JP4332741B2 - Color conversion based on multiple color conversion profiles - Google Patents

Description

  The present invention relates to a technique for speeding up color conversion processing based on a plurality of color conversion profiles.

Image devices such as displays and printers usually use image data in which the color of each pixel is expressed by a color component value (tone value for each color component). Since the color based on the color component value is usually a device-dependent color, when the same image is handled by different image devices, color conversion is performed to match the colors. This color conversion is executed based on the color conversion profile. That is, a color conversion profile that defines the correspondence between colors in different color systems is created in advance, and color conversion for an arbitrary color is performed by interpolation calculation with reference to the color conversion profile. In defining the correspondence relationship for a certain color system, it is necessary to consider various factors such as color gamut differences and memory colors between image devices. To perform color conversion, multiple color conversion profiles are required. Sometimes used. In addition, when performing color conversion based on a plurality of color conversion profiles, it takes time to repeat the color conversion, and thus a technique for combining a plurality of color conversion profiles in advance is known (for example, patents). Reference 1).
US Pat. No. 5,432,906

In the conventional technology described above, it is difficult to perform color conversion based on a plurality of arbitrary color conversion profiles at high speed.
That is, in a configuration that requires processing for combining a plurality of color conversion profiles, it is necessary to create a color conversion profile that is combined in advance, and color conversion is performed based on the combined profile based on an arbitrary color conversion profile. It is not possible. Even if the color conversion process is performed based on the combined color conversion profile, it is difficult to perform a high-speed process if an interpolation operation is performed for color conversion of a large number of pixels.
SUMMARY An advantage of some aspects of the invention is that it provides a color conversion technique capable of performing color conversion based on a plurality of arbitrary color conversion profiles at high speed.

In order to achieve at least one of the above objects, the present invention uses a first color conversion profile and a second color conversion profile in which a correspondence relationship between an input value and an output value is defined by a plurality of combinations, and a color component. The color component value of the image data in which the pixel color is designated by the value is converted. At that time, the first color conversion profile is generated based on the original color conversion profile created in advance so that the plurality of output values in the first color conversion profile coincide with the plurality of input values in the second color conversion profile. And a color conversion profile of at least one of the second color conversion profile and a color component value of the image data based on the first color conversion profile after the color conversion profile is generated. The output value obtained by the first color conversion means is used as an input value, and conversion is performed based on the second color conversion profile after the color conversion profile is created .

  That is, since the output value of the first color conversion profile matches the input value of the second color conversion profile, each color component value is converted based on the first color conversion profile when converting the color component value of the image data. After conversion to the output value, the conversion can be completed based on only the input value and the output value specified in the second color conversion profile. Therefore, it is not necessary to perform an interpolation operation for color conversion, and color conversion based on the first color conversion profile and the second color conversion profile can be performed at high speed.

  In the present invention, it is only necessary that the plurality of output values in the first color conversion profile match the plurality of input values in the second color conversion profile, and they must already match in performing the color conversion process. That's fine. Therefore, when performing the color conversion process, a profile in which the two match each other may be acquired, or a process for matching the two with reference to a profile in which the two do not match may be performed. As a result, the present invention can be implemented using any color conversion profile, and color conversion based on a plurality of arbitrary color conversion profiles can be performed.

  In each profile, it is only necessary to define the correspondence between two different color systems by defining the correspondence between input values and output values in a plurality of combinations. That is, in the color system, a color is expressed by combining the color component values of a plurality of color components. The combination of the color component values in the first color system and the color component values in the second color system. When the combinations are associated, the color system can be converted for a certain color.

  Furthermore, if the above combination is defined for a plurality of colors, an arbitrary color component value combination in the first color system is converted into a combination of any color component value in the second color system by interpolation calculation. Can do. Therefore, in this specification, a combination of color component values before color conversion is used as an input value, and a combination of color component values after color conversion is used as an output value. In the present invention, since the output value obtained by the first color conversion means and the input value in the second color conversion means match, the second color conversion profile is obtained without performing interpolation. It suffices if the conversion can be performed.

  Therefore, at least the output value corresponding to the color component value to be converted needs to match the input value of the second color conversion profile, but in order to improve versatility, all the values in the first color conversion profile It is preferable that the output value of the second color conversion profile matches all the input values in the second color conversion profile.

The color conversion device of the present invention may include image data acquisition means for acquiring image data in which the color of a pixel is designated by a color component value. The image data acquisition means may adopt a configuration for acquiring image data of an image to be printed as an object for color conversion at the time of printing, or an image scanned for color conversion at the time of image scanning The image data may be acquired. In the image data, it is only necessary that the color of each pixel can be specified by the color component value, and various color systems can be adopted as the color system for specifying the color of each pixel.

The first color conversion unit converts the color component value of the image data into an output value of the first color conversion profile based on the first color conversion profile after the color conversion profile is created . Therefore, an arbitrary color component value is associated with only the output value defined in the first color conversion profile. In other words, the first color conversion profile defines the correspondence between input values and output values for a plurality of colors, so that if an interpolation operation is performed, an output value corresponding to an arbitrary color component value is acquired. Can do.

