JP2005254817A - Printer, printing method, and recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enhance an image quality of a multivalued printer representing ternary or higher densities per pixel. <P>SOLUTION: An inkjet printer discharges ink continuously to each pixel during main scanning and represents many gradations for each pixel according to the number of the dots. In this operation, a relationship between a gradient of image data and a dot formation pattern is set differently between black and other colors. Black dots to be formed for each pixel are formed by two scannings, that is, an amount of ink to be discharged to each pixel in one main scanning is set to be smaller than the other colors. The bleeding of the black dots is suppressed thereby, so that the image quality improves. In a printer provided with more black nozzles than the other color ones, the image quality is improved without lowering a printing speed. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a printing apparatus that prints an image by forming dots on a printing medium, and more particularly to a printing apparatus that can express a density of three or more values for each pixel.

  2. Description of the Related Art Conventionally, various printers are widely used as computer output devices to print multi-color and multi-tone images. As one of such printers, for example, there is an ink jet printer that records an image by forming dots with several colors of ink ejected from a plurality of nozzles provided in a head. Inkjet printers usually can only express two gradations of dots on and off for each pixel. Therefore, an image is printed after performing halftone processing that expresses the multi-gradation of the original image data by the distribution of dots.

  In recent years, as a technique for realizing rich gradation expression, a printer capable of expressing more gradations than on / off binary values for each dot, a so-called multi-value printer, has been proposed. Examples of multi-value printers include those capable of forming dots with different ink amounts according to the gradation value given to each pixel as print data, and those that form a plurality of dots superimposed on each pixel. It is done. Such a multi-value printer can realize smooth gradation expression and perform high-quality printing.

  In general, in a printer, it is important to improve image quality by printing an image with low dot visibility and excellent graininess, and by realizing smooth gradation expression. It is also important to ensure the image printing speed. In conventional multi-value printers, gradation values that can be expressed for each pixel are set in consideration of these two sides.

  In the conventional multi-value printer, the relationship between the gradation value for each pixel and the dot formation mode is unified for all colors. For example, in a multi-value printer that forms dots by changing the amount of ink in three levels, large, medium, and small, the amount of ink for large dots, the amount of ink for medium dots, and the amount of ink for small dots are unified for all colors. .

  However, generally, even when dots are formed with the same ink amount, the visibility of the dots varies depending on the color. For example, a small dot formed with yellow ink and a small dot formed with black ink have higher visibility as dots. Further, the contribution to gradation expression when the ink amount is changed is also different. For example, when the difference between the density expressed by small dots and the density expressed by large dots is compared between yellow and black, the latter is larger than the former.

  In order to print an image with excellent graininess while suppressing dot visibility, setting a small amount of ink for each dot reduces the effect of enriching gradation expression for some colors such as yellow . On the other hand, if the difference in the ink amount of each dot is increased in order to enrich the gradation expression for such color, the dot will be easily visible for some colors such as black, and the graininess will be poor and smooth. The image is missing. Further, if the ink amount of each dot is increased, the printed dots are likely to be blurred. Bleeding that occurs with ink with high dot visibility is very visible and causes image quality to deteriorate. As described above, in the conventional multi-value printer, it is difficult to form each dot in a mode that can sufficiently improve the graininess and blur of the image and improve the gradation expression.

  On the other hand, a printer that prints multiple colors generally has a mode for printing only a single color. In such a printer, in order to ensure the printing speed at the time of monochromatic printing, the nozzles of the color used in monochromatic printing are often provided more than the nozzles of other colors. At the time of multicolor printing, printing is executed using the same number of nozzles for all colors, so that the extra nozzles for single color printing were not used for printing and were not fully utilized. It has not been studied to improve the image quality by using these surplus nozzles during multicolor printing.

  The present invention has been made to solve the above-described problems, and suppresses dot visibility and blurring in a multi-color printing apparatus capable of expressing three or more gradation values for each pixel. An object is to provide a technique for improving the image quality by improving the gradation expression. It is another object of the present invention to provide a technique for improving image quality by effectively using dot forming elements provided in a head.

