JP2004297390A - Color reproduction adjustment in output image - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method capable of properly adjusting the image quality independently of the differences between image generating apparatuses. <P>SOLUTION: The method for outputting an image by using object image data generated by the image generating apparatus is characterized in to include the steps of (a) preparing color reproduction information at least by each type of the image generating apparatuses, the color reproduction information including (i) color calibration information utilized for color calibration of optional image data generated by using the image generating apparatus and (ii) storage color information utilized for color correction for an object of colors within a prescribed range close to particular storage color in an optional image imaged by using the image generating apparatus as the color reproduction information for the optional image data generated by the image generating apparatus, (b) generating processed image data by performing a plurality of processes including color calibration using the color calibration information and color correction using the storage color information with respect to object image data generated by the image generating apparatus, and (c) outputting an image on the basis of the processed image data. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image quality adjustment technique for adjusting the image quality of image data.
[0002]
[Prior art]
As an image output device, for example, a CRT, an LCD, a printer, a projector, a television receiver, and the like are known, and by using these devices, an image based on image data can be output. Such image data can be generated using an image generation device such as a digital still camera (DSC), a digital video camera (DVC), or a scanner. In recent years, such an image generation device has been widely spread, and it has been desired to output a higher quality image.
[0003]
The image quality of such image data can be arbitrarily adjusted, for example, by using an image retouching application on a personal computer. Generally, an image retouching application is provided with an image adjustment function for automatically adjusting the image quality of image data. By using the image adjustment function, it is possible to improve the image quality of an image output from an output device. Can be. Further, a printer driver for controlling the operation of a printer, which is one of the output devices, has a function of automatically adjusting the image quality. Image quality can be improved.
[0004]
One of the important factors that determine the image quality of these image data is color reproducibility. If the color of the image data is reproduced in a color that the user prefers, the user can recognize the image as a high-quality image. In particular, if a color in a region that is easily noticed by a person is reproduced with a preferable color, it can be recognized as a high-quality image. Examples of such an easily noticeable area include a flesh color area of a person in a person image, a blue area of the sky and a green area of a mountain in a landscape image. Called memory color). Therefore, a method of improving the image quality by adjusting a color in a predetermined color range close to the memory color in the image data so as to be close to a color (target color) that the user feels preferable (for example, is used) And Patent Document 1.).
[0005]
[Patent Document 1]
JP 2001-169135 A
[0006]
[Problems to be solved by the invention]
In the image quality adjustment function provided by the image quality adjustment application such as the image retouching application or the printer driver, the image quality adjustment is performed based on image data having general image quality characteristics. However, the color space used when the image data generating device generates the image data may differ depending on the image data generating device. For this reason, when the image data generating devices are different, even if the image data is obtained by photographing the same subject, the image quality characteristics, particularly, the color reproducibility may be different. As a result, depending on the image generating apparatus that has generated the image data, even if the image data is subjected to image quality adjustment processing based on general image data, the image data may not be adjusted to the intended color.
[0007]
The present invention has been made to solve the above-described conventional problems, and has as its object to appropriately adjust the image quality regardless of the difference between image generation apparatuses.
[0008]
[Means for Solving the Problems and Their Functions and Effects]
In order to solve at least a part of the above-described problems, an image output method according to the present invention is a method of outputting an image using target image data generated by an image generation device. As color reproduction information for the generated arbitrary image data, (i) color calibration information used for color calibration of arbitrary image data generated by using the image generation device; and (ii) the image generation Memory color information used for color correction for a predetermined range of colors close to a specific memory color in an arbitrary image captured by using the device, and memory reproduction information including at least the image generation device And (b) a plurality of processes including color calibration using the color calibration information and color correction using the storage color information for the target image data generated by the image generation device. By the execution, and a step of generating a processed image data, and a step of outputting an image based on (c) the processed image data.
[0009]
According to the image output method of the present invention, the color calibration processing and the color correction processing are executed based on the color calibration information and the stored color information, so that the image quality is appropriately adjusted regardless of the difference between the image generating apparatuses. be able to.
[0010]
In the image output method, the color calibration information faithfully reproduces the color of the original image when reproducing the original image from image data obtained by capturing an original image including a color sample using the image generation device. It is preferable that the information is used for color calibration for performing the calibration.
[0011]
By doing so, it is possible to prepare color calibration information that further improves color reproducibility.
[0012]
In each of the above image output methods, the color calibration information defines a color space conversion process for converting a color space of arbitrary image data generated by the image generation device from a first color space to a second color space. Preferably, a color space conversion profile is included, and the color calibration for the target image data is realized by performing the color space conversion process on the target image data.
[0013]
In this way, color calibration can be easily performed using the color space conversion profile.
[0014]
In each of the image output methods, the first color space is a color space used when the image generation device generates the target image data, and the second color space is a device-independent color space. Preferably, there is.
[0015]
In this way, since color calibration is performed using the device-independent color space, color reproducibility can be easily improved.
[0016]
In each of the above image output methods, the step (a) includes a step of preparing a plurality of pieces of color reproduction information corresponding to a plurality of types of the image generation device, and the step (b) includes the step of preparing the plurality of color reproductions. It is preferable that the method includes a step of selecting one piece of color reproduction information suitable for the image generation device from the information according to a model of the image generation device.
[0017]
By doing so, color reproduction information suitable for outputting an image can be appropriately selected according to the model.
[0018]
In each of the above image output methods, the step (a) includes a step of preparing a plurality of pieces of color reproduction information, and the step (b) includes: Preferably, the method includes the step of selecting one piece of color calibration information.
[0019]
By doing so, color calibration and color correction are performed using the color reproduction information according to the user's instruction, so that the image quality can be appropriately adjusted according to the user's preference.
[0020]
According to another aspect of the present invention, there is provided an image file generating method for generating an image file including target image data generated by an image generating apparatus. ) As color reproduction information for arbitrary image data generated by the image generation device, (i) color calibration information used for color calibration of arbitrary image data generated using the image generation device; (Ii) memory color information used for color correction for a color in a predetermined range close to a specific memory color in an arbitrary image captured by using the image generation device. Preparing at least for each model of the image generating apparatus; and (b) generating an image file with color reproduction information for storing the color reproduction information in association with the target image data. Equipped with a.
[0021]
According to the image file generation method of the present invention, it is possible to generate an image file with color reproduction information in which target image data and color reproduction information are associated with each other. By using such an image file with color reproduction information, even when an image is output from an output system that does not store color reproduction information suitable for outputting an image, the color reproduction information included in the image file with color reproduction information can be output. To obtain an image whose image quality is appropriately adjusted.
[0022]
In the image file generating method, when the color calibration information reproduces the original image from image data obtained by capturing an original image including a color sample using the image generating device, the color of the original image is faithfully reproduced. The information is preferably used for color calibration for reproduction.
[0023]
By doing so, it is possible to associate color calibration information that further improves color reproducibility with the target image data.
[0024]
In each of the above image file generation methods, the color calibration information defines a color space conversion process for converting a color space of arbitrary image data generated by the image generation device from a first color space to a second color space. Preferably, the color calibration for the target image data is realized by executing the color space conversion process on the target image data.
[0025]
By doing so, it is possible to generate an image file that can easily execute color calibration using the color space conversion profile.
[0026]
In each of the image file generation methods, the first color space is a color space used when the image generation device generates the target image data, and the second color space is a device-independent color space. It is preferable that
[0027]
In this way, since the color calibration is performed using the device-independent color space, it is possible to generate an image file in which color reproducibility can be easily improved.
[0028]
In each of the image file generation methods, the step (a) includes a step of preparing a plurality of the color reproduction information corresponding to a plurality of types of the image generation device, and the step (b) includes the step of: Preferably, the method includes a step of selecting one piece of color reproduction information suitable for the image generation device from the reproduction information according to a model of the image generation device.
[0029]
By doing so, color reproduction information suitable for outputting an image can be appropriately selected according to the model.
[0030]
In each of the above image file generation methods, the step (a) includes a step of preparing a plurality of the color reproduction information, and the step (b) includes the step of responding to a user's instruction from the plurality of the color reproduction information. And selecting one piece of color reproduction information.
[0031]
By doing so, it is possible to associate the user's favorite color reproduction information with the target image data.
[0032]
Note that the present invention can be realized in various forms. For example, an image output method and an image output device, an image data processing method and an image data processing device, and the functions of these methods or devices are realized. Program, a recording medium on which the computer program is recorded, a data signal including the computer program and embodied in a carrier wave, and the like.
[0033]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, embodiments of the present invention will be described in the following order based on examples.
A. Color management image output system:
B. First Embodiment of Color Management Image Output Processing:
C. First Embodiment of Image File Generation Process with Profile:
D. Second Embodiment of Image Quality Adjustment Application:
E. FIG. Modification:
[0034]
A. Color management image output system:
FIG. 1 is an explanatory diagram showing the overall configuration of a color management image output system as one embodiment of the present invention. This color management image output system includes a media profile server 110, a digital film profile server 120, an output system 200 as a client device, and a DSC (digital still camera) 600 as an image generation device connected via a network NET. And The name “digital film profile” is a name given to information (color reproduction information) defining color reproduction characteristics, as described later. This name derives from the ability to select and use a digital film profile with the desired color-forming properties, as well as select and use a film with the desired color-forming properties when generating a silver halide photograph. ing.
[0035]
The output system 200 includes a computer 300 as an image data processing device, and a printer 400 as an image output unit that outputs an image. The computer 300 and the printer 400 are connected to each other via a cable, and can transmit and receive image data such as print data. The printer 400 includes a control circuit (not shown) for controlling the operation thereof, and executes an image output process based on the received image data. As the image output unit, in addition to the printer 400, a monitor 500 such as a CRT display and an LCD display, a projector and the like can be used. Note that the computer 300 as the image data processing device and the printer 400 as the image output unit can be called “output devices” in a broad sense.
