Printing apparatus having operating mode in which ink ejection is shared by first head and second head at prescribed contribution ratio

In a printing apparatus, a carriage is reciprocally movable in first and second directions. A control device is configured to perform executing one of first and second printing operations in accordance with an operation mode. The first printing operation prints a first image over a first range in a third direction crossing the first and second directions by ejecting ink from both first and second heads during one movement of the carriage in the first and second directions. The second printing operation prints a second image over a second range narrower than the first range in the third direction by ejecting ink from both the first and second heads during the one movement of the carriage. Ink ejection contribution during the one movement of the carriage is shared by the first and second heads at a prescribed contribution ratio in the second printing operation.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority from Japanese Patent Application No. 2021-052061 filed Mar. 25, 2021. The entire content of the priority application is incorporated herein by reference.

BACKGROUND

A recent printing technology known in the art performs printing on a printing medium by ejecting ink from a plurality of print heads. In this technology, for example, a single carriage is provided with two print heads that are offset but partially overlapped in a direction orthogonal to the scanning direction of the carriage. An apparatus using this conventional technology can perform printing on a printing medium at a high speed by ejecting ink from the two print heads while moving the carriage in the scanning direction.

SUMMARY

However, colors printed by the heads of this conventional printing apparatus do not always meet the user's expectations, requiring the user to adjust these colors. For such cases, there is a known technique of color calibration performed by printing patches and measuring the colors of the printed patches.

However, the heads provided in the conventional printing apparatus described above have individual differences owing to variation in manufacturing precision and the like for each head, resulting in differences in color reproducibility among heads. An example of variation in manufacturing precision is manufacturing error in nozzle diameters, resulting in different quantities of ink being ejected from different nozzles.

To overcome this problem, patches are printed using each of the plurality of heads, and colors of the printed patches are measured. Using these measurements, colors are adjusted to compensate for individual ink ejection quantities from the heads in order to achieve uniform color reproducibility. However, achieving uniform color reproduction properties among a plurality of print heads is difficult.

In view of the foregoing, it is an object of the present disclosure to provide a printing apparatus, a printing method, and a storage medium storing a set of computer-readable instructions for achieving high color reproducibility when printing using a plurality of heads.

In order to attain the above and other objects, according to one aspect, the present disclosure provides a printing apparatus including: a first head; a second head; a carriage; a storage device; and a control device. The first head has at least one first nozzle. The at least one first nozzle is configured to eject ink in a first color. The second head has at least one second nozzle. The at least one second nozzle is configured to eject ink in a second color same as the first color. The carriage is configured to support the first head and the second head. The carriage is reciprocally movable in a first direction and a second direction opposite to the first direction. The control device is configured to perform: (a) setting; and (b) executing. The (a) setting sets an operation mode to one of a first mode and a second mode. The (b) executing executes one of a first printing operation and a second printing operation in accordance with the operation mode set in the (a) setting. The first printing operation is performed in a case where the first mode is set as the operation mode. The second printing operation is performed in a case where the second mode is set as the operation mode. The first printing operation prints a first image over a first range in a third direction crossing the first direction and the second direction by ejecting ink from both the first head and the second head during one movement of the carriage in the first direction and the second direction. The second printing operation prints a second image over a second range in the third direction by ejecting ink from both the first head and the second head during the one movement of the carriage in the first direction and the second direction. The second range is narrower than the first range in the third direction. Ink ejection contribution during the one movement of the carriage in the first direction and the second direction is shared by the first head and the second head at a prescribed contribution ratio in the second printing operation.

According to the configuration described above, in the second mode, ink ejection contribution is shared by the first head and the second head at the prescribed contribution ratio, and an image is printed over a narrower range in the third direction than a range printed in the first mode by ejecting ink from both the first head and the second head during one movement of the carriage in the first direction and the second direction. Thus, printing with high color reproducibility can be executed with ink ejected from both the first head and the second head.

According to another aspect, the present disclosure provides a printing method using a printing apparatus. The printing apparatus includes: a first head; a second head; and a carriage. The first head has a first nozzle. The first nozzle is configured to eject ink in a first color. The second head has a second nozzle. The second nozzle is configured to eject ink in a second color same as the first color. The carriage is configured to support the first head and the second head. The carriage is reciprocally movable in a first direction and a second direction opposite to the first direction. The printing method includes: (a) setting; and (b) executing. The (a) setting sets an operation mode of the printing apparatus to one of a first mode and a second mode. The (b) executing executes one of a first printing operation and a second printing operation with the printing apparatus in accordance with the operation mode set in the (a) setting. The first printing operation is performed in a case where the first mode is set as the operation mode. The second printing operation is performed in a case where the second mode is set as the operation mode. The first printing operation prints a first image over a first range in a third direction crossing the first direction and the second direction by ejecting ink from both the first head and the second head during one movement of the carriage in the first direction and the second direction. The second printing operation prints a second image over a second range in the third direction by ejecting ink from both the first head and the second head during the one movement of the carriage in the first direction and the second direction. The second range is narrower than the first range in the third direction. Ink ejection contribution during the one movement of the carriage in the first direction and the second direction is shared by the first head and the second head at a prescribed contribution ratio in the second printing operation.

According to still another aspect, the present disclosure provides a non-transitory computer-readable storage medium storing a set of computer-readable instructions for a computer in a printing apparatus. The printing apparatus includes: a first head; a second head; and a carriage. The first head has a first nozzle. The first nozzle is configured to eject ink in a first color. The second head has a second nozzle. The second nozzle is configured to eject ink in a second color same as the first color. The carriage is configured to support the first head and the second head. The carriage is reciprocally movable in a first direction and a second direction opposite to the first direction. The set of computer-readable instructions, when executed by the computer, causes the printing apparatus to perform: (a) setting; and (b) executing. The (a) setting sets an operation mode to one of a first mode and a second mode. The (b) executing executes one of a first printing operation and a second printing operation in accordance with the operation mode set in the (a) setting. The first printing operation is performed in a case where the first mode is set as the operation mode. The second printing operation is performed in a case where the second mode is set as the operation mode. The first printing operation prints a first image over a first range in a third direction crossing the first direction and the second direction by ejecting ink from both the first head and the second head during one movement of the carriage in the first direction and the second direction. The second printing operation prints a second image over a second range in the third direction by ejecting ink from both the first head and the second head during the one movement of the carriage in the first direction and the second direction. The second range is narrower than the first range in the third direction. Ink ejection contribution during the one movement of the carriage in the first direction and the second direction is shared by the first head and the second head at a prescribed contribution ratio in the second printing operation.

According to the present disclosure, the printing apparatus provided with a plurality of heads can perform suitable printing with high color reproducibility using the plurality of heads.

