JP2005123976A - Image processing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image processing apparatus which deals with various kinds of color conversion processing to an input chrominance signal composed of four or more color components, and which is configurable with a little memory capacity. <P>SOLUTION: A first color conversion processing part 11 applies color conversion processing for three color components in the input chrominance signal to output the intermediate chrominance signals of three color components, and a second color conversion processing part 12 applies color conversion processing to the intermediate chrominance signals of three color components outputted from the first color conversion processing part 11 to output three color components in an output chrominance signal. On the other hand, a third color conversion processing part 13 applies color conversion processing to color components, except for the three color components inputted to the first color conversion processing part 11, in the input chrominance signals. Color profiles of apparatuses are used to apply conversion processing with the intermediate chrominance signal as an apparatus-independent chrominance signal, and a link color profile is also used for utilization with the intermediate chrominance signal as an apparatus-dependent chrominance signal. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an image processing apparatus that converts an input color signal composed of four or more color components into an output color signal composed of four or more color components.

  In the printing, advertising, and publishing industries, image signals are separated into four or more colors including black, such as C (cyan), M (magenta), Y (yellow), and K (black). It is often handled by. Such a color signal is created assuming a certain printing condition. The assumed printing conditions are variously set on the basis of the color reproduction characteristics of a specific printer or printing machine and output paper, and are color signals depending on the device and paper. For this reason, in general, in order for the client to simulate and reproduce the same image as when printing under the set printing conditions, it was necessary to place an order with a supplier who performs color calibration or color proofing.

  In recent years, techniques have been developed to enable such output image simulation on the client side using a color printer or the like. For example, a technique for creating color conversion parameters called color profiles using dedicated software and performing color conversion simulation using the color profiles has been devised. In this case, since it is necessary to purchase software, prepare a color measurement environment, and expensive measurement equipment, a business practice of designing a color profile and providing it to the user is also occurring. In addition, various products are beginning to be provided with users with device-specific color profiles.

  In general, when a color image input device such as a scanner is used, it is often output as a three-color signal such as R (red), G (green), and B (blue). Color conversion processing to color signals is performed. For the color conversion processing for the three-color signal at this time, for example, a method using a neural network as described in Patent Document 1 or a three-dimensional table as described in Patent Document 2 can be used. .

  Such a three-dimensional table can be used for the color conversion process using four or more color signals as input. The use of the multidimensional table is also described in Patent Document 3, Patent Document 4, and Patent Document 5, for example.

However, when a four-input table is used as described in Patent Documents 3 to 5, there is a problem that the size of the table becomes much larger than that in the case of three inputs. In particular, Patent Document 5 has a 4-input 3-output front-stage table with CMYK as an input and a 4-input 3-output rear-stage table with L ^* a ^* b ^* and K ′ as inputs. Two large four-dimensional tables are provided. For this reason, the amount of data for constructing the table is enormous, which is an obstacle to cost and mounting.

  Further, such a four-input conversion table is used only with fixed processing, and application to various color conversion processing has not been considered.

JP-A-2-241271 Japanese Patent Publication No.58-16180 JP 2002-152543 A JP 2002-330302 A JP 2001-119595 A

  The present invention has been made in view of the above-described circumstances, and provides an image processing apparatus that can cope with various color conversion processes for an input color signal composed of four or more color components and can be configured with a small amount of memory. It is intended to do.

  The present invention is an image processing apparatus that converts an input color signal composed of four or more color components into an output color signal composed of four or more color components, and performs color conversion processing for three color components of the input color signal. First color conversion processing means for outputting an intermediate color signal of three color components, and three of the output color signals by performing color conversion processing on the intermediate color signal of the three color components output from the first color conversion processing means. A second color conversion processing means for outputting a color component; and one or more third color converters that perform color conversion processing on color components other than the three color components input to the first color conversion processing means in the input color signal. It is characterized by comprising the above color conversion processing means.

  When performing color conversion processing in the image processing apparatus having such a configuration, for example, the first color conversion processing unit converts an input color signal in the device-dependent color space into an intermediate color signal in the device-independent color space, and The two color conversion processing means can convert the intermediate color signal in the device-independent color space into the output color signal in the device-dependent color space.

