JPH099082A - Color picture processing method and its system - Google Patents

Abstract

PURPOSE: To provide a color picture processing method and its system capable of restoring an original picture from an output picture to which different color space compression processings are adapted. CONSTITUTION: The color picture processing method executes processing by sharing a color picture by different kinds of devices provided with the different processing characteristics of color pictures. At the time of recording a color picture 24, the method outputs characteristic information 25 of picture processing including color transformation processing in the device of its own kind (46) and at the time of reading a color picture 45, the method inputs characteristic information 25 of the kind of a device recording the pertinent color picture. Then, referring to characteristic information 25 of the kind of the device recording the color picture and characteristic information 44 of picture processing in the device of its own kind, picture processing including color transformation processing is executed to reproduce the color picture. The output of this characteristic information is record 46 onto the recording paper of the color picture and the output of characteristic information is reading from on the recording paper of the color picture.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color image processing method for inputting or outputting a color image between different types of devices such as a color facsimile, a color scanner, a color printer and a color display, which have different color reproduction characteristics (range). And its system.

[0002]

2. Description of the Related Art Due to the expansion of color input / output devices, desktop publishing (Desk Top Publishing: DT, hereinafter) such as creating a color image on a personal computer and inputting / outputting an image on a color scanner or a color printer.
P) has become popular. FIG. 10 is a system diagram showing an example of DTP. In the figure, 51 is an input image to be input, 52 is an image input device such as a color scanner for inputting an image, 53 is a computer for processing the input image, 54 is an image display such as a color display for displaying the processed image. A device, 55 is an image output device such as a color printer that outputs an image, and 56 is an output image that is output. In the DPT, the input image 51 shown in the above example is input by the image input device 52, edited / processed by the computer 53 while being confirmed by the image display device 54, and then output by the image output device 55 to obtain an output image 56. Was there. Further, a new color image is created on the computer 53 by using the image display device 54, and an output image 56 is obtained by outputting the image on the image output device 55, thereby creating a new original document on the computer. Was there.

However, since different types of devices such as color scanners, color printers, and color displays have different color reproduction ranges, there is a problem that common color reproduction cannot be obtained. As an example, FIG. 11 shows a color reproduction range on an L * plane on the CIE1976 Lab color space,
A solid line shows a certain image display device, and a dotted line shows a certain image output device.

Therefore, in order to prevent image deterioration such as color crushing, a color management system (hereinafter referred to as CMS) has emerged based on a color space compression processing technique for adjusting a color reproduction range. By the CMS, the computer 53 shown in FIG. 10 holds characteristic data unique to each image peripheral device such as the image input device 52, the image display device 54, the image output device 55,
Image processing is performed so as to achieve common color reproduction in each peripheral device by using the held characteristic data unique to each peripheral device. For example, a color image created on the computer 53 by DTP is color space compressed by CMS at the time of printout, and is processed so as to be within the color reproduction range of the printer from the color reproduction range of the monitor.

The situation will be described below with reference to FIG.
In the hue in which the color reproduction range of the image output device is Vp with respect to the color reproduction range of the image display device, the saturation Vi of a pixel in the processed image is Vi> Vp. Cannot be expressed in Therefore, in order to preserve the gradation of the color in the area where the saturation Vi of the pixel of the original image is larger than the color reproduction range Vp of the image output apparatus, the saturation Vi of the pixel of the original image is reproduced by the color reproduction of the image output apparatus. It was compressed within the range Vp for each lightness and each hue and converted into the saturation Vo.

Further, among color images, color images whose gradation is important like photographs, images whose saturation is important like computer graphics, and company logo marks are specified. Since there are various types in which the reproduction of the color of is important, a color space compression process suitable for each object is required. Therefore, there are cases where the CMS is provided with several types of color space compression processing units and is switched to an appropriate color space compression processing unit depending on the image to be output. For example, the saturation Vi of the pixel of each object in the output document image Vi
As described below, four types of color space compression processes of linear compression, non-linear compression, region compression, and pasting compression are selectively switched to convert to saturation Vo.