DETAILED DESCRIPTION

Next, a printing apparatus1according to an embodiment of the present disclosure will be described, but the present disclosure is not limited to the printing apparatus1in the embodiment described below. In the following embodiment, a first head10and a second head20eject ink at a contribution percentage of 100% each when the printing apparatus1performs printing in a first mode, while the contribution percentages of the first head10and second head20together total 100% when the printing apparatus1performs printing in a second mode. However, these contribution percentages of ink ejection are not limited to 100%, as will be described below. Therefore, the present disclosure is not limited to the following embodiment, and elements may be added, omitted, and modified without departing from the spirit of the disclosure.

FIG.1is a perspective view showing the printing apparatus1according to one embodiment. The concept of directions in this specification and documentation for the claims conform to the up-down direction, left-right direction, and front-rear direction that are each orthogonal to the others, as illustrated inFIG.1. The left-right direction is also a main scanning direction Ds, and the front-rear direction is also a conveying direction Df of a printing medium W. More specifically, the conveying direction Df indicates a frontward direction. Thus, the conveying direction Df is orthogonal to the main scanning direction Ds.

As shown inFIG.1, the printing apparatus1according to the present embodiment is provided with a casing2, operating keys4, a display unit5, ink tanks6, a tray7, a top cover8, a carriage3, and a control device50(seeFIG.2). The carriage3is capable of reciprocating in the main scanning direction Ds. A first head10and a second head20described later are provided in the carriage3. The printing apparatus1has a first mode and a second mode for printing images using both the first head10and second head20. The printing apparatus1prints images with higher color reproducibility in the second mode than in the first mode.

The casing2is formed in a box shape, for example. The casing2has an opening2aformed in the front surface thereof for supplying a printing medium W into the casing2and discharging a printing medium W from the casing2. The printing medium W is fixed to the tray7, and the tray7is conveyed in both the conveying direction Df (i.e., the frontward direction) orthogonal to the main scanning direction Ds (the moving direction of the carriage3) and the direction opposite to the conveying direction Df (i.e., the rearward direction) by a conveying motor32(seeFIG.2). The conveying motor32is an example of the conveying device of the present disclosure, and is provided in the casing2. Hence, the printing medium W is conveyed from the outside to the inside of the casing2through the opening2aand is conveyed (discharged) from the inside to the outside of the casing2through the opening2a.

The operating keys4are provided in a location rightward and forward of the casing2. The display unit5is disposed in a position to the rear of the operating keys4. The operating keys4receive operations inputted by the user. The display unit5is configured of a touchscreen, for example, that displays prescribed information. Part of the display unit5functions as operating keys at prescribed timings. The control device50(seeFIG.2) implements a print function based on external input such as input from the operating keys4and controls the display on the display unit5.

FIG.2is a block diagram showing the primary configuration of the printing apparatus1shown inFIG.1. As shown inFIG.2, the printing apparatus1of the present embodiment is provided with the control device50. The control device50is an example of the control device and computer of the present disclosure, and possesses a CPU (not shown), a RAM51, a ROM52, and the like. The printing apparatus1is also provided with a storage device40that stores various information. A flash memory, a hard disk drive, or the like may be used for the storage device40. As an alternative, the storage device40can be included in the control device50.

The RAM51temporarily stores print jobs received from a computer200or other external personal computer via a network interface53. The RAM51also temporarily stores print data for each pass of a printing process. One pass is the width of the printing medium W in the conveying direction Df that is printed with a single head, where “width” includes the width when printing using all nozzles of the head and the width when printing using only some of the nozzles of the head. The ROM52stores the printing program of the present embodiment and a control program for performing various data processing.

The printing apparatus1also has a first head driver IC15for controlling the first head10, and a second head driver IC25for controlling the second head20. The printing apparatus1also has a motor driver IC31, and a motor driver IC33. The motor driver IC31controls a carriage motor30to actuate the carriage3. The motor driver IC33controls the conveying motor32to convey the printing medium W. While a printing medium W is fixed to the tray7, the conveying motor32conveys the tray7in the conveying direction Df or the direction opposite to the conveying direction Df, those are orthogonal to the moving direction of the carriage3(i.e., the main scanning direction Ds).

As its functional configuration, the control device50has an operating mode setting unit50a, a contribution percentage setting unit50b, and a printing unit50c. The operating mode setting unit50asets the operating mode of the printing apparatus1to one of a first mode, and a second mode for printing images with higher color reproducibility than in the first mode. The contribution percentage setting unit50bsets the contribution percentage of ink ejection for each of the first head10and second head20with respect to the density of dots constituting the image when printing in the second mode. That is, the contribution percentage setting unit50bsets contribution percentages of ink ejection so that the overall percentage of contribution for the first head10and second head20totals 100%. Contribution ratios for the first head10and second head20include 50:50(%), 70:30(%), and 60:40(%). The printing unit50cexecutes printing by ejecting ink with a contribution percentage of 100% for each of the first head10and second head20when the operating mode is set to the first mode and executes printing by ejecting ink so that the contribution percentages of ink ejection from the first head10and second head20total 100% when the operating mode is set to the second mode. The contribution ratio of ink ejection is an example of the prescribed contribution ratio of the present disclosure. The contribution percentage of ink ejection is an example of the ink ejection contribution percentage of the present disclosure.

The information stored in the storage device40includes nozzle property information. Nozzle property information specifies ink ejection properties for the plurality of nozzles provided in the first head10and second head20. Nozzle property information includes information indicating variation in the diameters of the nozzles (hereinafter called “nozzle diameter”) and information indicating the minimum droplet quantity of ink ejected from the nozzles. The storage device40also stores measured values for the shapes of ink channels in the first head10measured during manufacturing of the first head10, measured values for the shapes of ink channels in the second head20measured during manufacturing of the second head20, the median (design value) for the shape of ink channels in the first head10, and the median (design value) for the shape of ink channels in the second head20.

The storage device40also stores priority level information indicating priority levels based on the layout of the first head10and second head20. Priority levels will be described later.

When executing a prescribed printing program, the control device50controls the motor driver IC31to actuate the carriage motor30and controls the motor driver IC33to actuate the conveying motor32. In parallel with this operation control, the control device50controls the first head driver IC15to actuate the first head10and controls the second head driver IC25to actuate the second head20based on raster data for ejecting ink droplets according to the image being formed on the printing medium W.

Thus, the motor driver IC33controls driving of the conveying motor32based on commands received from the control device50, and the motor driver IC31controls driving of the carriage motor30based on commands received from the control device50. The first head driver IC15controls the first head10to eject ink based on commands received from the control device50, and the second head driver IC25controls the second head20to eject ink based on commands received from the control device50. Through this control, ink of prescribed quantities is ejected from the first head10and second head20.

