JP4189459B2 - Computer-readable recording medium having color matching method and color matching program recorded thereon - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a computer-readable recording medium in which a color matching method and a color matching program are recorded, and in particular, digital image data that can be reproduced by an apparatus such as a CRT (cathode ray tube) or the like and an image that can be reproduced by an output apparatus such as a printer. The present invention relates to a color matching method used for conversion into data and a computer-readable recording medium on which a color matching program is recorded.
[0002]
[Prior art]
In general, the color reproducible range with a CRT or scanner is different from the color reproducible range with a printer. Thus, when the color reproduction range (Gamut) between two apparatuses is different, when an image reproduced by one apparatus is reproduced by the other apparatus, color matching, that is, color matching is performed between the two apparatuses. Necessary. Hereinafter, the color matching method in the prior art will be briefly described.
[0003]
First, in FIG. 6, a flow of image data is shown to explain a color matching method between the input device 601 and the output device 607. Here, the image data reproduced by the input device 601 such as a CRT or a scanner is RGB data represented in the RGB color space, and the image data reproduced by the output device 607 such as a printer is represented in the CMY color space. CMYK data. As shown in the figure, the RGB data is finally converted into CMYK data through various conversion processes in the color conversion processing unit 603.
[0004]
First, RGB data in the input device 601 is input to the color conversion processing unit 603 and converted into data in a color space independent of the device. The device independent color space is, for example, an L * a * b * space, an XYZ space, or the like. Here, it is assumed that the data is converted into data (L * a * b * data) represented in the L * a * b * space. For the conversion process, conversion using LUT (lookup table) or masking method is used.
[0005]
Next, the converted L * a * b * data is converted into L * a * b * data in a range reproducible by the output device 607 in the Gamut mapping unit 605. That is, in this Gamut mapping unit 605, color matching between the input device 601 and the output device 607 is performed.
[0006]
Since the data after color matching is also data in a color space independent of the device (L * a * b * data), it is converted back to CMYK data. In this case as well, conversion using an LUT (lookup table) or a masking method is used for the conversion process.
[0007]
As described above, the image data reproduced by the input device 601 is once converted into data in a color space independent of the device, and then color matching is performed so that the image can be reproduced by the output device 607.
[0008]
FIG. 7 is a flowchart showing the flow of color matching processing in the Gamut mapping unit 605 in FIG. Referring to FIG. 7, in the Gamut mapping unit 605, when independent data (L * a * b * data) is input to the device in step S701, the gray axis is adjusted in step S703. That is, the entire input Gamut is moved so that the gray axis of the input Gamut (Gamut of the input device) matches the gray axis of the output Gamut (Gamut of the output device). This is because the gray axis of the input device 601 and the output device 607 are aligned to obtain an output image with a gray balance without color cast.
[0009]
The gray axis is a line segment connecting the white point and the black point in each device. For example, in a CRT, the color when all RGB are lit is a white point, and the color when all RGB are unlit is a black point. Here, in the L * a * b * color space, the line segment connecting the two points is the gray axis of the CRT. In the printer, the color of the paper to be used is a white point, and the output black color is a black point. Similarly, in the L * a * b * color space, the line segment connecting these two points becomes the gray axis of the printer.
[0010]
In step S704, the hue is adjusted by rotating the input Gamut. As the entire Gamut is moved by the gray axis adjustment process, a region where the hue changes appears. This is to correct this.
[0011]
Thereafter, in step S705, brightness and saturation are adjusted. That is, compression processing is performed to match the lightness and saturation of the input Gamut with the lightness and saturation of the output Gamut.
[0012]
If the brightness range is greatly different between the input device 601 and the output device 607, problems such as whiteout that causes halation in the output image or collapse of dark portions may occur. Therefore, the adjustment is performed in such a manner that the brightness range is matched with the output device 607. Also, if the saturation range is greatly different between the input device 601 and the output device 607, the output image becomes too vivid and full, or on the contrary, it becomes almost uncolored. Therefore, the saturation is also adjusted to some extent in accordance with Gamut of the output device 607.
[0013]
When the lightness and saturation compression processing ends, finally, in step S707, a pasting process is performed in which data outside the Gamut of the output device is pasted on the Gamut surface. This is because input image data outside the output Gamut that cannot be reproduced by the output device 607 at this time can be appropriately reproduced.