  However, in the present invention, in order not to perform the interpolation calculation in the second color conversion means, any color component value is converted into one of the output values defined in the first color conversion profile. To do. Since this conversion can be performed not by interpolation calculation but by a preset rule, it is not necessary to perform processing that requires many resources, and conversion can be performed at high speed.

The second color conversion means only needs to be able to convert an input value into an output value based on the second color conversion profile after the color conversion profile is created . Since all of the input values match the input values defined in advance in the second color conversion profile, the processing can be performed at high speed without performing an interpolation calculation.

Further, as a preferable configuration to allow performing the color conversion based on any of a plurality of color conversion profiles, by interpolation from any source color conversion profile of the first color conversion profile and the second color conversion profile at least You may employ | adopt the structure which produces one. In other words, when an arbitrary original color conversion profile is assumed, the combination of input values and output values is also arbitrary. However, if an interpolation operation is performed with reference to the original color conversion profile, an arbitrary color component value is input. It is possible to obtain an output value corresponding to the input value as a value.

Accordingly, if implementing the interpolation calculation with reference to the original color conversion profile created in advance, easily match a plurality of input values at a plurality of output values and the second color conversion profile in the first color conversion profile be able to. According to the above configuration, color conversion based on both the first color conversion profile and the second color conversion profile can be performed at high speed based on any color conversion profile.

Here, since it is only necessary to match a plurality of output values in the first color conversion profile with a plurality of input values in the second color conversion profile, either the first color conversion profile or the second color conversion profile is used. Interpolation calculation may be performed. Of course, it is also possible to perform an interpolation calculation for both. In the present invention, since the input value of the second color conversion profile is matched with the output value of the first color conversion profile, interpolation is performed using the output value of the first color conversion profile as the input value and referring to the second color conversion profile. If the configuration for performing the operation is adopted, it is possible to easily match the input value and the output value.

In the above configuration, it is necessary to perform an interpolation calculation based on an original color conversion profile created in advance. This interpolation calculation may be performed once before performing color conversion of image data. In general the number of pixels of the image data included in the image such as a photograph from (millions of pixels), the number (33 ^3, 65 ³ etc.) of a value to be defined as an input value of the color conversion profile overwhelmed found the following There are few. Therefore, even if the first color conversion profile or the second color conversion profile is created by interpolation, it is possible to perform processing at high speed.

  Further, the first color conversion means only needs to be able to convert the color component value of the image data into the output value of the first color conversion profile. As a preferable configuration thereof, a predetermined gradation number conversion rule is used. A configuration may be adopted. That is, since the number of output values in the first color conversion profile is smaller than the number of color component values (number of gradations), any color can be obtained by using a predetermined gradation number conversion rule for reducing the number of gradations. The component value can be converted into one of the input values in the first color conversion profile, and an output value associated with the input value can be obtained. As a result, an arbitrary color component value can be converted into one of output values defined in the first color conversion profile.

  Here, various rules can be adopted as the gradation number conversion rule, and various methods such as a multi-value error diffusion process, an average error minimum method, and a multi-valued systematic dither method can be adopted. . Each color component value may be converted into a specific input value according to a random number. At this time, a sum of a constant and a random number associated with each color component value in advance is calculated, and this sum is determined in advance. The input value may be determined by comparing with a set threshold value, and various rules can be adopted. In the first color conversion profile, a plurality of input values and output values are associated one-to-one, so that any color component value is converted into one of the input values in the first color conversion profile; It can be said that conversion of a color component value into one of output values in the first color conversion profile is equivalent.

  Of course, the above invention can be realized not only by the apparatus but also by a method, and can also be realized by a program that executes processing according to the above method. Furthermore, the present invention can be realized as a print control apparatus, method, and program for performing printing based on the result of the color conversion. In addition, the idea of the invention is that the apparatus, method, and program according to the present invention may be implemented independently, or may be implemented together with other apparatuses, methods, and programs while being incorporated in a certain device. Is not limited to this, and includes various aspects, and can be changed as appropriate.

  Further, it can be provided as a recording medium on which the program of the present invention is recorded. The recording medium for this program may be a magnetic recording medium, a magneto-optical recording medium, or any recording medium that will be developed in the future. In addition, the duplication stages such as the primary duplication product and the secondary duplication product are equivalent without any question. Further, even when a part is software and a part is realized by hardware, the idea of the invention is not completely different, and a part is stored on a recording medium and is appropriately changed as necessary. It may be in the form of being read. Further, not all functions are necessarily realized by a single program, but may be realized by a plurality of programs. In this case, what is necessary is just to make each function implement | achieve in a some computer.