[0036]
The output system 200 can output an image based on the input image data GD1 generated by the DSC 600 as an image generation device. As the image generating apparatus, a digital video camera (DVC), a scanner, or the like can be used in addition to the DSC 600. In the example of FIG. 1, the DSC 600 is connected to the computer 300 via the cable CB, and the computer 300 can receive the input image data GD1 via the cable CB. In addition, the input image data GD1 generated by the DSC 600 is stored in a memory card (not shown), and the memory card on which the input image data GD1 is recorded is mounted on the computer 300. A reading configuration may be used. Alternatively, the DSC 600 may be connected to the network NET, and the computer 300 may receive the input image data GD1 via the network NET. Note that the image generating apparatus generally generates an image file including the input image data GD1. Therefore, when transmitting and receiving the input image data GD1, an image file including the input image data GD1 is transmitted and received.
[0037]
On the computer 300, an image quality adjustment application 320 and an image file generation application with profile 340 can operate. The image quality adjustment application 320 executes an image quality adjustment process on the input image data GD1 using the digital film profile DPF and the media profile MPF to create output image data GD2 (details will be described later). The output image data GD2 is transmitted to the printer 400, and the printer 400 outputs an image based on the output image data GD2. If the format of the output image data GD2 is not compatible with the printer 400, print data PD compatible with the printer 400 is created based on the output image data GD2, and the created print data PD is transmitted to the printer 400. . In any case, it can be said that the printer 400 outputs an image based on the output image data GD2. Such a print data creation function is generally executed by a printer driver that operates on the computer 300. When the printer driver functions as the image quality adjustment application 320, the image quality adjustment application 320 creates print data PD based on the output image data GD2.
[0038]
The image file with profile generation application 340 executes a process of creating an image file with profile including the input image data GD1 and the digital film profile DPF.
[0039]
Note that the image quality adjustment application 320 corresponds to a program for realizing a function of generating output image data for outputting an image from the image output unit. The profile-added image file generation application 340 corresponds to a program for realizing a function of creating a profile-added image file that stores input image data and digital film profiles in association with each other. These programs 320 and 340 are supplied in a form recorded on a computer-readable recording medium. Examples of such a recording medium include a flexible disk, a CD-ROM, a magneto-optical disk, an IC card, a ROM cartridge, a punched card, a printed matter on which a code such as a bar code is printed, and a computer internal storage device (such as a RAM or ROM). Various computer readable media, such as memory and external storage, can be used.
[0040]
The media profile server 110 is a server that supports creation of a media profile MPF used for image quality adjustment processing and provides a media profile MPF. The digital film profile server 120 is a server that supports creation of a digital film profile used for image quality adjustment processing and provides a digital film profile. These two servers 110, 120 may be implemented on separate computer hardware, or may be implemented on the same computer hardware. Further, the service provided by the two servers 110 and 120 may be provided by one server.
[0041]
The two servers 110 and 120 store various data and program modules in order to provide a user with a profile for image output. That is, the media profile server 110 includes a media profile storage unit 118 that stores a media profile MPF as an output device profile, a media profile creation unit 112 that creates a media profile MPF, and a test chart data storage unit 114 for creating a media profile. And The digital film profile server 120 includes a digital film profile storage unit 128 that stores a digital film profile DPF, a digital film profile creation unit 122 that creates a digital film profile DPF, and a test chart data storage unit 124 for creating a digital film profile. have. The contents of these data and modules will be described later.
[0042]
FIG. 2 is a block diagram showing a configuration of the computer 300. The computer 300 includes a transmission / reception unit 306, a digital film profile storage unit 302, and a media profile storage unit 304. Further, on the computer 300, an image quality adjustment application 320 and an image file generation application with profile 340 can operate.
[0043]
The transmission / reception unit 306 performs transmission / reception processing of data via the network NET.
[0044]
The digital film profile storage unit 302 and the media profile storage unit 304 are configured in a memory or a hard disk (not shown) of the computer 300. The digital film profile storage unit 302 stores a digital film profile DPF, and the media profile storage unit 304 stores a media profile MPF. The digital film profile DPF and the media profile MPF are used when the image quality adjustment application 320 executes the image quality adjustment processing. These profiles can be downloaded from the transmission / reception unit 126 of the digital film profile server 120 and the transmission / reception unit 116 of the media profile server 110 via the network NET, respectively (details will be described later).
[0045]
The image quality adjustment application 320 includes a front end module 336 and a back end module 338. The front end module 336 includes an input color space conversion unit 322, an image quality correction unit 326, and a first selection unit 330. The input color space conversion unit 322 performs an input color space conversion process on the input image data GD1 based on the digital film profile DPF. The image quality correction unit 326 performs a memory color adjustment process on the image data on which the input color space conversion process has been performed, based on the digital film profile DPF. The first selection unit 330 executes a process of selecting a digital film profile DPF used by the input color space conversion unit 322 and the image quality correction unit 326. The front-end module 336 that performs the processing based on the digital film profile DPF may be implemented as a plug-in module of the image quality adjustment application 320.
[0046]
The back-end module 338 includes an image processing unit 325, an output color space conversion unit 324, and a second selection unit 332. The image processing unit 325 performs image processing such as brightness adjustment processing on the image data on which the memory color adjustment processing has been performed, in accordance with a user instruction. Further, the image processing unit 325 can also convert the color space expressing the image data as needed. The output color space conversion unit 324 performs an output color space conversion process on the image data processed by the image processing unit 325 based on the media profile MPF. The second selection unit 332 performs a process of selecting a media profile MPF used by the output color space conversion unit 324. In the following description, it is assumed that there is no user's instruction and the processing by the image processing unit 325 is omitted. When a configuration in which the printer driver functions as the image quality adjustment application 320 is used, the image processing unit 325 is generally omitted.
[0047]
The output image data GD2 based on the input image data GD1 is generated by the above-described three processes (input color space conversion process, output color space conversion process, and memory color adjustment process). The details of the image quality adjustment processing (input color space conversion processing, output color space conversion processing, memory color adjustment processing) and selection processing will be described later. Note that the memory color adjustment processing may be executed before the processing of outputting an image from the image output unit. For example, it may be performed on the input image data GD1 before the input color space conversion processing, or may be performed on the image data after the output color space conversion processing.
[0048]
The image file generation application with profile 340 includes an image file generation unit 342 and a selection unit 344. The image file generation unit 342 executes a process of generating an image file with a profile including the input image data GD1 and the digital film profile DPF stored in the digital film profile storage unit 302. The selection unit 344 executes a process of selecting a digital film profile DPF used for the image file generation process. Details of these processes will be described later.
[0049]
The functions of the image quality adjustment application 320 and the image file generation application with profile 340 are realized by the computer 300 executing a computer program stored in a memory or a hard disk (not shown) of the computer 300.
[0050]
B. First Embodiment of Color Management Image Output Processing:
FIG. 3 is a flowchart showing a color management image output process using the digital film profile DPF and the media profile MPF. In step S100, a preparation process for the media profile MPF is performed. The media profile MPF includes information on a color space that matches the color reproduction range of the printer 400. In this embodiment, it is assumed that an RGB color space (referred to as “wRGB color space”) wider than the monitor sRGB color space is used as the color space. In the following description, this color space is referred to as “color space wRGB suitable for a printer”. The printer 400 executes an image output process in accordance with the output image data GD2 expressed in the color space wRGB suitable for the printer, or the print data PD generated based on the output image data GD2. That is, it can be said that the printer 400 can output an image based on the output image data GD2 expressed in the color space wRGB suitable for the printer. The media profile MPF includes information on the relationship between the color space wRGB suitable for the printer and the colors of the output image, and is used by the printer 400 to perform faithful color reproduction. Such a media profile MPF is prepared in accordance with output conditions such as the type of printing medium and ink used for image output, and stored in the media profile storage unit 304 of the computer 300 (FIG. 2). When the media profile MPF corresponding to the output condition for outputting the image is not stored, the media profile MPF can be downloaded from the media profile server 110 to the computer 300 via the network NET. If the media profile server 110 does not store a media profile MPF corresponding to the printer 400, the media profile server 110 can create a new one using the media profile server 110. Details of these processes will be described later.
[0051]
In the next step S110, a preparation process of the digital film profile DPF is executed. The digital film profile DPF includes information on a color space (for example, an sRGB color space or another specific RGB color space) used when the image generation device such as the DSC 600 generates the input image data GD1. In the following description, this color space is referred to as “DSC color space iRGB”. The input image data GD1 is expressed in the DSC color space iRGB. Some image generating apparatuses compress the generated image data. When handling such compressed image data, the input image data GD1 expressed in the DSC color space iRGB can be obtained by expanding the compressed image data and performing color space conversion. Further, the digital film profile DPF includes a memory color parameter for adjusting a color in a predetermined color range close to a preset memory color in the image data so as to approach a preset target color. Such a digital film profile DPF is prepared according to the type of the image generating apparatus, and is stored in the digital film profile storage unit 302 of the computer 300 (FIG. 2). When the digital film profile DPF corresponding to the image generating device is not stored, the digital film profile DPF can be downloaded from the digital film profile server 120 to the computer 300 via the network NET. When the digital film profile server 120 does not store the digital film profile DPF corresponding to the image generating apparatus, the digital film profile server 120 can newly create the digital film profile using the digital film profile server 120. Details of these processes will be described later.
[0052]
In the next step S120, an image output process is executed. In step S120, the image quality adjustment application 320 (FIG. 2) executes an image quality adjustment process using the digital film profile DPF and the media profile MPF, and generates output image data. Next, the printer 400 outputs an image based on the output image data. Details of these processes will be described later.
[0053]
B1. Media profile preparation processing:
FIG. 4 is a flowchart showing the media profile preparation process (S100 in FIG. 3). This flowchart shows a series of processes from creation of the media profile MPF for the printer 400 to storage in the media profile storage unit 304 (FIG. 2). 4 shows processing executed by the output system 200, and the right side shows processing executed by the media profile server 110.
