JP2002368979A - Image processor and program for image processing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device and a program for image processing, which make it easy to confirm mechanical differences and temporal differences between proofers. SOLUTION: This image processor is equipped with a color conversion part 13 which generates color-converted image data 14 by performing specific color conversion processing for input image data 11, a patch data generation part 15 which generates patch data 16 representing a color patch independently of part of the color conversion processing by the color conversion part 13, a data composition part 17 which generates image data 19 representing an image composed of the image represented by the color-converted image data 14 and the color patch represented by the patch data 16 by putting the color- converted image data 14 and patch data 16 together, and a driver part 18 which drives a color printer 20 with the output image data 19.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image processing apparatus and an image processing program for generating output image data by performing color conversion processing on input image data.

[0002]

2. Description of the Related Art Conventionally, in the field of color printing, a small printer called a color proofer has been widely used in order to verify the color reproduction characteristics of color image data in an actual large printing press.

However, the color proofer has different color reproduction characteristics for each color proofer, which is an obstacle to verifying the color reproduction characteristics. In addition, it is difficult to prevent the color reproduction characteristics from changing over time in individual color proofers.

Therefore, various methods have been proposed for confirming the machine difference and the aging difference between color proofers. As one of them, by adding patch data for confirmation to the color image data, printing a color patch for confirmation in the margin area of the area where the color image is printed, and measuring the color of the color patch, There is a method of confirming the machine difference and aging difference between proofers.

[0005]

However, this method has a problem that it is difficult for a small design company or the like to equip the measuring instrument because the measuring instrument is expensive.

As a method without using a measuring instrument, a reference patch serving as a reference for confirmation is prepared in advance, and this reference patch is visually compared with a confirmation color patch added to a margin of an image to confirm. However, in the case of a color proofer, a plurality of types of color conversion LUTs (Look U) are used in order to predict the color of the final printed matter in accordance with the difference in color reproduction characteristics depending on the type of printing paper.
p Table) needs to be switched and output, so that there is a problem that the color of the added color patch changes depending on the difference in the color conversion LUT.

To solve the above problem, a color conversion LU is used.
Although a method of preparing a plurality of reference patches corresponding to the types of T is also conceivable, the color conversion LUT is sometimes customized for the user's convenience, and thus cannot be said to be a practically practical solution.

The present invention has been made in view of the above circumstances, and has as its object to provide an image processing apparatus and an image processing program in which machine differences and time differences between proofers can be easily confirmed.

[0009]

According to the present invention, there is provided an image processing apparatus which performs a color conversion process on input image data to generate output image data.
A color conversion unit that performs predetermined color conversion processing on input image data to generate color conversion image data; and converts the patch data representing a color patch into at least a part of the color conversion processing in the color conversion unit. And a patch data generation unit that generates the image data independently of the color conversion image data and the patch data, thereby forming an image represented by the color conversion image data and a color patch represented by the patch data. A data synthesizing unit for generating output image data representing the synthesized image.

The image processing apparatus according to the present invention includes a patch data generation unit that generates independently of at least a part of the color conversion processes in the color conversion unit. Output image data is generated by performing a color conversion process using a color conversion LUT selected from the color conversion LUTs, but the patch data for confirmation to be added is basically output without performing the color conversion process. By generating image data, even if color conversion processing is performed by switching between a plurality of types of color conversion LUTs in the color conversion unit, color accuracy can always be checked using a common color patch. Can be accurately confirmed.

Here, the image processing apparatus converts output image data representing an image obtained by adding a color patch to a proof output by a proofer that outputs a proof of an image output by a predetermined target device that outputs an image. Generating a first color conversion definition reflecting the profile of the target device and a second color conversion definition reflecting the profile of the proofer.
And performing a color conversion process based on the color conversion definition including the color conversion definition. The patch data generation unit converts the patch data into one of the first color conversion definition and the second color conversion definition. May also be generated independently from.

According to the image processing apparatus configured as described above, the patch data can be generated independently from both the color conversion definition of the target device and the color conversion definition of the proofer. Color accuracy can be checked, and the machine difference between proofers and the aging difference of proofers can be accurately checked.