Here, embodiments of the present invention will be described in the following order.
(1) Configuration of print control apparatus:
(2) Print control processing:
(2-1) Profile details:
(2-2) First color conversion process:
(2-3) Second color conversion process:
(3) Color conversion processing operation:
(4) Other embodiments:

(1) Configuration of print control apparatus:
FIG. 1 is a block diagram showing a schematic configuration of a computer serving as a print control apparatus and a color conversion apparatus according to the present invention. The computer 10 includes a central processing unit (CPU) and a ROM or RAM as storage media, and can execute a predetermined program using peripheral devices such as the HDD 15. An operation input device such as a keyboard 31 and a mouse 32 is connected to the computer 10 via a serial communication I / O 19a, and a display 18 is also connected via a video board (not shown). Further, it is connected to the printer 40 via a USB I / O 19b.

  The printer 40 according to the present embodiment includes a mechanism in which ink cartridges filled with a plurality of colors of ink can be attached and detached for each color. Mount ink cartridges. The printer 40 can form a large number of colors by combining these ink colors, thereby forming a color image on the print medium. The printer 40 in the present embodiment is an ink jet printer, but the present invention can be applied to various printers such as a laser method in addition to the ink jet method.

  Furthermore, the configuration using the six colored inks of CMYKlclm is not essential, and the configuration using four colors of CMYK and seven colors of CMYKlclmDY (dark yellow) may be used. Of course, other colors such as R (red) and V (violet) may be used instead of the lclm ink, and a dark and light ink may be used for the K ink. The connection interface between the computer 10 and the printer 40 is not limited to the above-described one, and various connection modes such as a parallel interface, SCSI connection, and wireless connection can be adopted. is there.

  Furthermore, in the present embodiment, the print control apparatus is configured by the computer 10, but the print control process according to the present invention can be implemented by the program execution environment installed in the printer 40, and the printer 40 can be directly Image data may be acquired from a digital camera connected to the printer and the print control process may be performed. Of course, the print control process may be performed with a digital camera in the same configuration, and various other configurations such as performing the print control process according to the present invention by a distributed process may be employed. The print control processing according to the present invention may be performed in a so-called multi-function machine in which a scanner for capturing an image and a printer for printing an image are integrated.

  In the computer 10 according to the present embodiment, a printer driver (PRTDRV) 21, an input device driver (DRV) 22, and a display driver (DRV) 23 are incorporated in the OS 20. The display DRV 23 is a driver that controls display of an image to be printed, a printer property screen, and the like on the display 18, and the input device DRV 22 is a code signal from the keyboard 31 or mouse 32 that is input via the serial communication I / O 19 a. And receiving a predetermined input operation.

(2) Print control processing:
The PRTDRV 21 can perform printing by performing predetermined processing on an image for which a print instruction has been issued from an application program (not shown). The PRTDRV 21 includes an image data acquisition module 21a, a color conversion module 21b, a halftone processing module 21c, and a print data generation module 21d in order to execute printing. When the above-described print instruction is given, the PRTDRV 21 is driven, the processing for the image data 15a is performed by each module, and print data is generated. The generated print data is output to the printer 40 via the USB I / F 14, and the printer 40 executes printing based on the print data.

  FIG. 2 is a flowchart showing this print control processing. When the print instruction is issued, first, the image data acquisition module 21a acquires image data 15a indicating an image for which a print instruction has been issued by the application program (step S100). At this time, if there is an excess or deficiency in the number of pixels of the image data 15a, resolution conversion processing is performed as appropriate in order to secure the pixels necessary for printing. In the present embodiment, the image data 15a is data in which each color component of RGB (red, green, blue) is expressed in gradation to define the color of each pixel, and each color has 256 gradations.

  In this embodiment, the RGB color component values of the image data 15a are data in accordance with the sRGB standard, but various data such as JPEG image data using the YCbCr color system and image data using the CMYK color system. Can be adopted. Of course, the present invention is applied to data conforming to the Exif 2.2 standard (Exif is a registered trademark of the Japan Electronics and Information Technology Industries Association), data corresponding to Print Image Matching (PIM: PIM is a registered trademark of Seiko Epson Corporation), etc. It can also be applied. In the present embodiment, the processing in step S100 described above corresponds to the processing in the image data acquisition unit.

  The color conversion module 21b converts the color system indicating the color of each pixel (steps S105 to S120). That is, the color conversion module 21b performs color conversion using the first color conversion profile 15b, the gradation number conversion profile 15c, and the original color conversion profile 15d prepared in advance. At this time, a process of generating a second color conversion profile 15e from the original color conversion profile 15d is performed, and the second color conversion profile 15e and the above profile are combined to perform a two-stage color conversion process. .

(2-1) Profile details:
In the present embodiment, the first color conversion profile 15b is a profile having the sRGB color component value as an input value and the RGB color component value for designating an output color in the printer 40 as an output value. The original color conversion profile 15d uses RGB color component values for designating the output color of the printer 40 as input values, and outputs CMYKlclm values for designating the amount of ink used in the printer 40 for each ink color. A profile with values.

  3 and 4 are explanatory diagrams for explaining these profiles. In FIG. 3, an example of the first color conversion profile 15b is shown in the upper part, and a combination of input values on the left side and output values on the right side. For example, when the sRGB color component value as an input value is (R, G, B) = (8, 0, 0), the corresponding output value is (R, G, B) = (7, 0, 1). ).