(1) Linear compression As shown in FIG. 12, this method is a method of uniformly compressing Vi into Vo with the ratio of Vp and Vm, which is converted into the following equation. Vo = Vi × (Vp / Vm) (2) Non-linear compression In this method, as the value of Vi is closer to 0, the compression rate is smaller, and as the value of Vi is closer to the value of Vm, the compression is denser, as shown in FIG. It is converted by the following method.

Vo = Vi × {1- (1-Vp / Vm) ^{Vm / Vi} } (3) Area compression As shown in FIG. 14, the value of Vi is up to a predetermined rate (α) of Vp. Holds Vi as it is, and when the value of Vi is equal to or higher than a predetermined rate (α) of Vp, it is converted by the following equation by a geometric compression method.

(When Vi ≦ α × Vp) Vo = Vi (when Vi> α × Vp) Vo = {(Vi-αVp)
× (Vp−αVp) / Vm−αVp)} + αVp (4) Pasting compression As shown in FIG. 15, this method uses V until Vi = Vp.
The value of i is maintained, and Vi exceeding it is a compression method with Vp, which is converted as in the following equation.

(When Vi ≦ Vp) Vo = Vi (when Vi> Vp) Vo = Vp Incidentally, FIGS. 12 to 15 show examples of each compression method in a hue having a certain lightness.

[0011]

[Problems to be Solved by the Invention] However, CMS
As shown in FIG. 10, since the image output device 55 such as a color printer has the final stage configuration, the color reproducibility when the output image 56 from the image output device 55 is input by the image input device 51 is as follows. Was not considered. That is, when processed by color space compression, the color reproduction range of the color display is converted into the color reproduction range of the color printer, so that the image on the output paper loses the original color reproduction range. Therefore, when the image is re-input by the scanner, the color reproduction range of the original image is not reproduced, and only the image within the color reproduction range of the printer can be obtained, so that there is a problem that the original image cannot be restored.

Further, even if an original image is to be restored by color space decompression processing (reverse processing of color space compression), different color space compression processing may be applied depending on an object or a device of a different model. There is a problem that the original image cannot be restored because it cannot be determined whether the spatial compression processing has been performed. The present invention provides a color image processing method and system that can eliminate the above-mentioned conventional defects and restore an original image from an output image to which different color space compression processing is applied.

[0013]

In order to solve this problem, a color image processing method of the present invention is a color image processing for sharing a color image between different models having different color image processing characteristics. When recording a color image, the characteristic information of the image processing including the color conversion processing within the model is output, and when reading the color image, the model of the model that recorded the color image is output. Characteristic information is input, image processing including color conversion processing is performed by referring to characteristic information of a model in which the color image is recorded and characteristic information of image processing in the own model, and a color image is reproduced. And

Here, the output of the characteristic information is recording of a color image on a recording sheet, and the input of the characteristic information is reading of a color image from the recording sheet. Further, the recording of the characteristic information includes a bar code, a two-dimensionally arranged code, a code, a magnetic code, or a mixture thereof. The recording of the characteristic information is toner, ink, thermal printing, or printing containing a mixture of these. The output of the characteristic information is information for each object of the recorded color image. The color conversion process is a color space conversion process including a color space compression process and a color space expansion process. In addition, the color space conversion processing, in the uniform perceptual color space,
The color reproduction range of the first model and the color reproduction range of the second model are used for each lightness and each hue. In the color space conversion process, the lightness and hue are kept constant, only the saturation of the smaller color reproduction range is expanded, and converted to the outermost edge of the larger color reproduction range. Further, in the color space conversion processing, only the saturation is linearly expanded, and the compression ratio corresponds to the ratio between the smaller color reproduction range and the larger color reproduction range. In the color space conversion process, only the saturation is expanded non-linearly, and the expansion rate increases as the color space distance from the center of the white point increases. Further, the color space conversion processing is performed from the center of the white point of the smaller color reproduction range (0 <α <10
Colors at a distance of α% in the range 0) are reproduced as they are, and colors at a distance greater than that linearly extend only the saturation.