[0014]
When the data pasting process on the output Gamut surface is completed, all the color matching processes are completed, and the image data after matching is output in step S709.
[0015]
The process flow in the Gamut mapping unit 605 has been described above.
Next, the gray axis adjustment process (step S703) in FIG. 7 will be described with reference to FIGS.
[0016]
FIG. 8 is a diagram showing how the gray axis of the input device 601 is moved in the gray axis direction of the output device 607 in the L * a * b * space. Referring to this figure, the white point of the input device 601 is P_wiThe black dot is P_wiThe white point of the output device is P_woThe black dot is P_boIt is. For this reason, P_wiAnd P_wiThe gray axis l of the input device 601_iAnd P_woAnd P_boThe gray axis l of the output device 607_oDoes not match.
[0017]
Therefore, the gray axis l_iThe gray axis l_oGray axis l to match_iThe above data is moved parallel to the a * b * plane. That is, the gray axis l_iEach data point above has a gray axis l with its brightness kept constant._oIt will be moved to the upper point. For example, the gray axis l_iTop point P₁Is the gray axis l_oTop point P of equal brightness₁′ And, similarly, l_iTop point P₂, P_ThreeRespectively_oTop lightness point P₂', P_ThreeTo '.
[0018]
FIG. 9 is a diagram showing a cross section of the input Gamut in the L * a * b * space before the gray axis movement. Here, a cross section of the input Gamut on an iso-lightness plane parallel to the a * b * plane is shown. A region Gin surrounded by a hexagon represents the input Gamut, and a point P therein is a point where the gray axes of the input Gamut intersect. The point where the gray axis of the output Gamut intersects the iso-lightness plane is the point P ′ and does not coincide with the point P.
[0019]
FIG. 10 is a diagram showing a cross section of the input Gamut in the L * a * b * space after the gray axis movement. Again, the cross section of the input Gamut on the same lightness plane as in FIG. 9 is shown. A region Gin surrounded by a dotted hexagon indicates the input Gamut before the movement in FIG. 9, and a region Gin ′ surrounded by a solid hexagon indicates the input Gamut after the movement.
[0020]
With reference to this figure, the entire data in the input GamutGin is moved by the gray axis adjustment process so that the point P coincides with the point P ′ on the iso-lightness plane of the output Gamut. That is, all data on the iso-lightness plane is translated by a vector similar to a vector (an arrow from the point P to the point P ′) on which the gray axis moves. Thus, for example, the point q on the input GamutGin is moved to the point q '.
[0021]
In this way, by moving the entire input Gamut so that the gray axis of the input Gamut coincides with the gray axis of the output Gamut, an output image with a gray balance that does not cause color cast or the like can be obtained.
[0022]
Next, the process of pasting on the Gamut surface of FIG. 7 (step S707) will be described using FIG. 11 and FIG.
[0023]
FIG. 11 is a diagram showing how data outside the output Gamut is pasted into the output Gamut in the L * a * b * space. Here, for simplification, a shape obtained by combining two cones with a circle on a plane parallel to the a * b * plane as the bottom is represented as an output GamutGout. The point P is a point outside the output Gamut Gout, and the point P ′ is a point within the output Gamut Gout (a point on the surface of Gout). In this figure, a * and b * for indicating chromaticity are attached to the axis passing through the center of gravity Q of the output GamutGout which is the center of compression.
[0024]
The point P is compressed with a predetermined compression rate in the direction of the center of gravity Q, which is the center point of compression, on the equi-hue surface H including the point P and the lightness axis L *.
[0025]
FIG. 12 shows this state on the equi-hue surface H. As shown in the figure, the point P outside the output Gamut Gout is compressed in the direction of the center of gravity Q and converted into a point P ′ within the output Gamut Gout.
[0026]
[Problems to be solved by the invention]
However, such a conventional color matching method is not sufficient to reproduce an image of the input device appropriately and easily on the output device.
[0027]
That is, first, when gray axis adjustment is performed, the entire input Gamut moves as the gray axis moves, so that other colors may be converted to slightly different colors. For example, in FIG. 10, the point q in the input Gamut before the movement becomes the point q ′ after the movement by the gray axis adjustment. In this case, the blue color in the input device 601 is reproduced as purple in the output device 607. When the input device 601 is a CRT and the output device 607 is a printer, the output image is reproduced as a whole reddish by moving the gray axis.