In the drawing, the color component value of the sRGB color system is shown as (RGB) ₀ , and the color component value of the RGB color system for designating the output color in the printer 40 is shown as (RGB) ₁ . The input value is a combination of values obtained by combining values (33 for each color) obtained by dividing the gradation value range of the sRGB color component values into 32 for each color. That is, when an orthogonal space with the sRGB colors as axes is considered, the input values are selected so that the lattice points formed by the input values form a cubic lattice. Of course, the numerical values shown in the figure are merely examples, and are not limited to these numerical values, and the method of selecting the lattice is not particularly limited.

In FIG. 4, an example of the original color conversion profile 15d is shown in the upper part, and a combination of input values on the left side and output values on the right side. For example, when the RGB color component value as an input value is (R, G, B) = (8, 0, 0), the corresponding output value is (C, M, Y, K, lc, lm) = (0, 5, 5, 249, 0, 0). In this figure, the color component value of the RGB color system for designating the output color in the printer 40 is (RGB) ₂ , and the amount of ink used in the printer 40 is designated for each ink color. The CMYKlclm value is shown as (CMYKlclm) ₀ . The method for selecting the input value is the same as that for the first color conversion profile 15b. Of course, the numerical values shown in the figure are merely examples, and the method for selecting the lattice is not limited to these numerical values.

  As described above, the color system of the output value in the first color conversion profile 15b matches the color system of the input value in the original color conversion profile 15d. Therefore, if color conversion based on the original color conversion profile 15d is further performed after color conversion based on the first color conversion profile 15b, color conversion based on the two color conversion profiles can be performed. However, as shown in FIGS. 3 and 4, even if the color system of the output value in the first color conversion profile 15b matches the color system of the input value in the original color conversion profile 15d, the output value The input value itself is different.

  Therefore, when performing the conventional color conversion, it is necessary to perform an interpolation operation with reference to the original color conversion profile 15d on the conversion result of the first color conversion profile 15b. Since this interpolation calculation causes a reduction in processing speed, the present invention employs a configuration for omitting this interpolation calculation. In other words, the color conversion is performed using the gradation number conversion profile 15c created based on the first color conversion profile 15b and the second color conversion profile created based on the original color conversion profile 15d. .

  An example of the gradation number conversion profile 15c is shown in the lower part of FIG. The gradation conversion profile 15c is a profile in which each value of the sRGB color component is associated with a predetermined constant, and the number of gradations for each color in the sRGB color component (256 in this embodiment) is reduced. This is a profile for setting the number of values that can be taken by the sRGB color component values as the input value of the first color conversion profile 15b for each color (33 in this embodiment, as described above).

  That is, the input value defined in the first color conversion profile 15b takes a predetermined value (for example, 0, 8, 16,...) For each color component. An arbitrary color component value is converted into one of the predetermined values for each color. Therefore, the gradation number conversion profile 15c associates each color component value with a constant indicating the ease of conversion when converting into one of the predetermined values, and the conversion is performed based on this constant. It can be implemented.

  In the present embodiment, this constant is determined by normalization so that the predetermined value interval is 1. For example, when the input value of each color component in the first color conversion profile 15b changes to 0, 8, and 16, the input value 0 corresponds to the constant 0, and the input value 8 corresponds to the constant 1. At this time, the input value 1 corresponds to 1/8 (0.125) as a constant. The input value 9 corresponds to 9/8 (1.125) as a constant. The details of the conversion process using the gradation number conversion profile 15c will be described later.

  In the present embodiment, the input value defined in the first color conversion profile 15b is a common value for each color. Therefore, if the gradation number conversion profile 15c is created for a certain color, the gradation number conversion profile 15c can be used for all colors. In the present embodiment, the gradation number conversion profile 15c is created in advance before the print control process shown in FIG. 2 is performed.

  In the lower part of FIG. 4, an example of the second color conversion profile 15e is shown. Here, the combination of input values is shown on the left side, and the combination of output values is shown on the right side. The second color conversion profile 15e is similar to the original color conversion profile 15d in that the RGB color component value for designating the output color in the printer 40 is an input value, and the amount of ink used in the printer 40. Is a profile in which CMYKlclm values for designating each ink color are output values.

  However, even if the original color conversion profile 15d and the second color conversion profile have the same color system before and after conversion, the combination of input values and the combination of output values are different. That is, the combination of input values in the second color conversion profile 15e is configured to match the combination of output values in the first color conversion profile 15b. The combination of output values of the second color conversion profile 15e is a combination of CMYKlclm values corresponding to the combination of output values in the first color conversion profile 15b as an input value, and is calculated by interpolation calculation (this embodiment) In the embodiment, this process is called “reconstruction” (details will be described later).