In order to solve at least a part of the above-described problems, the present invention employs the following configuration.
The printing apparatus of the present invention includes:
The level of print data that has been halftoned to more than three values for each pixel while performing main scanning in which a head capable of forming multicolor dots is reciprocally moved in one direction in a print medium in accordance with a drive signal. A printing apparatus that prints an image on the print medium by forming dots according to a tone value,
Storage means for storing a correspondence relationship between the gradation value and the dot to be formed, wherein at least one specific color of the multiple colors is set differently from other colors;
The present invention includes a driving unit that outputs the driving signal to the head during the main scanning and forms the multi-colored dots for each pixel in a forming manner corresponding to the correspondence.

  According to such a printing apparatus, it is possible to form dots corresponding to the halftone-processed gradation values in the formation mode different from the other colors for the specific color. As a result, it is possible to form dots in an appropriate formation mode set in consideration of the visibility and blurring of dots formed for each color, contribution to gradation expression, and the like. Therefore, according to the printing apparatus of the present invention, it is possible to realize high-quality printing with improved gradation expression while suppressing dot visibility and blurring.

  For example, in a printing apparatus that forms the two or more types of dots by changing the ink amount, the relationship between the gradation value and the ink amount can be made different. Accordingly, it is possible to set the ink amount for the gradation value 1 to be large for yellow and small for black. It is possible to set the change in the ink amount with respect to the gradation value 1 and the gradation value 3 to be large for yellow and small for black. As a result, both the dot visibility and the contribution to gradation expression can be improved for both colors. Since halftone processing is usually performed in consideration of the density expressed by the dots to be formed, printing is performed even if the correspondence between the gradation value and the ink amount for yellow is set differently as described above. The color tone of the printed image is not impaired.

  Here, yellow and black have been described as examples, but it is needless to say that other colors can also be set. In the printing apparatus that forms the two or more types of dots by changing the number of times the drive signal is output, an appropriate number of times can be set for each color.

In the printing apparatus of the present invention,
The correspondence relationship may be a relationship in which more dots formed by main scanning than the other colors correspond to the gradation value for the specific color.

  Such correspondence includes both the case where the relationship between the gradation value and the ink amount is unified for all colors and the case where the relationship is different for each color. According to the above-described correspondence relationship, the specific color forms dots with more main scans than other colors. When these dots are formed by different nozzles, it is possible to disperse the deviations in dot formation positions that occur for each nozzle, and to realize high-quality printing with little dot deviation.

  In a head that forms dots using ink, the dots can be formed in a plurality of times, so that ink bleeding can be suppressed and high-quality printing can be realized. In general, bleeding is considered to be caused by ink soaking into the gaps between fine fibers constituting the printing medium by capillary action. When the dots are formed in a plurality of times, the fine gaps are closed by drying the first ink. Accordingly, the second and subsequent inks are less likely to bleed.

In this way, in a printing apparatus that forms dots in many main scans for a specific color,
The head is preferably a head having more dot forming elements for forming the dots for the specific color than for other colors.

  In this way, it is possible to increase the number of main scans for a specific color while suppressing a decrease in printing speed. Here, the number of main scans means the total number of main scans required to form dots for each pixel. Accordingly, when dots are formed with two different dot forming elements for one pixel during one movement of the head, the total number of main scans is considered to be two.

The printing apparatus of the present invention can be applied to a printing apparatus including various heads. In particular, the head is a head that forms dots by discharging liquid ink onto the printing medium. preferable.
In a printing apparatus that forms dots using liquid ink, the effect of improving the image quality by suppressing misalignment or blurring of dot formation positions is very large.

Further, the printing apparatus of the present invention can be applied to various printing apparatuses that can express a density of three or more values for each pixel.
For example,
The head may be applied to a printing apparatus that is a head capable of forming the two or more types of dots by changing the ink amount in accordance with the drive signal.
The driving unit may be applied to a printing apparatus that is a unit that expresses a density of three or more values for each pixel by changing the number of driving signals output for each pixel.

