JP2020078066A - Information processing device, information processing method, and program - Google Patents

Abstract

To provide an information processing device capable of efficiently generating highly accurate device characteristics.SOLUTION: The information processing device includes: acquisition means for acquiring a measurement value corresponding to each of a plurality of colors obtained by measuring a color using a colorimeter of each of color patches in a color chart formed by arranging color patches corresponding to a plurality of colors output by an output device; display control means for displaying on a display unit an image for accepting an instruction of re-color measurement based on the acquired measurements; re-colorimetry control means for executing re-colorimetry using the colorimeter when the instruction for re-color measurement is accepted; and generation means for generating device characteristics of the output device based on the measured value of at least a part of the acquired measured value and the measured value obtained by the re-colorimetry.SELECTED DRAWING: Figure 5

Description

  The present invention relates to information processing for generating device characteristics from color measurement data of a color chart.

  In order to confirm whether the color reproduction characteristic of the output device is sufficient, it is necessary to acquire the color reproduction characteristic of the output device. In order to acquire the color reproduction characteristic of the output device, for example, the color patch of the color chart displayed or output by the output device is measured (color measurement). The color chart is composed of color patches of RGB data (729 colors), which is sliced into 9 slices (divided into 9 gradations) in the range of 0 ≦ R, G, B ≦ 255. When measuring color patches of a color chart, for example, a two-dimensional measuring device is used to measure a color chart including a plurality of color patches at once. When measuring a color patch of a printer color chart, a plurality of types of color charts may be measured. The color reproduction characteristics of the output device are called device characteristics.

The measurement data in the color patch measurement of such a color chart is affected by the in-plane unevenness of the output device and the change over time of the output device. In order to obtain accurate output device characteristics, it is necessary to eliminate the effects of in-plane unevenness of the output device and changes with time of the output device. The in-plane unevenness is color unevenness of the color output by the output device (for example, uneven density on the same paper surface).
Patent Document 1 discloses an apparatus that reduces the influence of color unevenness when creating a printer profile (device characteristic). In Patent Document 1, first, a color chart printed matter in which a plurality of color charts including a color patch for profile creation and a color patch for confirming color unevenness are arranged is produced. Then, the color chart including the color irregularity confirmation color patch having a large color difference from the other color irregularity confirmation color patches is determined to be the color chart including the abnormal color patch. After that, the color chart including the abnormal color patch is eliminated, and the remaining color chart is used to create the printer profile.

JP, 2013-42418, A

However, in Patent Document 1, since the entire color chart including an abnormal color patch is excluded, non-abnormal color patches included in the excluded color chart are also excluded. Therefore, even color patches that are originally effective for acquiring device characteristics (color patches that are not abnormal) are excluded. Further, in Patent Document 1, an abnormal color patch is detected based on the determination of color unevenness by the color unevenness confirmation patch, and therefore the color unevenness confirmation color patch needs to be created separately from the profile creation color patch. is there.
The present invention has been made in view of the above points, and an object thereof is to provide information processing capable of more efficiently generating highly accurate device characteristics.

  An information processing apparatus according to an aspect of the present invention measures a color of each of the color patches in a color chart formed by arranging color patches corresponding to a plurality of colors output by an output device using a colorimeter. Display control for displaying on a display unit an image acquisition unit for acquiring a measurement value corresponding to each of the plurality of colors, and an image for receiving an instruction for re-colorimetry based on the acquired measurement value. Means, when receiving the instruction of the re-color measurement, re-color measurement control means for executing re-color measurement using the colorimeter, at least a part of the measured values obtained, Generating means for generating device characteristics of the output device based on the measurement value obtained by the re-color measurement.

  According to the present invention, highly accurate device characteristics can be generated more efficiently.

FIG. 3 is a block diagram showing the configuration of the information processing apparatus of the first embodiment. 3 is a functional block diagram of the information processing apparatus of the first embodiment. FIG. It is a figure which shows the correspondence table of a patch number and RGB value. It is a figure which shows the structure of the color patch of a color chart. 6 is a flowchart showing a flow of processing of the first embodiment. It is a figure which shows an example of the message which the patch characteristic exclusion result display part displays. FIG. 6 is a block diagram showing the configuration of an information processing device according to a second embodiment. 9 is a flowchart showing a flow of processing according to the second embodiment. It is a figure which shows the other example of the message which the patch characteristic exclusion result display part displays. It is a figure which shows an example of the color chart which a chart re-creation part produces.