  In the present embodiment, since the first color conversion profile 15b, the gradation number conversion profile 15c, and the original color conversion profile 15d are created in advance, the second color conversion profile 15e is used for the print control shown in FIG. Create That is, after acquiring the image data in step S100, the reconstruction process is performed to create the second color conversion profile 15e (step S105). For this purpose, the color conversion module 21b includes an interpolation calculation unit 21b1, and the interpolation calculation unit 21b1 performs an interpolation calculation with reference to the original color conversion profile 15d. At this time, the first color conversion profile 15b is referred to, and the interpolation calculation is performed with the combination of the output values as the input value. As a result, a second color conversion profile 15e is created using the output value of the first color conversion profile 15b as an input value.

Various methods can be used for this interpolation calculation. For example, linear interpolation such as tetrahedral interpolation or non-linear interpolation such as spline interpolation may be used. If the former, high-speed processing is possible, and if the latter, high-precision interpolation can be performed. Incidentally, in this interpolation calculation, the number of combinations of output values in the first color conversion profile 15b may be carried out by (33 ^three in this embodiment), and, since once may be carried upon the print control process, interpolation Even if the calculation is performed, it does not cause a significant decrease in the speed of the print control process and the color conversion process. That is, if interpolation calculation is performed for the number of pixels of image data (million pixels in a photograph or the like), a very large number of interpolation calculations are required. Since the interpolation calculation for each pixel is not performed when the color conversion is performed on the pixel, the processing speed can be increased by the present invention. In the present embodiment, the processing in step S105 corresponds to the processing in the profile acquisition unit.

(2-2) First color conversion process:
After creating the second color conversion profile 15e, the color conversion module 21b acquires the gradation number conversion profile 15c (step S110) to perform the first-stage color conversion processing, and the image data acquired in the above step S100. A gradation number conversion process is performed for each color component value (step S115). Here, the gradation number conversion process is performed by comparing the sum of the output value (a constant shown in the lower part of FIG. 3) defined in the gradation number conversion profile 15c and a random number with a predetermined threshold value.

  In the present embodiment, random numbers are generated between 0 and 1, and are generated for each pixel of image data. Further, the threshold value is determined in advance according to the input values defined in the first color conversion profile 15b (0, 8, 16,... In the example shown in FIG. 3). In this embodiment, the threshold value is sandwiched between the input values. This is a common threshold for arbitrary color component values. The threshold value is an integer obtained by rounding up the decimal part of the constant defined in the gradation number conversion profile 15c. For example, since the constants 0.125 to 1 are associated with the input values 1 to 8 of the gradation number conversion profile 15c, the threshold value is set to 1 for the color component values 1 to 8.

  As shown in the lower part of FIG. 3, since the constant defined in the gradation number conversion profile 15c becomes the same value as the threshold value by rounding up the decimal part, “constant defined in the gradation number conversion profile 15c + random number” The result of “is included between“ threshold −1 ”and“ threshold +1 ”. Therefore, in step S115, the gradation number conversion profile 15c is referred to, and a constant associated with each color component value of each pixel in the image data is acquired. A random number is generated for each color component value.

  Thereafter, the sum of the constant and the random number is taken and compared with the threshold value. As a result, if it is determined that the sum is equal to or smaller than the threshold value, the input value defined in the first color conversion profile 15b is selected, and the smaller one of the two input values sandwiching the color component value to be converted is selected. If it is determined that the above sum is larger than the threshold value, the input value defined in the first color conversion profile 15b is selected, and the larger one of the two input values sandwiching the color component value to be converted is selected.

  For example, the threshold value corresponding to the color component value 3 is 1, and the constant associated with the color component value 3 by the gradation number conversion profile 15c is 0.375. At this time, two input values defined in the first color conversion profile 15b and having 3 as the color component value to be converted are 0 and 8. If the random number is 0.5, since the constant + random number is 0.875 and is equal to or less than the threshold value 1, the result of converting the color component value 3 is 0. On the other hand, if the random number is 1, the constant + random number is 1.5 and is larger than the threshold 1, so that the result of converting the color component value 3 is 8.

  As described above, in the present embodiment, the color component value in each pixel of the image data is converted to the same value as the input value defined in the first color conversion profile 15b based on the gradation number conversion profile 15c. Thereafter, with reference to the first color conversion profile 15b, an output value associated with the input value is acquired and set as the RGB value of each pixel. That is, an arbitrary color component value in each pixel is converted into one of the input values for each color defined in the first color conversion profile 15b by conversion referring to the gradation number conversion profile 15c. The value combinations correspond to any of the input value combinations defined in the first color conversion profile 15b.

  Therefore, if an output value associated with this combination is acquired, an arbitrary combination of color component values is converted into one of the output value combinations in the first color conversion profile 15b. With the above conversion, color conversion is performed from the sRGB color system to the RGB color system used by the printer 40 without performing any interpolation operation on arbitrary image data. Note that, here, an arbitrary color component value (256 gradations) is converted into one of the determined input values (33 in total). The probability of conversion to an input value close to is increased. Further, by introducing a random number, it is prevented from being converted into a uniform input value. Therefore, conversion can be performed without greatly degrading the gradation. In the present embodiment, the above steps S110 and S115 correspond to the processing of the first color conversion means.

