a second input image signal correction item that is a common correction item for color-adjusting the image of each of the plurality of image display devices by correcting the input image signal Selected by the selection unit and the correction item selection unit. For the first input image signal correction item and the second input image signal correction item, the target characteristic which is a characteristic value that is a common target when color-adjusting an image in the plurality of image display devices A target characteristic value setting unit for setting a value, a correction coefficient deriving unit for deriving a correction coefficient for correcting the characteristic value to the target characteristic value set by the target characteristic value setting unit, and the correction coefficient deriving unit A conversion relationship creating unit that creates a conversion relationship for converting an input image signal for each image display device in order to perform color adjustment of images of the plurality of image display devices based on the correction coefficient derived by This is a color adjustment system characterized by that.

The invention according to claim 7 is a function of acquiring a color value when a predetermined image is displayed on a plurality of image display devices that display an image on a computer, and from the acquired color value, A function for deriving a predetermined characteristic value of the image display device and a common function for color-adjusting the images of the plurality of image display devices by correcting an input image signal from the derived characteristic values Characteristic values other than the first input image signal correction item and the first input image signal correction item, which are correction items, and by correcting the input image signal, images for each of the plurality of image display devices are displayed. A function for selecting a second input image signal correction item, which is a common correction item for color adjustment, the selected first input image signal correction item, and the second input image signal For correction items, multiple images A function of setting a target characteristic value that is a characteristic value that is a common target when color-adjusting an image on a display device, and a function of deriving a correction coefficient for correcting the characteristic value to the set target characteristic value And a function for creating a conversion relationship for converting an input image signal for each image display device in order to perform color adjustment of the images of the plurality of image display devices based on the derived correction coefficient It is.
According to an eighth aspect of the present invention, the function for deriving the correction coefficient includes a first correction coefficient that is the correction coefficient for the first input image signal correction item, and a function for the second input image signal. The function of deriving a second correction coefficient, which is the correction coefficient for the correction item, and creating the conversion relationship for each image display device is the conversion relationship based on the first correction coefficient. The program according to claim 7, wherein a conversion relation of 1 and a second conversion relation that is the conversion relation based on the second correction coefficient are created.

According to the first aspect of the present invention, compared with the case where the present configuration is not provided, when the images are displayed on the plurality of image display devices, the color adjustment devices that can make the respective color expressions closer to each other. Can be provided.
According to the invention of claim 2, a color adjustment device that can make each color expression closer when an image is displayed on a plurality of image display devices as compared with the case where the present configuration is not provided. Can be provided.
According to the third aspect of the present invention, it is possible to adjust an image with a color expression closer to that of an image display device that is used more frequently than when the present configuration is not provided.
According to the fourth aspect of the present invention, it is possible to adjust images of a plurality of image display devices using characteristic values that tend to affect color expression as compared with the case where the present configuration is not provided.
According to the fifth aspect of the present invention, it is easier to derive a predetermined characteristic value than in the case where the present configuration is not provided.
According to the invention of claim 6, a color adjustment system capable of making each color expression closer when an image is displayed on a plurality of image display devices as compared with the case where this configuration is not provided. Can be provided.
According to the seventh aspect of the present invention, the computer has a function capable of making each color expression closer when images are displayed on a plurality of image display devices, as compared with the case where the present configuration is not provided. Can be realized.
According to the eighth aspect of the present invention, the first conversion relationship, which is a conversion relationship created in common for each image display device, is created for each image display device, as compared with the case where this configuration is not provided. The color adjustment can be performed using the second conversion relationship which is the conversion relationship to be performed.

1 shows an example of the overall configuration of a color adjustment system to which the present embodiment is applied. It is the figure which showed the hardware constitutions of the terminal device. It is a figure explaining the example of a function structure about the color adjustment apparatus of this Embodiment. It is a figure explaining the functional structural example of the color conversion profile preparation part. It is the flowchart explaining the operation example of the color conversion profile preparation part. FIG. 6 is a diagram showing characteristic values that can be selected as a first input image signal correction item and a second input image signal correction item. The figure explaining the procedure in which the target characteristic value setting unit of the first correction coefficient creating unit sets the first target characteristic value for the black luminance when black luminance is selected as the correction item by the correction item selection unit. It is. The figure explaining the procedure in which the target characteristic value setting unit of the first correction coefficient creating unit sets the first target characteristic value for this color temperature when the color temperature is selected as the correction item by the correction item selection unit. It is. It is the figure which showed the example of the upper limit of color temperature which can be set with a monitor, and a lower limit. A procedure has been described in which the target characteristic value setting unit of the first correction coefficient creating unit sets the first target characteristic value for the color gamut shape when the gamut shape is selected as the correction item by the correction item selection unit. FIG. When the black color is selected as a correction item by the correction item selection unit, the target characteristic value setting unit of the first correction coefficient creating unit sets the first target characteristic value for the black color FIG. It is a figure explaining other cases of the example of functional composition about the color adjustment device of this embodiment.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
FIG. 1 shows an example of the overall configuration of a color adjustment system 1 to which the present embodiment is applied.
The color adjustment system 1 illustrated here includes terminal devices 10a, 10b, 10c, and 10d, and a network 30 connected to the terminal devices 10a, 10b, 10c, and 10d. In the following description, when there is no need to distinguish the terminal devices 10a, 10b, 10c, and 10d, they are referred to as the terminal device 10. Moreover, although only four terminal devices 10 are shown in the figure, five or more terminal devices 10 may be provided.