[0028]
As described above, when the input Gamut is moved by gray axis adjustment, the reproduced output image is governed by the color in the moving direction, and becomes an image slightly different from the image of the input image.
[0029]
To correct this, a hue adjustment process is performed. This process requires a Gamut rotation operation or the like. For this reason, processing becomes very complicated, and processing time is also long. Moreover, the image as it was was not easily reproduced for such a complicated hue adjustment. For example, when the entire image is rotated in order to output blue as blue, green becomes yellow.
[0030]
Second, since the gray axis of the input Gamut is completely matched with the gray axis of the output Gamut by the gray axis adjustment process, the image of the input device may be damaged. By adjusting the gray axis, it is possible to obtain a gray-balanced image without a color cast, but a person has some image of the image reproduced by the input device. For this reason, it may not be preferable to reproduce an image that completely damages the image of the input device.
[0031]
The present invention has been devised in view of these circumstances, and the object thereof is to easily reproduce a desired image without being controlled by the color of the moving direction even if the gray axis is moved. And a computer-readable recording medium on which a color matching program is recorded.
[0032]
Another object of the present invention is to provide a color matching method capable of reproducing a desired image by keeping the image of the apparatus to some extent even when the gray axis is moved, and a computer-readable recording in which a color matching program is recorded. To provide a medium.
[0033]
[Means for Solving the Problems]
  In order to achieve the above object, according to one aspect of the present invention, when the color reproduction range of the first device is different from that of the second device, the image data within the color reproduction range of the first device is A color matching method for converting into image data within the color reproduction range of the apparatus is such that the gray axis of the first apparatus is in the direction of the gray axis of the second apparatus in a predetermined color space.Before the gray axis of the second deviceA moving step of moving each image data within the color reproduction range of the first device so as to move, the moving step depending on the distance in the saturation direction from the gray axis of the first device. The movement is performed according to the movement amount determined in the above.
[0034]
Here, the gray axis of the first device is a line segment connecting the white point and the black point defined by the first device, and the gray axis of the second device is the second device. It is a line segment connecting the white point and the black point defined by.
[0035]
According to the present invention, when all the image data in the color reproduction range of the first device is moved so that the gray axis of the first device moves in the gray axis direction of the second device, each image data It is moved according to the amount of movement determined according to the distance in the saturation direction from the gray axis of the apparatus 1.
[0036]
  Since each image data is moved according to an appropriate amount of movement according to the distance in the saturation direction from the gray axis, the image data with high saturation is moved greatly and converted into image data with completely different colors. There is no. In addition, since it is not necessary to correct the color, complicated and time-consuming hue correction is also unnecessary.Further, it is possible to prevent the image of the first apparatus from being damaged while ensuring a certain gray balance.
[0037]
Therefore, even if the gray axis is moved, it is possible to provide a color matching method that can easily reproduce a desired image without being controlled by the color of the moving direction.
[0038]
Preferably, the movement amount is determined so as to decrease as the distance in the saturation direction from the gray axis of the first device increases.
[0039]
According to this, each image data is moved so that it becomes so small that the distance of the saturation direction from the gray axis of a 1st apparatus becomes large. Therefore, it is possible to prevent a problem that an image with a different color is reproduced due to a large movement of image data with high saturation.
[0044]
  According to another aspect of the present invention, when the color reproduction ranges of the first device and the second device are different, the image data within the color reproduction range of the first device is within the color reproduction range of the second device. The color matching method for converting to the image data of the first device is such that the gray axis of the first device moves in the direction of the gray axis of the second device in a predetermined color space. A moving step for moving each image data in the image, wherein the moving step includes a gray axis of the first device.Before the gray axis of the second device between the gray axis of the first device and the gray axis of the second deviceEach image data is moved so as to move to a position.
[0045]
According to the present invention, all of the color reproduction ranges of the first device are moved so that the gray axis of the first device moves in the gray axis direction of the second device and does not coincide with the gray axis. Image data is moved. For this reason, it is possible to obtain a desired image that does not impair the image of the first device while maintaining a certain gray balance.
[0046]
Therefore, it is possible to provide a color matching method that can reproduce a desired image by maintaining the image of the first device to some extent even if the gray axis is moved.
