This application claims priority from Japanese Patent Application No. 2022-121574 filed on Jul. 29, 2022. The entire content of the priority application is incorporated herein by reference.
An information processing device known in the art is one example of a conventional colorimetry system for measuring colors in printed matter. The conventional information processing device extracts all colors represented by target data to be printed and acquires the occupancy ratio of each color in the printing area. The information processing device then generates data for calibration patch images based on these occupancy ratios and controls a printer to print the calibration patch images. Next, the information processing device uses a colorimeter to measure the colors of the printed calibration patch images and calibrates the image data for the target image based on this colorimetric data.
The conventional information processing device described above measures printed calibration patches with a colorimeter all in the same manner and calibrates the image data to be printed on the basis of this colorimetric data. However, using the same method to measure colors of all calibration patch images with the colorimeter may decrease the accuracy of color measurements, resulting in reduced accuracy of color calibration.
In view of the foregoing, it is an object of the present disclosure to provide a printing device, a color measurement method, and a color measurement program capable of improving the accuracy of color calibration.
In order to attain the above and other object, the present disclosure provides A printing device. The printing device includes a print head, a measuring member, and a controller. The print head is configured to print a patch chart on a print medium. The patch chart includes a plurality of patches including a plurality of first patches and one or more second patches. Each first patch has a predetermined color. Each second patch has a user specified color represented by an input color value. The measuring member is configured to measure a color of a patch. The controller is configured to perform: a second-patch measurement process to control the measuring member to measure a color of each second patch a plurality of times to acquire a plurality of color values for the each second patch; calculating an average value of at least two of the plurality of color values for the each second patch; and generating a table correlating an input color value with the average value as a measured color value for the each second patch.
According to another aspect, the disclosure provides a method for measuring colors of a plurality of patches included in a patch chart. The plurality of patches includes a plurality of first patches and one or more second patches. Each first patch has a predetermined color. Each second patch has a user specified color represented by an input color value. The method includes: performing a second-patch measurement process to control the measuring member to measure a color of each second patch a plurality of times to acquire a plurality of color values for the each second patch; calculating an average value of at least two of the plurality of color values for the each second patch; and generating a table correlating an input color value with the average value as a measured color value for the each second patch.
According to still another aspect, the disclosure provides a non-transitory computer readable storage medium storing a set of program instructions for a printing device. The printing device includes: a print head configured to print a patch chart on a print medium, the patch chart including a plurality of patches including a plurality of first patches and one or more second patches, each first patch having a predetermined color, each second patch having a user specified color represented by an input color value; and a measuring member configured to measure a color of a patch. The set of program instructions includes: a second-patch measurement process to control the measuring member to measure a color of each second patch a plurality of times to acquire a plurality of color values for the each second patch; calculating an average value of at least two of the plurality of color values for the each second patch; and generating a table correlating an input color value with the average value as a measured color value for the each second patch.
In the above structures, the accuracy of color measurements can be improved.
The embodiments of the present disclosure will be described while referring to the accompanied drawings. The following embodiments are just examples and the present invention is not limited to these embodiments. The embodiments can be modified without departing from the scope of the invention. For example, some components and/or steps can be added, and/or deleted.
As shown in
The printing device 1 is a serial printer, for example. The printing device 1 is provided with a plurality of ejection heads 20 (see
The ejection heads 20 use ink in primary colors (described later) to print images on print media W based on image data. The image data includes color values (input color values). In this example, each color value indicates a color and includes component values represented by RGB values in the RGB color space, i.e., as color coordinates in a device-dependent color space. The RGB values express a single color through a combination of a red color value, a green color value, and a blue color value, each of which represents one of a possible 256 gradations (0-255).
The ejection heads 20 print a patch chart PT described later (see
Examples of primary color inks are cyan ink, yellow ink, magenta ink, and black ink. Special color inks have different colors from the primary colors. Examples of special color inks are red ink, green ink, and blue ink.
The first tanks 12a store ink in the primary colors and communicate with the first ejection heads 21 through first channels 13a. Ink in the primary colors is supplied from the first tanks 12a to the first ejection heads 21 via the first channels 13a. The second tanks 12b communicate with the second ejection heads 22 via second channels 13b. When the second tanks 12b store ink in special colors, the special color inks flow from the second tanks 12b into the second channels 13b, filling the second channels 13b. From the second channels 13b, the special color inks are supplied to the ejection heads 20. Before ink in special colors is stored in the second tanks 12b, the second tanks 12b are filled with a storage solution. The first channels 13a and the second channels 13b are rubber or plastic tubes, for example, which are preferably resistant to kinking.