  Although described in detail later, the terminal device 10 is a computer device having a monitor that displays a predetermined image. Here, as the terminal device 10, a PC (Personal Computer) can be exemplified.

  The network 30 is a communication means used for information communication between the terminal devices 10 and is, for example, a LAN (Local Area Network). In the present embodiment, the network 30 is not necessarily required, and each of the terminal devices 10a, 10b, 10c, and 10d may be a so-called stand-alone.

Next, the hardware configuration of the terminal device 10 will be described.
FIG. 2 is a diagram illustrating a hardware configuration of the terminal device 10.
As shown in the figure, the terminal device 10 includes a CPU (Central Processing Unit) 11 that is a calculation means, a main memory 12 that is a storage means, and an HDD (Hard Disk Drive) 13. Here, the CPU 11 executes various software such as an OS (Operating System) and applications. The main memory 12 is a storage area for storing various software and data used for execution thereof, and the HDD 13 is a storage area for storing input data for various software, output data from various software, and the like.

  Furthermore, the terminal device 10 includes a communication interface (hereinafter referred to as “communication I / F”) 14 for performing communication with the outside, a video memory, a display, and the like, and an example of an image display device that displays an image. A monitor 15 and an input device 16 such as a keyboard and a mouse. Here, the monitor 15 is not limited to a liquid crystal monitor for a PC or a cathode ray tube monitor, but also includes a projector, a liquid crystal display for a television, a plasma display, and the like. The number of monitors 15 is not limited to one for each terminal device 10, and a plurality of monitors 15 may be provided.

  Here, it is desirable that the images displayed on the monitor 15 are all displayed in the same color representation for each monitor 15 of the terminal device 10a. In general, for example, if the input image signal is a color signal in the sRGB color space and the monitor 15 uses a signal corresponding to the sRGB color space, the image for each monitor 15 has the same color representation. It becomes easy to become.

  However, even if the same sRGB input image signal is input to each monitor 15, the device characteristics are different from each other. Therefore, the image displayed on the monitor 15 due to this is not the same color expression. is there. This device characteristic is different if the manufacturer and model number of the monitor 15 are different. Furthermore, even with the same model number of the same manufacturer, the device characteristics are usually different due to manufacturing variations and aging.

Therefore, in the present embodiment, the color adjustment device 100 built in the terminal device 10 is provided, and the color adjustment device 100 uses the common first target characteristic value for a predetermined characteristic value (device characteristic value). And the input image signal is corrected in common for each monitor 15. At the same time, a second target characteristic value common to other predetermined characteristic values is set, and the input image signal is corrected for each monitor 15 so that a similar color expression can be obtained. ing.
Hereinafter, this matter will be described in more detail.

FIG. 3 is a diagram illustrating a functional configuration example of the color adjustment apparatus 100 according to the present embodiment.
The color adjustment apparatus 100 shown in FIG. 3A is used in the color conversion unit 110 as an example of a color conversion unit that converts an input image signal using a predetermined conversion relationship, and the color conversion unit 110. A color conversion profile creating unit 130 for creating a color conversion profile to be processed. Here, although not constituting the color adjustment apparatus 100 of the present embodiment, the monitor 15 that displays an image by the output image signal is also illustrated.

FIG. 4 is a diagram illustrating an example functional configuration of the color conversion profile creation unit 130.
As illustrated, the color conversion profile creation unit 130 includes a correction item determination unit 131, a first correction coefficient creation unit 132, a second correction coefficient creation unit 133, a mapping unit 134, and a conversion relationship creation unit 135. Is provided.

The correction item determination unit 131 determines an item to be corrected from device characteristics that affect the color expression of the monitor 15.
The correction item determination unit 131 includes a color value acquisition unit 131-1, a characteristic value derivation unit 131-2, and a correction item selection unit 131-3.

The color value acquisition unit 131-1 acquires the color value when a predetermined image is displayed on the monitor 15 from the plurality of monitors 15. In the present embodiment, the color value acquisition unit 131-1 has a color value when a white image is displayed on the monitor 15 as a color value when a predetermined image is displayed, and a black image on the monitor 15. And the color value of the main color when the main color is displayed on the monitor 15 are acquired.
More specifically, an administrator who manages the color adjustment system 1 measures these color values using a predetermined measuring instrument and inputs the color values to the color adjustment apparatus 100 using the input device 16 or the like. Here, the main colors are colors used for displaying an image on the monitor 15 and are usually three colors of R (Red) color, G (Green) color, and B (Blue) color. Therefore, the color value acquisition unit 131-1 changes the RGB gradation value, and acquires the color value when each RGB color is saturated as the color value of the main color. .

The characteristic value deriving unit 131-2 derives a predetermined characteristic value (device characteristic value) of the monitor 15 from the color value acquired by the color value acquiring unit 131-1.
The predetermined characteristic value here will be described in detail later. For example, the luminance when the black image is displayed on the monitor 15 (black luminance), and the color when the white image is displayed on the monitor 15. Temperature, color gamut shape of the monitor 15, brightness when a white image is displayed on the monitor 15 (white brightness), color tone when a black image is displayed on the monitor 15 (black hue and saturation, black Color hue), and the hue angle of the main color. These characteristic values can be derived by using the color values described above or using a predetermined calculation formula.