  Alternatively, both the first and second color conversion processing means can be configured to perform conversion processing from the device-dependent color space to the device-dependent color space. In this case, either one of them can be used to output the input color signal as it is without performing the conversion process. For example, when using a link profile in which the color profiles of the input side device and the output side device are combined, the profile of the three color components generated from the link profile is used in either one of the first and second color conversion processing means. The other color conversion process can be performed, and the other can be configured to output the input color signal as it is without performing the conversion process. In this case, the third color conversion processing means may be configured to perform color conversion processing using a color component profile other than the three color components generated from the link profile. Further, either one of the first and second color conversion processing means can perform color conversion processing for preserving the pure color of the input color signal.

  Further, it is possible to perform a predetermined color conversion process on one of the first and second color conversion processing units, and to adjust the adjustment on the other side. It can also be used effectively. The parameters for adjustment can be configured to be settable from the outside.

  Note that the first color conversion processing means and the second color conversion processing means can be configured by a three-dimensional lookup table. By using a look-up table with a dimension smaller than the number of colors, the memory capacity can be reduced. At this time, even if two three-dimensional lookup tables are provided, a smaller amount of memory can be used than when a four-dimensional or more lookup table is provided. At this time, at least the first color conversion processing means can be configured so that conversion parameters can be set from the outside. For example, when considering use in an image forming apparatus or the like, color conversion processing depending on the image forming apparatus is performed by the second color conversion processing means with fixed color conversion parameters, and color conversion corresponding to the input side apparatus is performed. The process and other various conversion processes can be performed by the first color conversion processing unit capable of changing the conversion parameter.

  As a specific example of the input color signal, it can be a color signal composed of four color components including a black component, and the color signals of three color components excluding black are processed by the first and second color conversion processing means. The third color conversion processing means can be configured to process the black component color signal. The third color conversion processing means at this time can be constituted by a one-dimensional lookup table, and can perform conversion processing for storing the black component of the input color signal.

  According to the present invention, the first and second color conversion processing means for processing the three color components of the input color signal composed of four or more color components, and the third color for processing the other color components. Since the conversion processing means is included, the memory capacity can be greatly reduced as compared with the use of a table with the number of color components, and various color conversion processes can be applied to the input color signal. is there.

FIG. 1 is a block diagram showing a first embodiment of the present invention. In the figure, 11 is a first color conversion processing unit, 12 is a second color conversion processing unit, 13 is a third color conversion processing unit, and 14 is an output device. Here, the input color signal input to the first color conversion processing unit 11 and the third color conversion processing unit 13 is a color signal depending on a specific device, and is Ci (cyan), Mi (magenta), Yi ( Yellow) and Ki (black). The output color signals output from the second color conversion processing unit 12 and the third color conversion processing unit 13 are color signals depending on the output device 14, and are Co (cyan), Mo (magenta), and Yo (yellow). ), Ko (black). Furthermore, in this example, the case where the color signal passed from the first color conversion processing unit 11 to the second color conversion processing unit 12 is a device-independent color signal (L ^* a ^* b ^* ) is shown. Am and bm.

  The first color conversion processing unit 11 performs color conversion processing on three color components of the input color signal and outputs an intermediate color signal of the three color components. In this example, Ci, Mi, Yi in the device-dependent input color signal is input, color conversion is performed, and device-independent Lm, am, bm is output. The first color conversion processing unit 11 is configured using, for example, a three-dimensional three-output lookup table with interpolation of three inputs and three outputs. This three-input three-output interpolated three-dimensional lookup table is described in, for example, Patent Document 2.

  The second color conversion processing unit 12 performs color conversion processing on the intermediate color signal of the three color components output from the first color conversion processing unit 11, and outputs the three color components of the output color signal. In this example, device-independent Lm, am, and bm are input, color conversion is performed, and Co, Mo, and Yo in the output color signal depending on the output device 14 are output. The second color conversion processing unit 12 can also use, for example, a three-dimensional three-output lookup table with interpolation of three inputs and three outputs.

  The third color conversion processing unit 13 performs color conversion processing on the color components excluding the three color components input to the first color conversion processing unit 11 from the input color signal. In this example, Ki in the device-dependent input color signal is input, color conversion is performed, and Ko in the output color signal depending on the output device 14 is output. As the third color conversion processing unit 13, for example, a one-dimensional lookup table with interpolation can be used. Here, the third color conversion processing unit 13 is shown as a single unit. However, as the first color conversion processing unit 11 and the second color conversion processing unit 12, it is configured as two units. can do.