Further, the color image processing system of the present invention is
In a color image processing system including at least two different models having different color image processing characteristics and performing processing by sharing a color image, image processing including color conversion processing within the own model when recording a color image Characteristic information output means for outputting characteristic information of the color image, characteristic information input means for inputting characteristic information of a model in which the color image is recorded, and characteristic information of a model in which the color image is recorded. It is characterized by comprising a color image reproducing means for reproducing a color image by performing image processing including color conversion processing with reference to the characteristic information of the image processing within the own model.

Here, the characteristic information output means records the characteristic information on the recording sheet of the color image, and the characteristic information input means reads the characteristic information from the recording sheet of the color image. Further, the recording of the characteristic information includes a bar code, a two-dimensionally arranged code, a code, a magnetic code, or a mixture thereof. Also,
The recording of the characteristic information is toner, ink, thermal printing, or printing containing a mixture thereof. Further, the characteristic information output means outputs characteristic information for each object of the recorded color image. The color conversion process is a color space conversion process including a color space compression process and a color space expansion process. In addition, the color space conversion processing is performed in the uniform perceptual color space by using the color reproduction range of the first model and the second color reproduction range.
The color reproduction range of the model is used for each lightness and each hue. In the color space conversion process, the lightness and hue are kept constant, only the saturation of the smaller color reproduction range is expanded, and converted to the outermost edge of the larger color reproduction range. Further, in the color space conversion processing, only the saturation is linearly expanded, and the compression ratio corresponds to the ratio between the smaller color reproduction range and the larger color reproduction range. In the color space conversion process, only the saturation is expanded non-linearly, and the expansion rate increases as the color space distance from the center of the white point increases. Further, the color space conversion process reproduces the color as it is from the center of the white point of the smaller color reproduction range to the color that is α% of the range of (0 <α <100), and is at a further distance. Color only linearly extends saturation.

Further, the color image processing apparatus of the present invention is a color image processing apparatus for outputting a color image created on a monitor to a printer, and when the color image is recorded on the printer, color conversion within its own model is performed. It is characterized by further comprising characteristic information output means for outputting characteristic information of image processing including processing. Here, the characteristic information output means records the characteristic information on a recording sheet of a color image by a bar code, a two-dimensionally arranged code, a code, a magnetic code, or a mixture of these. To do. Also,
The characteristic information includes the type and color reproduction range of the printer, the type and color reproduction range of the monitor, the number / position of objects in the created image, and the type of color space compression for each object performed when outputting the image.

The color image processing apparatus of the present invention is a color image processing apparatus for reproducing an original color image read from a scanner on a monitor, and is a model of a model in which the color image is recorded when the color image is read. Image information including color conversion processing is performed by referring to characteristic information input means for inputting characteristic information, characteristic information of a model in which the color image is recorded, and characteristic information of image processing in the own model, and a color image is displayed. And a color image reproducing means for reproducing. Here, the characteristic information input means reads the characteristic information from a color image recording sheet by a bar code, a two-dimensionally arranged code, a code, a magnetic code, or a mixture of these. . Further, the input characteristic information includes the type and color reproduction range of the printer, the type and color reproduction range of the monitor that created the original, the number / position of objects in the created image, and the color of each object applied when outputting the image. Includes spatial compression type. Further, the characteristic information of the own model includes a monitor type and color reproduction range, a color space compression type that can be supported by color space expansion, a scanner type and color reproduction range, and unique characteristics.

[0019]

Embodiments of the present invention will now be described in detail with reference to the accompanying drawings. <Structural Example of Color Image Processing System> FIG. 1 is a diagram showing the flow of images in the color image processing system of this embodiment. In the figure, 1 is a computer for creating an original document image, 2 is an image display device such as a color display used at the time of creation, 3 is an image output device such as a color printer for outputting an image, 4 is an image 45 and characteristic information 46. An output image including the output, 5 is an image input device such as a color scanner for inputting an image, 6 is a computer for reprocessing the input image, and 7 is an image display device such as a color display used at the time of reprocessing.