[0047]
Preferably, the moving step includes moving the first device at a rate of 0.5 to 0.9 relative to the moving amount when the gray axis of the first device coincides with the gray axis of the second device. The gray axis is moved.
[0048]
According to this, an appropriate image in which the gray balance and the image of the first device are harmonized is reproduced.
[0049]
Preferably, the moving step makes the white point of the first device coincide with the white point of the second device.
[0050]
According to this, the gray axis of the first device is moved so as not to coincide with the gray axis of the second device, but only the white point on the gray axis of the first device is on the gray axis of the second device. Is matched to the white point. Therefore, it is possible to maintain the image of the first device to some extent without destroying the image that the person feels for white.
[0051]
Preferably, the predetermined color space is a device-independent color space.
[0052]
More preferably, the device-independent color space includes a Lab color space.
According to these, since the moving step is performed in a color space that does not depend on the device such as Lab space, image data within the color reproduction range of the first device can be appropriately and easily moved within the color reproduction range of the second device. Can be converted into image data.
[0053]
  According to still another aspect of the present invention, the computer-readable recording medium stores image data within the color reproduction range of the first device when the color reproduction ranges of the first device and the second device are different. A color matching program for causing a computer to execute a color matching method for converting to image data within the color reproduction range of the second apparatus is recorded. In the color matching method, the gray axis of the first device is in the direction of the gray axis of the second device in a predetermined color space.Before the gray axis of the second deviceA moving step of moving each image data within the color reproduction range of the first device so as to move, the moving step depending on the distance in the saturation direction from the gray axis of the first device. The movement is performed according to the movement amount determined in the above.
[0054]
According to the present invention, when all the image data in the color reproduction range of the first device is moved so that the gray axis of the first device moves in the gray axis direction of the second device, each image data is It is moved according to the amount of movement determined according to the distance in the saturation direction from the gray axis of the apparatus 1.
[0055]
  Since each image data is moved according to an appropriate amount of movement according to the distance in the saturation direction from the gray axis, the image data with high saturation is moved greatly and converted into image data with completely different colors. There is no. In addition, since it is not necessary to correct the color, complicated and time-consuming hue correction is also unnecessary.Further, it is possible to prevent the image of the first apparatus from being damaged while ensuring a certain gray balance.
[0056]
Accordingly, it is possible to provide a computer-readable recording medium on which a color matching program capable of easily reproducing a desired image without being controlled by the color of the moving direction even if the gray axis is moved. Is possible.
[0057]
  According to still another aspect of the present invention, the computer-readable recording medium stores image data within the color reproduction range of the first device when the color reproduction ranges of the first device and the second device are different. A color matching program for causing a computer to execute a color matching method for converting to image data within the color reproduction range of the second apparatus is recorded. The color matching method moves each image data within the color reproduction range of the first device so that the gray axis of the first device moves in the direction of the gray axis of the second device in a predetermined color space. A moving step, wherein the moving step has a gray axis of the first device.Before the gray axis of the second device between the gray axis of the first device and the gray axis of the second deviceEach image data is moved so as to move to a position.
[0058]
According to the present invention, the gray axis of the first device is all in the color reproduction range of the first device so as to move to a position that is in the gray axis direction of the second device and does not coincide with the gray axis. Image data is moved. For this reason, it is possible to obtain a desired image that does not impair the image of the first device while maintaining a certain gray balance.
[0059]
Therefore, it is possible to provide a computer-readable recording medium that records a color matching program that can reproduce a desired image by maintaining the image of the first device to some extent even if the gray axis is moved. Become.
[0060]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 is a flowchart showing the overall processing flow of the color matching method according to the first embodiment of the present invention. The processing performed here is performed by the Gamut mapping unit 605 shown in FIG.
[0061]
Referring to this figure, first, when independent data (here, L * a * b * data) is input to the device in step S101, the gray axis is adjusted in consideration of saturation in step S103. Done. This is because the gray balance of the output image to be reproduced is achieved by matching the gray axes of the input device and the output device.
[0062]
In this step, unlike the conventional gray axis adjustment (step S703 in FIG. 7 and the like), the entire input Gamut is not simply moved in the same manner as the movement of the gray axis. Each data in the input Gamut is moved by a moving amount determined according to the saturation (distance in the saturation direction from the gray axis of each data). Details will be described later.