  Next, an example of the operation in the first embodiment of the present invention will be described. In the configuration shown in FIG. 1, since the output device 14 is connected, the second color conversion processing unit 12 outputs the output color signal depending on the output device 14 from the device-independent Lm, am, bm as described above. A process of converting into Co, Mo, and Yo is performed. Therefore, the second color conversion processing unit 12 may set the conversion parameter obtained from the profile of the output device 14 in a fixed manner.

  About the 1st color conversion process part 11 and the 3rd color conversion process part 13, the conversion parameter is set beforehand before performing a color conversion process. For example, when the CMY → CMY three-dimensional color profile is given to the first color conversion processing unit 11, the color profile can be used. For example, when a four-dimensional color profile of CMYK → CMYK is given, a parameter for performing CMY → CMY conversion may be calculated from the given four-dimensional color profile.

  In addition to the first color conversion processing unit 11 and the second color conversion processing unit 12, the third color conversion processing unit 13 can be given a parameter for performing one-dimensional conversion, or a color profile can be used. You can also create parameters. In this example, since the output of the third color conversion processing unit 13 is directly passed to the output device 14, the third color conversion processing unit 13 needs to consider the profile of the output device 14.

  Hereinafter, a case where conversion parameters are set in the first color conversion processing unit 11 and the third color conversion processing unit 13 using a color profile will be briefly described. FIG. 2 is an explanatory diagram of an example of a parameter setting process using a color profile. When a four-dimensional color profile corresponding to the input side device is given, a three-dimensional parameter is extracted by extracting, for example, data of K = 0 from the given four-dimensional color profile in S21. In step S <b> 22, the extracted three-dimensional parameter is set in the first color conversion processing unit 11.

  In S23, one-dimensional parameters are extracted by extracting, for example, data of C = M = Y = 0 from the given four-dimensional color profile. In general, since there are few one-dimensional grid points in the color profile, interpolation is performed between ranges (for example, 0 to 255) in S24. The parameters obtained in this way are for conversion into device-independent K values (Lk). Therefore, it is necessary to consider a parameter for converting the device-independent Lk to a K value (Ko) depending on the output device 14. In S25, the parameters for performing the conversion of Ki → Lk obtained in the processes up to S24 and the parameters for performing the conversion of Lk → Ko depending on the characteristics of the output device 14 given in advance are represented in, for example, a one-dimensional table. A one-dimensional parameter for performing the conversion from Ki to Ko is generated by combining by abutting or the like. In S 26, the obtained one-dimensional parameter for performing Ki → Ko conversion is set in the third color conversion processing unit 13.

  FIG. 3 is an explanatory diagram of another example of parameter setting processing using a color profile. In this example, a one-dimensional parameter is given together with a four-dimensional color profile corresponding to the device on the input side. At this time, although the one-dimensional parameter can be set as it is in the third color conversion processing unit 13, an example in which the conversion characteristic of the black component is adjusted using the four-dimensional color profile is shown. Note that the processing of S31 and S32 for setting a three-dimensional parameter in the first color conversion processing unit 11 is the same as the processing of S21 and S22 in FIG.

  In S33, the given one-dimensional parameter is adjusted based on the given four-dimensional color profile. Here, the brightness is adjusted to be preserved. Similar to S25 of FIG. 2 described above, in S34, the adjusted one-dimensional parameter is combined with a parameter for performing Lk → Ko conversion depending on the output device 14, and the combined one-dimensional parameter is added in S35 to the third parameter. The color conversion processing unit 13 is set.

  As shown in FIG. 2 or FIG. 3 described above, parameters to the first color conversion processing unit 11 and the third color conversion processing unit 13 from a given four-dimensional color profile (or one-dimensional parameter) are given. Can be set. Thus, the parameters can be easily set according to the color profile given according to the input color signal.