[0013] The color conversion section may perform a color conversion process based on a color conversion definition including a third color conversion definition for correction in addition to the first color conversion definition and the second color conversion definition. Wherein the patch data generation unit includes:
The patch data may be independent of both the first color conversion definition and the second color conversion definition, and may be generated independently of the third color conversion definition.

According to the image processing apparatus configured as described above, the patch data is independently generated from any of the first color conversion definition, the second color conversion definition, and the third color conversion definition for correction. With this configuration, the machine difference between proofers and the aging difference of proofers can be accurately confirmed.

Further, the color conversion unit may perform a color conversion process based on a color conversion definition including a third color conversion definition for correction in addition to the first color conversion definition and the second color conversion definition. Wherein the patch data generation unit converts the patch data from the first color conversion definition and the second color conversion definition and is independent of the third color conversion definition. It may be generated by performing a color conversion process based on.

According to the image processing apparatus having the above-described configuration, the patch data is independent of both the first color conversion definition and the second color conversion definition, and is based on the third color conversion definition. With the configuration in which the proofer is generated by performing the conversion process, it is possible to accurately confirm whether the machine difference between the proofers and the aging difference between the proofers are correctly corrected.

Further, the image processing program of the present invention for achieving the above object is executed in a computer, and causes the computer to operate as an image processing apparatus which performs a color conversion process on input image data to generate output image data. In the image processing program, a color conversion unit that performs a predetermined color conversion process on the input image data to generate color conversion image data, and patch data representing a color patch is stored in at least one of the color conversion processes in the color conversion unit. And a patch data generation unit that generates the image data independently of the color conversion process, and synthesizes the color conversion image data and the patch data to form an image represented by the color conversion image data and the patch data. A data synthesizing unit for generating output image data representing an image synthesized with the color patch To.

An image processing program according to the present invention includes a patch data generation unit that generates independently of at least a part of the color conversion processes in the color conversion unit,
The input image data is subjected to color conversion processing by a color conversion LUT selected from a plurality of types of color conversion LUTs to generate output image data. By generating the output image data without performing the conversion process, even if the color conversion unit switches the plurality of types of color conversion LUTs and performs the color conversion process, it is possible to always check the color accuracy using a common color patch. It is possible to easily form an image processing apparatus on a desired computer which can accurately confirm the machine difference and the time-dependent difference.

Here, the image processing program causes the computer to output a proof of an image output by a predetermined target device that outputs an image, a proof output by a proofer that outputs an image having a color patch attached to a proof output by a proofer. Operating as an image processing apparatus that generates image data, wherein the color conversion unit includes a first color conversion definition reflecting the target device profile and a second color conversion definition reflecting the proofer profile.
And performing a color conversion process based on the color conversion definition including the color conversion definition. The patch data generation unit converts the patch data into one of the first color conversion definition and the second color conversion definition. May also be generated independently from.

According to the image processing program configured as described above, the patch data can be generated independently from both the color conversion definition of the target device and the color conversion definition of the proofer. This makes it possible to easily form, on a desired computer, an image processing apparatus capable of accurately confirming machine differences between proofers and aging differences of proofers.

Further, the color conversion section performs a color conversion process based on a color conversion definition including a third color conversion definition for correction in addition to the first color conversion definition and the second color conversion definition. Wherein the patch data generation unit includes:
The patch data may be independent of both the first color conversion definition and the second color conversion definition, and may be generated independently of the third color conversion definition.

According to the image processing program configured as above, the patch data is converted into the first color conversion definition and the second color conversion definition.
Image processing that can accurately confirm the machine difference between proofers and the aging difference of proofers by being configured to be generated independently from any of the color conversion definitions described above and the third color conversion definition for correction. The device can be easily formed on a desired computer.

Further, the color conversion section performs a color conversion process based on a color conversion definition including a third color conversion definition for correction in addition to the first color conversion definition and the second color conversion definition. Wherein the patch data generation unit converts the patch data from the first color conversion definition and the second color conversion definition and is independent of the third color conversion definition. It may be generated by performing a color conversion process based on.

According to the image processing program configured as described above, the patch data is independent of both the first color conversion definition and the second color conversion definition and is based on the third color conversion definition. An image processing device capable of accurately confirming whether or not the machine difference between proofers and the aging difference between proofers is correctly corrected is configured on a desired computer by being configured to generate by performing the conversion process. It can be easily formed.

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of an image processing apparatus and an image processing program according to the present invention will be described below.