Hence, in a conveying process, the conveying motor32is driven to convey the printing medium W downstream in the conveying direction Df (i.e., frontward). Note that prior to the conveying process in a printing process, the printing medium W is conveyed upstream in the conveying direction Df. In other words, the printing medium W is conveyed in the direction opposite to the conveying direction Df (i.e., frontward). In a carriage moving process, the carriage motor30is driven to move the carriage3in the main scanning direction Ds. As the carriage3moves in the main scanning direction Ds in this way, the control device50performs an ink ejection process to eject ink from the first head10and second head20provided in the carriage3. When performed in combination, these operations implement the printing process.

FIG.3Ais a plan view schematically illustrating the first head10and second head20provided in the carriage3of the printing apparatus1shown inFIG.1.FIG.3Bis a plan view schematically illustrating printing results by the first head10and second head20in the second mode. As shown inFIG.3A, the first head10and second head20are supported on a printing surface (bottom surface) of the carriage3. The first head10has nozzles that eject ink, and the second head20has nozzles that eject ink in the same colors as the first head10. The first head10and second head20are arranged to be partially overlapped in the conveying direction Df.

The first head10and second head20are each provided with a plurality of nozzle row sets, with each set of nozzle rows corresponding to a different color of ink. The sets of nozzle rows in each head are juxtaposed at regular intervals in the main scanning direction Ds. Specifically, the first head10has a nozzle row set11for yellow (Y), a nozzle row set12for magenta (M), a nozzle row set13for cyan (C), and a nozzle row set14for black (K) that eject ink in the respective colors (collectively referred to as color inks). Similarly, the second head20has a nozzle row set21for yellow, a nozzle row set22for magenta, a nozzle row set23for cyan, and a nozzle row set24for black. Each set of nozzle rows includes a plurality of nozzles (black dots indicated in the drawing using the same reference numerals with an appended “a”). While nozzles are only indicated on the ends of the nozzle row sets inFIG.3A, nozzles are actually provided over the entire surface of each nozzle row set. The numbers of nozzle row sets shown in the drawing are merely one example. While the carriage3is in an idle position (the left side, as shown inFIG.1), the nozzle row sets in the respective first head10and second head20are arranged in the order of nozzle row sets11and21for yellow, nozzle row sets12and22for magenta, nozzle row sets13and23for cyan, and nozzle row sets14and24for black beginning from the right side and progressing leftward.

The contribution percentage setting unit50bof the control device50executes a contribution percentage setting process for setting the contribution percentage of ink ejection from each of the first head10and second head20with respect to the density of dots constituting the image being printed in the second mode. The contribution percentage of each of the first head10and second head20can be set based on conditions described later for selecting the head with the higher contribution percentage. In other words, the contribution percentage setting process executed by the control device50in the second mode includes a selection process described later.

In the contribution percentage setting process, the control device50can vary the contribution percentages assigned to the first head10and second head20for printing in the second mode. In the example ofFIG.3B, the first head10is responsible for 50% and the second head20for 50%, resulting in a total of 100% when the printing is executed. However, printing can be executed using other contribution ratios. That is, when printing is executed under the second mode, the first head10ejects ink at the contribution percentage for the first head10and the second head20ejects ink at the contribution percentage for the second head20for a total ink ejection quantity of 100% in order to reproduce a single color through cooperation with the first head10and second head20. The contribution ratio of the first head10and second head20is set such that the contribution percentage for each of the first head10and second head20is greater than 0% and the total contribution percentage is equivalent to 100%. Sample contribution ratios are 30:70 and 60:40.

When the contribution percentage for the first head10is 30% and the contribution percentage for the second head20is 70%, for example, the control device50divides the raster data produced through rasterization into raster data for the first head10and raster data for the second head20. The control device50performs a masking process to mask the raster data for the first head10and the raster data for the second head20. Since the contribution percentage for the first head10is 30%, raster data for the first head10is generated using mask data that masks 70% of the original raster data, leaving 30% of the original raster data for ejecting ink using the first head10. Similarly, since the contribution percentage for the second head20is 70%, raster data for the second head20is generated using mask data that masks 30% of the original raster data, leaving 70% of the original raster data for ejecting ink using the second head20. In the subsequent printing process, the first head10prints in accordance with its contribution percentage by ejecting ink based on the raster data for the first head10. Similarly, the second head20prints in accordance with its contribution percentage by ejecting ink based on the raster data for the second head20.

FIG.4is a schematic diagram showing the layout of the ink tanks6, first head10, and second head20in the printing apparatus1ofFIG.1, and the conveying direction Df of the printing medium W. InFIG.4, the nozzle row sets described above with reference toFIG.3Aare depicted only with shading. While ink tanks6are provided for the four different ink colors described above, only one ink tank6is depicted inFIG.4. Each ink tank6provided in the printing apparatus1is connected to the first head10by a first ink tube16. Each ink tank6is connected to the second head20by a second ink tube26. The first ink tubes16and second ink tubes26are ink channels. Since the first head10and second head20are offset from each other but partially overlapped in the conveying direction Df, the second ink tube26in this example is longer than the first ink tube16.

The conveying motor32conveys the printing medium W in the conveying direction Df so that the printing medium W is discharged out through the opening2a(seeFIG.1). In this example, the second head20is positioned downstream (frontward) in the conveying direction Df of the printing medium W (indicated by the arrow shown inFIGS.3A and4) from the first head10in the carriage3. The second head20is also positioned downstream in the main scanning direction Ds from the first head10in the carriage3when the carriage3moves in the main scanning direction Ds from the idle position, in this example. Priority levels are set based on these layout conditions of the first head10and second head20and the priority level information indicating these priority levels is stored in the storage device40.

Priority levels can be set and stored as priority level information so that the head among the first head10and second head20connected by the shorter of the first ink tube16and second ink tube26is set to be a head with a higher priority level. In the present embodiment, the first head10corresponding to the first ink tube16can be set to have a higher priority level than the second head20corresponding to the second ink tube26longer than the first ink tube16.

Alternatively, the head among the first head10and second head20positioned upstream in the main scanning direction Ds when the carriage3moves in the main scanning direction Ds from the idle position can be set to have a higher priority level and the corresponding priority level can be stored. In the present embodiment, the first head10is positioned upstream in the main scanning direction Ds when the carriage3moves in the main scanning direction Ds from the idle position and can be set to have a higher priority level than the second head20. Alternatively, the head among the first head10and second head20positioned upstream in the conveying direction Df of the printing medium W can be set to have a higher priority level and the corresponding priority level information can be stored. In the present embodiment, the first head10is positioned upstream in the conveying direction Df of the printing medium W and can be set to have a higher priority level than the second head20. Alternatively, the head among the first head10and second head20that is farther from the opening2acan be set to have a higher priority level and the corresponding priority level information can be stored. In the present embodiment, the first head10is positioned farther from the opening2athan the second head20is from the opening2a, and can be set to have a higher priority level than the second head210. The priority levels will be described later in detail.