The conveying device 30 has two sets of conveying rollers 31, and a conveying motor 32 (see
The scanning device 40 has a carriage 41, a pair of guide rails 42, a scanning motor 43, and an endless belt 44. The guide rails 42 extend in the moving direction Ds over the platen 11 so that the ejection heads 20 are interposed between the guide rails 42 in the conveying direction Df. The carriage 41 is supported on the guide rails 42 to be movable in the moving direction Ds. The carriage 41 supports the ejection heads 20. The endless belt 44 extends in the moving direction Ds and is attached to the carriage 41. The endless belt 44 is also attached to the scanning motor 43 via a pulley 45. When the scanning motor 43 is driven, the endless belt 44 circulates and the carriage 41 reciprocates in the moving direction Ds along the guide rails 42. In this way, the carriage 41 moves the ejection heads 20 in the moving direction Ds.
The colorimetric device 201 is connected to the personal computer 301 via a network, such as a wired or wireless LAN. The colorimetric device 201 has a base 202 and an arm 204. The base 202 is disposed at a prescribed position in the colorimetry system 100 to a side of the printing device 1, for example. A white reference 210 is provided on the base 202. A color measuring unit 208 described later uses the white reference 210 in a process for adjusting the measurement accuracy for color values (hereinafter also called “calibration process” or “calibration”).
The white reference 210 is disposed in an area that the color measuring unit 208 can measure. For example, the white reference 210 is located within the range in the moving direction Ds within which the color measuring unit 208 can be moved by the arm 204 and within the range in the up-down direction within which the color measuring unit 208 oppose and can measure the white reference 210. The white reference 210 has a predetermined color such that the color measuring unit 208 outputs a predetermined color value when the color measuring unit 208 measures a color of the white reference 210 under a specific measuring condition. Here, the predetermined color value has component values expressed by color coordinates in a device-independent color space, such as L*a*b* values. During the calibration process, the color measuring unit 208 is controlled to measure the color of the white reference 210 to acquire a measured color value (or a colorimetric value) having components values represented in the L*a*b*. The predetermined color value for the white reference 210 is then acquired from a storage and, together with the measured color value and color measuring conditions described later, are used to calibrate the measuring precision of the color measuring unit 208.
The arm 204 has a first link 205 and a second link 206, for example. The proximal end of the first link 205 is connected to the base 202 by a first rotary joint 203, for example. The first rotary joint 203 has an actuator, such as a motor, which rotates the arm 204 relative to the base 202 about a central axis aligned in the up-down direction. The proximal end of the second link 206 is connected to the distal end of the first link 205 by a second rotary joint 207. The second rotary joint 207 has an actuator, such as a motor, which rotates the second link 206 relative to the first link 205 about a central axis aligned in the up-down direction. Additionally, the distal end of the second link 206 is connected to the color measuring unit 208 by a prismatic joint 209, for example. The prismatic joint 209 has a linear actuator, such as a motor or solenoid, which moves the color measuring unit 208 up and down relative to the second link 206. With this configuration, the arm 204 can move the color measuring unit 208 three-dimensionally.
The color measuring unit 208 is a spectrophotometer and colorimeter, for example, and has a light-emitting element and a light-receiving element which have respectively the same structures as a light-emitting element 211 (
The personal computer 301 is connected to the printing device 1 and the colorimetric device 201 via a network, such as a wired or wireless LAN. The personal computer 301 is provided with a user interface 302, a CPU 303, a work memory 304, a storage 305, and a data input/output interface 306. The user interface 302 performs processes related to input from the user and displays for the user. The user interface 302 includes input devices such as a keyboard and mouse, and display devices such as a display. The storage 305 is a hard disk, for example. The CPU 303 performs various processes according to programs stored in the storage 305. The work memory 304 is used as a work area when the CPU 303 performs these processes. The data input/output interface 306 is an interface for inputting and outputting image data as printing target data. The user can use the personal computer 301 and user interface 302 to send instructions to the printing device 1 for printing a patch chart PT (see
The printing device 1 is further provided with a display 14, an input interface 15, and a controller 50. The controller 50 has an interface 51, an arithmetic unit 52, and a storage 53. The interface 51 receives image data and other various data from an external device 200. The external device 200 may be a computer, a camera, a communication network, a storage medium, a display, a printer, or the like. The image data is raster data and the like representing an image to be printed on print media W. The image data includes information on printing conditions such as the type of print medium W and the like. The controller 50 may be configured as a standalone device, or a plurality of devices in a distributed arrangement. In the latter case, the devices interact with each other to operate the printing device 1.