FIG. 2 is a block diagram showing a configuration example of the color image processing system of this embodiment including the configuration of each device of FIG. The computer 1 includes a CPU 10 which is the center of various processes such as calculation, a RAM unit 11 (20 is a resident portion of a processing program, 21 is a work area required for processing, 22 is a resident portion of a system program,
(These are included in the RAM 11), the ROM unit 12 (including the boot program and the ROMB10S23), and the keyboard unit (KBD) for performing the input operation of the computer 1.
13 and a pointing device (mouse) 14, a processing program including a system program 17 and an image creation processing (profile creation) program 19, an image 24 to be output as necessary, and a hard disk (HD) where the characteristic information 25 is stored. And MO and CD and FD
A file device 15 including necessary elements, and a bus 16 including a data bus, an address bus, and a control signal bus, which connect the above-described components to the CPU 10 for exchanging information.

Further, the computer 6 includes a CPU 30 which is a center of various processing such as various calculations, and a RAM section 31.
(40 is a resident portion of the processing program, 41 is a work area required for processing, 42 is a resident portion of the system program, and these are included in the RAM 31)
And ROM section 32 (boot program and ROMB10S
43, and characteristic information 44), a keyboard unit (KBD) 33 for performing an input operation of the computer 6, a pointing device (mouse) 34, a system program 37, and an image input processing (profile creation) program 39. If necessary, a file device 35 composed of necessary elements such as a hard disk (HD), MO, CD, FD for storing the input image and its characteristic information, and the CPU 30
A bus 36 composed of a data bus, an address bus, and a control signal bus, which are connected to each other so as to transfer information.

In the following description, the computer 1, the image display device 2 and the image output device 3 are also referred to as the output side, and the image input device 5, the computer 6 and the image display device 7 are also referred to as the input side. <Example of Operation of Color Image Processing System> First, the operator uses the image display device 2 on the computer 1 side to newly create a color image, and the image output device 3 outputs the created image. Here, the computer 1 uses the image display device 2
The color space compression process is performed on the computer 1 in consideration of the difference in color reproduction range between the image output device 3 and the image output device 3. As a result of the processing, the processed image and output-side profile data (characteristic information of the image display device 2 and the image output device 3) are sent to the image output device 3. At the same time that the image output device 3 outputs the image 45, as shown in FIG. 4, the output side profile data received from the computer 1 is printed as a bar code 46 on the output paper. In this way, the output image 4 in which the profile data is written is obtained.

The output image 4 thus output is input by the image input device 5 in order to be edited again by the computer 6. Here, while inputting the image, the profile data on the output side printed on the output paper is also read. The computer 6 inputs these input images and profile data.
Sent to. In the computer 6, the characteristics of the image display device 7 such as a color display used for re-editing and the profile data on the input side such as the characteristics of the image input device 5 such as a color scanner that inputs an image are held in advance, and these input data are stored. Side profile data and output side profile data are used to expand the color reproduction range from the color reproduction range of the image output device 3 used during image output to the color reproduction range of the image display device 7 used during re-editing. Then, the original color image created on the computer 1 is restored. Here, the profile data on the output side is as follows: ・ Type of printer on the output side ・ Color reproduction range of the printer on the output side ・ Type of monitor that created the original image ・ Color reproduction range of the monitor that created the original image ・ In the original image The number of objects / positions of the object-There is information such as the type of color space compression (for each object) applied at the time of output, and these are written on the output paper. on the other hand,
The profile data on the input side includes: -Type of monitor on the input side-Color reproduction range of the monitor on the input side-Type of color space compression that can be supported by color space expansion-Type of scanner on the input side-Color of scanner on the input side Reproduction range-There is information such as the gamma of the scanner on the input side and the characteristics peculiar to the scanner. It is stored in the computer 6 on the input side in advance, and color space expansion / color correction is performed.