[0054]
In the present embodiment, the user can give an instruction for the series of processes in FIG. 4 through the setting screen of the image quality adjustment application 320. FIG. 5 shows an example of a setting screen of the image quality adjustment application 320. As shown, the screen includes a test chart setting unit TCSA and a media profile download setting unit MPFSA. Such a setting screen is displayed on the monitor 500.
[0055]
By operating the test chart setting unit TCSA, the user can select test chart data to be used for outputting the test chart. The test chart is an image composed of a plurality of color patches corresponding to a plurality of colors. The test chart includes a plurality of color patches having at least some of the hue, saturation, and brightness different from each other so that the colors of the color batch are widely distributed within the color reproduction range of the printer 400. The test chart data is image data for causing the printer 400 to output the test chart, and is preferably image data expressed in a color space wRGB suitable for the printer.
[0056]
The test chart data is stored in the media profile server 110. When the user operates the download start button TCDA (S202: Y), the test chart data is transmitted from the media profile server 110 to the output system 200 (S204). Subsequently, when the user operates the test chart output start button TCOA, a test chart based on the received test chart data is output from the printer 400 (S206).
[0057]
Instead of downloading the test chart data, it is also possible to use the test chart data already stored. As such test chart data, for example, data downloaded in the past, standard test chart data provided with the image quality adjustment application 320, or the like can be used. The user can set the stored test chart data by operating the test chart data file setting section TCFA on the setting screen of FIG. 5 (FIG. 4: S200).
[0058]
Next, in step S208, the color measurement processing of each color patch of the test chart output in step S206 is performed. The colorimetric processing is performed using a colorimeter. The data obtained as a result of the color measurement is data expressed in a color space independent of devices such as a printer and a monitor, for example, an L * a * b * color space or an XYZ color space. As described above, in step S208, by performing color measurement of each color patch, it is possible to determine the correspondence between the wRGB color space suitable for the printer and the device-independent color space. The test chart output in step S206 is sent to an operator who performs colorimetry using a method such as mailing or bringing in the test chart. This operator also manages the media profile server 110 (FIG. 1).
[0059]
Next, in step S210, the process of calculating parameter values representing the correspondence between the wRGB color space suitable for the printer and the device-independent color space (for example, the L * a * b * color space) is performed by the media profile creation unit 112 ( 1). In general, various methods can be used to represent the correspondence between two color spaces. For example, a method using a matrix, a method using a predetermined function such as γ correction, A method using a look-up table can be used. In this embodiment, the correspondence between the wRGB color space and the L * a * b * color space is represented using the look-up table N.
[0060]
As described above, in the present embodiment, the look-up table N relates the wRGB color space and the L * a * b * color space suitable for the printer. In step S210, the look-up table N is set based on the result of the color measurement process in step S208. The lookup table N obtained in this way is used as a media profile MPF. That is, the media profile MPF is information on the correspondence between the color space wRGB suitable for the printer and the device-independent color space (L * a * b * color space in this example). The media profile MPF is, for example, an ICC profile, and is used when performing conversion from a device-independent color space to a color space (wRGB) suitable for the printer 400 (FIG. 2). By this color conversion, the color represented in the device-independent color space is faithfully reproduced by the printer 400. Therefore, the media profile MPF can be considered as information for realizing the color calibration of the printer 400.
[0061]
After the lookup table N of the media profile MPF is calculated, when the user accesses the media profile server 110 again and operates the download start button MPFDLA on the setting screen (FIG. 5), the transmission / reception unit 116 of the media profile server 110 (FIG. From 2), the media profile MPF is transmitted to the output system 200 (S212). The output system 200 stores the received media profile MPF in the media profile storage unit 304 (S214).
[0062]
An ordinary printer is assumed to use one print medium selected by a user from a plurality of types of print media (plain paper, glossy paper, matte paper, film, and the like). Some printers can change the type of ink used. Color reproducibility depends on the type of printing medium and ink. Normally, a color conversion look-up table used when converting the output image data GD2 from the wRGB color space to a color space represented by ink colors available in the printer, for example, a CMYK color space, is stored in a print medium or the like. Since each media type is prepared according to the type of ink, faithful color reproduction can be realized by preparing one media profile MPF. Instead, a standard table that does not depend on the type of printing medium or ink is used as a color conversion lookup table that converts the wRGB color space into the CMYK color space, and the media profile MPF is set according to the type of printing medium or ink. A prepared configuration may be used. In the present embodiment, it is assumed that the media profile MPF is prepared according to the type of the print medium or the ink. Therefore, the media profile storage unit 304 of the present embodiment can store a plurality of types of media profiles MPF. In addition, in order to easily identify the plurality of media profiles MPF, the media profile storage unit 304 is configured to be able to store the media profile MPF and output conditions associated with the media profile MPF. I have. This output condition can be used as information for identifying a media profile MPF to be used when outputting an image (details will be described later).
[0063]
By operating the output condition setting unit OCA on the setting screen shown in FIG. 5, the user can set output conditions (print medium and ink type, etc.) to be associated with the media profile MPF. When the download start button MPFDLA is operated after setting the type of paper and ink used for outputting the test chart (S206) in the output condition setting unit OCA, the media profile MPF is stored in association with the set output condition. You. As the output condition, an arbitrary name that is easy for the user to understand can be set.
[0064]
In this embodiment, one media profile MPF is stored as one file. The user can set the file name for the media profile MPF by operating the file name setting section MPFA on the screen in FIG. Therefore, the output condition and the media profile MPF can be associated with each other by storing and storing the output condition and the media profile MPF in the same file. Instead, it is also possible to generate association data that associates the output condition with the media profile MPF, and store the media profile MPF and the association data in independent files. In any case, when selecting a media profile to be used for outputting an image, it is preferable that the configuration is such that the profile can be easily selected using output conditions. When the media profile is downloaded, it is preferable that the authentication is performed so as to be distinguished from other users, so that only the appropriate user can download the appropriate media profile MPF. As such an authentication method, for example, authentication using a password can be used.
[0065]
When preparing a plurality of media profiles MPF to correspond to a plurality of types of output conditions, a series of processes in FIG. 4 are repeatedly executed as necessary. In this case, the test chart output processing in step S206 is executed using the print medium and the ink according to the desired output conditions.
[0066]
FIG. 6 is an explanatory diagram for explaining the preparation process of the media profile MPF shown in FIG. In this embodiment, the test chart data is expressed in a color space wRGB suitable for a printer. In step S206, a test chart based on the test chart data is output from printer 400. In the output process (step S206) in this embodiment, a standard conversion process from the wRGB color space to the CMYK color space and a halftone process based on image data represented in the CMYK color space are performed. In the conversion process from the wRGB color space to the CMYK color space, a conversion process using a lookup table (LUT) without color correction is performed. Here, “no color correction” means that intentional color correction is not performed. Therefore, the “lookup table without color correction” determines the input / output correspondence more faithfully than other lookup tables available in this application. In this embodiment, the lookup table without color correction uses the lookup table without color correction to cover the entire range of gradation values when the color reproduction range that can be reproduced by the printer is expressed in the CMYK color space and the color reproduction range that can be expressed in the wRGB color space. The entire range of the tonal value is associated. Therefore, it is possible to perform color space conversion processing that effectively utilizes the color reproduction range reproducible by the printer. In this embodiment, the process of step S206 is executed by a printer driver (not shown).
[0067]
Next, in step S208, a colorimetric process of each color patch of the output test chart is performed. As a result of this processing, a gradation value in the L * a * b * color space corresponding to the color of each color patch can be obtained.
[0068]
Next, in step S210, a comparison process is performed between a tone value represented in the L * a * b * color space corresponding to the color of each color patch and a tone value represented in the wRGB color space. . Further, a lookup table N is created based on the comparison result.
[0069]
As described above, the media profile MPF prepared in the present embodiment is set so as to measure the color of a color batch and reflect the result of the color measurement. Therefore, it is possible to prepare a media profile MPF that more accurately reflects the color space characteristics of the printer 400. Further, in this embodiment, the media profile MPF is set using the printer 400 actually used by the user. Therefore, even when the color space suitable for the printer 400 differs depending on the model of the printer 400, or when there is an individual difference in the color space suitable for the printer even with the same model, the characteristics of the color space suitable for the printer 400 can be improved. A media profile MPF accurately reflected can be prepared. Furthermore, as in the present embodiment, by preparing a plurality of media profiles MPF according to image output conditions such as the type of printing medium and ink, even if the color-forming characteristics differ depending on the type of printing medium and ink, etc. , A media profile MPF corresponding to the output condition can be used. If the media profile MPF corresponding to the output condition is used, the color calibration of the printer is performed according to the output condition.
[0070]
The media profile server 110 stores the prepared media profile MPF in the media profile storage unit 118 (FIG. 1). By the way, if the printer model is the same, the color space wRGB suitable for the printer is almost the same. Therefore, another user who uses the same type of printer under the same output condition may be allowed to download and use the stored media profile MPF. By doing so, the user can improve the color reproducibility of the output image using the prepared media profile MPF without creating a media profile MPF unique to his / her printer. However, if the media profile MPF is created using the printer 400 actually used according to the flowchart of FIG. 4, even if there is an individual difference in the color space suitable for the printer 400, the color of the image output from the printer 400 Reproducibility can be made more accurate.
[0071]
B2. Digital film profile preparation process:
FIG. 7 is a flowchart showing the digital film profile preparation processing (S110 in FIG. 3). This flowchart shows a series of processes from creation of the digital film profile DPF for the DSC 600 to storage in the digital film profile storage unit 302 (FIG. 2). The left side of FIG. 7 illustrates processing executed by the output system 200, and the right side illustrates processing executed by the digital film profile server 120.
[0072]
In the present embodiment, the user can give an instruction for the series of processes in FIG. 7 through the setting screen of the image quality adjustment application 320. FIG. 8 shows an example of the setting screen. As shown, the screen includes a test chart setting unit TCSB, a test chart image transmission setting unit IMB, and a digital film profile download menu button DFB.