The storage 53 stores patch chart data representing a patch chart PT (see
The arithmetic unit 52 includes a CPU or other processor and at least one circuit, such as an ASIC or other integrated circuit. By performing the printing program and color measurement program, the arithmetic unit 52 controls the components of the printing device 1 to implement a printing operation and other various operations.
The display 14 is a display, for example. In accordance with instructions from the controller 50, the display 14 displays images represented by image data, and the like. The input interface 15 includes buttons and the like, for example, that the user operates. Alternatively, the input interface 15 may be a touchscreen integrated with the display 14.
The controller 50 is electrically connected to the conveying motor 32 of the conveying device 30 via a conveyance drive circuit 33 for controlling the drive of the conveying motor 32. Accordingly, the controller 50 controls conveyance of the print medium W by the conveying rollers 31 of the conveying device 30. The controller 50 is also electrically connected to the scanning motor 43 of the scanning device 40 via a scan drive circuit 46 for controlling the drive of the scanning motor 43. Accordingly, the controller 50 controls movement of the ejection heads 20 by the carriage 41 of the scanning device 40. The controller 50 is further electrically connected to the drive elements 25 via an ejection head drive circuit 26. The controller 50 outputs control signals for the drive elements 25 to the ejection head drive circuit 26, and the ejection head drive circuit 26 generates and outputs drive signals to the drive elements 25 on the basis of these control signals. When driven according to the drive signals, the drive elements 25 eject ink droplets from corresponding nozzles 27.
With the printing device 1 having the above configuration, the controller 50 acquires image data and performs a printing operation based on this image data. In the printing operation, the controller 50 ejects ink onto the print medium W from the ejection heads 20 while moving the ejection heads 20 in the moving direction Ds for each printing pass. Next, the controller 50 conveys the print medium W forward in the conveying direction Df The printing device 1 repeatedly alternates between a printing pass and a conveying operation in this way to print an image on the print medium W based on the image data.
The CPU 303 in the personal computer 301 displays the preview image PI on the user interface 302 based on image data stored in the storage 305. The preview image PI in the example of
As shown in
The first patches Pb are patches P corresponding to the basic colors in the image data and are arranged at predetermined positions in the patch chart PT. The basic colors are predetermined colors always included in the first patch area R1 of the patch chart PT. The second patches Ps, on the other hand, have colors that the user has specified in the preview image PI described above. Each second patch Ps is a patch P having a color specified by the user in the preview image PI shown in
Here, a process must be performed to acquire position information on the patches P in order to measure the color of each patch P. Therefore, a process to acquire position information for each patch column PR is performed prior to measuring the colors of the patches P. This process will be described in detail below.
After printing the patch chart PT with the printing device 1, the user places the print medium W having the printed patch chart PT on the base 202 of the colorimetric device 201. The patch chart PT includes at least three first marker images Mi1 arranged at positions surrounding or within an entire patch area including the first patch area R1 and the second patch area R2, as shown in
Each first marker images Mi1 is an image designating (denoting) a position or region in the first patch area R1. By specifying the first marker images Mi1, the controller 50 can specify the entire patch area including the first patch area R1 and the second patch area R2. Further, because the dimensions in the left-right direction and the front-rear direction of each patch are predetermined and the patches are continuously arranged in the first patch area R1, the controller 50 can specify the position of each patch P located in the first patch area R1 by specifying the first marker images Mi1. The first marker image Mi1 may be a frame of bold black line surrounding a patch P. When the first marker image Mi1 is formed in a region where the patch P is not formed, the first marker image Mi1 may be a bold frame surrounding a portion or region having the same dimensions of the first patch Pin the first patch area R1. The first marker image Mi1 may have a shape of an arrow or a triangle that designates a patch or a region or portion. The first marker image Mi1 may have a specific color other than black.