(Creation of profile) Hereinafter, FIG. 3 and FIG.
The profile creation process will be described in detail with reference to. FIG. 3 is a flowchart showing a processing procedure for creating profile data on the output side after color image creation and color space compression processing by the computer 1 shown in FIG.

In step S11, a color image is created, and in step S12, it is selected whether or not the color space compression process is performed when the image is output by the image output device 3. If the color space compression process is not performed, the process proceeds to step S13, the color conversion process from the color signals MR, MG, MB of the image display device 2 to the color signals PR, PG, PB of the image output device 3 is performed, and the process proceeds to step S26. And proceed.

When the color space compression processing is performed in step S12, the process proceeds to step S14, and the color signals MR, MG, MB of the image display device 2 are converted into the color space compression processed color signals L ^* , a.
Perform processing to convert to ^* , b ^* . Next, in order to perform the color space compression process, the profile data of the image display device 2 is read in step S15, and the profile data of the image output device 3 is read in step S16. In step S17, the profile data read in steps 15 and S16 is recognized and analyzed.

In the next step S18, step S11
The number of objects in the color image created in step 3 is determined. If there are more than one, the process proceeds to step S19, where the number of objects (=
Substitute the number of objects into a variable k representing OBJ). If the number of objects is singular, step S2
Go to 0 and substitute "1" for k. Next, in step S21, a color space compression processing method suitable for the object is set from among a plurality of color space compression processing methods, and the processing is executed in the next step S22. In step S23, a variable k representing the number of objects is used to execute step S11.
It is determined whether or not there is an unprocessed object in the color image created in. If there still remains, the process proceeds to step S24, k is decremented by 1, and steps S21 to S24 are performed until the color space compression processing of all the objects in the color image created in step S11 is completed.
Repeat until That is, step S21, step S
The processing of 22 is performed for each object.

When the color space compression processing is performed on all the objects in the color image created in step S11, the process proceeds to step S25, and the color space compression processed color signal L is obtained.
^{From *} , a ^* , b ^* , the color signals PR, P of the image output device 3
Processing for converting into G and PB is performed. In step S26, it is determined whether or not the profile data on the output side is to be written on the output paper, and if it is to be written, the output data is output in step S27 based on the characteristics of the device on the output side and the processing from step S11 to step S25. Side profile data is created. The above is the processing flow on the output side shown in FIG.

FIG. 4 shows an example in which profile data on the output side is converted into a bar code as characteristic information and output. (Color Space Expansion Processing) Image input and processing (color space expansion processing) will be described in detail below with reference to FIGS.

FIG. 5 is a flow chart in which, after the output image 4 is input by the image input device 5, the computer 6 performs color space expansion processing from the output side profile data and the input side profile data. The output image 4 is input in step S31, and it is determined in step S32 whether profile data is recorded in the input image. If profile data is not recorded, step S3
3, the color signals SR, SG, SB of the image input device 5 are converted into the color signals mR, mG, mB of the image display device 7, and the process is completed.

If the profile data is recorded in step S32, the process proceeds to step S34, where the color signals SR, SG, SB of the image input device 5 are converted into the color space expansion processed color signals L ^* , a ^* , b ^* . Perform the conversion process. Next, in order to perform color space expansion processing, in step S35, the profile data of the output side when the output image 4 is output is read, and in the next step S36, the profile data of the input side when the output image 4 is input is obtained. Read. In step S37, the profile data read in steps S35 and S36 is recognized and analyzed.

In the next step S38, step S31
The number of objects in the color image input in is judged. If there are plural objects, the process proceeds to step S39 and the number of objects is substituted into the variable k representing the number of objects. In the case of a singular number, the process proceeds to step S40 and "1" is substituted for k. Next, in step S41, it is determined whether or not the color space compression process has been performed on the object being processed, and if the color space compression process has not been performed, the process proceeds to step S45.
If the color space compression processing has been performed, the process proceeds to step S42, the type of the color space compression processing on the output side is recognized from the profile data analyzed in step S37, and step S4
In step 3, the color space expansion process corresponding to the color space compression process is set, and in step S44, the color space expansion process is executed. In step S45, it is determined whether or not an unprocessed object remains in the color image input in step S31, using the variable k representing the number of objects. If it still remains, the process proceeds to step S46, k is subtracted by one, and step S31 is performed until the color space expansion processing of all objects in the color image input in step S31 is completed.
41 to step S46 are repeated. That is, steps S42, S43, and S44 perform processing for each object.