Although the specific color in the present invention can be set to various colors, it is particularly desirable that the specific color is black.
In general, since black is easily visible, the effect of improving the image quality by suppressing the visibility and blurring of dots by applying the present invention greatly appears. Of course, the specific color is not limited to one color, and can be set to a plurality of colors. Even in this case, it is desirable to include black.

The present invention can also be configured as a printing method described below.
The printing method of the present invention includes:
The level of print data that has been halftoned to more than three values for each pixel while performing main scanning in which a head capable of forming multicolor dots is reciprocally moved in one direction in a print medium in accordance with a drive signal. A printing method for printing an image on the print medium by forming dots according to a tone value,
(A) inputting the print data;
(B) The driving signal is output to the head during the main scanning, and the multiplicity for each pixel is formed according to a predetermined correspondence relationship stored in advance for the gradation value and the dot to be formed. Forming a color dot,
The correspondence relationship is a printing method in which at least one specific color among the multiple colors is a correspondence relationship set differently from the other colors.
According to such a printing method, high-quality printing can be realized by the same operation as that described in the printing apparatus.

The present invention can also be configured as a recording medium on which a program is recorded. That is, the recording medium of the present invention is
The level of print data that has been halftoned to more than three values for each pixel while performing main scanning in which a head capable of forming multicolor dots is reciprocally moved in one direction in a print medium in accordance with a drive signal. A recording medium in which a program for driving a printing apparatus that forms dots according to tone values is recorded in a computer-readable manner,
The data used in the program is a correspondence relationship between the gradation value and the dot to be formed, and at least one specific color among the multiple colors is set differently from the other colors Is a recording medium.

  By realizing the program recorded on such a recording medium by a computer, the printing apparatus and the printing method of the present invention can be realized. Note that a configuration as a recording medium in which the main body of the program for driving the printing apparatus is stored in another recording medium and only the predetermined correspondence relationship is stored is also possible.

  As storage media in this case, flexible disks, CD-ROMs, magneto-optical disks, IC cards, ROM cartridges, punch cards, printed matter on which codes such as barcodes are printed, computer internal storage devices (such as RAM and ROM) Various types of computer-readable media such as a memory) and an external storage device can be used. Moreover, the aspect as a program supply apparatus which supplies these programs and the said corresponding relationship to a computer via a communication path is also included.

(1) Device configuration:
Hereinafter, embodiments of the present invention will be described based on examples. FIG. 1 is an explanatory diagram showing the configuration of a printing system using a printer PRT as an embodiment of the present invention. The printer PRT is connected to the computer PC, receives image data from the computer PC, and executes printing. The computer PC is connected to an external network TN, and can also download a program for driving the printer PRT by connecting to a specific server SV. It is also possible to load necessary programs and data from a recording medium such as a flexible disk or a CD-ROM using a flexible disk drive FDD or a CD-ROM drive CDD.

  FIG. 1 also shows the functional block configuration of the printer PRT. The printer PRT includes an input unit 91, a buffer 92, a main scanning unit 93, a sub-scanning unit 94, a head driving unit 95, and a formation pattern table 96. The input unit 91 receives image data from the computer PC and temporarily stores it in the buffer 92. The image data given from the computer PC is data giving a density to be expressed by forming dots for each pixel arranged two-dimensionally. The main scanning unit 93 performs main scanning in which the head of the printer PRT reciprocates relative to the printing paper based on the image data. The sub-scanning unit 94 performs sub-scanning for transporting the printing paper in a direction orthogonal to the main scanning direction every time the main scanning is completed. The head driving unit 95 drives the printer head based on the image data stored in the buffer 92 during main scanning, and forms dots on the printing paper. As will be described later, the printer PRT of this embodiment can express four levels of density by changing the number of dots formed in each pixel. The correspondence relationship between the density given as image data and the dot formation pattern is stored in the formation pattern table 96. The head driving unit 95 forms dots in a predetermined pattern on each pixel while referring to the formation pattern table 96.