The user rotates the arm 204 to move the color measuring unit 208 opposite a patch P or portion (or region) designated by each of at least three first marker images Mi1 arranged at positions surrounding or within the entire patch area including the first patch area R1 and the second patch area R2 on the print medium W, as shown in
The CPU 303 acquires position information on each first patch Pb in the patch chart PT based on the information on the three first marker positions acquired above. Since the area of the first patch area R1, the area of each patch column PR, and the dimensions of each patch P are all known in this case, the CPU 303 can calculate position information on each first patch Pb simply by acquiring position information on the three first marker images Mi1. The method of acquiring position information on second patches Ps is essentially the same as that for the first patches Pb. The patch chart PT includes at least three second marker images Mi2 located at positions surrounding or within the second patch area R2. Each second marker images Mi2 is an image designating a position or region in the second patch area R2. By specifying the second marker images Mi2, the controller 50 can specify the second patch area R2. Further, because the dimensions in the left-right direction and the front-rear direction of each patch are predetermined, the controller 50 can specify the position of each patch P located in the second patch area R2 by specifying the second marker images Mi2. The second marker image Mi2 may be a bold frame of black color surrounding a patch P. The combination of shape and color of the second marker image Mi2 may be different from that of the first marker image Mi2 so the user and the controller 50 can distinguish the second marker images Mi2 from the first marker images Mi1. When the second marker image Mi2 is formed in a region where the patch P is not formed, the second marker image Mi2 may be a bold frame surrounding a portion or region having the same dimensions of the second patch P in the second patch area R2. The second marker image Mi2 may have a shape of an arrow or a triangle that designates a patch or a region or portion. The second marker image Mi2 may have a specific color other than black.
The user rotates the arm 204 to move the color measuring unit 208 opposite a patch P or portion (region) designated by each of at least three second marker images Mi2 located at positions surrounding or within the second patch area R2 on the print medium W. As in the example of
Next, the process for measuring a patch P in the patch chart PT will be described.
To measure the colors of patches P in the patch chart PT with the colorimetry system 100, the user rotates the arm 204 to move the color measuring unit 208 opposite the patch P to be measured. In this state, the light-emitting element (211) of the color measuring unit 208 irradiates light onto the patch P. The light-receiving element (212) of the color measuring unit 208 receives the light irradiated from the light-emitting element (211) and reflected off the patch P. The color measuring unit 208 measures the color of the patch P based on the light received by the light-receiving element (212).
As shown in
In the embodiment, similarly to the second patches Ps, color measurement may be performed at single position for each first patch Pb, or color measurements may be performed at a plurality of measurement positions for each first patch Pb.
The measurement results for all measurement positions are transmitted to the CPU 303 from the colorimetric device 201 via the data input/output interface 306. The CPU 303 receives the results of the plurality of measurements (measured color values) and calculates the averages of the measurement results by dividing the sums of component values of measured color values by the total number of measurements for each of L*, a*, b* components. In the example of
Alternatively, the maximum and minimum values may be determined on the basis of the optical density of each measured color value. An optical density may be calculated from each measured color value. In this case, the measured color value corresponding to the highest optical density among the calculated optical densities from the measured color values of the second patch Ps may be determined as the maximum value, and the measured color value corresponding to the lowest optical density among the calculated optical densities from the measured color values of the second patch Ps may be determined as the minimum value. Alternatively, the maximum and minimum value may be determined on the basis of one component of the L*a*b*. For example, the measured color value having a highest L* component value among L* component values of the measured color values of the second patch Ps may be determined as the maximum value, and the measured color value having a lowest L* component value among L* component values of the measured color values of the second patch Ps may be determined as the minimum value. The maximum and minimum value may be determined on the basis of the a* component values or b* component values.
In a case that the difference between two of the measured color values acquired while varying the measurement position of the color measuring unit 208 within a single second patch Ps as described above (e.g., the maximum difference among the measured color values at the measurement positions Mp1-Mp5 in
The CPU 303 stores the average calculated for the plurality of measured color values calculated as described above in the table Ta as the measured color value of each second patch Ps. In this way, the average of the plurality of measured color values measured for each second patch Ps is correlated with the color values (input color values) of that second patch Ps. Here, a second patch Ps is a patch P that the controller 50 formed for each color that the user specified in the preview image PI described above. In other words, the table Ta correlates the color value (input color value) of each color in the preview image PI with the average of the measured color values measured for that color. Since the correlation of color values for colors in the preview image PI to the averages of their measured color values changes with each measurement, a new table Ta is effectively generated with each color measurement.
When such a mixed patch column PRc exists, the patch chart P includes a new second marker image Mi2 as well as the second marker images Mi2 located at the same positions as those shown in
In the present embodiment, the CPU 303 may acquire position information so that the number of acquired second marker positions is greater than the number of acquired first marker positions. In the example of
As shown in
A printing device 1A according to a second embodiment is basically the same as the printing device 1 in the first embodiment but differs from the first embodiment in that the printing device 1A has a built-in colorimetric device 70. The controller 50 in the second embodiment can perform the processes the same as that of the first embodiment. Specifically, the controller 50 in the second embodiment can form the patch charts PT described in the first embodiment or the variations thereof, and perform a process for measuring colors similar to that performed by the CPU 303 in the first embodiment and, hence, a description of these processes has been omitted. In this embodiment, the arithmetic unit 52 corresponds to the computer, the color measurement controlling member, the calculating member, and the generating member. In the following description, structures in the printing device 1A of the second embodiment identical to those in the printing device 1 of the first embodiment are designated with the same reference numerals to avoid duplicating description.