[0063]
When the adjustment of the gray axis is completed, the hue adjustment process (step S704 in FIG. 7) as conventionally performed is not performed, and the process proceeds to the next step (step S105).
[0064]
In step S105, brightness and saturation are adjusted. That is, compression processing is performed to match the lightness and saturation of the input Gamut with the lightness and saturation of the output Gamut. By compressing the lightness range in accordance with the output device, problems such as whiteout occurring in the output image and collapse of dark portions can be prevented. Also, by adjusting the saturation range according to the output device, an output image with a natural color overall is reproduced.
[0065]
When the lightness and saturation compression processing ends, finally, in step S107, a pasting process is performed in which data outside the Gamut of the output device is pasted in the Gamut. This is because input image data outside the output Gamut that cannot be reproduced by the output device at this point can be appropriately reproduced.
[0066]
When the data pasting process into the output Gamut is completed, the color matching process is completed, and the image data after matching is output in step S109.
[0067]
The above is the rough processing flow of the color matching method of the present invention.
Next, the gray axis adjustment process (step S103 in FIG. 1) in consideration of the saturation will be described with reference to FIG. Note that the gray axis l of the input device in the L * a * b * space before gray axis adjustment._iAnd the gray axis of the output device_oIs the same as that shown in FIG. Further, the data in the input Gamut is also moved in the same lightness plane, that is, while maintaining the lightness by the gray axis adjustment process, as in the conventional case.
[0068]
FIG. 2 is a diagram showing an input Gamut cross section on an iso-lightness plane parallel to the a * b * plane in the L * a * b * space after gray axis adjustment. A region Gin surrounded by a dotted hexagon indicates an input Gamut before movement, and a region Gin ′ surrounded by a solid hexagon indicates an input Gamut after movement. Further, the point P and the point P ′ are points where the gray axis of the input device and the gray axis of the output device intersect on the equal lightness plane.
[0069]
As shown in the figure, the input GamutGin is moved so that the point P coincides with the point P ′. At this time, each data in the input Gamut on the iso-lightness plane also moves in the same direction as the gray axis moves, but the moving amount changes according to the distance from the point P.
[0070]
Specifically, the movement amount of each data becomes smaller as the distance from the gray axis (point P) of the input Gamut increases. When the movement amount of the gray axis on the iso-lightness plane is α, the movement amount Δ of each data is determined according to the relational expression, for example, Δ = α × β / (d + β).
[0071]
Here, d is a distance from the gray axis on the iso-lightness plane of the target pixel data point. In this figure, it is the distance from the point P. Β is an arbitrary constant. For example, a number such as 1 to 3 is used for β.
[0072]
If each data point in the input Gamut is moved in accordance with such a relationship, the point P coincides with the point P ′, but the point with high saturation hardly moves. For example, a point q with high saturation only moves to a nearby point q 'even after gray axis adjustment.
[0073]
Therefore, the color does not change so much and the phenomenon that blue is shifted to purple is prevented. Moreover, since the gray axis of the input device matches the gray axis of the output device, an image with a gray balance can be obtained.
[0074]
As described above, according to the color matching method in the present embodiment, it is possible to obtain a gray-balanced image while preventing the phenomenon that blue is shifted to purple when printed out.
[0075]
Conventionally, as shown in step S704 in FIG. 7, it has been necessary to perform a Gamut rotation operation in order to adjust the hue. Since a combination of trigonometric functions is used for the rotation operation, a lot of processing time is required. However, in the present embodiment, data conversion corresponding to the saturation is performed simultaneously with the gray axis movement, so that there is no need for hue adjustment by a rotating operation. For this reason, data conversion is possible only by four arithmetic operations, and the processing time can be shortened.
[0076]
Although the case where the movement amount of each data point is determined according to the relational expression described above is shown here, the present invention is not limited to this. The relationship may be such that the moving amount decreases as the distance from the gray axis increases.
[0077]
Therefore, if the movement amount of the gray axis on the iso-lightness plane is α, the movement amount Δ of each data may be determined according to the relational expression Δ = α (1-d / β), for example. Here, d is the distance from the gray axis on the iso-lightness plane of the pixel data point of interest, and β is an arbitrary constant. A sufficiently large number such as 150, for example, a distance from the gray axis where the movement distance is 0 is used as β.