  Hereinafter, preferred embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings. The embodiment described below is an example as a means for realizing the present invention, and should be appropriately modified or changed depending on the configuration of the device to which the present invention is applied and various conditions. It is not limited to the embodiment.

Embodiment 1
The information processing apparatus according to this embodiment is an apparatus that generates the color reproduction characteristics of an output device. In the following description, the color reproduction characteristic of the output device is referred to as device characteristic.
The configuration of the information processing apparatus according to the first embodiment will be described with reference to the block diagram shown in FIG. The information processing apparatus according to the first embodiment includes a CPU 101, a ROM 102, a RAM 103, an operation unit 104, an image processing unit 105, a monitor 106, an input device 107, an output device 108, and a measuring instrument 109. .. The above components of the information processing device are interconnected by a bus 110.
The ROM 102 stores software (computer programs) such as an operating system, an information processing application program, and device drivers necessary for the information processing device.

The CPU 101 controls the RAM 103, the operation unit 104, the image processing unit 105, the monitor 106, the input device 107, and the output device 108 according to the operating system stored in the ROM 102.
The RAM 103 functions as a work area and a temporary save area for data handled by various control programs and data input from the operation unit 104.
The operation unit 104 inputs data to the input device 107, the output device 108 and the like. The data input is performed, for example, by the user of the information processing device. In addition, the operation unit 104 receives, for example, from a user, an instruction to activate the information processing application program stored in the ROM 102 or the image processing unit 105.

The image processing unit 105 includes an HDD and executes arithmetic processing for performing image processing in this embodiment. The image processing unit 105 also stores software necessary for this arithmetic processing. The image processing unit 105 also has a function as an image processing device in this embodiment.
The monitor 106 displays the processing result of the image processing unit 105, the data input by the operation unit 104, and the like. The processing result and the like displayed on the monitor 106 can be displayed in a state in which the user can operate. That is, the monitor 106 can function as a user interface. The monitor 106 is, for example, a liquid crystal display device.
In the present embodiment, the output device 108 is a printer that outputs (prints) an image. The measuring device 109 measures the Lab value of the color patch output by the output device 108. The measuring instrument 109 has, for example, a spectral radiance meter. When the measuring device 109 measures the Lab value of the color patch in advance, or when the Lab value of the color patch is provided to the information processing apparatus from outside the information processing apparatus, the measurement value is stored in the image processing unit 105 ( Stored).

In the following description, various processes realized by the CPU 101 operating various software stored in the ROM 102 and the image processing unit 105 will be described.
First, the CPU 101 activates an information processing application stored in the ROM 102 or the image processing unit 105 according to a user's instruction to the operation unit 104. Then, the CPU 101 can load the information processing application on the RAM 103 and display the items required by the user (for example, an error message described later) in the loaded contents on the monitor 106. The CPU 101 functions as a display control unit that causes the monitor 106 to display predetermined items and the like. When displaying the expanded content of the information processing application on the monitor 106, the monitor 106 functions as a user interface as described above. Subsequently, various data stored in the image processing unit 105 is transferred to the RAM 103 based on a command from the CPU 101. Predetermined arithmetic processing is performed on various data transferred to the RAM 103 according to a command from the CPU 101. Then, the result of the arithmetic processing is displayed on the monitor 106 or stored in the image processing unit 105.

Next, in the information processing apparatus having the above configuration, a process in which the information processing application generates the device characteristic of the output device 108 based on a command from the CPU 101 will be described.
FIG. 2 is a functional block diagram of the information processing apparatus of this embodiment. The information processing apparatus includes a patch measurement value acquisition unit 201, a patch abnormal value detection unit 202, a patch abnormal value exclusion unit 203, a patch average value calculation unit 204, a device characteristic generation unit 205, and a patch abnormal value exclusion result display. And a section 206. The measured value of the color patch is a Lab value. Here, the Lab value is a value using, for example, CIE (Commission internationale de l'eclairage: International Lighting Commission) L * a * b * coordinates.