The correction item selection unit 131-3 is a common correction item for color-adjusting the images of the plurality of monitors 15 by correcting the input image signal from the characteristic values derived by the characteristic value deriving unit 131-2. These are characteristic values other than the first input image signal correction item and the first input image signal correction item, and are used for color adjustment of the images of the plurality of monitors 15 by correcting the input image signal. A second input image signal correction item that is a correction item is selected.
That is, although details will be described later, the first input image signal correction item and the second input image signal correction item are different as the correction items to be selected. As the first input image signal correction item, a common correction item is selected for each monitor 15, and the correction value for correcting the characteristic value is also common. On the other hand, a common correction item for each monitor 15 is selected as the second input image signal correction item, but the correction value for correcting the characteristic value differs for each monitor 15.

The first correction coefficient creating unit 132 derives a first correction coefficient for correcting the characteristic value for the first input image signal correction item for correcting the input image signal.
The first correction coefficient creating unit 132 includes a target characteristic value setting unit 132-1 and a correction coefficient deriving unit 132-2.

The target characteristic value setting unit 132-1 adjusts the color of the image on the plurality of monitors 15 for the first input image signal correction item selected by the correction item selection unit 131-3 of the correction item determination unit 131. A first target characteristic value, which is a characteristic value serving as a common target, is set.
That is, here, a common target value is set to match the characteristic values for the first input image signal correction item selected from the characteristic values.

  The correction coefficient deriving unit 132-2 derives a first correction coefficient for correcting the characteristic value to the first target characteristic value set by the target characteristic value setting unit 132-1. This first correction coefficient is a correction coefficient common to the monitors 15.

The second correction coefficient creation unit 133 derives a second correction coefficient for correcting the characteristic value for the second input image signal correction item for correcting the input image signal.
The second correction coefficient creating unit 133 includes a target characteristic value setting unit 133-1 and a correction coefficient deriving unit 133-2.

The target characteristic value setting unit 133-1 adjusts the color of the image on the plurality of monitors 15 for the second input image signal correction item selected by the correction item selection unit 131-3 of the correction item determination unit 131. A second target characteristic value, which is a characteristic value serving as a common target, is set.
That is, here, a common target value is set to match the characteristic values for the second input image signal correction item selected from the characteristic values.

  The correction coefficient deriving unit 133-2 derives a second correction coefficient for correcting the characteristic value to the second target characteristic value set by the target characteristic value setting unit 133-1. This second correction coefficient is a different correction coefficient for each monitor 15.

  The mapping unit 134 adjusts the color gamut when the correction is performed using the first input image signal correction item and the color gamut when the input image signal is corrected using the second input image signal correction item. Performs compression and mapping of areas. In other words, the mapping unit 134 matches the color gamut when the input image signal is corrected with the first input image signal correction item and the color gamut when the input image signal is corrected with the second input image signal correction item. Functions as a color gamut matching unit.

The conversion relationship creating unit 135 performs input image adjustment for color adjustment of the plurality of monitors 15 based on the first correction coefficient and the second correction coefficient derived by the correction coefficient deriving units 132-2 and 133-2. A conversion relationship for converting the signal is created for each monitor 15.
Here, the conversion relationship is a color conversion profile, and a different one is created for each monitor 15. In the example of FIG. 3, the color conversion unit 110 is used to convert an input image signal. More specifically, the color conversion profile is in the form of, for example, a multi-dimensional table such as DLUT (Direct Look Up Table), Matrix, one-dimensional LUT (Look Up Table).

FIG. 5 is a flowchart illustrating an operation example of the color conversion profile creation unit 130.
Hereinafter, the operation of the color conversion profile creation unit 130 will be described with reference to FIGS. 4 and 5.

First, the color value acquisition unit 131-1 of the correction item determination unit 131 acquires predetermined color values from the plurality of monitors 15 (step 101). The color values acquired here are the color values when a white image is displayed on the monitor 15, the color values when a black image is displayed on the monitor 15, and the saturated colors of the RGB colors that are the main colors on the monitor 15. Color value. In the present embodiment, the color value acquisition by the color value acquisition unit 131-1 is performed by, for example, an administrator who manages the color adjustment system 1 using L ^* a ^* b ^* color system L ^* , a ^* , b ^*. And the XYZ values in the XYZ color system are input to the color adjusting apparatus 100.

Next, when the characteristic value deriving unit 131-2 of the correction item determining unit 131 displays a black image on the monitor 15 from the color value acquired by the color value acquiring unit 131-1, the monitor 15 When the white image is displayed on the monitor 15, the color temperature of the monitor 15, the color gamut shape of the monitor 15, the color when the monitor 15 displays the black image (black color), and the monitor 15 displays the white image The luminance (white luminance) and the hue angle of the main color are derived as predetermined characteristic values (step 102).
Here, for example, the black luminance is an L ^* value or a Y value when a black image is displayed. Further, the color temperature when the white image is displayed can be derived from the X value, Y value, and Z value of the white image. Furthermore, the color gamut shape can be derived from the a ^* value and b ^* value, or the X value, Y value, and Z value when the saturated colors of RGB are displayed.
The color tone when the black image is displayed can be derived from the a ^* value and b ^* value, or the X value, Y value, and Z value of the black image. The white luminance is an L ^* value or a Y value when a white image is displayed on the monitor 15. Further, the hue angle of the main color can be derived from the a ^* value and b ^* value of the main color, or the X value, Y value, and Z value.

  Next, the correction item selection unit 131-3 of the correction item determination unit 131 corrects the input image signal from the characteristic values derived by the characteristic value deriving unit 131-2 to color the images of the plurality of monitors 15. A first input image signal correction item, which is a common correction item for adjustment, is selected (step 103). Further, by correcting the input image signal, the second input image signal correction item, which is a correction item for adjusting the color of the images of the plurality of monitors 15, is selected (step 104).