[0073]
The user can select test chart data to be used for test chart output by operating the test chart setting unit TCSB. In the present embodiment, image data expressed in the L * a * b * color space is used as test chart data. The test chart includes, for example, a plurality of color patches (color samples).
[0074]
When the test chart data downloaded from the digital film profile server 120 is used (S300), when the user operates the download start button TCDB on the setting screen in FIG. 8 (S302: Y), the output system from the digital film profile server 120 is output. The test chart data is transmitted to 200 (S304). Subsequently, when the user operates the test chart output start button TCOB, color space conversion processing S308 is performed on the received test chart data, and the test chart is output from the printer 400 (S310).
[0075]
Instead of downloading the test chart data, it is also possible to use the test chart data already stored. As such test chart data, for example, data downloaded in the past, standard test chart data provided with the image quality adjustment application 320, or the like can be used. The user can set the saved test chart data by operating the test chart data file setting unit TCFB on the setting screen in FIG. 8 (FIG. 7: S300). )
[0076]
Step S308 is an output color space conversion process for converting a color space defining test chart data into a color space wRGB suitable for a printer, and is executed by the output color space conversion unit 324 (FIG. 2). This output color space conversion processing is executed using the media profile MPF. Since the media profile MPF is prepared according to the type of the printing medium and the ink, it is preferable to select the media profile MPF according to the printing medium and the ink to be used. The user can specify the media profile MPF to be used for the processing in step S308 by selecting a desired condition from the output condition list OCB on the setting screen in FIG. The output condition list OCB displays a list of output conditions (print media and ink types) associated with the media profile MPF, and the selected output conditions are surrounded by double lines. The file name of the media profile MPF associated with the output condition selected in the output condition list OCB is automatically set in the media profile name setting section MPFB. In step 308, the file (media profile MPF) set in the media profile name setting unit MPFB is used.
[0077]
As described later, the output test chart is used to generate image data using an image generation device such as the DSC 600. Here, when a test chart is output using a print medium having a high gloss, there is a possibility that image data in which a part of an image area is brightened by gloss is generated. If a digital film profile DPF is prepared based on such image data, there is a possibility that color reproducibility cannot be sufficiently improved. Therefore, it is preferable that the print medium used for outputting the test chart has low gloss. For example, it is preferable to use matte paper. In addition, if the configuration is such that the test chart is output using the print medium specified in advance, the user can output a preferable test chart without selecting the print medium by himself.
[0078]
If the media profile preparation process (S100 in FIG. 3) has not been performed on the desired print medium or ink, a standard media profile MPF corresponding to the print medium and ink may be used. preferable. Such a standard media profile MPF can be provided in advance together with the image quality adjustment application 320. By doing so, even when using a print medium or ink on which the media profile preparation process has not been performed, the digital film profile can be prepared using the standard media profile MPF. Also in this case, if the output conditions associated with the standard media profile MPF are set in advance, the user can easily select the media profile MPF by looking at the output condition list OCB.
[0079]
In step S310, the printer 400 outputs a test chart based on the test chart data expressed in the wRGB color space suitable for the printer. Since the output of the test chart is performed using the media profile MPF, the printer 400 functions as a color-calibrated printer. Therefore, each color is faithfully reproduced on the test chart.
[0080]
Next, in step S312, image data is generated based on the test chart output in step S310 using the image generation device. In this embodiment, since the DSC 600 is used as the image generating device, the DSC 600 captures a test chart. The image data obtained in this way is expressed in the DSC color space iRGB. This iRGB color space is a color space that reflects the characteristics of the image generation device. Here, the gradation value of each of the RGB color components of the generated image data may change under the influence of the type of the light source used at the time of generating the image data. Therefore, step S312 is preferably executed using a light source designated in advance, for example, a D65 standard light source, or a light source frequently used when generating image data, for example, sunlight. In addition, some image generation apparatuses can execute a function of adjusting a color in a plurality of operation modes. In this case, it is preferable to use an operation mode that is frequently used when generating image data. For example, depending on the image generation device, an auto white balance adjustment mode and a manual white balance adjustment mode may be available. Here, when the auto white balance adjustment mode is frequently used during normal shooting, it is preferable to use the auto white balance adjustment mode also when performing the processing in step S312.
[0081]
Next, in step S314, the generated image data is transmitted from the output system 200 to the digital film profile server 120. In the present embodiment, the DSC 600 generates an image file including image data. The generated image file is transmitted once to the computer 300 and transmitted from the computer 300 to the digital film profile server 120 via the network NET. The user can set the file name of the image data to be transmitted in the image data file name setting section IMFB on the setting screen in FIG. After setting the file name, the image data transmission start button IMUB is operated to start transmission.
[0082]
Next, in the digital film profile server 120, based on the image data received by the transmission / reception unit 126 (FIG. 2), processing for setting information on the correspondence between the DSC color space iRGB and the device-independent color space is performed by the digital film profile server. This is executed by the profile creation unit 122 (FIG. 1) (S316). In this embodiment, an L * a * b * color space is used as a device-independent color space, and the DSC color space iRGB and the L * a * b * color space are associated with each other by a matrix. In step S316, a matrix M that determines such a correspondence is a gradation value of each component in the iRGB color space and a gradation value of each component in the L * a * b * color space of each patch of the test chart. Is set so as to reflect the corresponding relationship with.
[0083]
The matrix M calculated in this manner is information on the correspondence between the DSC color space iRGB and the device-independent color space, and as described later, the color from the DSC color space iRGB to the device-independent color space. It is used when performing spatial transformation (FIG. 2). By this color conversion, the color of the input image data GD1 generated by the DSC 600 is faithfully reflected on the color in the device-independent color space. Therefore, the matrix M can be considered as color calibration information for realizing color calibration of image data generated using the image generation device (the DSC 600 in this example). In this embodiment, the input color space conversion unit 322 corresponds to a color calibration unit according to the present invention.
[0084]
FIG. 9 is an explanatory diagram for explaining the preparation process of the digital film profile DPF shown in FIG. 7, focusing on the color space. In this embodiment, the test chart data is expressed in the L * a * b * color space. In step S308, a color space conversion process using the media profile MPF is performed. By this processing, the color space representing the test chart data is converted from the L * a * b * color space to a color space wRGB suitable for a printer.
[0085]
Next, in step S310, the printer 400 outputs a test chart based on the test chart data whose color space has been converted. This processing is the same processing as S206 in FIG.
[0086]
Next, in step 312, the test chart is photographed by the DSC 600. As a result of the photographing, image data expressed in the DSC color space iRGB is generated.
[0087]
Next, in step S316, a comparison process is performed between the tone value represented in the L * a * b * color space corresponding to the color of each color patch and the tone value represented in the DSC color space iRGB. Is done. Further, a matrix M is set so as to reflect the comparison result.
[0088]
As described above, the color of the input image data GD1 generated by the DSC 600 is faithfully reflected on the color in the device-independent color space by the color calibration information (the matrix M in the present embodiment).
[0089]
Next, the memory color parameter MCP is set by a series of processes S318 and S320 in FIG. The memory color parameter MCP is a parameter value for a memory color adjustment process. The memory color adjustment process is a process of selecting a color in a predetermined color range (hereinafter, referred to as a memory color range) close to a memory color in image data as a processing target and adjusting the color so as to approach a target color. The memory color range includes a range close to skin color, a blue range, a green range, and the like. The color adjustment process is performed by modifying the image data.
[0090]
FIG. 10 is an explanatory diagram illustrating the memory color adjustment processing. FIG. 10A is an explanatory diagram illustrating an example of a condition for selecting a target pixel of the memory color adjustment processing. FIG. 10A shows the relationship between the value of the hue H and the color. In this embodiment, the possible range of the hue H is 0 ° to 360 °, where 0 ° indicates red, 120 ° indicates green, and 240 ° indicates blue. Here, if a pixel whose hue H is in a range close to red, for example, a pixel whose hue H is in a flesh color range SR of 0 to 40 degrees, is selected, only a color close to flesh color can be selected. In addition, if a green range GR having a hue H of 100 to 130 degrees is used, only a color close to green of a mountain can be selected. Similarly, if a range close to blue, for example, a blue range BR having a hue H of 200 to 260 degrees is used, only colors close to blue in the sky can be selected. In this embodiment, the storage color range is set by imposing a condition on hue, but a condition may be imposed on saturation or lightness. By doing so, the memory color range can be set more appropriately.
[0091]
When the image data to be subjected to the memory color adjustment processing is expressed in a color space that does not include hue, saturation, and lightness as parameters, for example, when the image data is expressed using an RGB color space, By converting into a color space including hue, saturation, and lightness as parameters, for example, an HLS color space or a HIS color space, the hue, saturation, and lightness at each pixel position can be obtained.
[0092]
FIG. 10B is an explanatory diagram illustrating a relationship between the input level Gin and the output level Gout of the green G tone value. In the present embodiment, the image data to be processed is represented by three gradation values of RGB, and FIG. 10B shows a tone curve used when adjusting the intensity of green G therein. ing. The graph GA is configured such that the output level Gout is smaller than the input level Gin. If the gradation value of green G is adjusted using this graph GA, the gradation value of green G is reduced in an image in which the gradation value of green G of the color satisfying the condition of the memory color range is larger than the target color. Then, the color can be made closer to the target color. The graph GB is configured so that the output level Gout is higher than the input level Gin. If the gradation value of green G is adjusted using this graph GB, the gradation value of green G is increased in an image in which the gradation value of green G of the color satisfying the condition of the memory color range is smaller than the target color. Then, the color can be made closer to the target color.