First, the hardware configuration of a computer system in which the image processing program according to each embodiment of the present invention is installed and operated as an image processing apparatus will be described.

FIG. 1 is an external view of a computer system operated as the image processing apparatus of the present embodiment.

As shown in FIG. 1, the computer system 100 has a main body 101 containing a CPU (Central Processing Unit), memories (RAM and ROM), a hard disk, a communication board, etc., and a screen according to instructions from the main body 101. CRT display 102 for display, keyboard 103 for inputting user's instructions and character information into this computer, mouse for specifying an arbitrary position on the screen of CRT display 102 and inputting an instruction corresponding to the position 104, and a communication cable 105 for connecting this computer to another computer.

The main body 101 includes a flexible disk (F
D) has an FD insertion slot 101a and a CD-ROM insertion slot 101b into which a CD-ROM and a CD-ROM are removably inserted. Drive is built-in.

As the computer system 100, a computer system generally called a workstation or a personal computer can be used.

FIG. 2 is a hardware configuration diagram of a computer system having the appearance shown in FIG.

The hardware configuration includes a CPU (Central Processing Unit) 111 and a RAM (Random Access).
ss Memory) 112, a hard disk controller 113, an FD drive 114, a CD-ROM drive 115, a mouse controller 116, a keyboard controller 117, a display controller 118, and a communication board 119, which are interconnected by a bus 110. Have been.

As described with reference to FIG. 1, the FD drive 114 and the CD-ROM drive 115 are provided with the FD loading port 101a and the CD-ROM loading port 101b, respectively.
This accesses the FD 710 and the CD-ROM 700 loaded from. The communication board 119 is a communication line 6
00 is connected.

FIG. 2 shows the hard disk 12 accessed by the hard disk controller 113.
0, a mouse 104 controlled by a mouse controller 116, a keyboard 103 controlled by a keyboard controller 117, and a CRT display 102 controlled by a display controller 118.

CD of the computer system described above
A CD-ROM 700, which is a storage medium for an image processing program of the present invention described below,
Is loaded and the image processing program stored in the CD-ROM 700 is installed to construct and operate the image processing apparatus of the present invention.

Next, an image processing apparatus according to the first embodiment of the present invention will be described.

FIG. 3 is a schematic block diagram of the image processing apparatus according to the first embodiment of the present invention.

The image processing apparatus 10 shown in FIG. 3 is an image processing apparatus that performs color conversion processing on input image data to generate output image data 19. This output image data 19
Is output as image data representing an image with a color patch attached to a proof by a color printer 20 that outputs a proof for verification of an image output by a predetermined target device (such as a printing machine as a final target). Is done.

The image processing apparatus 10 includes an image data receiving unit that receives input image data, a color conversion unit 13 that performs a predetermined color conversion process on the input image data 11 to generate color converted image data 14, and a color patch. The patch data generation unit 15 that generates the patch data 16 representing the image data independently of at least a part of the color conversion processes in the color conversion process in the color conversion unit 13, and the color conversion image data 14 and the patch data 16 are combined. By doing so, output image data 1 representing an image obtained by combining the image represented by the color-converted image data 14 and the color patch represented by the patch data 16
9 for generating the image data 9 and output image data 19
Driver section 1 for driving color printer 20 by
8 is provided.

Here, the patch data 16 is directly input to the data synthesizing unit 17, and is also input to the color conversion unit 13 as indicated by a dashed line in FIG. There are also forms that undergo conversion. Details will be described later.

The color printer 20 according to the present embodiment corresponds to a proofer according to the present invention.

In the color printer 20 according to the present embodiment, the color conversion unit 13 includes a first color conversion definition reflecting the profile of the target device and a second color conversion definition reflecting the profile of the color printer 20. The patch data generation unit 15 performs a color conversion process based on a color conversion definition including the following.
It is configured to be generated independently from both the first color conversion definition and the second color conversion definition.

FIG. 4 shows an example of an output image and a reference patch output from a color printer based on output image data output from the image processing apparatus shown in FIG.

As shown in FIG. 4, the output image 21 is
A proof image 22 serving as a proof of an image output by a predetermined target device, and the proof image 22
And a color patch 23 added to.