FIG. 6 is a diagram showing characteristic values that can be selected as the first input image signal correction item and the second input image signal correction item.
As shown in the drawing, characteristic values that can be selected as the first input image signal correction item are black luminance, color temperature, color gamut shape, and black color. On the other hand, characteristic values that can be selected as the second input image signal correction item are white luminance, black hue, hue angle of main color, color temperature, and color gamut shape.
The characteristic value that can be selected as the first input image signal correction item and the characteristic value that can be selected as the second input image signal correction item have some overlap. In this case, what is selected on one side is not selected on the other side. Therefore, the correction items that are actually selected are different without overlapping.

These characteristic values are not all selected, but at least one of them is selected.
More specifically, a predetermined threshold value is provided for each characteristic value, and when the variation in the characteristic value for each monitor 15 is larger than this threshold value, this characteristic value is selected as a correction item. That is, when the variation is equal to or smaller than the threshold value, the characteristic value is not corrected, and when the threshold value is exceeded, the characteristic value is corrected.

  As shown in FIG. 6, two threshold values are provided for characteristic values having overlapping color temperatures and the like. Here, assuming that the first threshold value and the second threshold value (first threshold value <second threshold value), if the variation in the characteristic value for each monitor 15 is less than or equal to the first threshold value, this characteristic value Are not selected for both the first input image signal correction item and the second input image signal correction item. If the variation exceeds the first threshold and is equal to or smaller than the second threshold, the characteristic value is selected as the first input image signal correction item. Further, when the variation exceeds the second threshold, it is selected as the second input image signal correction item. That is, when the variation is equal to or smaller than the first threshold value, the characteristic value is not corrected, and when the first threshold value is exceeded, the characteristic value is corrected. If the variation is not so large, it is selected as the first input image signal correction item, and if the variation is larger, it is selected as the second input image signal correction item.

  Returning to FIG. 4 and FIG. 5, the target characteristic value setting unit 132-1 of the first correction coefficient creating unit 132 then images the selected correction items for the first input image signal on the plurality of monitors 15. A first target characteristic value, which is a characteristic value that is a common target when the color is adjusted, is set (step 105). As will be described in detail later, the first target characteristic value may be calculated and set by a predetermined method or may be set by an administrator input.

  Further, the correction coefficient deriving unit 132-2 of the first correction coefficient creating unit 132 derives a first correction coefficient for correcting the characteristic value to the set first target characteristic value (step 106). This first correction coefficient is also a correction coefficient common to the respective monitors 15.

  Next, the common target when the target characteristic value setting unit 133-1 of the second correction coefficient creating unit 133 adjusts the color of the image on the plurality of monitors 15 for the selected second input image signal correction item. A second target characteristic value that is a characteristic value to be set is set (step 107). The second target characteristic value will be described in detail later, but may be calculated and set by a predetermined method, or may be set by an administrator input.

  Further, the correction coefficient deriving unit 133-2 of the second correction coefficient creating unit 133 derives a second correction coefficient for correcting the characteristic value to the set second target characteristic value (step 108). The second correction coefficient is created for each monitor 15 and is different for each normal monitor 15.

  In order for the mapping unit 134 to approach the difference between the color gamut when corrected with the first input image signal correction item and the color gamut when the input image signal is corrected with the second input image signal correction item, Mapping is performed to compress and map the color gamut (step 109).

  Finally, the conversion relationship creating unit 135 performs color adjustment on the plurality of monitors 15 based on the first correction coefficient and the second correction coefficient derived by the correction coefficient deriving units 132-2 and 133-2. A color conversion profile that is a conversion relationship for converting the input image signal is created (step 110). This color conversion profile is created for each monitor 15 and is different for each normal monitor 15.

  As described above, in the present embodiment, the first input image signal correction item is selected from various device characteristics for performing color adjustment on the monitor 15. This is selected from among black luminance, color temperature, and color gamut shape. A common first correction coefficient is created for the first input image signal correction item. In this way, the first correction coefficient for correcting the input image signal in common for each monitor 15 with respect to the characteristic value which is easily influenced by the color expression of the monitor 15 and does not vary greatly among the monitors 15. Can be sought. Then, the color conversion of the input image signal is performed using the color conversion profile reflecting the first correction coefficient. According to this, the device characteristics of the monitor 15 on the output side can be taken into the input image signal on the input side, and the color expression on the monitor 15 can be roughly adjusted to perform almost the same color expression. .

  In the present embodiment, the second input image signal correction item is selected from the device characteristics. This is selected from device characteristics other than the first input image signal correction item. Then, a different second correction coefficient is created for each monitor 15 for the second input image signal correction item. In this way, it is possible to obtain the second correction coefficient for correcting the input image signal for each monitor 15 with respect to the characteristic value having a larger variation for each monitor 15. Then, color conversion of the input image signal is performed using a color conversion profile reflecting the second correction coefficient. According to this, a color conversion profile reflecting the characteristic value of each monitor 15 can be created for the characteristic value having a large variation for each monitor 15, and the color expression of the monitor 15 is further finely adjusted to obtain a more similar color expression. You can do it.

  By performing color adjustment using the correction coefficient divided into two stages in this way, even when the difference in device characteristics for each monitor 15 is originally large, more accurate color adjustment can be performed more easily. The color expression on the monitor 15 is likely to be the same.