  FIG. 4 is a flowchart showing an example of color conversion processing in the first embodiment of the present invention. When Ci, Mi, Yi, and Ki signals, which are input color signals depending on the input side device, are input, the Ci, Mi, and Yi signals are input to the first color conversion processing unit 11, and the Ki signal is the first signal. Input to the three-color conversion processing unit 13. In S41, the Ci, Mi, Yi signals are subjected to color conversion processing according to the three-dimensional parameters set as described above by the first color conversion processing unit 11, and are Lm, am, bm which are device-independent color signals. Converted to a signal.

  The Lm, am, and bm signals output from the first color conversion processing unit 11 are input to the second color conversion processing unit 12. In S <b> 42, the second color conversion processing unit 12 converts the input Lm, am, and bm signals into Co color which is an output color signal depending on the output device 14 in accordance with the three-dimensional parameter set corresponding to the output device 14. , Mo, Yo signals. At this time, the Ci, Mi, and Yi signals and the Co, Mo, and Yo signals are in the same color relationship because they pass through the same device-independent color signals that are intermediate signals, that is, Lm, am, and bm signals.

  On the other hand, the Ki signal among the input color signals is a Ko signal that is an output color signal depending on the output device 14 according to the one-dimensional parameter set as described above by the third color conversion processing unit 13 in S43. Is converted to At this time, since the Ki signal and the Ko signal are intermediately connected via the device-independent Lk signal as described above, they have an equal brightness relationship, and K (black) storage can be realized.

  In this way, the color components (Ci, Mi, Yi) excluding black (Ki) in the input color signal are respectively converted into three-dimensional parameters by the first color conversion processing unit 11 and the second color conversion processing unit 12. Conversion processing is performed to obtain output color signals (Co, Mo, Yo) excluding black. In addition, black (Ki) in the input color signal is converted with a one-dimensional parameter by the third color conversion processing unit 13 to obtain black (Ko) in the output color signal. As described above, in the first embodiment, since processing is performed using two three-dimensional parameters and one one-dimensional parameter for a four-dimensional color signal, when using a four-dimensional parameter as in the prior art. Compared to this, the amount of data can be significantly reduced. In addition, the black component can be converted with a one-dimensional parameter, whereby K (black) storage conversion processing can be performed, and simple and highly accurate color conversion can be performed.

  FIG. 5 is a block diagram showing a second embodiment of the present invention. The reference numerals in the figure are the same as those in FIG. In the first embodiment described above, the intermediate color signal output from the first color conversion processing unit 11 and input to the second color conversion processing unit 12 is a device-independent signal. The present invention is not limited to this, and the intermediate color signal may be a device-dependent signal. In particular, the second embodiment is applied when several input devices are assumed in advance.

  As conversion parameters set in advance, a profile from a device-dependent color signal corresponding to the input-side device to a device-independent color signal, and a device-dependent color corresponding to the output device 14 from the device-independent color signal A conversion parameter for converting a device-dependent color signal to a device-dependent color signal is obtained by combining the profile with the signal. Then, the obtained conversion parameter is set in the second color conversion processing unit 12.

  In this example, the processing performed by the first color conversion processing unit 11 and the second color conversion processing unit 12 in the first embodiment described above can be performed only by the second color conversion processing unit 12. Therefore, in such a case, the first color conversion processing unit 11 may output the input color signal as it is without performing processing (through processing).

  Also, when several input side devices are assumed, conversion parameters corresponding to the respective input side devices are created and set in the second color conversion processing unit 12, and the input color signal is converted during color conversion. You may comprise so that a conversion parameter may be selected according to the apparatus of the corresponding input side. The same applies to the third color conversion processing unit 13, and a one-dimensional conversion parameter is created for each of a plurality of input side devices and set in the third color conversion processing unit 13. Along with the selection of the conversion parameter in the unit 12, the third color conversion processing unit 13 may be configured to select a one-dimensional conversion parameter.

  FIG. 6 is a flowchart illustrating an example of color conversion processing according to the second embodiment of the present invention. When Ci, Mi, Yi, and Ki signals, which are input color signals depending on the input side device, are input, the Ci, Mi, and Yi signals are input to the first color conversion processing unit 11, and the Ki signal is the first signal. Input to the three-color conversion processing unit 13. The first color conversion processing unit 11 outputs the Ci, Mi, Yi signals input by the through process in S51 as they are. Ci, Mi, and Yi signals output from the first color conversion processing unit 11 are input to the second color conversion processing unit 12. In S52, the second color conversion processing unit 12 outputs the input Ci, Mi, and Yi signals according to a three-dimensional parameter for performing conversion from a device-dependent color signal to a device-dependent color signal. 14 is converted into a Co, Mo, Yo signal which is an output color signal depending on 14.