In FIG. 2, the patch measurement value acquisition unit 201 acquires the measurement value of the color patch from the image processing unit 105 or the measuring device 109. Since the measurement value of the color patch can be referred to as the patch characteristic, the patch measurement value acquisition unit 201 can also be referred to as the patch characteristic acquisition unit.
The patch abnormal value detection unit 202 detects whether the patch measured value is an abnormal value by determining whether the patch measured value is an abnormal value. The abnormal patch value exclusion unit 203 excludes the abnormal value detected by the abnormal patch value detection unit 202.
The patch abnormal value exclusion result display unit 206 determines whether or not there is a predetermined number of patch measurement values remaining after the abnormal value of the patch measurement value is excluded, and then displays the patch abnormal value exclusion result as a message. If the patch measurement value is less than the predetermined number, it is considered that the patch measurement accuracy is insufficient. Therefore, the patch abnormal value exclusion result display unit 206 displays, for example, a message saying "the patch measurement accuracy is out of the guaranteed range". Is displayed. This message is an error message and is displayed on monitor 106 (FIG. 1).

The patch average value calculation unit 204 calculates an average value (patch average measurement value) of the patch measurement values remaining after excluding the patch measurement values having an abnormal value for each same color.
The device characteristic generation unit 205 generates the device characteristic of the output device 108 by storing the patch average measurement value of each color in a predetermined format. For example, a column for L value, a column for a value, and a column for b value are provided on the right side of the column “B” in FIG. 3 described later. Then, the device characteristic generation unit 205 stores the patch average measurement value of the Lab value calculated by the patch average value calculation unit 204 in the L value, a value, and b value fields. The reason why the patch average measurement value is used is to cancel or suppress the small fluctuation (variation between patch measurement values) of the patch measurement value due to the output device 108.

As described above, the output device 108 of this embodiment is a printer. In the following description, a case will be described in which the measured values of the arrayed color patches included in each of the five color charts output by the printer are averaged to generate the color characteristics (device characteristics) of the printer.
In the present embodiment, in order to exclude the in-plane unevenness of the output device (printer) 108 and the influence of the change over time to acquire the device characteristics, among the measured values of the color patch of the same color output a plurality of times (five times). , Exclude patch measurements that differ significantly from other color patches. Then, the average value of the patch measurement values other than the excluded patch measurement values is calculated. Excluding patch measurements that have values that are significantly different from other color patches reduces (or eliminates) the effects of large variations such as in-plane unevenness of the output device 108. Outputting five times means printing five color charts with a printer.

  In this embodiment, the five color charts are color charts A, B, C, D, and E. Each of the color charts A to E includes a plurality of color patches in which RGB data (729 colors) arranged in 9 slices in the range of 0 ≦ R, G, B ≦ 255 are arranged in each color chart. FIG. 3 shows the correspondence between patch numbers and RGB values of color patches. The patch number is No. 1-No. 729. Also, each of the RGB values is 0 to 255.

  The five color charts A to E differ in the arrangement (patch configuration) of color patches on the color chart. FIG. 4 shows the arrangement of the color patches of the color charts A to E in this embodiment. The numbers given to the color patches in each of the color charts A to E are patch numbers. In each color chart, 729 color patches are arranged in a predetermined order. Specifically, in the color chart A, the patch number No. Patch number No. from top left to bottom right in order from 1. Up to 729, 729 color patches are arranged. In the color chart B, the patch number No. 151 in order from the upper left to the lower right, the patch number No. Up to 150 patches are arranged. In the color chart C, the patch number No. No. 301 in order from the upper left to the lower right. Up to 300 patches are arranged. In the color chart D, patch numbers No. 451 are arranged in order from the upper left to the lower right in order from the patch number 451. Up to 450 color patches are arranged. In the color chart E, the patch number No. 601 in order from the upper left to the lower right, the patch number No. Up to 600 color patches are arranged.

Color patches having the same patch number in the five color charts A to E are color patches of the same color. As shown in FIG. 4, the positions where the color patches of the same number appear are different in the color charts A to E.
The processing executed by the information processing apparatus shown in FIG. 2 will be described below with reference to the flowchart of FIG.

In S501, the patch measurement value acquisition unit 201 acquires the patch measurement values (Lab values) of the color charts A to E. The Lab value of the color chart A is ( _LAi , _aAi , _bAi ), the Lab value of the color chart B is ( _LBi , _aBi , _bBi ), and the Lab value of the color chart C is ( _LCi). , A _Ci , b _Ci ). The Lab value of the color chart D is (L _Di , a _Di , b _Di ), and the Lab value of the color chart E is (L _Ei , a _Ei , b _Ei ). Here, i is 1 ≦ i ≦ 729, which is the same as the number of the patch number.
When the image processing unit 105 already holds the Lab values of the color charts A to E, the patch measurement value acquisition unit 201 may acquire the Lab values from the image processing unit 105. Otherwise, the patch measurement value acquisition unit 201 directly acquires the Lab value from the measuring device 109.