By comparing the color patch 23 with a reference patch 24 prepared in advance for reference, it is possible to verify the color reproduction characteristics of the color image data in the predetermined target device.

The color patch 23 and the reference patch 2
Reference numeral 4 in the present embodiment adjusts the three-color mixed gray of C (cyan), M (magenta), and Y (yellow) to nine gradation levels.

FIG. 5 is a flowchart showing the flow of image processing from the input image data to the output image data in the image processing apparatus shown in FIG.

In the image processing apparatus 10 shown in FIG. 3, after the image data is received by the image data receiving section 12, the color conversion processing shown in FIG. 5 is performed. That is, as shown in FIG. 5, the input image data 11 handled here is input image data composed of four colors of C (cyan), M (magenta), Y (yellow), and K (black). Yes, this CMYK four-color input image data 11
Is a print characteristic LUT2 describing print characteristics of a predetermined target device in the color conversion unit 13 (see FIG. 3).
5, that is, CM according to the first color conversion definition of the present invention.
Conversion from the YK color space to the XYZ color space is performed.
The inverse conversion LUT 26 describing the inverse function of the printing characteristics of the color printer 20 (proofer), that is, the color printer 2 from the XYZ space by the second color conversion definition according to the present invention.
0 is converted to a CMY color space. However, actually, the L which combines the printing characteristic LUT 25 and the inverse conversion LUT 26 is used.
A UT is created and converted by the merged LUT.

With the above-described color conversion processing, the color conversion for simulating the color reproduction characteristics of a predetermined target device by the color printer 20 (proofer) is completed.

On the other hand, as the patch data 16 of the color patch for confirming the machine difference between the proofers and the time difference, CMY gradation values capable of outputting in advance a color equivalent to the color of the reference patch 24 (see FIG. 4) for reference. The patch data 16 is generated in the patch data generation unit 15 (see FIG. 3) independently of the color conversion processing in the color conversion unit 13.

Next, the color conversion image data 14 and the patch data 16 are synthesized in the data synthesizing unit 17, and the image represented by the color conversion image data 14 and the color patch represented by the patch data 16 are synthesized. Output image data 19 representing the image thus generated is generated.

The output image data 19 thus generated
Is output from the color printer 20 via the driver unit 18. In this way, the patch data is generated independently from both the color conversion definition of the target device and the color conversion definition of the proofer, so that this image processing device can accurately confirm the machine difference between the proofers and the aging difference of the proofer. Can be. Here, since the color patch is simultaneously output on the same sheet as the image represented by the color-converted image data 14, that is, the proof image, the state of the color printer at the exact timing when the proof image is output is output. You can know. Also,
It is also possible to know the degree of fading of the proof image after a while.

Next, a description will be given of a second embodiment of the image processing apparatus according to the present invention.

As a proofer color space, an R (red), G (green), and B (blue) color space may be used in addition to the CMY color space. In the above embodiment, an example using the CMY color space has been described. Next, as a second embodiment, R, G, and
An example in which a color printer of three colors B is used will be described.

FIG. 6 is a flowchart showing the flow of image processing according to the second embodiment of the present invention.

In the second embodiment, the color conversion unit 13
(See FIG. 3) is a correction LUT 2 in addition to the print characteristic LUT 25 ′ and the inverse conversion LUT 26 ′ of the output device characteristic.
7, that is, a color conversion process based on the color conversion definition including the third color conversion definition according to the present invention.

Here, the printing characteristic LUT 25 and the inverse conversion LUT of the output device characteristic in the embodiment shown in FIG.
Reference numerals 26 denote lookup tables defining conversions between the CMYK color space and the XYZ color space, and between the XYZ color space and the CMY color space, respectively. The print characteristics LUT 25 in the embodiment shown in FIG. 'And the inverse transform LUT 26 of output device characteristics define the conversion between the CMYK color space and the L ^* a ^* b ^* color space and between the L ^* a ^* b ^* color space and the RGB color space, respectively. This is a look-up table. The correction LUT 27 shown in FIG.
Is a look-up table for fine adjustment when the characteristics of the color printer slightly change, and is a one-dimensional look-up table in which the three colors R, G, and B are slightly adjusted independently. In actual color conversion, a printing characteristic LUT 25 ′, an inverse conversion LUT 26 ′ of output device characteristics,
Further, one LUT combined with the correction LUT 27 is created, and color conversion is performed based on the combined one LUT.