  At this time, when a three-dimensional conversion parameter corresponding to a plurality of input devices is set in the second color conversion processing unit 12 in advance, the conversion parameter corresponding to the input device corresponding to the input color signal Select to perform color conversion. In addition, since the conversion parameters used in the second color conversion processing unit 12 are created through device-independent color signals, the Ci, Mi, Yi signals and the Co, Mo, Yo signals have the same color relationship. It becomes. In addition, since the input and output are in the same CMY color space, it is possible to easily realize conversion in which a specific color, for example, a pure color such as Y color, is stored.

  The Ki signal among the input color signals is the same as that in the first embodiment described above. In S53, the third color conversion processing unit 13 converts the Ki signal, which is an output color signal depending on the output device 14, to the Ko signal. Converted. At this time, a conversion process is performed by selecting one-dimensional conversion parameters corresponding to a plurality of devices on the input side. Further, K (black) storage can be realized by using a one-dimensional conversion parameter created via a device-independent Lk signal in the middle.

  Thus, in the second embodiment, the second color conversion processing unit 12 can be used to convert a device-dependent color signal to a device-dependent color signal. When converting to a device-independent color signal as an intermediate color signal as in the first embodiment, it is not easy to perform conversion that preserves a specific color such as a pure color. However, if the input / output is the same color space as in the second embodiment, the conversion process storing the specific color can be easily performed, and the present invention can be used for such a purpose. .

  FIG. 7 is a block diagram showing a third embodiment of the present invention. The reference numerals in the figure are the same as those in FIG. In the second embodiment described above, the first color conversion processing unit 11 is used as a through, and the second color conversion processing unit 12 performs conversion from a device-dependent input color signal to a device-dependent output color signal. However, the present invention is not limited to this, and the first color conversion processing unit 11 may perform conversion from the device-dependent input color signal to the device-dependent output color signal, and the second color conversion processing unit 12 may be through. An example in that case is shown as the third embodiment.

  That is, the first color conversion processing unit 11 converts an input color signal dependent on the input side device into an output color signal dependent on the output device 14 in accordance with a preset conversion parameter. For example, when a link color profile for CMY → CMY conversion corresponding to the input device and the output device 14 is provided, the link color profile is used as the conversion parameter. be able to. When a link color profile for CMYK → CMYK conversion is provided, a three-dimensional conversion parameter is set according to the method described with reference to FIGS. 2 and 3 in the first embodiment, for example. It can be generated and used. When the link color profile is not provided, a three-dimensional conversion parameter obtained by combining the color profile corresponding to the input device and the color profile corresponding to the output device 14 can be used. When combining, it is possible to easily control a specific color such as a pure color.

  The second color conversion processing unit 12 may be set to output the input color signal as it is without performing processing (through processing). The third color conversion processing unit 13 is the same as that in the first embodiment described above. For the conversion parameters set in the third color conversion processing unit 13, for example, when a link color profile for performing CMYK → CMYK conversion is provided, FIG. 2 and FIG. 2 in the first embodiment described above. One-dimensional conversion parameters can be generated and used in accordance with the method described in FIG. Of course, when the K characteristic of the input side and the K characteristic of the output device 14 are given separately, they may be combined and utilized by abutting or the like. In this case, K storage is possible.

  FIG. 8 is a flowchart illustrating an example of color conversion processing according to the third embodiment of the present invention. When Ci, Mi, Yi, and Ki signals, which are input color signals depending on the input side device, are input, the Ci, Mi, and Yi signals are input to the first color conversion processing unit 11, and the Ki signal is the first signal. Input to the three-color conversion processing unit 13. In S61, the first color conversion processing unit 11 uses the preset three-dimensional conversion parameters to convert the Ci, Mi, Yi signals of the input color signals out of the output color signals depending on the output device 14. To Co, Mo, and Yo signals. The converted output color signal is input to the second color conversion processing unit 12. In S62, the second color conversion processing unit 12 outputs the Co, Mo, and Yo signals input by the through process as they are.