  In the present embodiment, since the characteristic values to be corrected are different for the first input image signal correction item and the second input image signal correction item, the mapping unit 134 is used in order to ensure the consistency between them. A process for bringing the color gamut closer is performed at. Therefore, the color representation of each monitor 15 is likely to be the same. Note that the mapping unit 134 is not necessarily provided, and a color conversion profile may be created without matching the color gamut. In this case, the accuracy of the color adjustment may change, but a consistent color adjustment is still maintained and the color representation can be closer for each monitor 15.

Next, processing in steps 105 to 108 in FIG. 5 will be described in more detail.
FIG. 7 shows that when the black luminance is selected as the correction item by the correction item selection unit 131-3, the target characteristic value setting unit 132-1 of the first correction coefficient creating unit 132 sets the first luminance for the first luminance. It is a figure explaining the procedure which sets a target characteristic value. That is, FIG. 7 illustrates the operation of step 105 for black luminance.

  First, the target characteristic value setting unit 132-1 acquires a black luminance value for each monitor 15 (step 201). Then, a first target characteristic value for black luminance is set from the black luminance value for each monitor 15. In order to set the first target characteristic value, the black luminance values may be simply averaged. In the present embodiment, the first target characteristic value is weighted to reflect the frequency with which the monitor 15 is used. Set the target characteristic value.

  In this case, the target characteristic value setting unit 132-1 first obtains a weight w that is a parameter regarding the frequency with which the monitor 15 is used (step 202), and uses this weight w to obtain the first target characteristic value. Set (step 203). This weight w is performed, for example, when the administrator of the color adjustment system 1 performs input, and the target characteristic value setting unit 132-1 acquires it.

More specifically, there are n monitors 15, and the black luminance of each monitor 15 is represented by Y _k and the weight w is represented by w _k (where k = 1, 2, 3,..., N). In this case, the first target characteristic value for black luminance can be calculated by the following equation (1).

(First target characteristic value for black luminance) = Σ (Y _k × w _k ) / Σw _k (k = 1, 2, 3,..., N) (1)

In the present embodiment, the first correction coefficient calculated by the correction coefficient deriving unit 132-2 in step 106 is the luminance value (for example, the input image signal) when the black luminance is changed as in the present embodiment. , L ^* value and Y value). Here, for example, the smaller the luminance value, the larger the correction amount, and the larger the luminance value, the smaller the correction amount. In other words, the first correction coefficient is set so that the black luminance value that takes the minimum luminance value corresponding to the display of black is the first target characteristic value. On the other hand, the maximum luminance value corresponding to the white display is not corrected. As for the luminance value in the meantime, the correction amount increases as the luminance value decreases toward black, and the correction amount decreases as the luminance value increases toward white.
When white luminance is selected as the second input image signal correction item, the white luminance value is an L ^* value or a Y value when a color image is displayed on the monitor 15. The second target characteristic value for white luminance can be derived by the same method as that for black luminance.

  FIG. 8 shows that when the color temperature is selected as a correction item by the correction item selection unit 131-3, the target characteristic value setting unit 132-1 of the first correction coefficient creation unit 132 performs the first operation on the color temperature. It is a figure explaining the procedure which sets a target characteristic value. That is, FIG. 8 illustrates the operation of step 105 for the color temperature.

  First, the target characteristic value setting unit 132-1 acquires a settable color temperature range for each monitor 15 (step 301). Actually, the target characteristic value setting unit 132-1 acquires an upper limit value and a lower limit value of the color temperature that can be set for each monitor 15. The upper limit value and the lower limit value of the color temperature that can be set can be found, for example, by referring to the setting menu or specifications of the monitor 15 by the administrator of the color adjustment system 1. And an administrator inputs about the referred result, and the target characteristic value setting part 132-1 acquires this.

  To set the first target characteristic value for the color temperature from the color temperature range that can be set for each monitor 15, for example, the following is performed.

  When the administrator inputs the upper limit value and lower limit value of the settable color temperature, the administrator also inputs the desired color temperature, and the target characteristic value setting unit 132-1 acquires the desired color temperature ( Step 302). Next, the target characteristic value setting unit 132-1 determines whether or not the desired color temperature is within an upper limit value and a lower limit value that are color temperature ranges that can be set on each monitor 15 (step 303). ). If it has been entered (Yes in step 303), this desired color temperature is set as the first target characteristic value for the color temperature (step 304). On the other hand, if not (No in step 303), the desired color temperature is changed and the first target characteristic value is set (step 305).

Here, step 303 to step 305 are specifically performed as follows.
FIG. 9 is a diagram illustrating an example of the upper limit value and the lower limit value of the color temperature that can be set on the monitor 15.
As shown in the figure, here, it is assumed that there are four monitors 15 whose “device No.” is 1 to 4, and the upper limit value and lower limit value of the color temperature are indicated by absolute temperatures. The monitors 15 having “device No.” 1 to 4 correspond to the monitors 15 included in the image display devices 10a, 10b, 10c, and 10d, for example.

  At this time, if the desired color temperature is 6000K, the color temperature can be set by all four monitors 15, so the target characteristic value setting unit 132-1 sets 6000K as the first target characteristic value. On the other hand, when the desired color temperature is 4500 K, the desired color temperature is out of the lower limit of the color temperature that can be set for the monitor 15 of “device No. 2” and “device No. 3”. . The difference between the desired color temperature and the lower limit of the color temperature of “device No. 3” is 1000K, which is larger than “device No. 2” of 500K. At this time, the target characteristic value setting unit 132-1 sets the first target characteristic value of the color temperature so that the difference from the lower limit value of the setting range of “device No. 3” is within a predetermined range. To do. In this case, for example, the first target characteristic value of the color temperature is set to 5000K, which is 500K lower than 5500K. As described above, when the desired color temperature is outside the range of the color temperature that can be set by the monitor 15, the target characteristic value setting unit 132-1 has the largest difference between the upper limit value or the lower limit value of this range and the desired color temperature. The monitor 15 is selected. Then, a color temperature that is within 500 K from the upper limit value or the lower limit value of the monitor 15 is set as the first target characteristic value.