In S502, the patch abnormal value detection unit 202 first performs preprocessing before detecting a patch abnormal value. As preprocessing, an average value (L _avei , a _avei , b _avei ) (1 ≦ i ≦ 729) of patch measurement values of the same color in the color charts A to E, that is, the same patch number is calculated by Expression 1. In Expression 1, i is a patch number.
L _avei = (L _Ai + L _Bi + L _Ci + L _Di + L _Ei ) / 5
a _avei = (a _Ai + a _Bi + a _Ci + a _Di + a _Ei ) / 5
b _avei = (b _Ai + b _Bi + b _Ci + b _Di + b _Ei ) / 5 (Equation 1)
In step S <b> 503, the patch abnormal value detection unit 202 detects a patch measurement value that is considered to be affected by the change over time of the output device (printer) or the in-plane unevenness as an abnormal value. Specifically, the patch abnormal value detection unit 202 calculates the average value (L _avei ) calculated in S502 among the patch measurement values (L _Ai , a _Ai , b _Ai ) to (L _Ei , a _Ei , b _Ei ). , A _avei , b _avei ), a patch measurement value having a large color difference ΔE with respect to each other is detected as an abnormal value. In this embodiment, when the color difference ΔE is equal to or larger than the threshold value ΔEt, it is determined that the color difference ΔE is large. That is, it is assumed that the patch measurement value is an abnormal value when the color difference ΔE is equal to or larger than the threshold value ΔEt. Further, in the present embodiment, the threshold value ΔEt is assumed to be one value that does not depend on the color of the color patch. The threshold ΔEt can be referred to as a predetermined value.

_{First, (L Ai, a Ai,} b Ai) ~ for each _{(L Ei, a Ei, b} Ei) (1 ≦ i ≦ 729), (L avei, a avei, b avei) color difference Delta] E _Ai ~ with ΔE _Ei is calculated by the following formula.
ΔE _Ai = ((L _Ai −L _avei ) ² + (a _Ai −a _avei ) ² + (b _Ai −b _avei ) ² ) ^1/2
ΔE _Bi = ((L _Bi −L _avei ) ² + (a _Bi −a _avei ) ² + (b _Bi −b _avei ) ² ) ^1/2
ΔE _Ci = ((L _Ci −L _avei ) ² + (a _Ci −a _avei ) ² + (b _Ci −b _avei ) ² ) ^1/2
ΔE _Di = ((L _Di −L _avei ) ² + (a _Di −a _avei ) ² + (b _Di −b _avei ) ² ) ^1/2
ΔE _Ei = ((L _Ei −L _avei ) ² + (a _Ei −a _avei ) ² + (b _Ei −b _avei ) ² ) ^1/2
(Formula 2)

Next, ΔE _Ai , ΔE _Bi , ΔE _Ci , ΔE _Di , and ΔE _Ei are compared with ΔEt, and the patch measurement value satisfying ΔE _Xi > ΔEt (X = A to E, 1 ≦ i ≦ 729) is set as an abnormal value. .. The patch measurement value detected as an abnormal value here is a value that is affected by the in-plane unevenness of the printer or the change over time, and is not used for generating device characteristics described later.
In S504, the patch abnormal value excluding unit 203 sets a flag f _Xi (X = A to E, 1 ≦ i ≦ 729) indicating whether or not each patch measurement value is an abnormal value. The value of the flag of the patch measurement value determined to be an abnormal value in S503 is set to 0, and the value of the flag of the patch measurement value other than that is set to 1.

  In S505, the patch abnormal value exclusion result display unit 206 determines whether or not there are a predetermined number or more of patch measurement values for each color. In the present embodiment, the device characteristic is generated by calculating the average value of the patch measurement values in order to cancel or suppress the variation between the patch measurement values due to the output device. However, if the number of patch measurement values is less than the predetermined number, it may not be possible to cancel or suppress the variation between the patch measurement values. That is, if the number of patch measurement values becomes smaller than a predetermined number as a result of excluding the patch abnormal value in S504, it may not be possible to cancel or suppress the variation between the patch measurement values. Therefore, in S505, it is determined whether the number of patch measurement values for each color is equal to or larger than a predetermined number.