When the color space expansion processing has been performed on all the objects in the color image input in step S45, the process proceeds to step S47, and the color space compression processing color signal L ^* ,
From a ^* and b ^* , color signals mR, mG, and m of the image display device 7 are obtained.
A process of converting to B is performed. The above is the processing flow on the input side shown in FIG. (Setting and Execution of Color Space Expansion Processing) Next, step S43.
The color space expansion processing set in step S44 and executed in step S44 will be described in detail. For example, the saturation Vo of the pixel of the output image 4 output by the four types of color space compression processing of FIGS. 12 to 15 is changed to the saturation Vi by the computer 6 by the following four types of color space expansion processing. To be converted. These four types of color space expansion processing methods are examples of inverse conversion processing corresponding to each of the above four types of color space compression processing.

(1) Linear Expansion This method expands Vo uniformly with the ratio of Vm and Vp, as shown in FIG. Vi = Vo × (Vm / Vp) (2) Non-linear expansion As shown in FIG. 7, this method reduces expansion as the value of Vo approaches 0, and expands more densely as Vo approaches the value of Vp. Then, inverse conversion is performed as in the following equation.

Vi = Vo ÷ {1- (1-Vp / Vm) ^{Vm / Vi} } (3) Area expansion This method allows the value of Vo to reach a predetermined rate (α) of Vm as shown in FIG. Is Vo = Vi, and when the value of Vp is equal to or higher than a predetermined rate (α) of Vi, the ratio is expanded so that the inverse conversion is performed as follows.

(When Vo ≦ α × Vp) Vi = Vo (When Vo> α × Vp) Vi = {(Vo-αVp)
× (Vm−αVp) / (Vp−αVp)} + αVp (4) Sticking extension As shown in FIG. 9, this method uses V until Vp = Vi.
With o = Vi and Vp = Vi, Vp = Vm is used to perform the inverse conversion as in the following equation.

(When Vo <Vp) Vi = Vo (When Vo = Vp) Vi = Vm It is to be noted that FIGS. 6 to 9 are examples showing how each extension is performed in a hue having a certain lightness. In addition, as an output example of FIG.
Although the profile data is shown as a bar code, there is no reason to limit it to this, and the code may be a two-dimensionally arranged code, a code, or a magnetic code. The profile data may be printed by toner, ink, thermal printing, or invisible toner / ink. That is, the information may be added somewhere on the output paper by some means, and the encoding method and the recording method are not limited. Also, the location where the profile data is recorded is not limited.

Further, the output side processing is the color space compression processing and the input side processing is the color space expansion processing, but there is no reason to be limited to this and it is sufficient to match the color reproduction range between the devices at that time. The processing on the output side may be color space expansion processing, and the processing on the input side may be color space compression processing. Furthermore, color space compression processing and color space expansion processing may be mixed for each object.

The CIE1976 Lab color space was used as the color space compressed color signal / color space expanded color signal.
There is no reason to limit to the ab color space, and any color space suitable for color space compression / color space expansion may be used. Further, in the present embodiment, the processing on the output side is processed on the computer 1 and the processing on the input side is processed on the computer 6, but there is no reason to be limited to this, and if it is a high-performance peripheral device, It can be easily inferred that the output side process may be performed by the image output device 3 and the input side process may be performed by the image input device 5.

Further, the present invention may be applied to a system composed of a plurality of devices or an apparatus composed of a single device. Needless to say, the present invention can be applied to a case where the present invention is achieved by supplying a program to a system or an apparatus.