[Second Embodiment]
Next, a color matching method according to the second embodiment of the present invention will be described. The processing flow of the color matching method in the present embodiment is the same as the processing flow in the first embodiment shown in FIG. However, the content of the gray axis adjustment process (step S103 in FIG. 1) considering saturation is different. In other words, the color matching method in the present embodiment does not completely match the gray axis of the output Gamut when moving the gray axis of the input Gamut.
[0078]
The details of the gray axis adjustment process in the present embodiment will be described below with reference to FIG. Again, the gray axis l of the input device in the L * a * b * space before the gray axis adjustment._iAnd the gray axis of the output device_oThe same positional relationship as is shown in FIG. Further, the data in the input Gamut is also moved in the same lightness plane, that is, while maintaining the lightness by the gray axis adjustment process, as in the conventional case.
[0079]
FIG. 3 is a diagram showing an input Gamut cross section on an equibrightness plane parallel to the a * b * plane after the gray axis movement in the second embodiment. Here, the region Gin surrounded by the dotted hexagon indicates the input Gamut before the movement, and the region Gin ′ surrounded by the solid hexagon indicates the input Gamut after the movement. Further, the point P and the point P ′ also indicate points where the gray axis of the input device and the gray axis of the output device intersect on the iso-lightness plane.
[0080]
Unlike the case of FIG. 2, the point P is not moved to the point P ′, but is moved to the point P ″ on the line segment connecting the point P and the point P ′. Will not be perfectly aligned with the gray axis of the output device, but will be moved to its previous position.
[0081]
For example, if you see a 9300K CRT, we know that the screen is clearly blue. Accordingly, when each data is moved so that the gray axis of the CRT completely coincides with the gray axis of the printer as the output device, the blue atmosphere of the CRT is impaired. For this reason, the CRT atmosphere is left by setting the movement amount of the gray axis to a value smaller than the distance to the gray axis of the output device.
[0082]
The point that each data in the input Gamut is moved in the movement direction of the gray axis by the movement amount determined according to the distance from the gray axis is the same as in the first embodiment shown in FIG. It is. That is, also in the present embodiment, the movement amount of each data is controlled so as to decrease as the distance from the gray axis (point P) of the input Gamut increases.
[0083]
Specifically, assuming that the movement amount of the gray axis on the iso-lightness plane is α, the movement amount Δ of each data is determined according to the relational expression Δ = α × β / (d + β), for example.
[0084]
Here, d is a distance from the gray axis on the iso-lightness plane of the target pixel data point. In this figure, it is the distance from the point P. Β is an arbitrary constant. For example, a number such as 1 to 3 is used for β.
[0085]
At this time, the movement amount α of the gray axis is determined by α = α ′ × ε. α ′ is the distance between the gray axis of the input device and the gray axis of the output device on the iso-lightness plane. In this figure, it is the distance between point P and point P '. ε is an arbitrary constant less than 1, and may be between 0.3 and 1. From the experimental result, it is desirable that it is 0.5-0.9.
[0086]
In this figure, the movement amount α of the gray axis is the distance between the point P and the point P ″. Thus, by making the movement amount of the gray axis shorter than the distance between the point P and the point P ′. In the output image, it is possible to leave an image atmosphere represented by an input device such as a CRT.
[0087]
As described above, according to the present embodiment, for example, it is possible to maintain the image of the input device to some extent while suppressing a phenomenon such as blue shifting to purple.
[0088]
Here, the example applied to the gray axis adjustment process in consideration of the saturation shown in step S103 of FIG. 1 has been described, but it is applied to the gray axis adjustment process in the conventional example (step S703 of FIG. 7). Is also possible.
[0089]
When applied in step S703 in FIG. 7, the gray axis of the input device is moved to a position in front of the gray axis of the output device, as in the case described with reference to FIG. However, each data in the input Gamut moves in parallel with a movement amount similar to the movement amount of the gray axis on the iso-lightness plane. In this case, since an undesirable color change also occurs, a hue adjustment process (step S704 in FIG. 7) is performed thereafter.