  Even if the color temperature in the range that can be set by the menu of the monitor 15 is removed and the first target characteristic value of the color temperature is set, the first target characteristic value can be changed by changing the output of each color of RGB of the monitor 15. It is usually possible to display an image with the color temperature of the characteristic value. In other words, when it is desired to lower the color temperature, it is necessary for the color of the image to be reddish. For this purpose, the gradation curve of the B color is lowered from the R color, and the R color is relative to the B color. This can be realized by emitting light strongly. On the other hand, when it is desired to increase the color temperature, it is necessary to make the color of the image bluish, but this is achieved by lowering the gradation curve of the R color from the B color and making the B color relative to the R color. This can be realized by emitting light strongly. However, if the value is far larger than the upper limit value or lower limit value, problems such as the balance of RGB colors being lost and the gradation becoming difficult to display occur. Therefore, a range determined in advance from the upper limit value or the lower limit value as described above. The first target characteristic value is set so as to be within.

In the present embodiment, the first correction coefficient calculated by the correction coefficient deriving unit 132-2 in step 106 is, for example, a color correction coefficient for the input image signal. More specifically, when the color temperature is changed as in the present embodiment, for example, it becomes a correction coefficient for correcting the values of a ^* and b ^{* and} the values of X, Y and Z.

  The same applies to the case where the target characteristic value setting unit 133-1 of the second correction coefficient creating unit 133 sets the second target characteristic value for this color temperature. That is, the operation of step 107 is the same as that of step 105. However, the second correction coefficient calculated by the correction coefficient deriving unit 133-2 in step 108 is a correction coefficient for adjusting the color temperature of each monitor 15 to the second target characteristic value. For this reason, the second correction coefficient differs for each monitor 15.

  FIG. 10 shows that when the gamut shape is selected as a correction item by the correction item selection unit 131-3, the target characteristic value setting unit 132-1 of the first correction coefficient creation unit 132 sets the first gamut shape. It is a figure explaining the procedure which sets the target characteristic value. That is, FIG. 10 illustrates the operation of step 105 for the color gamut shape.

First, the target characteristic value setting unit 132-1 acquires color values when displaying the saturated colors of the respective RGB colors that are the main colors for each monitor 15 (step 401). Here, for example, the color values when the saturated colors of RGB are displayed are acquired as a ^* values and b ^* values. The first target characteristic value for the color gamut shape is set from the a ^* value and the b ^* value, for example, as follows.

To set the first target characteristic value for this color gamut shape, the a ^* value and b ^* value when the saturated colors of RGB of each monitor 15 are displayed may be simply averaged. In the present embodiment, as described with reference to FIG. 7, the first target characteristic value is set by weighting that reflects the frequency with which the monitor 15 is used.
In this case, the target characteristic value setting unit 132-1 first obtains a weight w that is a parameter regarding the frequency with which the monitor 15 is used (step 402), and uses this weight w to obtain the first color gamut shape. The target characteristic value is calculated (step 403). The color gamut shape thus obtained is set as a first target characteristic value. For example, the administrator of the color adjustment system 1 inputs the weight w as in the case of FIG.

  Then, it is determined whether or not the color gamut calculated as the first target characteristic value is included in the color gamut of each monitor 15 (step 404). If it is included (Yes in step 404), the first target characteristic value calculated in step 403 is directly used as the first target characteristic value for the color gamut shape (step 405). On the other hand, if there is a monitor 15 that is not included (No in step 404), the first target characteristic value calculated in step 403 is changed to set a new first target characteristic value (step 406). .

Examples of a method for setting the new first target characteristic value include the following methods.
(I) A weighted average is calculated from the a ^* value and b ^* value set in step 403 and the a ^* value and b ^* value for each main color of each monitor 15.
(Ii) The hue is maintained from the a ^* value and b ^* value set in step 403, and the saturation is set to the average saturation of each monitor 15.
(Iii) and a ^* and b ^* values set in step 403, selects the appropriate value from the value between the mean a ^* value and b ^* values of each monitor 15.

In the present embodiment, the first correction coefficient calculated by the correction coefficient deriving unit 132-2 in step 106 is, for example, a color correction coefficient for the input image signal. More specifically, when the color gamut shape is changed as in the present embodiment, for example, it becomes a correction coefficient for correcting the values of a ^* and b ^{* and} the values of X, Y, and Z.

  The same applies to the case where the target characteristic value setting unit 133-1 of the second correction coefficient creating unit 133 sets the second target characteristic value for this color gamut shape. That is, the operation of step 107 is the same as that of step 105. However, the second correction coefficient calculated by the correction coefficient deriving unit 133-2 in step 108 is a correction coefficient for matching the color gamut shape of each monitor 15 to the second target characteristic value. For this reason, the second correction coefficient differs for each monitor 15.

  In FIG. 11, when the black color is selected as a correction item by the correction item selection unit 131-3, the target characteristic value setting unit 132-1 of the first correction coefficient creating unit 132 displays the black color. It is the figure explaining the procedure which sets the 1st target characteristic value about. That is, FIG. 11 illustrates the operation of step 105 for the black color.