Further, in the embodiment shown in FIG. 6, the patch data generated by the patch data generator (see FIG. 3) is patch data defined in the RGB color space.

In the embodiment shown in FIG. 6, the print characteristic L
It is independent of the UT 25 '(first color conversion definition) and the inverse conversion LUT 26' (second color conversion definition) of the output device, and further has a correction LUT 27 (third color conversion definition).
The proofer is also generated independently from the proofer, and it is possible to accurately confirm the machine difference between the proofers and the aging difference of the proofer.

Next, a description will be given of a third embodiment of the image processing apparatus according to the present invention.

FIG. 7 is a flowchart showing the flow of image processing according to the third embodiment of the present invention.

In the third embodiment, a proofer (color printer) for outputting a proof image using four colors of CMYK is used.

The color conversion unit 13 (see FIG. 3) of the third embodiment is similar to the color conversion unit of the second embodiment shown in FIG. '' And a correction LUT 27 ′ are configured to perform a color conversion process based on a color conversion definition.

Here, in the third embodiment shown in FIG. 7, the print characteristic LUT 25 defines the color conversion between the CMYK color space and the XYZ color space, and is the same as the print characteristic LUT in the embodiment of FIG. However, the inverse conversion LUT of the output device characteristics in the embodiment shown in FIG. 7 is a look-up table defining color conversion between the XYZ color space and the CMYK color space, and the correction LUT 27 ′
4 is a one-dimensional lookup table for fine adjustment of a color printer in which four colors C, M, Y, and K are slightly independently adjusted.

Further, in the embodiment shown in FIG. 7, the confirmation patch data generated by the patch data generation section (see FIG. 3) is patch data defined in the CMYK color space. This check patch data is stored in the print characteristic LUT2.
5, independent of the inverse conversion LUT 26 ″ of the output device characteristics, but is input to the color conversion unit (see FIG. 3) and
After undergoing color conversion by the UT 27 ', the data synthesis unit 1
7 is combined with the color-converted image data. Therefore, in the third embodiment, the patch data generation unit shown in FIG. 3 with the effect of color conversion using only the correction LUT 27 'corresponds to the patch data generation unit according to the present invention.

In actual color conversion, one LUT is created by combining a print characteristic LUT 25 and an inverse conversion LUT 26 ″ of output device characteristics with a correction LUT 27 ′ for color conversion of input image data. The input image data undergoes color conversion by one LUT obtained by this combination, and color converted image data is generated. As described above, the patch data for confirmation is used for the correction LU.
The color conversion is performed only by T27 '.

In the case of this embodiment, on the image output by the color printer, a color patch subjected to color conversion by the correction LUT 27 'is obtained, and the machine difference between the proofers after the fine adjustment and the proofer (color printer) )
Can be correctly confirmed with time.

Here, the patch data for confirmation is CM
Although it has been described that the patch data is composed of four colors of YK, even if the patch data for confirmation is composed of three colors of CMY, there is no great problem.

Next, an embodiment of the image processing program of the present invention will be described.

FIG. 8 is a schematic configuration diagram of an embodiment of the image processing program of the present invention.

The image processing program 30 representatively shows a configuration corresponding to each of the above-described embodiments of the image processing apparatus, and is executed in a computer. Which is a program that operates as an image processing apparatus that generates output image data by performing a color conversion unit 31, a patch data generation unit 32, and a data synthesis unit 33.

The color conversion section 31 corresponds to the color conversion section 1 shown in FIG.
3, which performs predetermined color conversion processing on the input image data 11 to generate color conversion image data 14.

The patch data generation unit 32 corresponds to the patch data generation unit 15 in FIG. 3, and converts the patch data 16 representing a color patch into at least a part of the color conversion processing in the color conversion unit 13. Generated independently of the conversion process.

The data synthesizing section 33 corresponds to the data synthesizing section 17 in FIG.
4 and the patch data 16, the image represented by the color-converted image data 14 and the patch data 16 are combined.
And output image data 19 representing an image synthesized with the color patch represented by. The output image data 19 thus generated is output from the color printer 20 via the driver unit 18. In this way, the patch data is generated independently from both the color conversion definition of the target device and the color conversion definition of the proofer. Can be.