<Modification>
Finally, a modification of the second embodiment will be described. Also in the color matching method in the modified example, as shown in FIG. 3, the gray axis of the input GamutGin is not completely matched with the gray axis of the output device, and is moved to a position in front of it. However, only the white point of the gray axis of the input device is matched with the white point of the gray axis of the output device. That is, the gray axis of the input device is moved to a position before the gray axis of the output device, and only the white point of the input device is moved so as to coincide with the white point on the gray axis.
[0090]
If the white points do not match, the color that is supposed to be white will be output. For example, when a printer is used as the output device, if there is an input image in which characters are written on a white background, the white background portion will cause color cast on the output sheet, which makes it very unsightly.
[0091]
Therefore, here, as in the second embodiment shown in FIG. 3, the gray axis of the input Gamut itself does not coincide with the gray axis of the output device, but is moved to a previous position determined at a predetermined ratio. However, only the white point matches the white point of the output device. Note that each data in the input Gamut is also moved on the iso-lightness plane by a movement amount corresponding to the distance from the gray axis on the iso-lightness plane as in the case of FIG.
[0092]
In this way, only the white color can be matched with the white color of the output device while leaving the image of the input device such as a CRT. Therefore, the image received from the whole becomes more appropriate.
[0093]
Any of the color matching methods in the embodiment shown this time is realized by a program for causing the above-described series of processing operations to function. Therefore, these color matching may be executed on a computer.
[0094]
FIG. 4 is a diagram showing an external appearance of a computer for executing the above-described color matching method. A typical computer includes a main body 41, a magnetic tape device 43, a CD-ROM (Compact Disc-Read Only Memory) device 47, a display device 42 such as a CRT, a keyboard 45, a mouse 46, and a modem 49. Is included. A magnetic tape 44 is attached to the magnetic tape device 43, and a CD-ROM 48 is attached to the CD-ROM device 47.
[0095]
FIG. 5 shows the configuration of this computer in the form of a functional block diagram. As is well known, a computer main body 41 includes a CPU (Central Processing Unit) 50, a ROM (Read Only Memory) 51, a RAM (Random Access Memory) 52, and a hard disk device 53, as is well known. Contains. These are connected to each other by a bus.
[0096]
The current color matching program may be preinstalled in the hard disk device 53 or may be recorded on a removable recording medium such as the CD-ROM 48 or the magnetic tape 44.
[0097]
When the program is recorded on a removable recording medium, the recorded program is read from the recording medium by the magnetic tape device 43, the CD-ROM device 47, and the like and temporarily stored in the hard disk device 53. After that, the program is loaded from the hard disk device 53 to the RAM 52 in the same manner as previously installed in the hard disk device 53, and the execution control of the program is performed by the CPU 50.
[0098]
The recording medium on which the program is recorded includes a tape system such as a magnetic tape and a cassette tape, a disk system such as a magnetic disk (flexible disk, hard disk device, etc.) and an optical disk (CD-ROM / MO / MD / DVD, etc.), A medium such as a card system such as an IC card (including a memory card) or an optical card, or a semiconductor memory such as a mask ROM, EPROM, EEPROM, flash ROM, or the like is conceivable.
[0099]
Further, it may be a medium that carries the program in a fluid manner so that the program is downloaded from the network via the communication modem 49. When the program is downloaded from the network in this way, the program for downloading is stored in advance in the main body 41 of the computer or installed in the main body 41 from another recording medium in advance.
[0100]
The content stored in the recording medium is not limited to a program, and may be data.
[0101]
In the present embodiment, the CRT is used as the input device and the printer is used as the output device. However, the present invention is not limited to these. When color matching is performed between apparatuses having different color reproduction ranges, the present invention can be applied to any apparatus.
[0102]
Further, this time, it has been described that all the color matching processes shown in FIG. 1 are performed by the Gamut mapping unit 605 in FIG. However, the present invention is not limited to this case. For example, the Gamut compression process in step S107 can be performed during the color conversion process. For example, when L * a * b * data represented in the L * a * b * space is converted into CMYK data represented in the CMY space.
[0103]
Further, the color matching method is not limited to the processing flow shown in the flowchart of FIG. For example, the present invention can also be applied to the case where the gray axis adjustment process (step S103) and the lightness compression process (step S105) are performed simultaneously, or the processing order is reversed. .
[0104]
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.
[Brief description of the drawings]
FIG. 1 is a flowchart showing a flow of overall processing of a color matching method according to a first embodiment of the present invention.