  First, the target characteristic value setting unit 132-1 acquires a black color value for each monitor 15 (step 501). Then, a first target characteristic value is set for the black color from the black color value for each monitor 15. In order to set the first target characteristic value, each value of black hue (black hue and saturation value) may be simply averaged, but in this embodiment, the monitor 15 is used. The first target characteristic value is set by weighting reflecting the frequency.

  In this case, the target characteristic value setting unit 132-1 first obtains a weight w that is a parameter regarding the frequency with which the monitor 15 is used (step 502), and uses this weight w to obtain the first target characteristic value. Set (step 503). This weight w is performed, for example, when the administrator of the color adjustment system 1 performs input, and the target characteristic value setting unit 132-1 acquires it.

More specifically, there are n monitors 15, and the black hue of each monitor 15 is represented by H _k , the black saturation is represented by C _k , and the weight w is represented by w _k (where k = 1, 2, 3). ..., n). In this case, the first target characteristic value for the black hue and the first target characteristic value for the black saturation can be calculated by the following equations (2) to (3).

(First target characteristic value for black hue) = Σ (H _k × w _k ) / Σw _k (k = 1, 2, 3,..., N) (2)
(First target characteristic value for black saturation) = Σ (C _k × w _k ) / Σw _k (k = 1, 2, 3,..., N) (3)

In the present embodiment, the first correction coefficient calculated by the correction coefficient deriving unit 132-2 in step 106 is, for example, a color correction coefficient. More specifically, when the black color is changed as in the present embodiment, for example, the correction coefficient is used to correct the values of a ^* and b ^{* and} the values of X, Y, and Z.

  The same applies to the case where the target characteristic value setting unit 133-1 of the second correction coefficient creating unit 133 sets the second target characteristic value for the black color. That is, the operation of step 107 is the same as that of step 105. However, the second correction coefficient calculated by the correction coefficient deriving unit 133-2 in step 108 is a correction coefficient for matching the black color of each monitor 15 to the second target characteristic value. For this reason, the second correction coefficient differs for each monitor 15.

  In the example described in detail above, the color conversion profile created as described above is used for color matching between the monitors 15, but the present invention is not limited to this. For example, this method of creating a color conversion profile can be applied to an image forming apparatus such as a printer that forms an image on a recording material by an electrophotographic method or an ink jet method. That is, the input image signal is color-converted into a color space depending on the image forming apparatus to obtain an output image signal, and the above-described color conversion of the input image signal is performed for the image forming apparatus that forms an image using the output image signal. The color adjustment apparatus 100 can be used. By using this color adjusting device 100, the color expression of the monitor 15 and the image forming apparatus can be more easily matched.

In the example described in detail above, the color adjustment device 100 is provided in a form incorporated in the terminal device 10. However, the color adjustment device 100 may be separated from the terminal device 10 and may be a single device.
FIG. 12 is a diagram illustrating another example of the functional configuration example of the color adjustment apparatus according to the present embodiment.
In the illustrated color adjustment apparatus 100, the color conversion profile creation unit 130 is independent and becomes the color adjustment apparatus 100.

  In the example described in detail above, one color conversion profile is created in consideration of both the first input image signal correction item and the second input image signal correction item, and thereby the color of the monitor 15 is adjusted. However, it is not limited to this. For example, separate color conversion profiles are created for the first input image signal correction item and the second input image signal correction item, and the color adjustment of the monitor 15 is performed using these two color conversion profiles. May be. In this case, a first color conversion profile as a first conversion relationship is created based on the first correction coefficient, and a second color conversion profile is created based on the second correction coefficient. Then, after correcting the input image signal using the first color conversion profile, the input image signal is further corrected using the second color conversion profile as the second conversion relationship.

  The processing performed by the color adjustment apparatus 100 according to the present embodiment is performed, for example, when the CPU 11 of the terminal apparatus 10 loads various programs stored in the HDD 13 or the like to the main memory 12 and executes them. That is, the process performed by the color adjustment apparatus 100 is actually performed by the color adjustment software executed by the terminal apparatus 10.

  Therefore, the processing performed by the color adjustment apparatus 100 is performed by using a function for acquiring a color value when a predetermined image is displayed on a plurality of monitors 15 for displaying an image on the computer, and a monitor from the acquired color value. A function for deriving 15 predetermined characteristic values and a common correction item for color-adjusting the images of the plurality of monitors 15 by correcting the input image signal from the derived characteristic values. 1 is a characteristic value other than the input image signal correction item and the first image signal correction item, and is a common correction item for color-adjusting the image of each of the plurality of monitors 15 by correcting the input image signal. A function for selecting the second input image signal correction item, and the selected first input image signal correction item and the second input image signal correction item are displayed on the plurality of monitors 15. When the color is adjusted A function that sets a target characteristic value that is a common target characteristic value, a function that derives a correction coefficient for correcting the characteristic value to the set target characteristic value, and a plurality of functions based on the derived correction coefficient It can also be understood as a program that realizes a function of creating a conversion relationship for converting the input image signal for each monitor 15 in order to perform color adjustment of the image of the monitor 15.

  In this case, after the input image signal is corrected using the first color conversion profile, the input image signal is further corrected using the second color conversion profile as the second conversion relationship. Can be realized by this program. Specifically, the function for deriving the correction coefficient is a first correction coefficient that is a correction coefficient for the first input image signal correction item and a correction coefficient for the second input image signal correction item. The function of deriving the second correction coefficient and creating the conversion relationship for each monitor 15 is based on the first color conversion profile, which is the conversion relationship based on the first correction coefficient, and the second correction coefficient. And a second color conversion profile having the conversion relationship described above.