[0093]
Such a graph GA can be configured, for example, by adjusting the output level Gout at the adjustment input level Gref so as to be smaller than the original value by the adjustment amount GM. An output level Gout corresponding to another input level Gin is interpolated by a spline function. Similarly, the graph GB can be configured by adjusting the output level Gout at the adjustment input level Gref so as to be larger than the original value by the adjustment amount GM. A predetermined value can be used as the adjustment input level Gref. For example, when the range that green G can take is 0 to 255, an intermediate value of 128 may be used. The adjustment amount GM can be set based on a sensitivity evaluation that compares a plurality of output images obtained using a plurality of adjustment amounts GM having different values. By selecting an image in which a color close to the memory color is reproduced as a color close to the target color from a plurality of output images and using the adjustment amount GM corresponding to the selected output image, a predetermined color close to the memory color is obtained. The color of the range can be appropriately brought close to the target color.
[0094]
In the memory color parameter MCP, such a parameter value for setting a memory color range (a hue range in the example of FIG. 10) and a parameter value for setting a degree of color adjustment (in the example of FIG. 10). Adjustment amount GM).
[0095]
In this embodiment, the digital film profile server 120 can display a setting screen that allows the user to set the memory color parameter MCP. The user can display such a setting screen by operating the download menu button DFB on the setting screen in FIG. When the download menu button DFB is operated, the setting screen data is transmitted from the digital film profile server 120 to the output system 200, and the setting screen is displayed on the monitor 500.
[0096]
FIG. 11 is an explanatory diagram showing an example of such a setting screen. The user can set the memory color parameter MCP by operating the memory color setting unit MCSC on the screen in FIG. 11 (S320).
[0097]
The memory color setting unit MCSC of the setting screen shown in FIG. 11 has a standard setting unit STDC, a simple setting unit SPLC, and a detailed setting unit PRCC. The user can set the memory color parameter MCP by operating any one of these three setting units.
[0098]
The standard setting unit STDC is an operation unit for setting the memory color parameter MCP to a standard value. The user can set the memory color parameter MCP to a standard value by operating the standard setting unit STDC. The standard value is a value set in advance, and can be set based on, for example, the sensitivity evaluation of an image output after performing the memory color adjustment processing. As described above, the user can easily set the memory color parameter MCP by operating the standard setting unit STDC.
[0099]
The simple setting unit SPLC is a setting unit for selecting one from a plurality of memory color parameters MCP prepared in advance. By operating the simple setting unit SPLC, the user can select a desired one from the plurality of memory color parameters MCP. The simple setting unit SPLC displays a plurality of image samples having different colors in the memory color region. For example, the skin color column displays strong, medium, and weak reddish colors in the skin color area. In the sky blue column, those having a strong greenish appearance, medium, and weak in the color appearance of the sky blue region are displayed. The user can easily select the memory color parameter MCP for which the setting of the memory color adjustment is preferable by selecting a favorite image from these sample images. In the simple setting unit SPLC in FIG. 11, the selected sample image is displayed surrounded by a frame F. The setting of the memory color adjustment can be performed independently for a plurality of memory colors. In the example of FIG. 11, “medium red” is selected for the skin color, and “strong green” is selected for the sky color. When a plurality of memory color adjustment settings are thus selected, one memory color parameter MCP includes a plurality of memory color adjustment settings.
[0100]
The detailed setting unit PRCC is a setting unit for setting an arbitrary memory color parameter MCP. The user can set the memory color parameter MCP to an arbitrary value by operating the detailed setting unit PRCC. In the example of FIG. 11, a hue range adjustment bar for determining the memory color range and an adjustment bar for adjusting the degree of color adjustment (adjustment amount) are displayed. The user can adjust the memory color parameter MCP by adjusting these adjustment bars. In the detail setting section PRCC, a sample image IMBF before adjustment and a sample image IMAF after adjustment are displayed. The user can easily adjust the parameter values while comparing these images.
[0101]
When the download start button DPFDLC on the setting screen shown in FIG. 11 is operated after the setting of the memory color parameter MCP (S320) is completed by the above operation, the setting information is transmitted to the digital film profile server 120. In the digital film profile server 120, the memory color parameter MCP according to the received setting information is prepared by the digital film profile creation unit 122 (FIG. 1) (S318). The memory color parameter MCP is used when performing a memory color adjustment process for colors satisfying the condition of the memory color range. Therefore, in the present embodiment, the memory color adjustment processing corresponds to the color correction in the present invention, and the memory color parameter MCP corresponds to the memory color information in the present invention. This memory color adjustment processing is executed by the image quality correction unit 326 (FIG. 2). Therefore, in the present embodiment, the image quality correction unit 326 corresponds to the color correction unit in the present invention. At this time, it can be considered that the digital film profile creation unit 122 creates the storage color information according to the setting of the storage color information received from the client device (the output system 200 in this embodiment).
[0102]
Even if the preference of the memory color is the same, if the type of the color space representing the image data to be subjected to the memory color adjustment processing is different, the value of the memory color parameter MCP may be different. Therefore, in the present embodiment, a color space for executing the memory color adjustment processing is set in advance (hereinafter, referred to as a color space eRGB for image quality correction processing), and a memory color parameter is set based on the color space eRGB. Set the MCP. As will be described later, the memory color adjustment process is executed using image data expressed in the eRGB color space. By doing so, it is possible to improve the color reproducibility by the memory color adjustment processing.
[0103]
Next, the prepared storage color parameter MCP is output as the digital film profile DPF from the transmitting / receiving unit 126 (FIG. 2) of the digital film profile server 120 via the network NET, together with the matrix M calculated in step S316. (S322). That is, in the present embodiment, the digital film profile DPF corresponds to the color reproduction information in the present invention.
[0104]
In the output system 200, the received digital film profile DPF is stored in the digital film profile storage unit 302 (S324). In this embodiment, one digital film profile DPF is stored as one file. The user can set the file name for the digital film profile DPF by operating the file name setting unit DPFC on the screen in FIG. Therefore, the color calibration information (the matrix M in this example) and the storage color parameter MCP are associated by being stored in a common file. Instead, the configuration may be such that association data for associating the color calibration information with the storage color parameter MCP is generated and stored. In this case, as a method of storing the color calibration information and the storage color parameter MCP, for example, a plurality of color calibration information and a plurality of storage color parameters MCP may be stored and stored in one file. , The color calibration information and the storage color parameter MCP may be stored and stored in independent files. In any case, it is preferable that the color calibration information and the storage color parameter MCP are stored in association with each other. In this way, by selecting the digital film profile DPF, it is possible to easily select an appropriate combination of the memory color parameter MCP and the color calibration information.
[0105]
By the way, the color space iRGB of the DSC of the input image data GD1 generated by the image generation device generally differs depending on the image generation device. Therefore, it is preferable to use the digital film profile DPF properly according to the type of the image generating apparatus. Therefore, the digital film profile storage unit 302 of the present embodiment can store a plurality of types of digital film profiles DPF. Further, in order to easily identify the plurality of digital film profiles DPF, the digital film profile storage unit 302 of the present embodiment stores the digital film profile DPF and the identification name associated with the digital film profile DPF. It is configured to be able to. This identification name can be used as information for identifying a digital film profile DPF to be used when outputting an image (details will be described later).
[0106]
The user can set an identification name to be associated with the digital film profile DPF by operating the identification name setting unit IDC on the setting screen shown in FIG. As the identification name, for example, a model name of the image generation device can be set. After the model name of the image generating apparatus used for generating the image data of the test chart (S312, FIG. 7) is set in the ID setting section IDC and the download start button DPFDLC is operated, the digital film profile DPF is set to the set ID. It is stored in association with the name. An arbitrary name that is easy for the user to understand can be set as the identification name. Further, a model name included in the image file may be set. Some image generating apparatuses generate an image file including the input image data GD1 and the model name of the image generating apparatus. As described above, when the image generating apparatus generates an image file including the image data and the model name, the model name included in the image file received in step S316 (FIG. 7) is displayed on the setting screen of FIG. It is automatically set in the ID setting section IDC. An example of such a file format is the Exif file format. In the Exif file format, a tag is used to specify an area for storing information such as image data and a model name. The specification of the Exif file format is defined by the Japan Electronics and Information Technology Industries Association (JEITA).
[0107]
In this embodiment, one digital film profile DPF is stored as one file. Therefore, by storing and storing the identification name and the digital film profile DPF in the same file, the identification name and the digital film profile DPF can be associated with each other. Instead, the configuration may be such that association data for associating the digital film profile DPF with the identification name is generated and stored. In any case, it is preferable that the digital film profile DPF used for image output be selected so that the profile can be easily selected using the identification name. When the identification name and the digital film profile DPF are stored in the same file, the digital film profile server 120 creates a file including the digital film profile DPF and the identification name in step S322 in FIG. It can be configured to transmit.
[0108]
Further, a preferable color (target color) corresponding to the memory color range may change according to environmental conditions such as a light source and a subject used when generating image data. Therefore, even when using the same image generating apparatus, it is preferable to use the digital film profile DPF properly according to such environmental conditions. As described above, when storing a plurality of types of digital film profiles DPF corresponding to the same image generating apparatus, if a name combining a model name and an environmental condition is set as an identification name, the identification of the digital film profile DPF can be performed. Can be easily performed. As such an identification name, for example, the model name is “NiceDSC”, and a name “NiceDSC (daylight person)” is set for a digital film profile DPF suitable for a person image using daylight as a light source. be able to.
[0109]
In this case, the digital film profile storage unit 302 (FIG. 2) stores a plurality of digital film profiles DPF having the same color calibration information but different storage color parameters MCP. Here, only one color calibration information may be stored as information common to each digital film profile DPF. At this time, association data for associating a plurality of storage color parameters MCP for a plurality of digital film profiles DPF with one piece of color calibration information is created. By using such association data, one can be appropriately selected from a plurality of digital film profiles DPF and used. By doing so, the capacity required for the digital film profile storage unit 302 to store the digital film profile DPF can be saved.