The pair of guide rails 60 is arranged downstream of the carriage 41 in the conveying direction Df. The guide rails 60 extend in the moving direction Ds. The additional conveying rollers 31 described above are disposed downstream of the guide rails 60 in the conveying direction Df The endless belt 62 is attached to the base 202 of the colorimetric device 70. The endless belt 62 extends in the moving direction Ds. The endless belt 62 is also attached to the scanning motor 61 via the pulley 63. When the scanning motor 61 is driven, the endless belt 62 circulates, and the base 202 reciprocates in the moving direction Ds along the guide rails 60. In this way, the base 202 moves the color measuring unit 208 in the moving direction Ds. The base 202 corresponds to the moving member. The size of the base 202 in the second embodiment is smaller than that in the first embodiment. For example, in the second embodiment, the dimension of the base 202 in the left-right direction may be smaller than that of the print medium W. Though in the first embodiment the print medium W is placed on the base 202, in the second embodiment the print medium W is passing through a region below the base 202, and the print medium W is not placed on the base 202.
As shown in
In order to move the color measuring unit 208 in the up-down direction, the colorimetric device 70 is further provided with a linear motion drive circuit 80, a linear actuator 81 provided on the prismatic joint 209 described above that includes a motor and the like, for example, and a linear motion sensor 82. The linear actuator 81 moves the color measuring unit 208 up and down to place the color measuring unit 208 into contact with and separate from the print medium W. The controller 50 is connected to the linear actuator 81 via the linear motion drive circuit 80, and to the linear motion sensor 82. The linear motion sensor 82 is an encoder, for example, that detects the amount of movement of the linear actuator 81. The controller 50 controls the operations of the linear actuator 81 on the basis of detection results by the linear motion sensor 82, thereby controlling vertical movement of the color measuring unit 208 on the basis of the detection results of the linear motion sensor 82.
Thus, as components for moving the print medium W and the color measuring unit 208 relative to each other, the color measuring unit 208 has the conveying device 30 that conveys the print medium W in the conveying direction Df, the base 202 that moves the color measuring unit 208 in the moving direction Ds, the rotary actuator 91 that moves the color measuring unit 208 in the moving direction Ds and the conveying direction Df, and the linear actuator 81 that moves the color measuring unit 208 in the up-down direction.
As in the first embodiment (
The patch chart PT may include at least three first marker images Mi1 and at least three second marker images Mi2 similar to those shown in
As illustrated in
When the color measuring unit 208 is controlled to measure the colors of patches P continuously, the brightness of the measured color values decreases due to changes in measurement environment such as increasing of temperature, as illustrated in
On the other hand, a thirdly-performed calibration process is performed at a timing N3 that measurements for all the first patches Pb are completed. In this case, the timing N3 is after completing the number of color measurements lower than or equal to the prescribed first number of measurements, which has been used as the reference number for performing the first and secondly-performed calibrations process, in order to calibrate the color measuring unit 208 prior to measuring the colors of second patches Ps (i.e., patches P that are particularly important). In other words, after measurements of all the first patch Pb are completed and before measurements of the second patches Ps is started, a calibration process (thirdly-performed calibration process in this case) is always performed even if the number of measurements is lower than the prescribed first number of measurements since the immediately-previous calibration process has been performed. Because the patches P become second patches Ps from the 730-th patch P in the example of this embodiment, the timing N3 corresponds to the time at which color measurement has been completed for the 729-th first patch Pb.
After each calibration process is completed, the brightness of the measured color values tends to be relatively high up to a prescribed second number of measurements, as illustrated in
As shown in
In S2 the controller 50 acquires position data. Specifically, the controller 50 acquires position data on the first marker image Mi1 and the second marker images Mi2 for specifying the first patch area R1 and the second patch area R2. The position data on the marker images Mi1 and Mi2 is based on data used and acquired during printing of the patch chart PT, and indicates positions of the maker images Mi1 and Mi2 on the print medium W on which the patch chart PT is printed. The controller 50 specifies the positions of the marker images Mi1 and Mi2 to generate the position data thereon by using a distance in which the print medium is conveyed by the conveying device 30 and a distance of the ejection heads 20 moved by the scanning device 40 when the patch chart PT is printed and stores the position data on these marker images in the storage 53. The controller 50 may specify the positions of the marker images Mi1 and Mi2 by using patch chart image data of the patch chart PT. The controller 50 acquires the position data on the first marker image Mi1 and the first second marker images Mi2 from the storage 53. The controller 50 specifies the first patch area R1 and the second patch area R2 in the print medium on the basis of the acquired position data on the first marker image Mi1 and the second marker images Mi2.