[0041]

According to the present invention, it is possible to provide a color image processing method and system capable of restoring an original image from an output image to which different color space compression processing is applied.
That is, a means for writing profile data (color reproduction range, monitor characteristics used when an original was created, printer characteristics that output an image, type of color space compression processing, position / number of objects, etc.) on output paper when the printer is out. And a means for simultaneously reading the profile data at the time of scanner input, a means for obtaining the characteristic information of the display / printer that contributed to image creation / output based on the information, and a color space compression processing method at the time of output specified for each object Means for holding the input side characteristic information such as a scanner / display on the image input side, and using the output side characteristic information and the input side characteristic information for color correction / By providing a means for performing color space expansion processing, the input side reproduces the original image created on the output side. Rukoto can.

[Brief description of drawings]

FIG. 1 is a diagram showing an image flow in a color image processing system according to an embodiment.

FIG. 2 is a block diagram showing a configuration of a color image processing system of this embodiment.

FIG. 3 is a flowchart illustrating processing on the output side.

FIG. 4 is a diagram showing an example in which profile data is written on output paper.

FIG. 5 is a flowchart illustrating processing on the input side.

FIG. 6 is a diagram illustrating an example of color space expansion processing.

FIG. 7 is a diagram illustrating an example of color space expansion processing.

FIG. 8 is a diagram illustrating an example of color space expansion processing.

FIG. 9 is a diagram illustrating an example of color space expansion processing.

FIG. 10 is a diagram showing an example of a conventional system configuration.

FIG. 11 is a diagram showing a color reproduction range.

FIG. 12 is a diagram illustrating an example of color space compression processing.

FIG. 13 is a diagram illustrating an example of color space compression processing.

FIG. 14 is a diagram illustrating an example of color space compression processing.

FIG. 15 is a diagram illustrating an example of color space compression processing.

[Explanation of symbols]

 1,6 Computer 2,7 Image display device 3 Image output device 4 Output image 5 Image input device

Claims (29)