[0110]
As described above, in the present embodiment, the digital film profile server 120 can prepare the digital film profile DPF based on the image data generated using the DSC 600 as the image generating device and transmit the digital film profile DPF to the output system 200. It is. Therefore, the user can easily prepare color calibration information that more appropriately reflects the characteristics of the color space of the image generating apparatus. In addition, by performing image quality adjustment processing in consideration of the digital film profile DPF prepared in this manner, a color satisfying the condition of the storage color range can be appropriately determined regardless of the color space of the image data (image generation device). Can be adjusted. Further, if the digital film profile DPF is set based on the test chart output from the printer 400 as the image output unit, a media profile MPF prepared in advance without using the printer 400, for example, a standard media profile Even when the MPF is used, the color reproducibility of the image output from the printer 400 can be improved.
[0111]
Further, as shown in FIG. 2, in the present embodiment, the color space conversion processing from the DSC color space iRGB to the color space wRGB suitable for the printer is performed via the device-independent color space. The information is information that does not depend on the color space wRGB suitable for the printer, that is, information that does not depend on the image output unit. Therefore, the digital film profile DPF including the color calibration information and the memory color parameter MCP can be commonly used in an output system including a plurality of image output units of different types and types. In addition, they can be commonly used for different output systems.
[0112]
Note that the digital film profile server 120 can store the prepared digital film profile DPF in the digital film profile storage unit 128 (FIG. 1). If the model of the image generation device is the same, the color space iRGB of the DSC is almost the same. Therefore, other users using the same type of image generation device may be allowed to download and use the stored digital film profile DPF. By doing so, the user can easily prepare a digital film profile DPF that appropriately adjusts colors that satisfy the condition of the memory color range without creating a digital film profile DPF unique to his / her DSC. . However, if the digital film profile DPF is created using the image generating device and the image output unit actually used according to the flowchart of FIG. 7, even if there is an individual difference in the color space of the image generating device and the image output unit, the image can be obtained. A digital film profile DPF more suitable for the generating device and the image output unit can be prepared.
[0113]
B3. Image output processing:
FIG. 12 is a flowchart showing an image output process (S120 in FIG. 3) executed by the output system 200 using the media profile MPF and the digital film profile DPF. In the image output process, first, the input image data GD1 is read by the image quality adjustment application 320 (FIG. 2) (S500). The input image data GD1 is image data generated by the image generation device. The input image data GD1 is generally stored in an image file. Therefore, the image quality adjustment application 320 analyzes the image file and reads the input image data GD1.
[0114]
Next, the digital film profile DPF and the media profile MPF are selected by the first and second selection units 330 and 332 (FIG. 2) (S502).
[0115]
The user can confirm and set the profile selected in S502 through the setting screen of the image quality adjustment application 320. FIG. 13 shows an example of the setting screen. As shown, the screen has a media profile setting section MPFSD and a digital film profile setting section DPFSD.
[0116]
The media profile setting unit MPFSD displays a list OCD of output conditions associated with available media profiles MPF, and the selected output conditions are surrounded by double lines. The file name of the media profile MPF associated with the output condition selected in the output condition list OCD is automatically set in the media profile name setting section MPFD. In step S508 (FIG. 12) described later, a file (media profile MPF) set in the media profile name setting unit MPFD is used. When the selected output condition is different from the combination of the print medium and the ink type actually used, the user can reselect the preferable output condition.
[0117]
In the digital film profile setting section DPFSD, a list IDD of identification names associated with the available digital film profiles DPF is displayed, and the selected identification names are surrounded by double lines. In the digital film profile name setting section DPFD, the file name of the digital film profile DPF associated with the identification name selected in the identification name list IDD is automatically set. In steps S504 and S506 described later, a file (digital film profile DPF) set in the digital film profile name setting unit DPFD is used. The user can set a digital film profile DPF used for image output processing by selecting a desired identification name from these identification names.
[0118]
If the image file includes the model name of the image generation device, the digital film profile DPF associated with the identification name including the same model name is automatically selected. Therefore, an appropriate digital film profile is selected without setting by the user. The selection process according to the model name includes the contents of the input image data GD1 and the operation setting conditions of the image generating apparatus at the time of generating the input image data (for example, whether or not a flash is emitted, an aperture value, a shutter speed, and the like). This is executed regardless of the setting conditions of.). Therefore, the selection process can be executed at high speed without analyzing the input image data GD1 and the operation setting conditions. The operation setting conditions can be obtained from the information stored in the image file when the image generating device generates the image file including the input image data GD1, as with the model name.
[0119]
Further, when there are a plurality of identification names including the same model name, the user's favorite profile can be selected. The image display unit IMD in the screen displays an image obtained as a result of performing the image quality adjustment processing based on the selected digital film profile DPF. The user can easily select the digital film profile DPF by checking the image displayed on the image display unit IMD. Further, when the image file is an image file with a profile including the digital film profile DPF, by operating the profile specifying unit GFPD, it can be set to use the profile included in the image file.
[0120]
After confirming and setting the profile, by operating the print start button GO, step S502 ends, and the processing of step 504 and subsequent steps is executed.
[0121]
In the next step S504, the input color space conversion unit 322 (FIG. 2) converts the color space defining the image data from the DSC color space iRGB to the color space eRGB for image quality correction processing. Is executed. The DSC color space iRGB is a color space that defines the input image data GD1. The color space eRGB for the image quality correction processing is a color space in which a correspondence relationship with another color space is set in advance, and in this embodiment, eRGB-L * a * with the L * a * b * color space. The b * correspondence is set in advance. The input color space conversion process from the iRGB color space to the eRGB color space is performed by using the eRGB-L * a * b * correspondence and the color calibration information (matrix M) included in the digital film profile DPF. .
[0122]
In step S506, the image quality correction unit 326 (FIG. 2) executes a memory color adjustment process. The memory color adjustment processing is the processing shown in FIG. 10 described above. The storage color adjustment processing in step S504 is executed according to the storage color parameter MCP included in the digital film profile DPF selected in step S502.
[0123]
In the next step S508, the output color space conversion unit 324 (FIG. 2) converts the color space defining the image data from the color space eRGB for image quality correction processing to the color space wRGB suitable for the printer. Conversion processing is performed. This output color space conversion processing is executed by using the eRGB-L * a * b * correspondence and the media profile MFP (lookup table N).
[0124]
In the next step S510, the printer 400 outputs an image based on the output image data GD2 expressed in the wRGB color space suitable for the printer.
[0125]
FIG. 14 is an explanatory diagram for explaining the output processing of the image shown in FIG. 12 with a focus on the color space. In the present embodiment, the input image data GD1 is represented by the DSC color space iRGB. In step S504, an input color space conversion process is performed using the digital film profile DPF and the eRGB-L * a * b * correspondence. By this processing, the color space representing the image data is converted from the iRGB color space to the eRGB color space.
[0126]
Next, in step S506, a memory color adjustment process based on the digital film profile DPF is executed.
[0127]
Next, in step S508, an output color space conversion process using the media profile MPF and the eRGB-L * a * b * correspondence is executed. By this processing, the color space representing the image data is converted from the eRGB color space to a color space wRGB suitable for the printer.
[0128]
In the next step S510, an image is output from printer 400 based on the image data whose color space has been converted. This processing is the same processing as S206 in FIG.
[0129]
Note that, when an image is output from an application that cannot execute the image quality adjustment processing using the digital film profile DPF or the media profile MPF, the printer driver is configured to execute all the processes (S504 to S510) in FIG. Is preferred. At this time, it is preferable that the same digital film profile DPF and media profile MPF as those used by the image quality adjustment application 320 are used. As described above, when the plurality of image processing programs can execute the image quality adjustment processing using the digital film profile DPF or the media profile MPF, the same storage unit (the digital film profile storage unit 302 or the media profile storage unit 304) is used. It is preferable to use the same profile (digital film profile DPF or media profile MPF) stored in. In this way, an image whose quality has been appropriately adjusted can be output using any program (for example, the image quality adjustment application 320 or the printer driver).
[0130]
As described above, in the present embodiment, by using the digital film profile DPF including the color calibration information and the storage color parameter MCP and the media profile MPF including the information on the color space wRGB suitable for the printer, the image output unit The color reproducibility of the output image is improved, and color adjustment that satisfies the condition of the memory color range is executed. Therefore, if the setting of the memory color parameter MCP is the same, a case where image data generated by an image generating apparatus having a different color space iRGB of DSC and a case where an image output unit having a different color space wRGB suitable for a printer is used are used. In addition, an image having substantially the same coloring characteristics can be obtained. Further, in this embodiment, the digital film profile DPF is one in which the color calibration information and the storage color parameter MCP are associated. Therefore, by selecting the digital film profile DPF, an appropriate combination of the memory color parameter MCP and the color calibration information can be easily selected.
[0131]
C. First Embodiment of Image File Generation Process with Profile:
FIG. 15 is a flowchart illustrating an example of the profile-attached image file generation process. This process is a process of generating an image file with a profile including the input image data GD1 generated by the image generation device and the digital film profile DPF. As described above, the digital film profile DPF includes the color calibration information and the storage color parameter MCP, and corresponds to the color reproduction information. Therefore, in the present embodiment, the image file with profile corresponds to the image file with color reproduction information in the present invention.
[0132]
First, in step 600, preparation processing of the digital film profile DPF is executed. This preparation processing is the same processing as step S110 in the flowchart of FIG. If the desired digital film profile DPF is not stored in the digital film profile storage unit 302 (FIG. 2), the digital film profile may be downloaded from the digital film profile server 120. If the digital film profile server 120 does not store the desired digital film profile DPF, the digital film profile DPF may be created. For example, the method shown in FIG. 7 can be used as a digital film creation process. The digital film profile DPF prepared in this way contains the color calibration information and the memory color parameter MCP.
[0133]
Next, in step S602, the input image data GD1 is read by the image file generation application with profile 340 (FIG. 2). The user can set the input image data GD1 used in step S602 through the setting screen of the image file generation application with profile 340. FIG. 16 shows an example of the setting screen. As shown in the figure, the screen has an image file setting section GFE and a digital film profile setting section DPFSE.
[0134]
The image file setting unit GFE has an input file setting unit IGFE and an output file setting unit OGFE. By operating the input file setting unit IGFE, the user can specify an image file storing desired input image data GD1. By operating the output file setting unit OGFE, a file name of a newly generated image file can be specified.