For each patch number i, the patch abnormal value exclusion result display unit 206 determines whether or not there is the number of patches required to cancel or suppress the variation in the patch measurement value by the following equation.
Σ (f _Xi ) <N (X = A to E) (Formula 3)
Here, N is the number of patches assumed to be necessary to cancel the variation in patch measurement values. When Expression 3 is satisfied, the number of patch measurement values is less than the predetermined number. In this embodiment, the value of N is 4. That is, in the present embodiment, the device characteristics are generated by using the patch measurement values (four or more patch measurement values) of four or more color charts of the five color charts A to E.

The patch abnormal value exclusion result display unit 206 performs the determination by Expression 3 for all patch numbers i, and if there is a patch number i that satisfies Σ (f _Xi ) <N, holds (stores) the patch number i. If there is a patch number i that satisfies Σ (f _Xi ) <N, the determination in S505 is No, so the process proceeds to S506. If there is no patch number i that satisfies Σ (f _Xi ) <N, the determination in S505 is Yes, and the process proceeds to S507.

In step S506, the patch abnormal value exclusion result display unit 206 displays a message regarding the patch abnormal value exclusion result. For example, as shown in FIG. 6, the patch abnormal value exclusion result display unit 206 displays a table 601 of patch numbers i _satisfying Σ (f _Xi ) <N held in S505 and RGB information corresponding to the patch numbers i. Is displayed. Further, the patch abnormal value exclusion result display unit 206 displays a message indicating that the calculation accuracy of the patch measurement value is out of the guaranteed range. The patch abnormal value exclusion result display unit 206 also displays an OK button 602 below the table 601. When the user of the printer confirms the message in FIG. 6, the user presses the OK button 602. When the OK button 602 is pressed, the patch abnormal value exclusion result display unit 206 erases the display contents (the message in FIG. 6, the table 601 and the OK button 602).
It progresses to S507 after S506. That is, in the present embodiment, whether the determination in S505 is Yes or No, the process reaches S507.

In step S <b> 507, the patch average value calculation unit 204 obtains the patch average measurement value of each color by Expression 4. Specifically, the patch average value calculation unit 204 calculates the patch average measurement value of each color by averaging the measurement values of the color patches of the same color, excluding the color patches excluded by the patch abnormal value exclusion unit 203. ..
L _i = Σ (L _Xi * f _Xi ) / Σ (f _Xi )
a _i = Σ (a _Xi * f _Xi ) / Σ (f _Xi )
b _i = Σ (b _Xi * f _Xi ) / Σ (f _Xi )
(X = A to E, 1 ≦ i ≦ 729) (Formula 4)
In step S <b> 508, the device characteristic generation unit 205 stores the patch average measurement value (L _i , a _i , b _i ) (1 ≦ i ≦ 729) as a device characteristic (printer characteristic) in the image processing unit 105 in a predetermined format. The device characteristics are generated, and the flow chart of FIG. 5 ends.

  As described above, in the present embodiment, among the measurement values of the color patch of the same color output a plurality of times (five times), the patch measurement value having a value (abnormal value) greatly different from other color patches is excluded and left. Calculate the average of the patch measurement values of. In other words, the measured value of the color patch affected by the in-plane unevenness of the printer or the change over time is considered to have a value that is significantly different from other color patches, and is affected by the in-plane unevenness of the printer. Exclude color patches from device characteristic generation. Then, the color characteristic (printer characteristic) of the printer is acquired and generated by using the measured value of the color patch that is not affected by the in-plane unevenness of the printer. In the present embodiment, only patch measurement values having abnormal values are excluded. That is, the entire color chart including the patch measurement value having an abnormal value is not excluded. Therefore, the color characteristics of the printer (output device) can be generated without excluding the patch measurement values that are not affected by the in-plane unevenness of the output device or the change over time. In the present embodiment, it can be said that abnormal color patches are efficiently excluded. Further, in the present embodiment, when detecting the color patch affected by the in-plane unevenness, the color patch for confirming the in-plane unevenness is not used.

In this embodiment, by averaging the measured values of the color patches, the influence of small fluctuations such as continuous output is suppressed (or eliminated). In other words, although the patch measurement values are not so different as to be determined as an abnormal value, but the patch measurement values having a certain difference are used, the accuracy of the patch measurement values is increased by adopting the average value of the patch measurement values.
Further, in the present embodiment, when the number of measured values after excluding the patch measured value having the abnormal value is less than the predetermined number, the reliability of the above-mentioned average value is low (the measurement accuracy is out of the guaranteed range). I am thinking that, and displaying an error message to the user. The user who sees the error message can recognize that the average value of the measured values of the color patch is calculated by using the measured value less than the predetermined number.