Next, the second image processing program of the present invention will be described.
An embodiment will be described.

The image processing program according to the second embodiment corresponds to the image processing apparatus according to the second embodiment. In the second embodiment, the color conversion unit 13 (see FIG. 3) Is configured to perform a color conversion process based on a color conversion definition including a third color conversion definition for correction in addition to the first color conversion definition and the second color conversion definition. As a color space, a color printer of three colors of RGB can be used.

By doing so, the patch data generation section (see FIG. 3) separates the patch data from both the first color conversion definition and the second color conversion definition, and furthermore, It can also be generated independently from the third color conversion definition, and the difference between proofers and the aging difference between proofers can be accurately confirmed.

Next, the third image processing program of the present invention will be described.
An embodiment will be described.

The image processing program according to the third embodiment corresponds to the image processing apparatus according to the third embodiment. In the third embodiment, the color conversion unit 13 (see FIG. 3) Performs a color conversion process based on a color conversion definition including a third color conversion definition for correction, in addition to the first color conversion definition and the second color conversion definition. The generation unit (see FIG. 3) converts the patch data into a color conversion process independent of both the first color conversion definition and the second color conversion definition and based on the third color conversion definition. It is configured to perform.

By doing so, it is possible to add a gradation patch of K single color.

[0081]

As described above, according to the image processing apparatus of the present invention, a color conversion section that performs predetermined color conversion processing on input image data to generate color conversion image data, and a patch representing a color patch A patch data generation unit that generates data independently of at least a part of the color conversion processing in the color conversion unit, and a color conversion image data by synthesizing the color conversion image data and the patch data. A plurality of types of color conversion LUTs are switched in the color conversion unit by providing a data synthesizing unit that generates output image data representing an image obtained by synthesizing the image represented by the image data and the color patch represented by the patch data. Even if color conversion is performed, color accuracy can always be checked using a common color patch, and machine differences and aging differences between proofers can be checked accurately. It is possible to realize an image processing apparatus.

Further, as described above, according to the image processing program of the present invention, the program is executed in a computer,
An image processing program that causes the computer to operate as an image processing device that performs color conversion processing on input image data and generates output image data generates a color conversion image data by performing predetermined color conversion processing on the input image data A color conversion unit, a patch data generation unit that generates patch data representing a color patch independently of at least a part of the color conversion processes in the color conversion unit, and a color conversion image data and patch data. By combining the image represented by the color-converted image data and the color patch represented by the patch data with a data combining unit that generates an output image data representing an image combined. It is possible to easily form an image processing apparatus on a computer in which machine differences and aging differences between proofers can be easily confirmed.

[Brief description of the drawings]

FIG. 1 is an external view of a computer system operated as an image processing apparatus according to an embodiment.

FIG. 2 is a hardware configuration diagram of a computer system having the appearance shown in FIG.

FIG. 3 is a schematic configuration diagram of an image processing apparatus according to the first embodiment of the present invention.

4 is an example of an output image and a reference patch output from a color printer based on output image data output from the image processing apparatus shown in FIG. 3;

FIG. 5 is a flowchart showing a flow of image processing in the image processing apparatus shown in FIG. 3 until output image data is generated from input image data.

FIG. 6 is a flowchart illustrating a flow of image processing according to a second embodiment of the present invention.

FIG. 7 is a flowchart illustrating a flow of image processing according to a third embodiment of the present invention.

FIG. 8 is a schematic configuration diagram of an embodiment of an image processing program according to the present invention.

[Explanation of symbols]

 Reference Signs List 10 image processing device 11 input image data 12 image data decoding unit 13 color conversion unit 14 color conversion image data 15 patch data generation unit 16 patch data 17 data synthesis unit 18 driver unit 19 output image data 20 color printer 21 output image 22 proof image 23 color patch 24 reference patch 25, 25 'printing characteristic LUT 26, 26', 26 '' inverse conversion LUT 27, 27 'correction LUT 30 image processing program 31 color conversion unit 32 patch data generation unit 33 data synthesis unit 100 computer System 101 Main body 101a FD insertion slot 101b CD-ROM insertion slot 102 CRT display 103 Keyboard 104 Mouse 105 Communication cable 110 Bus 111 CPU (Central processing unit) 112 Memory 113 Memory controller Roller 114 Chipset 115 ROM (Read Only Memory) 116 Mouse Controller 117 Keyboard Controller 118 Display Controller 119 Communication Board 120 Hard Disk 600 Communication Line 700 CD-ROM 710 FD