[0135]
Next, the digital film profile DPF is selected by the selection unit 344 (FIG. 2) (S604). The user can confirm and set the digital film profile DPF selected in step S604 through the digital film profile setting unit DPFSE on the setting screen (FIG. 16).
[0136]
In the digital film profile setting section DPFSE, a list IDE of identification names associated with the available digital film profiles DPF is displayed, and the selected identification names are surrounded by double lines. The user can set a digital film profile DPF used for the image file with profile generation process by selecting a desired identification name from these identification names. In the digital film profile name setting section DPFE, the file name of the digital film profile DPF associated with the identification name selected in the identification name list IDE is automatically set. In step S606 (FIG. 15) described later, the file (digital film profile DPF) set in the digital film profile name setting unit DPFE is used.
[0137]
When the image file storing the image data GD1 includes the model name of the image generating device, the digital film profile DPF associated with the identification name including the same model name is automatically selected. Therefore, an appropriate digital film profile is selected without setting by the user. Further, such selection processing according to the model name is executed irrespective of the content of the input image data GD1 and the operation setting conditions of the image generating apparatus at the time of generating the input image data. Therefore, the selection process can be executed at high speed.
[0138]
Further, when there are a plurality of identification names including the same model name, the user's favorite profile can be selected. In the image display section IME in the screen, an image as a result of performing the image quality adjustment processing based on the selected digital film profile DPF is displayed. The user can easily select the digital film profile DPF by checking the image displayed on the image display unit IME.
[0139]
After confirming and setting the digital film profile DPF, an image file with a profile including the input image data GD1 and the digital film profile DPF is generated by operating the file generation button GOE (S606). A new image file is generated according to the file name specified by the output file setting unit OGFE.
[0140]
As described above, in the present embodiment, a process of generating an image file with a profile including the input image data GD1 generated by the image generating apparatus and the digital film profile DPF is executed. By using such an image file with a profile, even when an image is output from an output system that does not store a digital film profile DPF suitable for outputting an image, a digital film profile included in the image file with a profile is used. An image whose image quality is appropriately adjusted can be obtained. Further, in this embodiment, the color calibration information included in the digital film profile DPF is constituted by a matrix M. Therefore, the size of the digital film profile DPF can be reduced as compared with the case where the color calibration information is configured using the look-up table, so that the size of the image file with the digital film profile can be reduced. can do. As a result, the capacity of the recording medium when recording the image file with the digital film profile on a computer-readable recording medium such as a CD-ROM or a memory card can be saved. Further, processing for transmitting and receiving an image file with a digital film profile via a network or a cable can be executed at high speed.
[0141]
D. Second Embodiment of Image Quality Adjustment Application:
FIG. 17 is a block diagram illustrating a configuration of the image quality adjustment application 320a according to the present embodiment. The difference from the image quality adjustment application 320 shown in FIG. 2 is that the image quality adjustment application 320a includes a storage color parameter adjustment unit 334a. The functions of the other functional units (322a, 324a, 325a, 326a, 328a, 330a, 332a) are the same as the functional units (322, 324, 326, 328, 330, 332) shown in FIG.
[0142]
The storage color parameter adjustment unit 334a executes a process of adjusting a storage color parameter MCP (not shown) included in the digital film profile DPF selected by the first selection unit 330a. The image quality correction unit 326a performs a memory color adjustment process according to the digital film profile DPF in which the memory color parameter MCP has been adjusted by the memory color parameter adjustment unit 334a.
[0143]
In this embodiment, the user can set the adjustment processing executed by the storage color parameter adjustment unit 334a through the setting screen of the image quality adjustment application 320a. As such a setting screen, a setting screen similar to that of the memory color setting unit MCSC shown in FIG. 11 can be used. By operating such a setting screen, the user can adjust the memory color parameter MCP as desired.
[0144]
As described above, in this embodiment, the user can adjust the storage color parameter MCP used by the image quality correction unit 326a for the actual storage color adjustment processing. Therefore, even when the digital film profile DPF including the memory color parameter MCP desired by the user is not available, the image quality can be appropriately adjusted by adjusting the memory color parameter MCP.
[0145]
As described above, in each of the above-described embodiments, an image is output using a digital film profile including color calibration information and storage color parameters. Therefore, it is possible to output an image having a desired coloring characteristic regardless of the difference between the image generating apparatuses. In particular, by using the digital film profile DPF with the same setting of the memory color parameter MCP, it is possible to obtain an image having substantially the same coloring characteristics even when using different types of image generating apparatuses. Further, by executing the image output using the media profile MPF including the information on the color space wRGB suitable for the printer, the color satisfying the condition of the memory color range becomes the target color regardless of the difference of the image output unit. It is possible to output an image reproduced in a near preferable color. Further, by generating and using an image file with a profile including a digital film profile DPF and image data, even when an image is output from an output system that does not store a digital film profile DPF suitable for image output, the image quality can be improved. Can be obtained. Further, by using the digital film profile server 120, the user can easily prepare a digital film profile DPF suitable for the image generating apparatus.
[0146]
E. FIG. Modification:
The present invention is not limited to the above-described examples and embodiments, but can be implemented in various modes without departing from the gist of the invention, and for example, the following modifications are possible.
[0147]
E1. Modification 1
The memory color adjustment processing in each of the above-described embodiments is not limited to the processing using the tone curve, and may be any processing that adjusts a color in a range close to the memory color to a color close to the target color. For example, the color may be adjusted using a look-up table including a plurality of combinations of input values and output values. In this case, a look-up table is used as the memory color parameter MCP.
[0148]
E2. Modified example 2:
The method of expressing the correspondence between the input value and the output value for executing the color space conversion processing is not limited to the method using a matrix or a lookup table, but may be a method that can appropriately execute the color space conversion processing. I just need.
[0149]
E3. Modification 3:
In each of the embodiments, the color calibration information included in the digital film profile DPF is information on the correspondence between the color space iRGB of the DSC and the device-independent color space. In general, the color calibration information is the color calibration of the image data. Any information can be used as long as it is used for When the color calibration is realized by the color space conversion process, the color calibration information can be generally information on the correspondence between the first color space and the second color space. For example, a DSC color space iRGB may be used as the first color space, and a color space wRGB suitable for a printer may be used as the second color space. At this time, the input color space conversion unit 322 (FIG. 2) executes a color space conversion process for converting the color space defining the image data from the DSC color space iRGB to a color space wRGB suitable for a printer. Further, the media profile storage unit 304, the second selection unit 332, the output color space conversion unit 324 (FIG. 2), and the media profile preparation processing S100 (FIG. 3) can be omitted. Even when such a configuration is used, if the color calibration information is set based on the test chart output from the image output unit, the color reproducibility of the output image can be improved regardless of the difference between the image generation device and the image output unit. In addition to the above, it is possible to obtain an image in which a color satisfying the condition of the memory color range is reproduced in a preferable color close to the target color.
[0150]
In each of the above-described embodiments, the color calibration is performed by performing the color space conversion process. Alternatively, the color space conversion process and the color calibration may be separately performed. . At this time, the color reproduction information is configured to include parameter values for color calibration separately from the color space conversion profile.
[0151]
E4. Modification 4:
The setting screens (FIGS. 5, 8, and 11) for exchanging information with various servers (media profile server 110, digital film profile server 120) in each of the above-described embodiments are the setting screens of the image quality adjustment application 320. The screen is not limited to the configuration in which the setting is displayed as long as the screen allows the user to confirm and change the setting. For example, a configuration may be adopted in which a browser is operated on the computer 300 and a web page for a setting screen provided by the media profile server 110 or the digital film profile server 120 is displayed by the browser.
[0152]
E5. Modification 5:
In the above embodiments, the image quality adjustment application 320 of the computer 300 performs the process using the profiles MPF and DPF. Instead, the control circuit (not shown) of the printer 400 The function may be realized. At this time, for example, a configuration can be used in which the printer 400 is connected to the DSC 600 as an image generating device by a cable CB, and the printer 400 receives the input image data GD1 via the cable CB. Also, the input image data GD1 generated by the DSC 600 is stored in a memory card (not shown), and the memory card on which the input image data GD1 is recorded is mounted on the printer 400. A reading configuration may be used. Further, the DSC 600 and the printer 400 may be connected to the network NET, and the printer 400 may receive the input image data GD1 via the network NET.
[0153]
E6. Modification 6:
In the embodiment of the application for generating an image file with a profile, the case where the input image data GD1 and the digital film profile DPF are included in the same image file has been described as an example. However, the input image data GD1 and the digital film profile DPF are not necessarily used. They do not need to be stored in the same file. That is, the input image data GD1 and the digital film profile DPF may be associated with each other. For example, association data for associating the input image data GD1 with the digital film profile DPF is generated, and the input image data GD1 and the digital film profile DPF are associated with each other. May be stored in independent files, and the associated digital film profile DPF may be referenced when processing the input image data GD1. In such a case, the input image data GD1 and the digital film profile DPF are stored in separate files, but at the time of image data processing using the digital film profile DPF, the input image data GD1 and the digital film profile DPF are not stored. This is because they are associated with each other and function substantially as if they were stored in the same file. That is, at least at the time of image data processing, a file in which the input image data GD1 is associated with the digital film profile DPF can be regarded as a profiled image file.
[0154]
E7. Modification 7:
In each of the above-described embodiments, the processing for color calibration (input color space conversion processing and output color space conversion processing) and the memory color adjustment processing are executed by one application (image quality adjustment application 320). Alternatively, each processing may be executed by an independent application. For example, the front-end module 336 and the back-end module 338 in FIG. 2 may be configured as different applications. At this time, the image data processed by each application is passed to another application, but it is preferable that information on a color space representing the image data be passed along with the image data. By doing so, the application that has received the image data can execute processing while maintaining faithful color reproduction. The information on the color space may be any information used for color calibration, and for example, information indicating the correspondence between a color space representing image data and another color space can be used.