Although the output device 108 is the printer in the above-described embodiment, the output device 108 is not limited to the printer. For example, the output device 108 may be a display device. Since the display device does not print the color charts A to E, the color charts A to E are displayed on the display of the display device, patch measurement values are acquired, abnormal values are detected and excluded, and device characteristics are generated.
In the above-described embodiment, the color difference ΔE used when detecting an abnormal value from the patch measurement values is a unique value (fixed value) regardless of the color of the color patch, but for each color of the color patch The color difference ΔE may be changed. Furthermore, the color difference used when detecting an abnormal value is not limited to ΔE, and ΔL, Δa, and Δb may be used. The color difference ΔL in this case is (L _Ai −L _avei ).

In the above-described embodiment, the patch measurement value is the Lab value, but XYZ value, RGB value, or the like may be used. Further, although N in Expression 3 is set to 4, it may be a value other than 4 (for example, 3 or 5).
For color patches of which the number of patch measurement values is less than a predetermined number, patch average measurement values may be calculated by using (instead of) patch measurement values in the vicinity of the patch. For example, in the state after the color patch having the abnormal value is excluded, the patch number No. When the number of patches of 2 is 3, the patch number No. of the color chart A is 2. The measured value of the patch No. 3 is the patch number No. It may be used as the measurement value of the second patch. That is, the patch average value calculation unit 204 removes the color patches having the abnormal value from the color chart, and as a result, for the colors whose number of color patches is less than the predetermined number, the measured values of the color patches close to the color patch are also measured. The average measured value may be calculated using the above.

Embodiment 2
In the first embodiment, as a result of excluding the patch measurement values that are abnormal values, if there are colors whose patch measurement values do not reach a predetermined number, a message indicating that the patch measurement accuracy is out of the guaranteed range is displayed, Even if the patch measurement value was less than the predetermined number, the patch average measurement value was calculated. The present invention is not limited to such an embodiment. For example, as a result of excluding abnormal patch measurement values, if there is a color with less than a predetermined number of patch measurement values, generate a color chart composed of color patches of that color and re-output the color chart. The patch average measurement value may be calculated using the result of the remeasurement. Such an information processing apparatus will be described below as a second embodiment.

An information processing apparatus according to the second embodiment will be described with reference to FIGS. 1 and 7 to 10. The configuration of the information processing device of the second embodiment is the same as the configuration of the information processing device of the first embodiment shown in FIG. Also in the second embodiment, the output device 108 is assumed to be a printer. In the following description, differences from the first embodiment will be described. About the same component as Embodiment 1, the same reference numeral as Embodiment 1 is used.
FIG. 7 is a functional block diagram of the information processing apparatus according to the second embodiment. The difference from the first embodiment (FIG. 2) is that the information processing apparatus of the second embodiment includes a chart recreating unit 701. The chart recreating unit 701 creates a color chart composed of color patches of which the number of patch measurement values is less than a predetermined number. The same parts as those in FIG. 2 are designated by the same reference numerals and the description thereof will be omitted.

Next, the processing executed by the information processing apparatus shown in FIG. 7 will be described using the flowchart of FIG. Each of S801 to S805 executes the same processing as S501 to S505 of FIG. 5 used in the description of the first embodiment.
If the determination in S805 is No, the process proceeds to S806. In S806, the patch abnormal value exclusion result display unit 206 displays a message about the patch exclusion result. Specifically, the patch abnormal value exclusion result display unit 206 displays a message regarding a color patch of a color in which the number of patch measurement values is less than a predetermined number. That is, the patch abnormal value exclusion result display unit 206 displays a message regarding the color patch with the patch number i that satisfies Σ (f _Xi ) <N in S805. In the present embodiment, the patch number i satisfying Σ (f _Xi ) <N in S805 is No. 28, No. 91, No. 163 and No. 163. It is 649.

FIG. 9 shows an example of the message displayed by the patch abnormal value exclusion result display unit 206. In the example of FIG. 9, the patch abnormal value exclusion result display unit 206 displays the patch number i that holds Σ (f _Xi ) <N held in step S805 and the table 901 that displays the RGB information corresponding to the patch number i. , Display a message recommending re-output and re-measurement of color patch. The patch abnormal value exclusion result display unit 206 also displays a “Yes” button 902 and a “No” button 903. The message in FIG. 9 may include a message indicating that the patch measurement accuracy is out of the guaranteed range, like the message shown in FIG.