  Next, a schematic configuration of the printer PRT will be described with reference to FIG. As shown in the figure, the printer PRT includes a mechanism for transporting the paper P by the paper feed motor 23, a mechanism for reciprocating the carriage 31 in the axial direction of the platen 26 by the carriage motor 24, and a print head mounted on the carriage 31. And a control circuit 40 that controls the exchange of signals with the paper feed motor 23, the carriage motor 24, the print head 28, and the operation panel 32.

  The mechanism for reciprocating the carriage 31 in the axial direction of the platen 26 is an endless drive belt between the carriage motor 24 and a slide shaft 34 that is installed in parallel with the axis of the platen 26 and slidably holds the carriage 31. 36, a pulley 38 for extending 36, a position detection sensor 39 for detecting the origin position of the carriage 31, and the like.

  This carriage 31 is a cartridge containing black ink (K) cartridge 71 and five colors of ink, cyan (C), light cyan (LC), magenta (M), light magenta (LM), and yellow (Y). An ink cartridge 72 can be mounted. A total of six ink ejection heads 61 to 66 are formed on the print head 28 below the carriage 31. When the cartridges 71 and 72 are mounted on the carriage 31, ink is supplied from each ink cartridge to the heads 61 to 66.

  FIG. 3 is an explanatory diagram showing the arrangement of the nozzles Nz in the heads 61-66. These nozzles consist of six sets of nozzle arrays that eject ink for each color. In the nozzle array for black ink, 96 nozzles Nz are arranged in a staggered manner at a constant nozzle pitch k. In the nozzle array for color ink, 48 nozzles Nz are arranged in a line at a nozzle pitch 2k that is twice that of black. The printer PRT has twice as many nozzles for black ink as nozzles for color ink.

  A mechanism for ejecting ink will be described. FIG. 4 is an explanatory diagram showing a schematic configuration inside the ink ejection head 28. For convenience of illustration, three colors K, C, and LC are shown. In the heads 61 to 66, a piezoelectric element PE is arranged for each nozzle. As shown in FIG. 4, the piezo element PE is installed at a position in contact with the ink passage 68 that guides ink to the nozzle Nz. As is well known, the piezo element PE is an element that transforms electro-mechanical energy at a very high speed because the crystal structure is distorted by application of a voltage. In this embodiment, by applying a voltage having a predetermined time width between the electrodes provided at both ends of the piezo element PE, the piezo element PE expands for the voltage application time, and as shown by the arrows in the figure, the ink path One side wall of 68 is deformed. As a result, the volume of the ink passage 68 contracts according to the expansion of the piezo element PE, and the ink corresponding to the contraction becomes particles Ip and is ejected from the tip of the nozzle Nz at high speed. Printing is performed by the ink particles Ip soaking into the paper P mounted on the platen 26.

  The printer PRT of this embodiment can express four levels of density for each pixel by changing the number of dots formed per pixel in the range of 0 to 4. FIG. 5 shows a dot formation pattern in this embodiment. The printer PRT forms dots using drive waveforms W1 to W4 for each pixel. As shown in FIG. 5, each driving waveform has a waveform in which the voltage is once lowered from the reference voltage, and then a high voltage is applied to return to the reference voltage. The drive waveforms W1 to W4 are the same waveform, and are output at a cycle in which four drive waveforms are entered for each pixel as the carriage 31 moves.

  The control circuit 40 of the printer PRT changes the number of dots formed for each pixel by selectively turning on and off the drive waveforms W1 to W4, and changes the density expressed for each pixel in four stages. . As the state D0 having the lowest expressed density, all of the drive waveforms W1 to W4 are turned off. At this time, dots are not formed as shown in FIG.

  As the state D1 having the second lowest density, only the drive waveform W2 is turned on. At this time, one dot is formed in the pixel as shown in FIG. In the figure, it means a dot on which a hatched circle is formed. As the state D2 in which the density is the third lowest, the drive waveforms W2 and W3 are turned on. At this time, as shown in FIG. 5, two dots are formed in the pixel. As the state D3 having the highest density, all the drive waveforms W1 to W4 are turned on. At this time, as shown in FIG. 5, four dots are formed in the pixel.