FIG. 2 is a diagram showing an input Gamut cross section on an iso-brightness plane parallel to the a * b * plane in the L * a * b * space after gray axis adjustment.
FIG. 3 is a diagram showing an input Gamut cross section on an iso-lightness plane parallel to the a * b * plane after the gray axis movement in the second embodiment. here
FIG. 4 is a diagram showing an external appearance of a computer for executing a color matching method.
5 is a functional block diagram showing a configuration of the computer of FIG. 4. FIG.
FIG. 6 is a diagram illustrating a flow of image data in order to explain a color matching method between the input device 601 and the output device 607;
7 is a flowchart showing a flow of color matching processing in the Gamut mapping unit 605 in FIG. 6;
FIG. 8 is a diagram showing how the gray axis of the input device 601 is moved in the gray axis direction of the output device 607 in the L * a * b * space.
FIG. 9 is a diagram showing a cross section of an input Gamut in the L * a * b * space before moving the gray axis.
FIG. 10 is a diagram showing a cross section of an input Gamut in the L * a * b * space after moving the gray axis.
FIG. 11 is a diagram showing how data outside the output Gamut is pasted into the output Gamut in the L * a * b * space.
12 is a diagram showing a state of being compressed at a predetermined compression rate on an equi-hue surface H. FIG.
[Explanation of symbols]
44 magnetic tape, 48 CD-ROM, 601 input device, 605 Gamut mapping unit, 607 output device.

Claims (9)

To convert image data within the color reproduction range of the first device into image data within the color reproduction range of the second device when the color reproduction range of the first device and the second device are different. Color matching method,
In a predetermined color space, the color reproduction of the first device is such that the gray axis of the first device moves in the direction of the gray axis of the second device to a position before the gray axis of the second device. A moving step of moving each image data within the range,
The color matching method according to claim 1, wherein the moving step moves the image data according to a moving amount determined according to a distance in a saturation direction from the gray axis of the first device.   The color matching method according to claim 1, wherein the movement amount is determined so as to decrease as the distance in the saturation direction from the gray axis of the first device increases. To convert image data within the color reproduction range of the first device into image data within the color reproduction range of the second device when the color reproduction range of the first device and the second device are different. Color matching method,
A moving step of moving each image data within the color reproduction range of the first device so that the gray axis of the first device moves in the direction of the gray axis of the second device in a predetermined color space. Including
The moving step is such that the gray axis of the first device moves to a position before the gray axis of the second device between the gray axis of the first device and the gray axis of the second device. In addition, the color matching method is characterized in that each image data is moved. In the moving step, the first device is moved at a rate of 0.5 to 0.9 with respect to the moving amount when the gray axis of the first device coincides with the gray axis of the second device. The color matching method according to claim 1, wherein the gray axis is moved. 5. The color matching method according to claim 1, wherein in the moving step, a white point of the first device is matched with a white point of the second device. 6. The color matching method according to claim 1, wherein the predetermined color space is a device-independent color space. The color matching method according to claim 6 , wherein the device-independent color space includes a Lab color space. To convert image data within the color reproduction range of the first device into image data within the color reproduction range of the second device when the color reproduction range of the first device and the second device are different. A computer-readable recording medium on which a color matching program for causing a computer to execute the color matching method is recorded,
The color matching method is:
In a predetermined color space, the color reproduction of the first device is such that the gray axis of the first device moves in the direction of the gray axis of the second device to a position before the gray axis of the second device. A moving step of moving each image data within the range,
The computer-readable recording medium, wherein the moving step moves the image data according to a moving amount determined according to a distance in a saturation direction from the gray axis of the first device. To convert image data within the color reproduction range of the first device into image data within the color reproduction range of the second device when the color reproduction range of the first device and the second device are different. A computer-readable recording medium on which a color matching program for causing a computer to execute the color matching method is recorded,
The color matching method is:
A moving step of moving each image data within the color reproduction range of the first device so that the gray axis of the first device moves in the direction of the gray axis of the second device in a predetermined color space. Including
The moving step is such that the gray axis of the first device moves to a position before the gray axis of the second device between the gray axis of the first device and the gray axis of the second device. In addition, the computer-readable recording medium is characterized in that the image data is moved.

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