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04N 1/46 H04N 1/40 D 1/60 1/46 Z F term (Reference) 2C087 AA15 AB05 AC07 BA03 BA07 BD07 BD36 CB04 5B057 CA01 CA12 CB01 CB12 CB19 CE08 CE18 CH01 CH07 CH11 5C076 AA14 AA19 AA26 BA06 5C077 LL19 MM27 MP08 PP23 PP32 PP33 PP36 PQ12 PQ22 PQ23 5C079 HB01 HB03 HB05 MA04 MA03MA

Claims (8)

[Claims] An image processing apparatus that performs a color conversion process on input image data to generate output image data, a color conversion unit that performs a predetermined color conversion process on the input image data to generate color conversion image data, A patch data generation unit that generates patch data representing a color patch independently of at least a part of the color conversion processes in the color conversion unit; and synthesizes the color converted image data and the patch data. A data synthesizing unit for generating output image data representing an image obtained by synthesizing the image represented by the color-converted image data and the color patch represented by the patch data. Image processing device. 2. An image processing apparatus according to claim 1, wherein the image processing apparatus generates output image data representing an image in which a proof is output by a proofer that outputs a proof of an image output by a predetermined target device that outputs an image and a color patch is attached to the proof. Wherein the color conversion unit is based on a color conversion definition including a first color conversion definition reflecting the profile of the target device and a second color conversion definition reflecting the profile of the proofer. Performing a color conversion process, wherein the patch data generation unit generates the patch data independently from both the first color conversion definition and the second color conversion definition. The image processing apparatus according to claim 1. 3. A color conversion process based on a color conversion definition including a third color conversion definition for correction in addition to the first color conversion definition and the second color conversion definition. Wherein the patch data generation unit is configured to convert the patch data independent of both the first color conversion definition and the second color conversion definition, and to further execute the third color conversion. The image processing apparatus according to claim 2, wherein the image processing apparatus is generated independently of the definition. 4. A color conversion process based on a color conversion definition including a third color conversion definition for correction in addition to the first color conversion definition and the second color conversion definition. Wherein the patch data generating unit is configured to convert the patch data independent of both the first color conversion definition and the second color conversion definition, and to execute the third color conversion definition 3. The image processing apparatus according to claim 2, wherein the image processing apparatus is generated by performing a color conversion process based on the image. 5. An image processing program that is executed in a computer and causes the computer to operate as an image processing apparatus that performs color conversion processing on input image data and generates output image data. A color conversion unit that performs processing to generate color conversion image data; and patch data that generates patch data representing a color patch independently of at least a part of the color conversion processing in the color conversion processing in the color conversion unit. A generation unit, by combining the color-converted image data and the patch data, an output image representing an image in which an image represented by the color-converted image data and a color patch represented by the patch data are combined An image processing program comprising: a data synthesizing unit that generates data. 6. An image processing program according to claim 1, wherein said computer outputs a proofer that outputs a proof of an image output by a predetermined target device that outputs an image. Operating as an image processing apparatus that generates data, wherein the color conversion unit is configured to perform a first color conversion definition reflecting the target device profile and a second color conversion reflecting the proofer profile. And performing a color conversion process based on the color conversion definition including the definition. The patch data generation unit separates the patch data from any of the first color conversion definition and the second color conversion definition. 6. The image processing program according to claim 5, wherein the image processing program is generated. 7. A color conversion process based on a color conversion definition including a third color conversion definition for correction in addition to the first color conversion definition and the second color conversion definition. Wherein the patch data generation unit is configured to convert the patch data independent of both the first color conversion definition and the second color conversion definition, and to further execute the third color conversion. 7. The image processing program according to claim 6, wherein the image processing program is generated independently of the definition. 8. A color conversion process based on a color conversion definition including a third color conversion definition for correction in addition to the first color conversion definition and the second color conversion definition. Wherein the patch data generating unit is configured to convert the patch data independent of both the first color conversion definition and the second color conversion definition, and to execute the third color conversion definition 7. The image processing program according to claim 6, wherein the image processing program is generated by performing a color conversion process based on the image.