  In this embodiment, an image is printed by properly using the four types of formation patterns D0 to D3 shown in FIG. 5 according to image data. The correspondence between the formation pattern and the gradation value of the image data is set to be different depending on the print mode. The correspondence setting is shown in FIG. The printer PRT has, as printing modes, a monochrome printing mode in which printing is performed using only black ink, and a color printing mode in which printing is performed using all inks. FIG. 6 shows the correspondence between the image data and the formation pattern in each print mode. Note that a state D0 in which no dot is formed corresponds to the gradation value 0 of the image data in any mode, and thus the illustration is omitted.

  In the monochrome printing mode, the formation pattern D1 corresponds to the gradation value 1 of the image data, the formation pattern D2 corresponds to the gradation value 2, and the formation pattern D3 corresponds to the gradation value 3. With this setting, the density corresponding to the image data can be expressed for each pixel.

  In the color printing mode, the formation pattern corresponding to the gradation value of the image data is set to have a different correspondence between the black ink (K) and the colored ink (C, LC, M, LM, Y). With respect to colored ink, the formation pattern D1 corresponds to the gradation value 1 of the image data, the formation pattern D2 corresponds to the gradation value 2, and the formation pattern D3 corresponds to the gradation value 3. For the black ink (K), the combination of the formation pattern D1 and the formation pattern D0 for the gradation value 1 of the image data, the combination of the formation pattern D1 and the formation pattern D1 for the gradation value 2, and the gradation value 3 On the other hand, a combination of the formation pattern D2 and the formation pattern D2 is set.

  The combination means that dots are formed in two steps. For example, in the combination of the formation pattern D1 and the formation pattern D1, after one dot is formed as the formation pattern D1 for a certain pixel, another dot is formed as the formation pattern D1 again for the same pixel by another nozzle. Means that A total of two pixels are formed in this pixel with time. Since the number of dots to be formed is the same as the number of formation patterns D2, it is possible to express the density corresponding to the formation pattern D2. Similarly, the combination of the formation pattern D2 and the formation pattern D2 means that a total of four dots are formed in two divided into two. As described above, the reason why different correspondences are set between the monochrome printing mode and the color printing mode and the reason why different correspondences are set between the black ink and the colored ink in the color printing mode will be described later.

  In general, if the gradation value that can be expressed by the printer PRT increases, high-quality printing can be realized. On the other hand, the burden of halftone processing by the computer PRT increases and the printing time becomes longer. In this embodiment, in order to avoid a decrease in printing time, the gradation values that can be expressed by the printer PRT are set in four stages, and a state in which three dots are formed in a pixel is not used. Of course, it may be possible to express gradations in five levels for each pixel by using a state in which three dots are formed in the pixel.

  Next, the internal configuration of the control circuit 40 of the printer PRT will be described. FIG. 7 is an explanatory diagram showing the internal configuration of the control circuit 40. As shown in the figure, the control circuit 40 includes a CPU 81, a PROM 42, a RAM 43, a PC interface 44 for exchanging data with the computer PC, a paper feed motor 23, a carriage motor 24, an operation panel 32, and the like. A peripheral input / output unit (PIO) 45 for exchanging signals, a timer 46 for measuring time, a driving buffer 47 for outputting dot on / off signals to the heads 61 to 66, and the like are provided. The circuits are connected to each other by a bus 48. The control circuit 40 is also provided with a transmitter 51 that outputs a drive waveform, and a distributor 55 that distributes the output from the transmitter 51 to the heads 61 to 66 at a predetermined timing.

  The control circuit 40 receives the print data that has been halftoned by the computer PC, temporarily stores it in the RAM 43, and outputs it to the drive buffer 47 at a predetermined timing. The drive buffer 47 determines on / off of the drive waveforms W <b> 1 to W <b> 4 for each pixel in accordance with the print data according to the print mode, and outputs it to the distributor 55. In accordance with this result, drive waveforms W1 to W4 are output to each nozzle, and various dots shown in FIG. 5 are formed. The correspondence (see FIG. 6) between the gradation value of the image data and the on / off of the drive waveforms W1 to W4 is stored in the PROM 42 as a formation pattern table.