(2-3) Second color conversion process:
As described above, after performing the first color conversion for reducing the number of gradations in step S115, color conversion with reference to the second color conversion profile 15e is performed (step S120). The combination of input values of the second color conversion profile 15e matches the combination of output values in the first color conversion profile 15b, and all the values obtained in step S115 are output in the first color conversion profile 15b. Match the value combination.

  Therefore, at the time of color conversion in step S120, the input value matches the combination of input values in the second color conversion profile 15e. For this reason, it is possible to perform color conversion without performing interpolation calculation only by referring to the second color conversion profile 15e and acquiring a combination of output values corresponding to a combination of input values. As a result, color conversion can be performed very quickly. In the present embodiment, the above step S120 corresponds to the processing by the second color conversion means.

  As described above, when the second color conversion is performed, data specifying the color of the pixel in each color of CMYKlclm is generated for each pixel of the image data acquired in step S100. Therefore, the halftone processing module 21c Performs halftone processing (step S125). That is, the halftone processing module 21c converts the gradation value of each pixel expressed in the CMYKlclm color system into halftone image data that specifies ink ejection / non-ejection in each pixel. That is, ejection / non-ejection of ink droplets is determined for each pixel in the printer 40. Needless to say, not only ink droplet ejection / non-ejection but also the amount of ejected ink can be controlled stepwise to determine the size of the ejected ink droplet.

  Further, the print data generation module 21d receives the halftone image data, rearranges them in the order used by the printer 40 (step S130), and sequentially prints the printer 40 in units of data used in one main scan. (Step S135). That is, in the printer 40, an ejection nozzle row is mounted as an ink ejection device, and a plurality of ejection nozzles are arranged in parallel in the sub-scanning direction in the nozzle row. used.

  Therefore, the data to be used at the same time among the data arranged in the main scanning direction is rearranged in order so that the printer 40 can simultaneously buffer the data. The print data generation module 21d generates print data by adding predetermined information such as image resolution to the rearranged data, and outputs the print data to the printer 40 via the USB I / O 19b. When all the data necessary to form an image is transferred by the printer 40, the image is formed on the print medium by the printer 40. In the present embodiment, the processes in steps S125 to S135 correspond to the print execution unit.

(3) Color conversion processing operation:
FIG. 5 is a diagram showing the color conversion processing operation in the above print control processing. In the figure, a state in which image data to be printed is subjected to a halftone process (H / T) through a first color conversion and a second color conversion, and the color component value of the image data at each stage is shown. Both the number of possible values and the profile to be referred to are shown. As shown in the figure, in the image data acquired in step S100, the RGB color component values can take 256 values independently, so the combinations of values that can be taken for each pixel of the image data are 256. ^Three .

In the case of normal interpolation calculation, one of the 256 ^three values is input, and the calculation with reference to the profile is performed to output one of the 256 ^three values. It is heavy and causes a reduction in processing speed. On the other hand, in the above-described embodiment, the conversion is performed so that an arbitrary color component value is limited to one of the input values in the first color conversion profile 15b with reference to the gradation number conversion profile 15c. Processing can be performed at high speed. That is, for each color component value of each pixel, conversion can be completed simply by calculating the sum of a predetermined constant and a random number and comparing it with a threshold value, and high-speed processing is possible.

In the embodiment shown in FIG. 3, the color component values of the 256 gradations per color to be converted into either 33 gradation value, a combination of values after conversion is 33 ^3. The combination of the 33 ^three values are consistent with a combination of input values of the first color conversion profile 15b ((RGB) ₀ hereinafter). Therefore, only by referring to the value defined in the first color conversion profile 15b, the conversion result of the gradation number conversion profile 15c is expressed as a combination of output values defined in the first color conversion profile 15b ((RGB) ₁ ). ). The above conversion is conversion based on the first color conversion profile (first color conversion), and is conversion with reference to the profile. However, a combination of output values can be acquired without interpolation. Therefore, conversion can be performed at a very high speed.

When the first color conversion is completed, conversion is performed using the second color conversion profile 15e. The combination of output values ((RGB) ₁ ) defined in the first color conversion profile 15b and the second color conversion profile 15e are defined. Since this combination of input values matches, this conversion can be executed only by referring to the output value defined in the second color conversion profile 15e. In this conversion, since the number of combinations of input values is 33 ³ , the number of combinations of output values is also 33 ³ .

In the present embodiment, when the second color conversion profile 15e is created, the interpolation calculation referring to the original color conversion profile 15d is performed. As described above, the interpolation calculation is performed on at most 33 ³ values. Therefore, processing can be performed at high speed as compared with normal color conversion that involves interpolation for several million pixels. Since the interpolation calculation in the present embodiment has only to be performed at least once before color conversion, the speed improvement effect is noticeable when performing color conversion on a plurality of images.

  In the present embodiment, the color conversion with reference to the second color conversion profile 15e is the second color conversion. Therefore, in the present embodiment, the first color conversion based on the first color conversion profile 15b and the second color conversion based on the second color conversion profile 15e (which may be said to be based on the original color conversion profile 15d) The two-stage color conversion is performed. When performing an interpolation operation as in the prior art, it is necessary to perform a two-step interpolation operation for a large number of pixels. However, in the present embodiment, color conversion can be performed without performing any interpolation calculation after performing a small number of interpolation calculations in the previous stage of color conversion, so that high-speed processing can be performed.