When printing in the first mode on the printing apparatus1having the structure described above, the control device50ejects ink from each of the first head10and second head20at a contribution percentage of 100%. When printing in the second mode, the control device50ejects ink from the first head10and second head20so that the total contribution percentage of the first head10and second head20is equivalent to 100%.

FIG.5is a flowchart illustrating steps in a process executed by the control device50of the printing apparatus1shown inFIG.1for setting the operating mode of the printing apparatus1. Specifically, the operating mode setting unit50aof the control device50sets the operating mode for one pass worth of printing to one of the first mode and second mode, as follows.

In S10at the beginning of the process inFIG.5, one pass worth of image data is inputted into the control device50, and the control device50acquires the inputted image data. In S11the control device50references the image data and reads a look-up table (hereinafter abbreviated as “LUT”). The LUT may possess a table of uncalibrated RGB values as well as a conversion table of calibrated RGB values, for example. Calibrated LUTs include LUTs possessing RGB data resulting from color calibration of the original RGB data.

In S12the control device50determines whether the LUT includes a reference (a color-calibrated conversion table). If the LUT includes a reference (S12: YES), in S13the control device50references the color-calibrated RGB data. If the LUT does not include a reference (S12: NO), in S14the control device50references normal data constituting the original RGB values. Subsequently, in S15the control device50performs color conversion on the inputted image data based on the LUT. In S16the control device50determines whether the entire pass worth of image data has been converted. If there remains data to convert in the pass (S16: NO), the control device50returns to S11, reads the LUT, and repeats the above determination.

Once the entire pass worth of image data has been converted (S16: YES), in S17the control device50determines whether a calibration LUT has been referenced during color conversion. If a calibration LUT has been referenced during color conversion (S17: YES), in S18the control device50sets the operating mode for printing to the second mode and subsequently ends the process ofFIG.5. However, if a calibration LUT has not been referenced during color conversion (S17: NO), in S19the control device50sets the operating mode for printing to the first mode and subsequently ends the process inFIG.5. Note that the control device50may be configured to select a LUT based on correlations with printing media determined in advance since colors produced during printing may appear different when printed on different printing media.

The printing apparatus1performs printing by scanning the carriage3provided with the first head10and second head20in the main scanning direction Ds. When the control device50determines that printing is to be performed in the first mode (S19), the printing apparatus1performs printing by ejecting ink from both the first head10and second head20. However, if the control device50determines that printing is to be performed in the second mode (S18), the printing apparatus1executes printing over a narrower range in the conveying direction Df of the printing medium W during one reciprocating movement of the carriage3than the range printed during one reciprocating movement of the carriage3in the first mode. At this time, the ink ejection contribution during one reciprocating movement of the carriage3in the main scanning direction Ds is shared by the first head10and second head20at a prescribed contribution ratio. For example, when determining that printing is being performed in the second mode (S18), the control device50divides printing responsibilities for one pass of printing between the first head10and second head20at prescribed contribution ratio so that contribution percentages total 100% (a divided halftone print). In this case, the feed amount of the printing medium W following the print for the pass is equivalent to the length of one head in the conveying direction Df.

On the other hand, if the control device50determines that printing is to be performed in the first mode (S19), the first head10and second head20both eject ink for one pass at a contribution percentage of 100%, thereby printing a total of two passes worth, for example. In this case, the feed amount for the printing medium W following the print for the pass (i.e., two passes worth of printing) is equivalent to the length of two heads (the first head10and second head20) in the conveying direction Df Note that the width of one pass may be the width when printing using all nozzles of a single head, or the width when printing using only some of their nozzles. Further, the printing of two passes in the first mode does not include a method of printing known as shingling for partially overlapping neighboring passes to prevent the occurrence of unprinted areas on either side of a pass (bordering areas between neighboring passes). In other words, the width of a two-pass print is the width printed by the first head10and second head20supported in the carriage3and includes cases in which the printing width is less than twice the printing width of one pass, assuming all nozzles were used to print that one pass.

Next, the method of selecting one of the first head10and second head20to be the head with the higher contribution percentage of ink ejection in the second mode will be described. Examples of prescribed contribution ratios for the first head10and second head20are 70:30(%) and 60:40(%). The following description focuses on selecting a head to have the higher contribution percentage in the contribution ratio. The control device50executes a contribution percentage setting process for setting the contribution percentages of ink ejection for the first head10and second head20with respect to the density of dots constituting the image being formed in the second mode. Specifically, the contribution percentage setting unit50bof the control device50performs the contribution percentage setting process. When selecting a head to have the higher contribution percentage in the contribution ratio for ink ejection in the second mode, the control device50selects a head in good condition and a head whose ink quantity is easy to adjust.

FIG.6is a flowchart illustrating steps in a first example of a selection process executed by the control device50of the printing apparatus1. The selection process ofFIG.6is performed to select one of the first head10and second head20to have a higher contribution percentage of ink ejection when printing in the second mode. The first example of the selection process ofFIG.6is an example of the (d-1) selecting of the present disclosure.

As described above, the storage device40stores nozzle property information indicating the ink ejection properties of nozzles. This nozzle property information may include information indicating the condition of nozzles such as variation in nozzle diameter and the minimum droplet quantity of ink ejected from the nozzles.

In S20of the selection process inFIG.6, the control device50acquires nozzle property information. The nozzle property information may be information on the condition of the nozzles. This information on nozzle condition includes the results of printing measurements conducted during manufacturing indicating. For example, the experimental results may indicate that the variation in nozzle diameter is small and that no nozzles with a small minimum droplet quantity exist.

In S21the control device50determines whether the first head10is in better condition than the second head20based on this nozzle property information. For example, the control device50may determine that the first head10is in better condition when the first head10has a smaller variation in nozzle diameter or, unlike the second head20, does not include any nozzles with a small minimum droplet quantity.

If the control device50determines that the first head10is in better condition (S21: YES), in S22the control device50selects the first head10to be a head with a higher contribution percentage, and subsequently ends the selection process. However, if the control device50determines that the second head20is in better condition than the first head10(S21: NO), in S23the control device50selects the second head20to be a head with a higher contribution percentage, and subsequently ends the selection process. In the first example of the selection process described above, the control device50selects a head with a higher contribution percentage based on the consideration that the head in better condition will have more stable ink ejection.

In the first example of the selection process described above, the determination in S21for determining whether the first head10is in better condition than the second head20can be achieved with one of the following embodiments.