In step S807, the chart recreating unit 701 determines whether to re-output the color patch. Specifically, the chart recreating unit 701 determines whether or not the “No” button 903 displayed together with the message in FIG. 9 has been selected by the user. When the “No” button 903 is selected by the user (S807: No), the process proceeds to S810, and the same processes as S507 and S508 of the first embodiment are executed in S810 and S811. When the user selects the “Yes” button 902 of FIG. 9 (S807: Yes), the process proceeds to S808.
In step S < _b > 808, the chart recreating unit 701 creates the color chart composed of the color patch with the patch number i satisfying Σ (f _Xi ) <N held in step S < _b > 805, and outputs it from the printer that is the output device 108. FIG. 10 shows an example of the color chart 1000 created in S808. As shown in FIG. 10, in this embodiment, five color patches (P, Q, R, S, T) having the same patch number are arranged in a horizontal row. The number (5) of the color patches is M.

In S809, the measured value of the color patch of the color chart created in S808 is acquired. The measurement value of the color patch may be acquired from the image processing unit 105 or directly from the measuring device 109, as in S801. The patch number is No. 28, No. 91, No. 163, No. The measured values of the color patch of 649 are (L _Pj , a _Pj , b _Pj ), (L _Qj , a _Qj , b _Qj ), (L _Rj , a _Rj , b _Rj ), (L _Sj , a _Sj , b). _Sj ), (L _Tj , a _Tj , b _Tj ). Here, j = 28, 91, 163, 649.
In step S810, the patch average value calculation unit 204 averages the measurement values of the color patches of the same color to calculate the average measurement value of each color. The process of S810 is executed when the determination of S805 is Yes, when the determination of S805 is No and the determination of S807 is No, and when the determination of S805 is No and the determination of S807 is Yes. In the present embodiment, the process of S810 executed when the determination of S805 is Yes and the process of S810 executed when the determination of S805 is No and the determination of S807 is No. This process is different from the process executed when the determination in S805 is No and the determination in S807 is Yes. First, the process of S810 executed when the determination of S805 is Yes will be described.

For the color patch having the patch number that satisfies Σ (f _Xi ) ≧ N in S805 (that is, when the determination in S805 is Yes), the patch average measurement value is calculated by the following equation, as in the first embodiment.
L _i = Σ (L _Xi * f _Xi ) / Σ (f _Xi )
a _i = Σ (a _Xi * f _Xi ) / Σ (f _Xi )
b _i = Σ (b _Xi * f _Xi ) / Σ (f _Xi )
(X = A to E, 1 ≦ i ≦ 729 and i ≠ 28, 91, 163, 649) (Equation 5)
On the other hand, when the determination in S805 is No and the determination in S807 is Yes (that is, Σ (f _Xi ) <N in S805 and the patch measurement value is newly acquired in S809), the patch average measurement value is , Calculated by the following formula.
L _j = Σ (L _Xj * f _Xj ) / M
a _j = Σ (a _Xj * f _Xj ) / M
b _j = Σ (b _Xj * f _Xj ) / M
(X = P to T, j = 28, 91, 163, 649) (Equation 6)

In step S811, the device characteristic generation unit 205 stores the patch average measurement values (L _i , a _i , b _i ) (1 ≦ i ≦ 729) calculated by the patch average value calculation unit 204 as a device characteristic in a predetermined form. By doing so, the device characteristics are generated, and the flow chart of FIG. 8 ends.
As described above, in the second embodiment, among the measurement values of the color patch of the same color output a plurality of times, the patch measurement value having a value significantly different from other color patches is excluded (S804). As a result, if there is a color whose patch measurement value does not reach the predetermined number (S805: No), a color chart composed of color patches of the color can be regenerated as necessary (S807). .. Then, the color chart is re-output (S808) and re-measured (S809) so that the patch average measurement value can be calculated (S810).

Also in the second embodiment, when acquiring (generating) the device characteristics, only the patch measurement value having the abnormal value is excluded. That is, the entire color chart including the patch measurement value having an abnormal value is not excluded. Therefore, it is possible to generate the color characteristic of the output device without excluding the patch measurement value that is not affected by the in-plane unevenness of the output device or the change over time. Also in this embodiment, it can be said that abnormal color patches are efficiently excluded.
Note that the patch average measurement values were calculated in S809 using all the patch measurement values included in the color chart recreated in S808. However, for these patch measurement values, the abnormal value of the abnormal values performed in S803 and S804 is calculated. Detection and exclusion may be performed. Further, in FIG. 10, five color patches having the same patch number are arranged (P, Q, R, S, T), but the number M of arranged color patches is not limited to five.