  The printer PRT having the hardware configuration described above transports the paper P by the paper feed motor 23 (hereinafter referred to as sub-scanning), and reciprocates the carriage 31 by the carriage motor 24 (hereinafter referred to as main scanning). The piezo elements PE of the color heads 61 to 66 of the print head 28 are driven to discharge the inks of the respective colors to form dots and form a multicolor image on the paper P.

  In this embodiment, as described above, the printer PRT having the head for ejecting ink using the piezo element PE is used. However, a printer that ejects ink by other methods may be used. For example, the present invention may be applied to a printer of a type in which electricity is supplied to a heater arranged in the ink passage and ink is ejected by bubbles generated in the ink passage. In addition, various printers such as a so-called thermal transfer type, sublimation type, and dot impact type can be applied.

(2) Dot formation control:
Next, the dot formation process in the present embodiment will be described. A flowchart of the dot formation routine is shown in FIG. This is a process executed by the CPU 41 of the printer PRT. When this process is started, the CPU 41 inputs print data (step S10). This image data is data that has been subjected to halftone processing by the computer PC, and is data in which the density to be expressed by each ink included in the printer PRT is represented by gradation values 0 to 3 for each pixel constituting the image. .

  When this data is input, the CPU 41 temporarily stores it in the RAM 43. Then, data to be sequentially output to each nozzle during the main scanning is set in the drive buffer 47 (step S20). The CPU 41 determines the raster on which dots are to be formed by each nozzle from the positional relationship between the print data and the head, and sequentially transfers the data on the raster to the drive buffer 47. When the print data is transferred to the drive buffer 47, the print data is converted into data indicating on / off of each of the drive waveforms W1 to W4 with a correspondence relationship according to the print mode (see FIG. 6). For example, in the monochrome print mode, if the gradation value of the print data is 1, the drive buffer 47 stores the value 0 indicating that the drive waveform W1 is OFF, the value 1 indicating that the drive waveform W2 is ON, and the drive waveform W3. , W4 is transferred, and 4-bit data “0100” having a value 0 indicating transfer of W4 is transferred.

  In the color printing mode, for black, each pixel is formed by two different nozzles. As shown in FIG. 6, for example, when the gradation value is 1, the nozzle that first passes through the pixel forms one dot with the formation pattern D1. The second nozzle that passes through the pixel does not form a formation pattern D2, that is, a dot. Thus, for black, the correspondence between the gradation value of each pixel and the formation pattern differs between the first passing nozzle and the second passing nozzle. The CPU 41 determines whether each nozzle is a nozzle that first passes through each pixel from the positional relationship between the head and the print data and the previous print history, and then, based on the correspondence shown in FIG. Data is set in the drive buffer 47. Note that, as will be described later, when sub-scanning is performed with a constant feed amount, each black nozzle and the order of passing through pixels have a unique relationship. Judgment can be made easily.

  When data is thus set in the drive buffer 47, the CPU 41 forms dots while performing main scanning (step S30). Next, the CPU 41 carries the paper, that is, performs sub-scanning with a predetermined feed amount (step S40). The above processing is repeated until printing is completed (step S80), and the image is completed.

  FIG. 9 shows how dots are formed according to this embodiment. The left side of the figure shows the position of the black ink head (hereinafter referred to as the black head) in the sub-scanning direction in the first to sixth main scans. The right side of the figure shows the position of the colored ink head (hereinafter referred to as a color head) in the sub-scanning direction in the first to sixth main scans. A dot formed between them is indicated by a circle. Here, for convenience of illustration, the heads of black ink and colored ink are merely drawn on the left and right, and it goes without saying that both heads actually move together. In FIG. 9, for the convenience of illustration, the black head is provided with six nozzles at a nozzle pitch of 2 dots, and the color head is provided with three nozzles at a nozzle pitch of 4 dots. The relationship between the number of nozzles and the nozzle pitch between the black head and the color head is the same as described above with reference to FIG.