In one embodiment, the nozzle property information described above may be information indicating variation in the diameters of the plurality of nozzles in the first head10and second head20. Thus, in the first example of the selection process, the control device50can select the first head10or second head20that has the smaller variation in nozzle diameter to be a head with a higher contribution percentage of ink ejection when printing in the second mode. This selection assumes that the head having the smaller variation in nozzle diameter will have more stable ink ejection.

As another embodiment, the nozzle property information may be information indicating the minimum droplet quantity of ink ejected from each of the plurality of nozzles in the first head10and second head20. In the first example of the selection process, the control device50can select the first head10or second head20having the larger minimum droplet quantity ejected from its nozzles to be a head with a higher contribution percentage of ink ejection. This selection is made based on the consideration that ink quantity is easier to adjust in a head having a larger minimum droplet quantity.

FIG.7is a flowchart illustrating steps in a second example of the selection process executed by the control device50in the printing apparatus1. The second example of the selection process is an example of the (c-2) selecting of the present disclosure.

As shown inFIG.3Aand described above, the first head10and second head20supported in the carriage3are arranged offset from each other but in a partially overlapped state in the conveying direction Df. In other words, each of the first head10and second head20has a portion in which the first head10and second head20overlap in the conveying direction Df (overlapped portion) and a portion in which the first head10and second head20do not overlap in the conveying direction Df (non-overlapped portion). When printing is performed, printing artifacts may be produced in a printing area printed by using nozzles of the overlapped portion. Therefore, when printing in the second mode, the control device50can perform printing using a normal distribution of ink ejection between the first head10and second head20so as to avoid such printing artifacts being produced. In this way, the control device50can prevent a drop in color reproducibility in printing areas printed by using nozzles in the overlapped portion. When printing artifacts are produced in printing areas printed by using nozzles in the non-overlapped portion, on the other hand, the control device50performs printing by ejecting ink from the first head10and second head20at the prescribed contribution ratio.

Note that a normal distribution sets contribution percentages of the first head10and second head20which is set in advance such that the contribution percentages of the first head10and second head20total 100% in order that the printing area printed by nozzles in the overlapped portion does not have a density difference perceivable by the user from printing areas printed by nozzles in the non-overlapped portions. The contribution percentages of the first head10and second head20corresponding to the normal distribution is pre-stored in the storage device40, and may be different from the contribution percentages set by the prescribed contribution ratio. The contribution percentages of the first head10and second head20corresponding to the normal distribution will be simply denoted as normal distribution.

In S30at the beginning of the selection process shown inFIG.7, the control device50acquires nozzle property information. In S31the control device50first determines whether any misdirection of ink ejection has occurred in the first head10. “Misdirection” includes a condition in which ink droplets land at positions on the printing medium W offset from their prescribed positions, for example. Misdirection can be confirmed in advance using a pin check pattern or a nozzle irregularity pattern, for example. Here, determining whether misdirection of ink ejection has occurred can be a process of determining whether the frequency of misdirection occurrences exceeds a prescribed threshold.

When misdirection has occurred in the first head10(S31: YES), in S32the control device50determines whether the ink ejection portion (more specifically, nozzles) in which this misdirection has occurred is the overlapped portion of the first head10and second head20. If the ink ejection portion in which the misdirection has occurred is nozzles in the overlapped portion of the first head10with the second head20(S32: YES), in S33the control device50sets the contribution percentages of the first head10and second head20to a normal distribution, and subsequent ends the selection process. However, if the ink ejection portion in which misdirection has occurred is not nozzles in the overlapped portion of the first head10(S32: NO), in S34the control device50selects the second head20to be a head with a higher contribution percentage, and subsequently ends the selection process.

On the other hand, when the control device50determines in S31that misdirection has not occurred in the first head10(S31: NO), in S35the control device50determines whether misdirection has occurred in the second head20. If misdirection has occurred in the second head20(S35: YES), in S36the control device50determines whether the ink ejection portion (more specifically, nozzles) in which the misdirection has occurred is nozzles in the overlapped portion of the second head20with the first head10. If the ink ejection portion in which the misdirection has occurred is nozzles in the overlapped portion of the second head20(S36: YES), in S37the control device50sets the contribution percentages of the first head10and second head20to a normal distribution, and subsequently ends the selection process. However, if the ink ejection portion in which misdirection has occurred is not the overlapped portion of the second head20(S36: NO), in S38the control device50selects the first head10to be a head with a higher contribution percentage, and subsequently ends the selection process.

However, if the control device50determines in S35that misdirection has not occurred in the second head20(S35: NO), in S39the control device50determines whether the nozzle diameter in the second head20is smaller than the nozzle diameter in the first head10. If the nozzle diameter in the second head20is smaller than the nozzle diameter in the first head (S39: YES), in S40the control device50selects the first head10to be a head with a higher contribution percentage, and subsequently ends the selection process. However, if the nozzle diameter of the second head20is not smaller than the nozzle diameter in the first head (S39: NO), in S41the control device50selects the second head20to be a head with a higher contribution percentage, and subsequently ends the selection process.

Through the second example of the selection process described above, the control device50selects the head having the lower frequency of misdirection and the larger nozzle diameter since nozzle variation in this head is easier to correct. An additional condition for making this determination is whether the printing area is printed using nozzles in the overlapped portion of the first head10and second head20. The nozzles in the overlapped portion of the first head10and the second head20are examples of the specific first nozzle and the specific second nozzle of the present disclosure.

Next, a third example of the selectin process will be described with reference toFIGS.8and9.FIG.8is a schematic diagram of an image process in which the color gamut is different when printing by moving the first head10and second head20of the printing apparatus1rightward in the main scanning direction Ds (the forward direction indicated by the arrow shown inFIG.8) and when printing by moving the first head10and second head20leftward in the main scanning direction Ds (the return direction).FIG.9is a flowchart illustrating steps in the third example of the selection process performed by the control device50of the printing apparatus1. Note thatFIG.8has been simplified for purposes of explaining the image process. The forward direction and return direction are examples of the first direction and second direction of the present disclosure. The third example of the selection process is an example of the (f) selecting of the present disclosure.

As illustrated inFIG.3A, each nozzle row set in the first head10and second head20has a plurality of nozzles arranged at regular intervals along the conveying direction Df. While the carriage3is in the idle position (the left side, as shown inFIG.1), the nozzle row sets in the respective first head10and second head20of the present embodiment are arranged in the order of nozzle row sets11and21for yellow (Y), nozzle row sets12and22for magenta (M), nozzle row sets13and23for cyan (C), and nozzle row sets14and nozzle row set24for black (K) beginning from the right side (from the downstream side in the forward direction) and progressing leftward (toward the upstream side in the forward direction).