In S2 the controller 50 also acquires data on the second patches Ps. Colors the second patches Ps in the patch chart PT are selected by the user and thus the number of the second patches Ps in the patch chart PT depends on the user's selection. Thus, the controller 50 needs to determine what extent the second patches Ps exist in the second patch area R2. In S2 the controller 50 may acquire, as the data on the second patches Ps, the number of the second patches Ps in the patch chart. Alternatively, the controller 50 may acquire, as the data on the second patches Ps, a position of each second patch Ps that is based on the data used and acquired during printing of the patch chart PT and/or the patch chart image data. On the basis of the acquired data on the second patches Ps, the controller 50 specifies the extent in which the second patches Ps exist in the second patch area R2.
The controller 50 may receive and acquire the position data on the first marker image Mi1 and the second marker images Mi2 and the data on the second patches Ps inputted via the external device 200, the input interface 15, or the like for each patch column PR.
In S3 the controller 50 performs a correction process to acquire positions of the actually printed first marker images Mi1 and second marker images Mi2 to correct positions and ranges of the specified first patch area R1 and second patch area R2 on the print medium W specified in S2. Steps in this correction process are shown in
In S31 of
Here, the controller 50 acquires information on each first marker position by controlling the rotary actuator 91 to rotate the arm 204 in order that the color measuring unit 208 opposes in turn a patch or region designated by each of the first marker images Mi1 whose position data is acquired in S2 and controls the linear actuator 81 to move the color measuring unit 208 vertically via the prismatic joint 209 in order to position the color measuring unit 208. The controller 50 acquires information on the first marker position on the basis of the position of the color measuring unit 208 opposing the first marker image Mi1.
In S32 the controller 50 searches the printed patch chart PT for each second marker image Mi2 by using the color measuring unit 208 on the basis of the acquired position data on the second marker images Mi2 and the data on the second patches Ps. Because each second marker images Mi2 has a predetermined shape and color (a black bold frame in this case), the controller 50 searches the printed patch chart PT for the predetermined shape and color of each second marker image Mi2 on the basis of measured color by the color measuring unit 208 to find the second marker images Mi2. The control device 50 acquires information on second marker positions on the basis of the found second marker images Mi2.
In S32 the controller 50 controls the rotary actuator 91 to rotate the arm 204 on the basis of the position data on second patches Ps so that the color measuring unit 208 opposes in turn a patch or region designated by each of the second marker images Mi2 whose position data is acquired in S2 and controls the linear actuator 81 to move the color measuring unit 208 vertically via the prismatic joint 209 in order to position the color measuring unit 208. The controller 50 acquires information on the second marker position on the basis of the position of the color measuring unit 208 opposing the second marker image Mi2.
Here, the number of first marker images Mi2 is greater than the number of second marker images Mi2 in the patch charts PT shown in
In S33 the controller 50 corrects positions and ranges of the first patch area R1 and second patch area R2 specified in S2 on the basis of the position information on first marker images Mi1 and the position information on second marker images acquired in S31 and S32 and the predetermined dimensions of each patch through calculations, and specifies positions of the first patches Pb and the second patches Ps included in the first patch area R1 and the second patch area R2. The controller 50 creates the patch column table Tp shown in
Returning to
At the timing of S4, the controller 50 performs a calibration process based on the color measuring conditions acquired in S1.
In S5 the controller 50 selects a patch column among patch columns in the patch chart PT whose colors of patches P have not been measured. The controller 50 selects a patch column while giving priority to each patch column including the first patches Pb only over each patch column including one or more second patches Ps. Accordingly, the controller 50 selects a patch column including one or more second patches Ps, only after all the patch columns each including the first patches Pb only have been measured.
The controller 50 acquires patch column information for the selected patch column from the patch column table Tp described above for one patch column PR indicating whether the patch column PR includes a second patch Ps. In S6 the controller 50 determines whether the patch column PR includes one or more second patches Ps. When the patch column PR includes no second patch Ps (e.g., the patch column PR corresponding to the first column in the patch chart PT; S6: NO), in S9 the controller 50 controls the color measuring unit 208 to measure color of each patch Pin the patch column PR. In this case, the controller 50 measures colors in this patch column PR without waiting for a prescribed time period (described later) to elapse because the patch column PR includes only first patches Pb.