  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.

DESCRIPTION OF SYMBOLS 1 ... Color adjustment system, 10 ... Terminal device, 15 ... Monitor, 100 ... Color adjustment device, 110 ... Color conversion part, 130 ... Color conversion profile creation part, 131 ... Correction item determination part, 131-1 ... Color value acquisition part , 131-2 ... characteristic value deriving unit, 131-3 ... correction item selecting unit, 132 ... first correction coefficient creating unit, 132-1, 133-1 ... target characteristic value setting unit, 132-2, 133-2 ... correction coefficient deriving unit, 133 ... second correction coefficient creating unit, 134 ... mapping unit, 135 ... conversion relation creating unit

Claims (8)

A color value acquisition unit that acquires a color value when a predetermined image is displayed on a plurality of image display devices that display an image;
A characteristic value deriving unit for deriving a predetermined characteristic value of the image display device from the color value acquired by the color value acquiring unit;
The first input image signal which is a common correction item for color-adjusting the images of the plurality of image display devices by correcting the input image signal from the characteristic values derived by the characteristic value deriving unit. Correction item and a characteristic value other than the first input image signal correction item, and a common correction item for color-adjusting the image for each of the plurality of image display devices by correcting the input image signal. A correction item selection unit for selecting a certain second input image signal correction item;
For the first input image signal correction item and the second input image signal correction item selected by the correction item selection unit, a common target when color-adjusting an image on a plurality of the image display devices; A target characteristic value setting unit that sets a target characteristic value that is a characteristic value
A correction coefficient deriving unit for deriving a correction coefficient for correcting the characteristic value to the target characteristic value set by the target characteristic value setting unit;
Creation of a conversion relationship for creating a conversion relationship for converting the input image signal for each image display device in order to perform color adjustment of the images of the plurality of image display devices based on the correction coefficient derived by the correction coefficient deriving unit And
A color adjusting device comprising:   A color that matches the color gamut when the input image signal is corrected with the first input image signal correction item and the color gamut when the input image signal is corrected with the second input image signal correction item The color adjustment apparatus according to claim 1, further comprising a gamut matching unit.   The color adjustment apparatus according to claim 1, wherein the target characteristic value setting unit sets the target characteristic value by weighting that reflects a frequency with which the image display apparatus is used.   The correction item selection unit, as the first input image signal correction item, brightness when a black image is displayed on the image display device, color when a white image is displayed on the image display device At least one of temperature, color gamut shape of the image display device, luminance when a white image is displayed on the image display device, hue and saturation when a black image is displayed on the image display device The color adjustment apparatus according to claim 1, wherein one of the color adjustment apparatuses is selected.   The color value acquisition unit displays a color value when a white image is displayed on the image display device as a color value when a predetermined image is displayed, and when a black image is displayed on the image display device 5. The color adjustment device according to claim 1, wherein a color value of the main color when the main color is displayed on the image display device is acquired. A plurality of image display devices for displaying images;
A color value acquisition unit for acquiring a color value when a predetermined image is displayed on the plurality of image display devices;
A characteristic value deriving unit for deriving a predetermined characteristic value of the image display device from the color value acquired by the color value acquiring unit;
The first input image signal which is a common correction item for color-adjusting the images of the plurality of image display devices by correcting the input image signal from the characteristic values derived by the characteristic value deriving unit. Correction item and a characteristic value other than the first input image signal correction item, and a common correction item for color-adjusting the image for each of the plurality of image display devices by correcting the input image signal. A correction item selection unit for selecting a certain second input image signal correction item;
For the first input image signal correction item and the second input image signal correction item selected by the correction item selection unit, a common target when color-adjusting an image on a plurality of the image display devices; A target characteristic value setting unit that sets a target characteristic value that is a characteristic value
A correction coefficient deriving unit for deriving a correction coefficient for correcting the characteristic value to the target characteristic value set by the target characteristic value setting unit;
Creation of a conversion relationship for creating a conversion relationship for converting the input image signal for each image display device in order to perform color adjustment of the images of the plurality of image display devices based on the correction coefficient derived by the correction coefficient deriving unit And
A color adjustment system comprising: On the computer,
A function of acquiring a color value when a predetermined image is displayed on a plurality of image display devices for displaying an image;
A function of deriving a predetermined characteristic value of the image display device from the acquired color value;
Among the derived characteristic values, a first input image signal correction item that is a common correction item for color-adjusting the images of the plurality of image display devices by correcting the input image signal, A second input image that is a characteristic value other than the first input image signal correction item and is a common correction item for color-adjusting the images of the plurality of image display devices by correcting the input image signal A function for selecting signal correction items,
A target that is a characteristic value that is a common target for color adjustment of an image in the plurality of image display devices for the selected correction item for the first input image signal and the correction item for the second input image signal. The ability to set characteristic values;
A function of deriving a correction coefficient for correcting the characteristic value to the set target characteristic value;
A function for creating a conversion relationship for converting an input image signal for each image display device in order to perform color adjustment of images of the plurality of image display devices based on the derived correction coefficient;
A program that realizes The function for deriving the correction coefficient is the first correction coefficient that is the correction coefficient for the first input image signal correction item and the correction coefficient for the second input image signal correction item. A second correction factor is derived,
The function of creating the conversion relationship for each image display device has the first conversion relationship that is the conversion relationship based on the first correction coefficient and the conversion relationship based on the second correction coefficient. The program according to claim 7, wherein the second conversion relationship is created.

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