When performing a two-way scan in which the carriage3is reciprocated in both directions along the main scanning direction Ds (the forward direction and return direction) with the nozzle row sets having this arrangement, ink is ejected in a sequence beginning from yellow (Y) when the carriage3is scanned from left to right in the forward direction and in a sequence beginning from black (K) when the carriage3is scanned from right to left in the return direction. Consequently, the color gamut for the forward direction differs from the color gamut of the return direction.

Prior to printing the target image, one pass worth of the image is divided into a plurality of blocks and RGB values are derived for each block unit. Next, weights are calculated based on the RGB values in each block unit to determine whether color reproducibility is maintained. When the weight per unit area in a block exceeds a threshold value, printing of the pass for that block is controlled as a one-way scan (a forward scan in the present embodiment). The threshold value for the weight is set based on whether the color gamut is changed. If the color gamut is changed based on the sequence of ink ejection during printing, the control device50performs control to print in a one-way scan along the main scanning direction Ds (the forward direction in the present embodiment) to expand the color gamut. In other words, the control device50selects the direction for which the color gamut is wider than the color gamut for the other direction as a printing direction, and performs control to perform printing for the pass in a one-way scan along the selected printing direction. For example, when the color gamut when printing in the forward direction is wider than the color gamut when printing in the return direction, the forward direction is selected as the printing direction.

Note thatFIG.8provides one example of weights for each block unit. In this example, 1.0 is a value that exceeds the threshold. Thus, a one-way scan is used to print passes that include blocks having a weight of 1.0. The pass shown inFIG.8includes blocks having a weight of 1.0. Hence, the forward direction would be selected as the printing direction for this pass, as described below with reference toFIG.9.

In S50ofFIG.9, the control device50acquires head property information for the first head10and second head20. The head property information includes information indicating one of the forward direction and reverse direction that expands the color gamut. In S51the control device designates a single block from among a plurality of blocks included in the current pass as a target block. In S52the control device50determines for the target block whether the color gamut when printing in the rightward (forward) direction (a forward print) differs from the color gamut when printing in the leftward (return) direction (a return print) by a prescribed value or greater. Specifically, the control device50determines that the difference in color gamut between a forward print and a return print is equal to or greater than the prescribed value when the weight for the target block exceeds the threshold.

If the change in color gamut is equal to or greater than the prescribed value (S52: YES), in S53the control device50selects the direction that expands the color gamut as the printing direction, sets a one-way print in the selected printing direction for the pass, and subsequently ends the selection process. For example, when the forward direction is selected as the printing direction, the forward print is set for the pass and printing is performed only when the carriage3moves in the forward direction. In this case, the contribution ratio of the first head10and second head20can be set to 100:0, for example. When the head property information for the first head10includes the information indicating the forward direction but the head property information for the second head20includes the information indicating the reverse direction, the contribution percentages of the first head10and second head20are set to 100% and 0% respectively, and the forward print is performed for the pass by ejecting ink from the first head10. With this method, the printing speed drops since the pass is printed only in one direction.

However, if the change in color gamut is smaller than the prescribed value (S52: NO), in S54the control device50determines whether the determination in S52has been completed for all blocks included in the current pass. If the determination has not been completed (S54: NO), the control device50returns to the process in S51to designate one of unprocessed blocks as a target block, and repeats the process from S52for the target block.

Once the determination has been completed for all blocks in the pass (S54: YES), in S55the control device50sets the contribution percentages of the first head10and second head20to a normal distribution, and subsequently ends the selection process. In this case, the contribution ratio of the first head10and second head20can be set to 50:50. Further, printing speed is increased since a two-way print is performed for the pass.

Thereafter, the control device50executes a print in the second mode by ejecting ink from the first head10and second head20at the contribution ratio set in the selection process. Through this process, the control device50can prevent a drop in color reproducibility caused by changes in the color gamut.

FIG.10is a flowchart showing steps in a fourth example of the selection process executed by the control device50of the printing apparatus1. In the fourth example of the selection process ofFIG.10, the control device50selects a head with a higher contribution percentage when printing in the second mode based on manufacturing error in the first head10and second head20. The fourth example of the selection process is an example of the (g-1) selecting of the present disclosure.

Here, head property information can be stored in the storage device40. The head property information may include a measured value for the ink channels in the first head10measured when the first head10was manufactured and a median value for the ink channels in the first head10(a representative value that is a design value), and a measured value for the ink channels in the second head20measured when the second head20was manufactured and a median value for the ink channels in the second head20(a representative value that is a design value).

The control device50performs the selection process inFIG.10when printing in the second mode. In S60at the beginning of this process, the control device50acquires head property information. In S61the control device50determines whether the measured value for the ink channels in the first head10is closer to its median value than the measured value for the ink channels in the second head20is to its median value. If the measured value for the ink channels in the first head10is closer to its median value than the measured value for the ink channels in the second head20is to its median value (S61: YES), in S62the control device50selects the first head10to be a head with a higher contribution percentage, and subsequently ends the selection process. However, if the measured value for the ink channels in the second head20is closer to its median value than the measured value for ink channels in the first head10is to its median value (S61: NO), in S63the control device50selects the second head20to be a head with a higher contribution percentage, and subsequently ends the selection process. Thus, in the fourth example of the selection process, the control device50selects a head with a higher contribution percentage based on the consideration that the head having a measured value for ink channels closer to the median value will have more stable ink ejection.

In the example shown inFIG.4, the ink tank6provided in the printing apparatus1is connected to the first head10by the first ink tube16and is connected to the second head20by the second ink tube26. Further, priority level information can be set so that the priority levels indicate which of the first head10and second head20would be most favorably selected to be a head with a higher contribution percentage based on the layout of the first head10and second head20relative to the conveying direction Df of the printing medium W, the arrangement of the printing medium W relative to the main scanning direction Ds in which the first head10and second head20move, and the like. The priority level information can be set based on favorability of ink supply and low probability of damage, for example. Priority level information indicating priority levels based on the layout of the first head and second head20are stored in the storage device40.

The control device50executes the contribution percentage setting process when printing in the second mode to set the contribution percentages at which the first head10and second head20contribute to ink ejection with respect to the density of dots constituting the image. The control device50executes a fifth example of the selection process for selecting one of the first head10and second head20to be a head with a higher ink ejection contribution percentage based on these priority levels indicated by the priority level information. Through this fifth example of the selection process, the control device50selects a head with a higher contribution percentage toward ink ejection based on the layout of the first head10and second head20. The priority level information is set to indicate the priority level higher for the first head10or second head20having the more favorable ink channel length, layout, and the like. Specifically, the control device50can perform the fifth example of the selection process as follows. The fifth example of the selection process is an example of the (h-1) selecting of the present disclosure.