[0155]
E8. Modification 8:
In each of the above embodiments, the memory color adjustment processing is executed in addition to the processing for color calibration (input color space conversion processing, output color space conversion processing), but other image quality adjustment processing is executed. It is good also as composition. For example, the image quality correction unit 326 may be configured to execute contrast adjustment processing and sharpness adjustment processing in addition to the memory color adjustment processing. Also at this time, by configuring the digital film profile DPF to include parameters for the contrast adjustment processing and the sharpness adjustment processing, the user can easily output an image whose image quality has been appropriately adjusted.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing the overall configuration of a color management image output system.
FIG. 2 is a block diagram showing a configuration of a computer 300.
FIG. 3 is a flowchart illustrating a color management image output process.
FIG. 4 is a flowchart showing a media profile preparation process.
FIG. 5 is an example of a setting screen of an image quality adjustment application 320.
FIG. 6 is an explanatory diagram of a media profile preparation process.
FIG. 7 is a flowchart showing a digital film profile preparation process.
FIG. 8 is a diagram showing an example of a setting screen.
FIG. 9 is an explanatory diagram of a digital film profile preparation process.
FIG. 10 is an explanatory diagram illustrating a memory color adjustment process.
FIG. 11 is an explanatory diagram illustrating an example of a setting screen.
FIG. 12 is a flowchart illustrating an image output process.
FIG. 13 is an explanatory diagram showing an example of a setting screen.
FIG. 14 is an explanatory diagram of an image output process.
FIG. 15 is a flowchart illustrating an example of an image file with profile generation process.
FIG. 16 is an explanatory diagram showing an example of a setting screen.
FIG. 17 is a block diagram illustrating a configuration of an image quality adjustment application 320a.
[Explanation of symbols]
110 ... Media profile server
112 ... Media profile creation unit
114: Test chart data storage for media profile creation
116, 126, 306...
120 ... Digital film profile server
122: Digital film profile creation unit
124: Test chart data storage for digital film profile creation
200 ... Output system
300 ... Computer
302: Digital film profile storage unit
304: Media profile storage unit
320, 320a: Image quality adjustment application
322, 322a: input color space conversion unit
324, 324a ... output color space conversion unit
326, 326a: Image quality correction unit
328, 328a: color space conversion unit
330, 330a... First selection unit
332, 332a... Second selection unit
334a... Memory color parameter adjustment unit
336, 336a: Front-end module
338, 338a: Back-end module
340: Image file generation application with profile
342 ... Image file generation unit
344 ... Selection unit
400 ... Printer
500 monitor
NET ... Network
CB ... Cable
GD1 ... input image data
GD2: output image data
PD… Print data
DFB: Digital film profile download menu button
IMB: Test chart image transmission setting section
OCA: Output condition setting section
OCB, OCD ... output condition list
DPF: Digital film profile
DPFSD, DPFSE: Digital film profile setting unit
DPFC, DPFD, DPFE: Digital film profile name setting section
DPFDLC… Download start button
MPF: Media profile
MPFSA: Media profile download setting section
MPFSD: Media profile setting section
MPFA, MPFB, MPFD: Media profile name setting section
MPFDLA… Download start button
TCDA, TCDB ... Download start button
TCFA, TCFB ... Test chart data file setting section
TCOA, TCOB ... Test chart output start button
TCSA, TCSB ... test chart setting section
IMFB: Image data file name setting section
IMUB ... Image data transmission start button
MCP: Memory color parameter
DFB: Digital film profile download menu button
MCSC: Memory color setting section
STDC: Standard setting section
SPLC: Simple setting unit
PRCC ... Detailed setting section
IMBF: Sample image before adjustment
IMAF: Sample image after adjustment
IDC: Identification name setting section
IDD, IDE ... ID list
IMD: Image display unit
GFPD… Profile designator
GO… Print start button
GFE: Image file setting section
IGFE: Input file setting section
OGFE: Output file setting section
IME: Image display unit
GOE… File generation button

Claims (18)

A method of outputting an image using target image data generated by an image generation device,
(A) As color reproduction information for arbitrary image data generated by the image generation device,
(I) color calibration information used for color calibration of arbitrary image data generated using the image generation device;
(Ii) storage color information used for color correction of a color in a predetermined range close to a specific storage color in an arbitrary image captured using the image generation device;
Preparing color reproduction information including at least for each model of the image generating apparatus;
(B) performing, on the target image data generated by the image generation device, a plurality of processes including color calibration using the color calibration information and color correction using the memory color information; Generating data;
(C) outputting an image based on the processed image data;
An image output method comprising: The image output method according to claim 1, wherein
The color calibration information, when reproducing the original image from the image data obtained by imaging the original image including a color sample using the image generation device, in color calibration to faithfully reproduce the color of the original image Image output method, which is the information used. An image output method according to claim 1 or 2, wherein:
The color calibration information includes a color space conversion profile that defines a color space conversion process for converting a color space of arbitrary image data generated by the image generation device from a first color space to a second color space,
The image output method, wherein the color calibration on the target image data is realized by executing the color space conversion process on the target image data. The image output method according to claim 3, wherein
The first color space is a color space used when the image generation device generates the target image data,
The second color space is a device-independent color space;
Image output method. An image output method according to any one of claims 1 to 4, wherein
The step (a) includes a step of preparing a plurality of the color reproduction information corresponding to a plurality of types of the image generating device,
The image output method, wherein the step (b) includes a step of selecting, from the plurality of pieces of color reproduction information, one piece of color reproduction information suitable for the image generation apparatus according to a model of the image generation apparatus. An image output method according to any one of claims 1 to 4, wherein
The step (a) includes a step of preparing a plurality of the color reproduction information,
The image output method, wherein the step (b) includes a step of selecting one piece of color calibration information from the plurality of pieces of color reproduction information in accordance with a user's instruction. An output device that outputs an image using target image data generated by the image generation device,
A color calibration unit that performs color calibration of any image data generated using the image generation device,
A color correction unit that performs color correction on a color in a predetermined range close to a specific storage color in an arbitrary image captured using the image generation device,
An image output unit that outputs an image based on processed image data obtained by performing a plurality of processes including the color calibration and the color correction on the target image data,
With
The color calibration unit and the color correction unit,
Color reproduction information for any image data generated by the image generation device,
(I) color calibration information used for the color calibration;
(Ii) memory color information used for the color correction;
Including, executing a process based on at least color reproduction information prepared for each model of the image generating device,
Output device A computer program for causing a computer to execute a process of generating processed image data for outputting an image from an image output unit using target image data generated by an image generation device,
(A) a function of performing color calibration of arbitrary image data generated using the image generation device;
(B) a function of executing a color correction for a color in a predetermined range close to a specific storage color in an arbitrary image captured by using the image generation device;
(C) a function of executing the functions (a) and (b) on the target image data to generate the processed image data;
Is a computer program that causes the computer to realize,
The functions (a) and (b) are
Color reproduction information for any image data generated by the image generation device,
(I) color calibration information used for the color calibration;
(Ii) memory color information used for the color correction;
And a computer program realized based on at least color reproduction information prepared for each model of the image generation device. A computer-readable recording medium on which the computer program according to claim 8 is recorded. An image file generation method for generating an image file including target image data generated by an image generation device,
(A) As color reproduction information for arbitrary image data generated by the image generation device,
(I) color calibration information used for color calibration of arbitrary image data generated using the image generation device;
(Ii) storage color information used for color correction of a color in a predetermined range close to a specific storage color in an arbitrary image captured using the image generation device;
Preparing color reproduction information including at least for each model of the image generating apparatus;
(B) generating an image file with color reproduction information that stores the color reproduction information in association with the target image data;
Image file generation method. The image file generating method according to claim 10, wherein:
The color calibration information, when reproducing the original image from the image data obtained by imaging the original image including a color sample using the image generation device, for color calibration to faithfully reproduce the color of the original image An image file generation method that is information to be used. An image file generating method according to claim 10 or claim 11, wherein
The color calibration information includes a color space conversion profile that defines a color space conversion process for converting a color space of arbitrary image data generated by the image generation device from a first color space to a second color space,
The image file generation method, wherein the color calibration on the target image data is realized by executing the color space conversion process on the target image data. An image file generation method according to claim 12, wherein:
The first color space is a color space used when the image generation device generates the target image data,
The second color space is a device-independent color space;
Image file generation method. An image file generating method according to any one of claims 10 to 13, wherein:
The step (a) includes a step of preparing a plurality of the color reproduction information corresponding to a plurality of types of the image generating device,
The image file generating method, wherein the step (b) includes a step of selecting one piece of color reproduction information suitable for the image generation device from the plurality of pieces of color reproduction information according to a model of the image generation device. An image file generating method according to any one of claims 10 to 13, wherein:
The step (a) includes a step of preparing a plurality of the color reproduction information,
The step (b) is a method for generating an image file, including the step of selecting one piece of color reproduction information from the plurality of pieces of color reproduction information in accordance with a user's instruction. An image file generation device that generates an image file including target image data generated by the image generation device,
Color reproduction information for any image data generated by the image generation device,
(I) color calibration information used for color calibration of arbitrary image data generated using the image generation device;
(Ii) storage color information used for color correction of a color in a predetermined range close to a specific storage color in an arbitrary image captured using the image generation device;
And an image file generation unit that generates an image file with color reproduction information that stores at least color reproduction information prepared for each model of the image generation device in association with the target image data,
Image file generation device. A computer program for causing a computer to execute a process of generating an image file including target image data generated by the image generation device,
(A) color reproduction information for arbitrary image data generated by the image generation device,
(I) color calibration information used for color calibration of arbitrary image data generated using the image generation device;
(Ii) storage color information used for color correction of a color in a predetermined range close to a specific storage color in an arbitrary image captured using the image generation device;
Including the function of generating an image file with color reproduction information that stores at least the color reproduction information prepared for each model of the image generation device in association with the target image data.
Computer program. A computer-readable recording medium recording the computer program according to claim 17.

Images