  In the present invention, the interpolation calculation is omitted by utilizing the fact that the combination of output values in the first color conversion profile 15b matches the combination of input values in the second color conversion profile 15e. However, as in the present embodiment, even if the combination of the output values of the profiles (the first color conversion profile 15b and the original color conversion profile 15d) prepared in advance does not match the combination of the input values, the above interpolation calculation is performed. If the restructuring process is performed, the two can be matched.

  Therefore, the number of combinations of input values and output values defined in the first color conversion profile 15b and the second color conversion profile 15e is not particularly limited, and the combination of both input values and output values for an arbitrary profile matches. Color conversion can be performed. As a result, it is possible to perform color conversion based on a plurality of profiles at high speed, not limited to a predetermined profile.

(4) Other embodiments:
In the above embodiment, when color conversion is performed based on two profiles, it is only necessary to perform sequential color conversion processing for each pixel without performing an interpolation operation, and other configurations are employed. It is also possible. For example, the color system to be converted using two profiles is not limited to the one described above, and the RGB color system is converted to the L ^* a ^* b ^* color system using the first color conversion profile, and the second color is converted. A configuration may be adopted in which the L ^* a ^* b ^* color system is color-converted to a CMYK color system according to a conversion profile. That is, the color system to which the present invention is applied is not limited, and can be applied to various color systems.

  In the above-described embodiment, the second color conversion profile 15e is created from the original color conversion profile 15d. However, the second color conversion profile 15e is created in advance, and the reconstruction process is performed based on the predetermined primary color conversion profile. May be adopted to create the first color conversion profile 15b. Of course, you may perform a reconstruction process about both. In the reconstruction process, the number of combinations of input values and the number of combinations of output values may be increased or decreased, and it is not essential that the number of combinations before and after reconstruction is constant.

  Furthermore, in the above-described embodiment, the gradation number conversion profile 15c is created in advance. However, before the color conversion is performed, the gradation number conversion profile 15c is created based on the first color conversion profile 15b. May be. According to this processing, it is not necessary to create the gradation number conversion profile 15c in advance, and versatility is enhanced. Of course, the method of determining the constant associated with each color component value in the gradation number conversion profile 15c is not limited to the above-described method.

  For example, in associating an integer constant with a predetermined value as an input value of the first color conversion profile 15b and associating a constant between them with a constant including a decimal point, the constant is linear with respect to a change in the color component value. It is not essential to change, and it may be determined to change nonlinearly. For example, the constant may be defined by a tone curve, and various configurations can be adopted. According to this configuration, it is possible to control the ease with which each color component value is converted when conversion is performed using the gradation number conversion profile 15c. Of course, it is not essential that the input values of the first color conversion profile 15b be selected uniformly from the entire range, and input values selected at unequal intervals may be used.

  Furthermore, the configuration for converting an arbitrary color component value in the image data into one of the input values defined in the first color conversion profile 15b is not limited to the configuration referring to the gradation number conversion profile 15c. For example, a configuration in which halftone processing is performed on image data may be adopted so that the result of the halftone processing is only the input value defined in the first color conversion profile 15b. As a configuration for this, various configurations can be adopted, and various methods such as a multi-value error diffusion process, an average error minimum method, and a multi-value systematic dither method can be adopted.

  Furthermore, since the present invention is applicable to a configuration that performs color conversion based on two profiles, it may be applied when performing color conversion based on a larger number of profiles. At this time, if the combination of the input values and the combination of the output values in at least two profiles match, it is possible to skip the interpolation calculation in the color conversion in these profiles, and to perform the processing at high speed. Is possible.

FIG. 2 is a block diagram illustrating a schematic configuration of a print control apparatus. 6 is a flowchart illustrating print control processing. It is explanatory drawing for demonstrating a profile. It is explanatory drawing for demonstrating a profile. It is a figure which shows a color conversion process operation.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Computer, 15a ... Image data, 15b ... 1st color conversion profile, 15c ... Tone number conversion profile, 15d ... Original color conversion profile, 15e ... 2nd color conversion profile, 21 ... Printer driver, 21a ... Image data acquisition Module, 21b ... Color conversion module, 21b1 ... Interpolation calculation unit, 21c ... Halftone processing module, 21d ... Print data generation module, 40 ... Printer

Claims (8)