However, when the patch column PR includes one or more second patches Ps (S6: YES), in S7 the controller 50 determines whether the prescribed time period since the patch chart PT was printed on the print medium W has elapsed. Here, the case of a mixed patch column PRc that includes one or more second patches Ps also corresponds to a case in which the patch column PR includes second patches Ps. When the prescribed time period has elapsed since the patch chart PT was printed on the print medium W (S7: YES), the controller 50 controls the color measuring unit 208 to measure colors in the patch column PR. However, when the prescribed time period has not elapsed (S7: NO), in S8 the controller 50 waits for the prescribed time period to elapse and subsequently in S9 controls the color measuring unit 208 to perform color measurements of patches P in the patch column PR. In S9 the controller 50 measures the color of each second patch Ps a plurality of times as shown in
In S10 the controller 50 determines whether color measurements have been completed for all patch columns PR in the patch chart PT. When color measurements have been completed for all patch columns PR (S10: YES), the controller 50 ends the process in
According to the colorimetry system 100 of the first embodiment and the printing device 1A of the second embodiment described above, the color measuring unit 208 is controlled to measure the color of a single second patch Ps a plurality of times and the average of the color measurement results is calculated. Next, the table Ta is generated to correlate the color value (the input color value) of color in the image with an average measured value as its measured color value for each second patch Ps. Averaging the measurement results in this way can suppress bias in the measured color values for second patches Ps, thereby improving the accuracy of color measurements and the accuracy of color calibration.
In the second embodiment, the controller 50 can reciprocate the base 202 in the moving direction Ds along the guide rails 60 for each of the plurality of color measurements. By moving the color measuring unit 208 in the moving direction Ds in this way, the measurement position of the color measuring unit 208 in one second patch Ps can easily be modified.
When the color of a second patch Ps is measured four or more times in the first and second embodiments, the average value of the color can be calculated from the measurement results after excluding the measured values corresponding to the minimum and maximum. This method can suppress bias in the measured color value.
In the first and second embodiments, position information on each first patch Pb in the patch chart PT is acquired through calculations based on position information on each first marker image Mi1. This method is efficient because the positions of all first patches Pb in the first patch area R1 need not be acquired through measurements.
In the first and second embodiments, position information on each second patch Ps in the patch chart PT is acquired through calculations based on the position information on each second marker image Mi2. This method is efficient because the positions of all second patches Ps in the second patch area R2 need not be acquired through measurements.
In the first and second embodiments, position information on the first patches Pb and second patches Ps may be reacquired (for example, perform the process S3 again) when a difference in measured color values acquired while varying the position of the color measuring unit 208 within the same second patch Ps exceeds a prescribed value. This ensures that more suitable position information on the first patches Pb and second patches Ps can be acquired.
Through the process to acquire position information on each second marker image Mi2 in the first and second embodiments, images designating second patches Ps arranged in four corner positions LT1 of the second patch area R2, and positions LT2, LT3, LT4 in a rectangular region defined by the four corner positions LT1 (see
Also, in the process of acquiring position information on each second marker Mi2 in the first and second embodiments, an image designating one of the neighboring first patch Pb and second patch Ps in the mixed patch column PRc (see
In the first and second embodiments, the number of acquired second marker positions is greater than or equal the number of acquired first marker positions. In this way, more suitable position information can be acquired on second patches Ps, for which color measurements of relatively high accuracy is desired.
In the second embodiment, the controller 50 controls the color measuring unit 208 to begin color measurements after the prescribed time period has elapsed since the patch chart PT was printed on the print medium W. This allows color measurements to be performed after the printed patch chart PT is properly fixed to the print medium W, ensuring that more suitable measured color values can be acquired.
In the second embodiment, color measurement of second patches Ps is performed up to a prescribed number of times after the color measuring unit 208 has been calibrated. This allows second patches Ps to be measured at a time when the brightness of measured color values is relatively high, thereby improving the reliability of measured color values for the second patches Ps.