  The Ki signal of the input color signals is the same as that of the first embodiment described above. In S63, the third color conversion processing unit 13 converts the Ki signal, which is an output color signal depending on the output device 14, to the Ko signal. Converted.

  FIG. 9 is a block diagram showing a fourth embodiment of the present invention. The reference numerals in the figure are the same as those in FIG. In the above-described second and third embodiments, an example in which the intermediate color signal is a device-dependent color signal has been described. At this time, either the first color conversion processing unit 11 or the second color conversion processing unit 12 is used. Through. The present invention is not limited to such a case, and color conversion processing using both the first color conversion processing unit 11 and the second color conversion processing unit 12 is possible even when the intermediate color signal is a device-dependent signal. .

  As an example in which both the first color conversion processing unit 11 and the second color conversion processing unit 12 perform color conversion processing, in the example illustrated in FIG. 9, the first color conversion processing unit 11 performs various correction processes, The second color conversion processing unit 12 performs conversion processing according to the color profile (or link color profile). As the correction processing performed by the first color conversion processing unit 11, various items such as the paper quality assumed in the input color signal and the color temperature of the illumination light source are corrected to change to the actually used paper quality and color temperature. Processing can be performed.

  If correction processing is also performed for the K component, the correction processing may be included in the one-dimensional conversion parameter set in the third color conversion processing unit 13.

  FIG. 10 is a flowchart illustrating an example of color conversion processing according to the fourth embodiment of the present invention. When Ci, Mi, Yi, and Ki signals, which are input color signals depending on the input side device, are input, the Ci, Mi, and Yi signals are input to the first color conversion processing unit 11, and the Ki signal is the first signal. Input to the three-color conversion processing unit 13. The first color conversion processing unit 11 performs correction processing on the Ci, Mi, Yi signals input in S71, and outputs Cm, Mm, Ym signals as intermediate color signals. The Cm, Mm, and Ym signals output from the first color conversion processing unit 11 are input to the second color conversion processing unit 12. In S72, the second color conversion processing unit 12 outputs the input Cm, Mm, and Ym signals in accordance with a three-dimensional parameter that converts a preset device-dependent color signal into a device-dependent color signal. 14 is converted into a Co, Mo, Yo signal which is an output color signal depending on 14.

  The Ki signal of the input color signals is the same as that of the first embodiment described above. In S73, the third color conversion processing unit 13 converts the Ki signal into an Ko signal that is an output color signal depending on the output device 14. The

  Thus, in the fourth embodiment, the first color conversion processing unit 11 and the second color conversion processing unit 12 are effectively used, and the device-dependent color signal is used by using the second color conversion processing unit 12. Can be converted into a device-dependent color signal, and correction processing that is necessary from time to time can be performed by the first color conversion processing unit 11. In the fourth embodiment, it is assumed that the first color conversion processing unit 11 performs correction processing, and the second color conversion processing unit 12 performs color conversion processing from device-dependent color signals to device-dependent color signals. However, of course, the reverse is also possible.

  FIG. 11 is a block diagram showing a fifth embodiment of the present invention. In the figure, the same parts as those in FIG. Reference numeral 15 denotes a front stage conversion unit, and 16 denotes a rear stage conversion unit. In the fifth embodiment, an example is shown in which the third color conversion processing unit 13 is configured by a front-stage conversion unit 15 and a rear-stage conversion unit 16 based on the first embodiment described above.

  In the first embodiment, for example, when a color profile corresponding to the input device and a color profile corresponding to the output device 14 are given, the third color conversion processing unit 13 is obtained from each color profile. One-dimensional conversion parameters are synthesized and set. In the fifth embodiment, for example, the one-dimensional conversion parameter obtained from the color profile of the output device 14 is fixedly set for the subsequent stage conversion unit 16 and obtained from the color profile corresponding to the input side device. The one-dimensional conversion parameter can be used so as to be set in the pre-stage conversion unit 15 each time.

  Of course, like the first color conversion processing unit 11 and the second color conversion processing unit 12 described in the second and third embodiments, either the front stage conversion unit 15 or the rear stage conversion unit 16 is made through. Can also be used. Further, as described in the fourth embodiment, the correction process may be performed by one of the front-stage conversion unit 15 and the rear-stage conversion unit 16, and the conversion process depending on the apparatus may be performed on the other side. .