In the fifth example of the selection process, the control device50determines that the head among the first head10and second head20connected by the shorter one of the first ink tubes16and second ink tubes26(seeFIG.4) is a head having a higher priority and can select this head as a head with a higher ink contribution percentage. This selection is based on the consideration that the head connected with the shorter ink tubes supplies ink more readily. In the example ofFIG.4, the first ink tubes16are shorter than the second ink tubes26. Since the first ink tubes16are shorter than the second ink tubes26and ink is more readily supplied through the shorter ink tubes, the first head10connected to the first ink tubes16can be said to be in better condition.

In the fifth example of the selection process, the control device50also determines that the head among the first head10and second head20positioned upstream in the main scanning direction Ds (the forward direction) when the carriage3moves in the main scanning direction Ds from the idle position has a higher priority level and can select this head to be a head with a higher ink contribution percentage. This selection is based on the consideration that the head positioned upstream in the main scanning direction Ds (the forward direction) when the carriage3moves in the main scanning direction Ds from the idle position (the position inFIG.1) has fewer opportunities to print and, hence, is in better condition. When the carriage3begins moving in the main scanning direction Ds from the idle position shown inFIG.1, the second head20begins printing first. Since movement of the carriage3normally begins from the idle position, the first head10has fewer printing opportunities than the second head20. Therefore, the first head10can be said to be in better condition.

In the fifth example of the selection process, the control device50also determines that the head among the first head10and second head20farther from the opening2ahas a higher priority level and can select this head to be a head with a higher ink contribution percentage. This selection is based on the consideration that the head farther from the opening2a, i.e., the head positioned upstream in the conveying direction Df of the printing medium W has fewer opportunities to contact the printing medium W than the head closer to the opening2a, i.e., the head positioned upstream in the conveying direction Df of the printing medium W. In the example ofFIG.1, the first head10is the head farther from the opening2a. The tray7is moved rearward (the direction opposite to the conveying direction Df of the printing medium W) inFIG.1by the drive force of the conveying motor32prior to a printing process. Since the second head20is positioned forward of the first head10, the second head20is more likely to contact the printing medium W before the first head10as the printing medium W fixed to the tray7moves rearward together with the tray7. If the second head20contacts the printing medium W, the user or the printing apparatus1halts movement of the tray7at the moment of contact to prevent damage to the second head20. Consequently, there is a lower probability that the first head10will contact the printing medium W than the probability that the second head20will contact the printing medium W. Since the first head10that is farther from the opening2aand is positioned upstream in the conveying direction Df of the printing medium W has fewer opportunities to contact the printing medium W than the second head20that is closer to the opening2aand is positioned downstream in the conveying direction Df of the printing medium W, the first head10can be considered to be in better condition.

FIG.11is a flowchart illustrating steps in a sixth example of the selection process executed by the control device50of the printing apparatus1. In the example ofFIG.11, the control device50selects a head with a higher contribution percentage of ink ejection when printing in the second mode based on usage history of the first head10and second head20. The sixth example of the selection process is an example of the (j-1) selecting of the present disclosure.

Usage history information stored in the storage device40and indicating usage history may include information on usage time for the first head10after the first head10was last replaced and information on the usage time for the second head20after the second head20was last replaced. Usage history information stored in the storage device40may also include information on the total ink ejection quantity for the first head10and information on the total ink ejection quantity for the second head20. Usage history information stored in the storage device40may also include opportunities for pin omissions in the first head10and second head20. Usage history information stored in the storage device40may also include the number of purges on the first head10and second head20including the number of suction purges and the number of pressure purges. The opportunities for pin omissions may be stored as the number of times ink could not be ejected from a nozzle. The number of purges may be stored as the number of times ink was discharged from a head.

In S70of the sixth example of the selection process ofFIG.11, the control device50acquires head usage history information. In S71the control device50determines whether the second head20has been used more than the first head10. The control device50makes this determination based on information on usage time, total ink ejection quantity, fewest opportunities for pin omissions, and the like described above. If the second head20has been used more than the first head10(S71: YES), in S72the control device50selects the first head10to be a head with a higher contribution percentage, and subsequently ends the selection process. However, if the second head20has not been used more than the first head10(S71: NO), in S73the control device50selects the second head20to be a head with a higher contribution percentage, and subsequently ends the selection process. Thus, in the sixth example of the selection process, the control device50determines which head is in better condition based on information on usage time, information on the total ink ejection quantity, information on pin omissions, and the like and selects the head in better condition to be a head with a higher contribution percentage.

FIG.12is a flowchart illustrating steps in a seventh example of the selectin process executed by the control device50of the printing apparatus1. The seventh example of the selection process ofFIG.12is performed to select one of the first head10and second head20to have the higher contribution percentage of ink ejection when printing in the second mode. The seventh example of the selection process is an example of the (j-1) selecting of the present disclosure.

Usage history information stored in the storage device40and indicating usage history may include information specifying the number of times the cleaning process has been executed for the first head10, and information specifying the number of times the cleaning process has been executed for the second head20. Usage history information stored in the storage device40may also include information specifying the amount of time that has elapsed after the last replacement of the first head10, and information specifying the amount of time that has elapsed after the last replacement of the second head10. Usage history information stored in the storage device40may also include information specifying the total ink ejection quantity for the first head10, and information specifying the total ink ejection quantity for the second head20.

In the seventh example of the selection process performed when printing in the second mode, the control device50determines which of the first head10and second head20is the head having the less number of times that the cleaning process has been executed therefor, i.e., the head having the smaller cleaning frequency, the head having the less amount of elapsed time after the last replacement thereof, or the head having the smaller total ejection quantity. Based on these results, the control device50can select one of the heads to have a higher contribution percentage of ink ejection. Through this process, the control device50can properly determine which of the first head10and second head20is in better condition and can select the head with the higher contribution percentage. Specifically, the control device50performs the seventh example of the selection process as follows.

In S80of the seventh example of the selection process ofFIG.12, the control device50acquires the head usage history information. In S81the control device50determines whether the second head20has a greater number of times that the cleaning process has been executed than the first head10by the prescribed threshold or greater. In other words, in S81the control device50determines whether the second head20has a cleaning frequency greater than a cleaning frequency of the first head by the prescribed threshold or greater. If the cleaning frequency of the second head20is not greater than the cleaning frequency of the first head10by the prescribed threshold or greater (S81: NO), in S82the control device50selects the second head20to be a head with a higher contribution percentage, and subsequently ends the seventh example of the selection process. This selection is made based on the consideration that the head hat has undergone fewer cleaning processes is in better condition.