Modified Embodiment In the first embodiment, the patch abnormal value exclusion result display unit 206 displays the patch exclusion result message (S506) only when the determination in S505 is No in the flowchart of FIG. 5, but the determination in S505 The message may be displayed even when is Yes. The message displayed by the patch abnormal value exclusion result display unit 206 when the determination in S505 is Yes is not an error message but a message indicating to the user that the number of patch measurement values is not insufficient. Similarly, a message may be displayed when the determination in S805 of the second embodiment is Yes.

The message in FIG. 6 is not limited to “the color in the table below is out of the guaranteed range of color patch measurement accuracy”. For example, the message in FIG. 6 may be “Re-output and re-measurement of color patch is recommended for the colors in the table below”.
The present invention supplies a recording medium recording a program code of software that realizes the functions of the above-described embodiments (for example, the steps shown by the above-described flowchart) to a system connected to the information processing apparatus or the information processing apparatus. It can also be realized by In this case, the computer (CPU, MPU, or the like) of the system or the information processing device reads out and executes the program code stored in the recording medium so that the computer can read the functions of the above-described embodiments. Further, the program may be executed by one computer, or may be executed by interlocking a plurality of computers.

  108 ... Output device, 201 ... Patch measurement value acquisition unit, 202 ... Patch abnormal value detection unit, 203 ... Patch abnormal value exclusion unit, 204 ... Patch average value calculation unit, 206 ... Patch abnormal value exclusion result display unit, A to E … Color chart

Claims (10)

Corresponding to each of the plurality of colors obtained by measuring color of each of the color patches in the color chart formed by arranging the color patches corresponding to the plurality of colors output by the output device using a colorimeter Acquisition means for acquiring the measured value to
Based on the acquired measurement value, an image for receiving an instruction for re-color measurement, display control means for displaying on the display unit,
Re-colorimetry control means for executing re-colorimetry using the colorimeter when receiving the re-colorimetry instruction,
Based on at least a part of the acquired measured values and the measured values obtained by the re-colorimetry, a generating unit that generates device characteristics of the output device,
An information processing device comprising:   The display control unit causes the display unit to display the image including at least a part of the acquired measurement values and a button for receiving the instruction of the re-color measurement. The information processing apparatus according to claim 1.   The information processing apparatus according to claim 1, wherein the re-color measurement is color measurement of a color patch in a color chart different from the color chart.   The color chart measured by the re-color measurement is a color chart having a smaller number of color patches than the color chart corresponding to the acquired measurement value. The information processing device according to one item.   5. The display control means displays a warning on the display unit when a color difference between measured values corresponding to color patches of the same color included in the acquired measured values is large. The information processing apparatus according to any one of 1.   The said acquisition means acquires the measured value of each color patch in each of several color charts obtained by outputting the said output device several times, The any one of Claim 1 thru | or 5 characterized by the above-mentioned. Information processing equipment.   The generation unit, based on an average value obtained by averaging the measured values obtained by averaging the measured values corresponding to color patches of the same color with the acquired measured values and the measured values obtained by the re-color measurement, The information processing apparatus according to claim 1, wherein the information processing apparatus generates device characteristics.   The generation unit, the acquired measurement value, the measurement value corresponding to the color patch of the same color in the measurement value obtained by the re-color measurement, the measurement value not suitable for generating the device characteristics The information processing apparatus according to claim 7, wherein the device characteristic of the output device is generated based on an average value obtained by averaging out.   A program for causing a computer to function as each unit of the information processing apparatus according to claim 1. Corresponding to each of the plurality of colors obtained by measuring color of each of the color patches in the color chart formed by arranging the color patches corresponding to the plurality of colors output by the output device using a colorimeter To obtain the measurement values to
Based on the acquired measurement value, a step of displaying an image for receiving an instruction of re-color measurement on the display unit,
A step of re-measuring using the colorimeter when receiving the instruction of re-measuring,
Generating a device characteristic of the output device based on at least a part of the obtained measured values and the measured value obtained by the re-colorimetry,
An information processing method comprising:

Images