(Variations)
While the invention has been described in conjunction with various example structures outlined above and illustrated in the figures, various alternatives, modifications, variations, improvements, and/or substantial equivalents, whether known or that may be presently unforeseen, may become apparent to those having at least ordinary skill in the art. Accordingly, the example embodiments of the disclosure, as set forth above, are intended to be illustrative of the invention, and not limiting the invention. Various changes may be made without departing from the spirit and scope of the disclosure. Therefore, the disclosure is intended to embrace all known or later developed alternatives, modifications, variations, improvements, and/or substantial equivalents. Some specific examples of potential alternatives, modifications, or variations in the described invention are provided below:
In the above embodiments, color measurements are performed without waiting for the prescribed time period to elapse when the patch column PR includes only first patches Pb and are performed after the prescribed time period has elapsed when the patch column PR includes one or more second patches Ps. However, the method of the present invention is not limited to these embodiments. The prescribed time period may include a prescribed first time period for performing color measurements on first patches Pb, and a prescribed second time period longer than the prescribed first time period for performing color measurements on second patches Ps. This method provides not only a wait time for measuring the colors of second patches Ps but also a wait time for measuring the colors of first patches Pb. In this case, the controller 50 determines whether each of the prescribed first time period and prescribed second time period has elapsed since the patch chart PT was printed on the print medium W. The controller 50 controls the color measuring unit 208 to perform color measurements in a patch column PR that includes only first patches Pb after the prescribed first time period has elapsed. The controller 50 controls the color measuring unit 208 to perform color measurements in patch columns PR including one or more second patches Ps (including the mixed patch column PRc) after the prescribed second time period has elapsed.
As described above, the prescribed first time period is shorter than the prescribed second time period. Thus, after the prescribed first time period has elapsed and before the prescribed second time period elapses, the controller 50 controls the color measuring unit 208 to perform color measurements of the first patches Pb only. After the prescribed second time period has elapsed, the controller 50 may start color measurements of the second patch Ps even when the measurement of all the first patches Pb are not completed. That is, after the prescribed second time period has elapsed, the controller 50 may perform color measurements of the first patches Pb and the color measurements of the second patches in an arbitrary order. That is, in a case that the prescribed second time period elapses since the patch chart has been printed on the print medium, the controller 50 may start the measurement process of the second patches Ps even when there remains an unprocessed first patch Pb of the measurement process among the plurality of first patches Pb.
In the first embodiment, after the prescribed time period has elapsed (S7: YES), the controller 50 may start color measurements of the second patch Ps even when the measurement of all the first patches Pb are not completed. In this case, when the controller 50 selects a patch column, the controller 50 may not give priority to each patch column including the first patches Pb only over each patch column including one or more second patches Ps. That is, the controller 50 can select a patch column including one or more second patches Ps prior to selecting a patch column including the first patches Pb only.
While an inkjet printer is offered as an example of the printing devices 1 and 1A in the embodiments described above, the printing devices 1 and 1A may be another printer, such as a laser printer or a thermal printer. A laser printer is provided with a print engine (printing unit). The print engine of a direct tandem laser printer includes an image carrier such as a photosensitive drum or a photosensitive belt, a charging member that charges the image carrier through contact or non-contact, an exposure member that forms an electrostatic latent image on the charged image carrier using a laser semiconductor or the like (known as “exposure”), a toner cartridge or developing cartridge that supplies toner to the image carrier on which an electrostatic latent image has been formed, a transfer member such as a transfer roller or belt that transfers the developed toner image from the image carrier directly to a print medium, and a fixing member such as a fixing roller or belt that thermally fixes the toner transferred onto the print medium. The laser printer is not limited to a direct tandem laser printer but may be an intermediate transfer laser printer. The intermediate transfer laser printer first transfers the developed toner image from the image carrier onto an intermediate transfer belt before using the transfer member to transfer the toner image from the intermediate transfer belt onto the print medium. A thermal printer is also provided with a print engine (printing unit). The print engine of a thermal printer includes a thermal head, and an ink ribbon. The thermal head contacts the ink ribbon and transfers ink in the ink ribbon onto a print medium by generating heat in selected heating elements.
Further, while the printing devices 1 and 1A are serial printers in the embodiments described above, the printing devices 1 and 1A may be line printers, for example.
While each of the colorimetric devices 70 and 70A is provided with one or more links in the above embodiments, the colorimetric device may simply be provided with the prismatic joint 209 on the base 202, without the links. In this case, the color measuring unit 208 is moved in the moving direction Ds by the base 202 and is moved vertically by the linear actuator 81 of the prismatic joint 209.
In the example of
The CPU 303 may acquire position information on each second patch Ps in the patch chart PT on the basis of acquired position information on the three second marker images Mi2 only. Alternatively, the CPU 303 may acquire position information on second patches Ps in the patch chart PT on the basis of the acquired information on the first marker images Mi1 and second marker images Mi2.
In the above embodiments, the controller 50 performs the process according to the flowchart of
Number | Date | Country | Kind |
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2022-121574 | Jul 2022 | JP | national |