The color component value of the image data in which the color of the pixel is specified by the color component value using the first color conversion profile and the second color conversion profile in which the correspondence relationship between the input value and the output value is defined by a plurality of combinations. A color conversion device for converting
The first color conversion profile and the first color conversion profile are generated based on an original color conversion profile created in advance so as to match a plurality of output values in the first color conversion profile with a plurality of input values in the second color conversion profile. Means for creating a color conversion profile of at least one of the two-color conversion profiles;
First color conversion means for converting a color component value of the image data into an output value of the first color conversion profile based on the first color conversion profile after creation of the color conversion profile;
And second color conversion means for converting the output value obtained by the first color conversion means as an input value based on the second color conversion profile after creation of the color conversion profile. Color conversion device. It means for creating at least one of the color conversion profile of the first color conversion profile and the second color conversion profile, the color conversion profile created by interpolation based on the original color conversion profile, the first by the interpolation operation the color conversion apparatus according to claim 1, characterized in that to match the plurality of input values at a plurality of output values and the second color conversion profile in one color conversion profile. The first color conversion means converts an arbitrary color component value into one of input values in the first color conversion profile according to a predetermined gradation number conversion rule, and the input value based on the first color conversion profile. The color conversion apparatus according to claim 1 , wherein the color conversion apparatus converts the color to an output value. The color component value of the image data in which the color of the pixel is specified by the color component value using the first color conversion profile and the second color conversion profile in which the correspondence relationship between the input value and the output value is defined by a plurality of combinations. A color conversion method for converting
The first color conversion profile and the first color conversion profile are generated based on an original color conversion profile created in advance so as to match a plurality of output values in the first color conversion profile with a plurality of input values in the second color conversion profile. Creating a color conversion profile of at least one of the two-color conversion profiles;
A first color conversion step of converting a color component value of the image data into an output value of the first color conversion profile based on the first color conversion profile after the creation of the color conversion profile;
And a second color conversion step of converting the output value obtained in the first color conversion step as an input value and performing conversion based on the second color conversion profile after the color conversion profile is created. Color conversion method. The color component value of the image data in which the color of the pixel is specified by the color component value using the first color conversion profile and the second color conversion profile in which the correspondence relationship between the input value and the output value is defined by a plurality of combinations. A color conversion program that allows a computer to realize the function of converting
The first color conversion profile and the first color conversion profile are generated based on an original color conversion profile created in advance so as to match a plurality of output values in the first color conversion profile with a plurality of input values in the second color conversion profile. A function for creating a color conversion profile of at least one of the two-color conversion profiles;
A first color conversion function for converting a color component value of the image data into an output value of the first color conversion profile based on the first color conversion profile after creation of the color conversion profile;
The output values obtained by the first color conversion function as input values, characterized in that revealed actual and the second color conversion function for performing conversion based on the second color conversion profile after creation of the color conversion profile Color conversion program. The color component value of the image data in which the color of the pixel is specified by the color component value using the first color conversion profile and the second color conversion profile in which the correspondence relationship between the input value and the output value is defined by a plurality of combinations. A print control device that controls the printing device based on the converted data,
The first color conversion profile and the first color conversion profile are generated based on an original color conversion profile created in advance so as to match a plurality of output values in the first color conversion profile with a plurality of input values in the second color conversion profile. Means for creating a color conversion profile of at least one of the two-color conversion profiles;
First color conversion means for converting a color component value of the image data into an output value of the first color conversion profile based on the first color conversion profile after creation of the color conversion profile;
An input value the output value obtained in the first color conversion unit, and a second color conversion means for performing conversion based on the second color conversion profile after creation of the color conversion profile,
Print control apparatus, characterized in that it comprises a means for controlling the printing device based on the data converted by the second color conversion means. The color component value of the image data in which the color of the pixel is specified by the color component value using the first color conversion profile and the second color conversion profile in which the correspondence relationship between the input value and the output value is defined by a plurality of combinations. A printing control method for controlling the printing apparatus based on the converted data,
The first color conversion profile and the first color conversion profile are generated based on an original color conversion profile created in advance so as to match a plurality of output values in the first color conversion profile with a plurality of input values in the second color conversion profile. Creating a color conversion profile of at least one of the two-color conversion profiles;
A first color conversion step of converting a color component value of the image data into an output value of the first color conversion profile based on the first color conversion profile after the creation of the color conversion profile;
A second color conversion step in which the output value obtained in the first color conversion step is used as an input value, and conversion is performed based on the second color conversion profile after creation of the color conversion profile;
And a step of controlling the printing apparatus based on the data after the conversion by the second color conversion step. The color component value of the image data in which the color of the pixel is specified by the color component value using the first color conversion profile and the second color conversion profile in which the correspondence relationship between the input value and the output value is defined by a plurality of combinations. A print control program for causing a computer to realize a function of controlling the printing apparatus based on the converted data,
The first color conversion profile and the first color conversion profile are generated based on an original color conversion profile created in advance so as to match a plurality of output values in the first color conversion profile with a plurality of input values in the second color conversion profile. Creating a color conversion profile of at least one of the two-color conversion profiles;
A first color conversion function for converting a color component value of the image data into an output value of the first color conversion profile based on the first color conversion profile after creation of the color conversion profile;
A second color conversion function that uses the output value obtained by the first color conversion function as an input value and performs conversion based on the second color conversion profile after creation of the color conversion profile;
Print control program for causing the function of controlling the printing apparatus based on the data converted by the second color conversion function actual revealed.

Images