Alternatively, in the determination of S81the control device50may select the head among the first head10and second head20whose cleaning frequency has not exceeded a threshold value to be a head with a higher contribution percentage. This selection is made based on the consideration that a head that has undergone fewer cleaning processes than the threshold value is in good condition.

In the present embodiment, if the control device50determines in S81that the second head20has a cleaning frequency greater than a cleaning frequency of the first head10and that the difference between the cleaning frequency of the second head20and the cleaning frequency of the first head10is equal to or greater than the prescribed threshold (S81: YES), in S83the control device50determines whether the usage time of the second head20is greater than the usage time of the first head10by a prescribed time or greater. If the usage time of the second head20is not greater than the usage time of the first head10by the prescribed time or greater (S83: NO), in S82the control device50selects the second head20to be a head with a higher contribution percentage, and subsequently ends the seventh example of the selection process. This selection is made based on the consideration that the head having lower usage is in better condition.

Alternatively, in the seventh example of the selection process the control device50may select the head among the first head10and second head20having the shorter elapsed time after the last replacement to be a head with a higher contribution percentage based on the usage history. This selection is made based on the consideration that the head for which a shorter amount of time has elapsed since first being used is in better condition.

In the present embodiment, if the usage time of the second head20does exceed the usage time of the first head10by the prescribed time or greater (S83: YES), in S84the control device50determines whether the second head20has a higher total ink ejection quantity than the first head10. If the total ink ejection quantity for the second head20is not higher than the total ink ejection quantity for the first head (S84: NO), in S82the control device50selects the second head20to be a head with a higher contribution percentage, and subsequently ends the seventh example of the selection process. On the other hand, if the total ink ejection quantity for the second head20is higher than the total ink quantity for the first head (S84: YES), in S85the control device50selects the first head10to be a head with a higher contribution percentage, and subsequently ends the seventh example of the selection process. This selection is made based on the consideration that the head with a lower total ink ejection quantity is in better condition.

Alternatively, in the seventh example of the selection process the control device50may select the head among the first head10and second head20whose total ink ejection quantity is lower based on the usage history to be a head with a higher ink contribution percentage. This selection is made based on the consideration that a head with a lower total ink ejection quantity is in better condition.

Thus, in the second mode the control device50selects one of the first head10and second head20to be a head with a higher contribution percentage and executes printing by ejecting ink from the first head10and second head20to achieve a total contribution percentage of 100%. By setting a higher contribution percentage for the more stable head in this way, the control device50can perform suitable printing with high color reproducibility.

The selection process executed by the control device50can be achieved according to the following embodiment. The following embodiment is an example for setting the contribution percentages of ink ejection from the first head10and second head20based on the condition of nozzles in the nozzle row sets for each of the first head10and second head20.

When executing the contribution percentage setting process in this embodiment for setting the contribution percentages of ink ejection from the first head10and second head20with respect to the density of dots constituting the image being printed in the second mode, a predetermined mask is used in the contribution percentage setting unit50b, but the present disclosure is not limited to this configuration. The control device50may generate a new mask in the contribution percentage setting unit50b.

(1) The new mask determines whether misdirection of ink ejection has occurred for all nozzles assigned the same number among the nozzle row sets for the first head10and second head20. Next, the nozzles in which misdirection has occurred are masked and printing is executed by ejecting ink using nozzles in which misdirection has not occurred. In this case, ink equivalent to the contribution percentage of masked nozzles in the head with masked nozzles is ejected from nozzles in the other head.

(2) A mask may be configured to mask nozzles that are not being used and not to mask nozzles that are being used for reducing the occurrence of density differences between printing areas printed using overlapped portions in which the first head10and second head20overlap in the conveying direction Df and printing areas printed using non-overlapped portions in which the first head10and second head20do not overlap in the conveying direction Df so that the user cannot recognize such density differences. Similarly, a new mask may be configured to mask nozzles that are not being used and not to mask nozzles that are being used when misdirection has not occurred in nozzles assigned the same number among both nozzle row sets in the first head10and nozzle row sets in the second head20and when nozzles assigned the same number in both the first head10and second head20have an ink ejection portion positioned in the overlapped portions of the first head10and second head20.

(3) A new mask may also be configured to mask nozzles not being used and not to mask nozzles being used based on the diameter of relevant nozzles in the first head10and the diameter of relevant nozzles in the second head20when nozzles assigned the same number in both nozzle row sets of the first head10and nozzle row sets of the second head20have an ink ejection portion that is not positioned in the overlapped portions of the first head10and second head20. Specifically, the new mask masks relevant nozzles in the second head20and does not mask relevant nozzles in the first head10when the diameter of the relevant nozzles in the first head10is greater than the diameter of the relevant nozzles in the second head20. On the other hand, the new mask masks relevant nozzles in the first head10and does not mask relevant nozzles in the second head20when the diameter of the relevant nozzles in the second head20is greater than the diameter of the relevant nozzles in the first head10.

These new masks may be human-generated. Once an entire pass worth of image data has been converted in the process ofFIG.5described above, the control device50determines whether a calibration LUT has been referenced during color conversion (S17), sets the operating mode of the printing apparatus1to the second mode (S18) when determining that a calibration LUT has been referenced during color conversion, and performs printing in the second mode using the new mask. However, when the control device50determines that a calibration LUT has not been referenced during color conversion, the control device50sets the operating mode of the printing apparatus1to the first mode (S19) and performs printing in the first mode without using the new mask.

As described above, the printing apparatus1has a first mode and a second mode for printing images, and the second mode executes printing with higher color reproducibility than the first mode. In the first mode, the printing apparatus1executes printing by ejecting ink at a contribution percentage of 100% from each of the first head10and second head20. In the second mode, the printing apparatus1executes printing by ejecting ink so that the contribution percentages for the first head10and second head20total 100%. Accordingly, when printing requires high color reproducibility, the printing apparatus1can eject ink at a contribution percentage from the first head10and second head20totaling 100% in the second mode to achieve this high color reproducibility.

In the embodiment described above, the printing unit50cexecutes printing by ejecting ink at a contribution percentage of 100% from each of the first head10and second head20when the operating mode is set to the first mode, but the present disclosure is not limited to this configuration. When the operating mode is set to the first mode, the printing unit50cmay eject ink at approximately 100% contribution percentage from each of the first head10and second head20. Here, approximately 100% includes a range of about 95%-105%.

Further, in the embodiment described above, the printing unit50cexecutes printing by ejecting ink from both the first head10and second head20such that their contribution percentages total 100% when the operating mode is set to the second mode, but the present disclosure is not limited to this configuration. When the operating mode is set to the second mode, the printing unit50cmay execute printing by ejecting ink from both the first head10and second head20so that their total contribution percentage is approximately 100%. Here, approximately 100% includes a range of about 95%-105%.