  In each of the above-described embodiments, an example in which CMYK signals are used as input color signals and output color signals has been described. However, the present invention is not limited to this, and any color signal having four or more color components may be used. If applicable. For example, in addition to CMYK, a special color can be used, and RGBK can be similarly configured. Further, for example, the case where the input color signal is different from the color component of the output color signal, such as the input color signal is RGBK and the output color signal is CMYK, can be dealt with.

It is a block diagram which shows the 1st Embodiment of this invention. It is explanatory drawing of an example of the parameter setting process using a color profile. It is explanatory drawing of another example of the parameter setting process using a color profile. It is a flowchart which shows an example of the color conversion process in the 1st Embodiment of this invention. It is a block diagram which shows the 2nd Embodiment of this invention. It is a flowchart which shows an example of the color conversion process in the 2nd Embodiment of this invention. It is a block diagram which shows the 3rd Embodiment of this invention. It is a flowchart which shows an example of the color conversion process in the 3rd Embodiment of this invention. It is a block diagram which shows the 4th Embodiment of this invention. It is a flowchart which shows an example of the color conversion process in the 4th Embodiment of this invention. It is a block diagram which shows the 5th Embodiment of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... 1st color conversion process part, 12 ... 2nd color conversion process part, 13 ... 3rd color conversion process part, 14 ... Output device, 15 ... Pre-stage conversion part, 16 ... Back-stage conversion part

Claims (11)

  In an image processing apparatus for converting an input color signal composed of four or more color components into an output color signal composed of four or more color components, a color conversion process is performed on three color components of the input color signal, and an intermediate color of the three color components First color conversion processing means for outputting a signal, and color conversion processing is performed on the intermediate color signal of the three color components output from the first color conversion processing means, and the three color components of the output color signal A second color conversion processing means for outputting a color signal, and one or more third color conversion processes for performing color conversion processing on color components excluding the three color components input to the first color conversion processing means among the input color signals. An image processing apparatus comprising a color conversion processing unit.   The input color signal and the output color signal are color signals in a device-dependent color space, the intermediate color signal is a color signal in a device-independent color space, and the first color conversion processing means is the device-dependent color space. An input color signal is converted into the intermediate color signal in the device-independent color space, and the second color conversion processing unit converts the intermediate color signal in the device-independent color space into the output color signal in the device-dependent color space. The image processing apparatus according to claim 1, wherein:   The image processing apparatus according to claim 1, wherein the input color signal, the intermediate color signal, and the output color signal are color signals in a device-dependent color space.   4. The image processing according to claim 3, wherein either the first color conversion processing unit or the second color conversion processing unit outputs the input color signal as it is without performing the conversion processing. apparatus.   Either the first color conversion processing unit or the second color conversion processing unit uses the profile of the three color components generated from a link profile obtained by combining the color profiles of the input side device and the output side device. The color conversion processing is performed, the other outputs the color signal inputted without performing the conversion processing, and the third color conversion processing means outputs color components other than the three color components generated from the link profile. The image processing apparatus according to claim 3, wherein color conversion processing is performed using the profile of the above.   5. The color conversion process performed by either the first color conversion processing unit or the second color conversion processing unit is a color conversion that preserves a pure color of the input color signal. Alternatively, the image processing apparatus according to claim 5.   The color conversion process performed by either the first color conversion processing unit or the second color conversion processing unit is a conversion process for adjusting the color conversion process performed by the other, and parameters are set from the outside. The image processing apparatus according to claim 3, wherein the image processing apparatus is configured to be possible.   The image according to any one of claims 1 to 7, wherein the first color conversion processing unit and the second color conversion processing unit are configured by a three-dimensional lookup table. Processing equipment.   9. The image processing apparatus according to claim 1, wherein the first color conversion processing unit is configured to be able to set a conversion parameter from the outside.   The input color signal is a color signal composed of four color components including a black component, the color signals of three color components excluding black are input to the first color conversion processing means, and the color signal of the black component is the third color signal. The image processing apparatus according to claim 1, wherein the image processing apparatus inputs the color conversion processing means.   The image processing apparatus according to claim 10, wherein the third color conversion processing unit includes a one-dimensional lookup table, and performs conversion processing for storing a black component of the input color signal.

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