[Claims] 1. A color image processing method of sharing a color image between different models having different color image processing characteristics, wherein the color conversion is performed within the model when recording the color image. The characteristic information of the image processing including the processing is output, and when reading the color image, the characteristic information of the model in which the color image is recorded is input, and the characteristic information of the model in which the color image is recorded and its own model are stored. A color image processing method characterized in that a color image is reproduced by performing image processing including color conversion processing with reference to the image processing characteristic information. 2. The output of the characteristic information is recording of a color image on a recording sheet, and the input of the characteristic information is reading of a color image from the recording sheet. Color image processing method. 3. The color according to claim 2, wherein the recording of the characteristic information includes a bar code, a two-dimensionally arranged code, a code, a magnetic code, or a mixture thereof. Image processing method. 4. The color image processing method according to claim 2, wherein the recording of the characteristic information is a toner, an ink, a thermal printing, or a printing including a mixture thereof. 5. The color image processing method according to claim 1, wherein the output of the characteristic information is information for each object of the recorded color image. 6. The color image processing method according to claim 1, wherein the color conversion process is a color space conversion process including a color space compression process and a color space expansion process. 7. The color space conversion process is performed for each lightness and each hue in the uniform perceptual color space using the color reproduction range of the first model and the color reproduction range of the second model. The color image processing method according to claim 6. 8. In the color space conversion process, the lightness and hue are kept constant, and only the saturation of the smaller color reproduction range is expanded,
8. The color image processing method according to claim 7, wherein the outermost edge of the larger color reproduction range is converted. 9. The color space conversion process is characterized in that only saturation is linearly expanded, and a compression ratio thereof corresponds to a ratio between a smaller color reproduction range and a larger color reproduction range. The color image processing method according to claim 7. 10. The color space conversion process nonlinearly expands only the saturation, and increases the expansion rate as the color space distance from the center of the white point increases.
The described color image processing method. 11. The color space conversion process reproduces a color as it is from a center which is a white point of a smaller color reproduction range to a color located at a% of a range of (0 <α <100), and further 8. The color image processing method according to claim 7, wherein only the saturation of the colors in the distance is linearly expanded. 12. In a color image processing system including at least two different models having different color image processing characteristics and performing processing by sharing a color image, when recording a color image, color conversion within its own model. Characteristic information output means for outputting characteristic information of image processing including processing, characteristic information input means for inputting characteristic information of a model in which the color image is recorded when reading the color image, and the color image recorded Color image processing characterized by including color image reproduction means for performing image processing including color conversion processing by referring to the characteristic information of the model and the characteristic information of the image processing within the own model, and reproducing the color image. system. 13. The characteristic information output means records the characteristic information on a color image recording sheet, and the characteristic information input means reads the characteristic information from the color image recording sheet. Color image processing system. 14. The recording of the characteristic information includes a bar code,
14. The color image processing system according to claim 13, further comprising a code arranged two-dimensionally, a code, a magnetic code, or a mixture thereof. 15. The color image processing system according to claim 13, wherein the recording of the characteristic information is toner, ink, thermal printing, or printing containing a mixture thereof. 16. The color image processing system according to claim 1, wherein the characteristic information output means outputs characteristic information for each object of the recorded color image. 17. The color image processing method according to claim 12, wherein the color conversion process is a color space conversion process including a color space compression process and a color space expansion process. 18. The color space conversion process is performed for each lightness and each hue in a uniform perceptual color space using a color reproduction range of a first model and a color reproduction range of a second model. The color image processing method according to claim 17. 19. The color space conversion processing is characterized in that the lightness and hue are constant, only the saturation of the smaller color reproduction range is expanded and converted to the outermost edge of the larger color reproduction range. The color image processing method according to claim 18. 20. The color space conversion processing is characterized in that only saturation is linearly expanded, and a compression ratio thereof corresponds to a ratio between a smaller color reproduction range and a larger color reproduction range. The color image processing method according to claim 18. 21. The color space conversion processing nonlinearly expands only the saturation, and increases the expansion rate as the color space distance from the center of the white point increases.
8. The color image processing method according to item 8. 22. The color space conversion process reproduces as it is up to a color at a distance of α% in the range of (0 <α <100) from the center of the white point of the smaller color reproduction range, and further 19. The color image processing method according to claim 18, wherein only the saturation of the colors in the distance is linearly expanded. 23. In a color image processing apparatus for outputting a color image created on a monitor to a printer, when recording a color image on the printer, characteristic information of image processing including color conversion processing within its own model is displayed. A color image processing apparatus comprising a characteristic information output unit for outputting. 24. The characteristic information output means includes a bar code, a code for arranging the characteristic information two-dimensionally on a recording sheet of a color image, a code, or a magnetic code.
24. The color image processing apparatus according to claim 23, wherein the recording is performed by using a mixture of these. 25. The characteristic information includes a printer type and color reproduction range, a monitor type and color reproduction range, the number / position of objects in a created image, and a type of color space compression for each object when outputting an image. 25. The color image processing device according to claim 23, further comprising: 26. In a color image processing apparatus for reproducing an original color image read from a scanner on a monitor, characteristic information input means for inputting characteristic information of a model in which the color image is recorded when reading the color image. And a color image reproducing means for reproducing a color image by performing image processing including color conversion processing with reference to the characteristic information of the model in which the color image is recorded and the characteristic information of the image processing in the own model. A color image processing device characterized by the above. 27. The characteristic information input means includes characteristic information on a recording sheet of a color image, a bar code, a code arranged two-dimensionally, a code, a magnetic code, or a mixture thereof. 27. The color image processing apparatus according to claim 26, which is read by 28. The input characteristic information includes the type and color reproduction range of a printer, the type and color reproduction range of a monitor that created an original, the number / position of objects in the created image, and the objects applied when the image is output. 27. Another color space compression type is included.
7. The color image processing device according to item 7. 29. The characteristic information of the own model includes a monitor type and color reproduction range, a color space compression type that can be supported by color space expansion, a scanner type and color reproduction range, and unique characteristics. The color image processing device according to claim 26.