  The numbers and letters in the figure are circled. Numbers and letters mean nozzle symbols. For the nozzles in which the position in the sub-scanning direction is the same between the black head and the color head, the nozzle symbol is assigned with a number from 1 to 3. For the nozzles specific to the black head, the nozzle symbols are given in English letters a to c. The color head is provided with only No. 1 to No. 3 nozzles. The black head is provided with nozzles 1 to 3, and nozzles a to c are provided between them and below the nozzle 3.

  In a head having nozzles with such an interval and number, the third nozzle is positioned in the region shown in the center of FIG. 9, that is, the first main scan, by performing sub-scanning with a constant feed amount corresponding to 3 dots. Images can be printed in the area below the raster. At this time, in the first few main scans, dots are formed only by the nozzles located below (No. 3 nozzle or the like). This is because rasters formed by nozzles located above (such as the first nozzle) include rasters that cannot complete adjacent rasters in the subsequent main scanning.

  The black head has twice as many nozzles as the color head. Therefore, as is clear from FIG. 9, the color head forms each raster with one nozzle, whereas the black head can form each raster with two nozzles. That is, the black head can form each raster with two nozzles without reducing the driving efficiency of the color head. As a result, in the color printing mode, it is possible to use a formation pattern set to form dots with two nozzles for each pixel without causing a decrease in the overall printing speed.

  When printing an image with a constant sub-scanning amount, as is apparent from FIG. 9, there is a unique relationship in the order in which each nozzle of the black head passes through each raster. Three nozzles located below the black head, that is, the nozzle c, the third nozzle, and the nozzle b are nozzles that pass through each raster first. The upper three nozzles, that is, the first nozzle, the nozzle a, and the second nozzle are nozzles that pass through each raster second. FIG. 9 illustrates the case where six nozzles are provided as a black head. Similarly, in the case where 48 nozzles are provided, the lower half of the nozzles are the first nozzles to pass through, and the upper half of the nozzles. Becomes the nozzle that passes through second. Therefore, when printing an image with a fixed amount of sub-scanning, the CPU 41 can easily set the correspondence between the gradation value and the formation pattern for each nozzle based on such a unique correspondence.

  According to the printer PRT of the present embodiment described above, in the color printing mode, black dots of each pixel are formed with two nozzles at a time interval. The ink ejected from the nozzle that passes first penetrates into the gap between the fibers of the printing paper P by capillary action. After the ink is dried, the ink is ejected from the nozzle that passes second. At this point in time, the gap between the fibers of the printing paper is blocked by the previously ejected ink, so the second ejected ink dries without spreading over a wide area. By thus ejecting the black ink in two portions, the printer PRT of the present embodiment forms a small area dot with less blurring than when the same amount of ink is ejected at once. be able to. As a result, according to the printer PRT of the present embodiment, it is possible to realize high-quality printing that suppresses dot visibility and blurring.

  The printer PRT of this embodiment is provided with nozzles twice as large as the color head for the black head. Therefore, as described with reference to FIG. 9, the printer PRT according to the present embodiment can realize the above-described high-quality printing without reducing the image printing speed in the color printing mode. Further, in the monochrome printing mode, it is possible to perform printing at high speed by using all the provided nozzles. As shown in FIG. 6, the printer PRT of the present embodiment changes the correspondence between the gradation value and the dot formation pattern according to the printing mode, while ensuring appropriate gradation expression in the monochrome printing mode. High-speed printing is possible. By doing so, the nozzles provided in the black head can be effectively used in both the monochrome printing mode and the color printing mode.

  As described above, the printer PRT of this embodiment forms black dots by using two nozzles for each pixel in the color printing mode. In general, in a head that forms dots by ejecting ink, ink ejection characteristics may vary due to mechanical manufacturing errors of the head, and the dot formation position may shift. Accordingly, light and shade unevenness may occur between a raster formed by a nozzle that causes a shift in the dot formation position and an adjacent raster, and image quality may deteriorate. In the printer PRT of this embodiment, dots are formed with two nozzles for each pixel for black, so that shading unevenness caused by a shift in dot formation position can be suppressed and image quality can be improved.

  The printer PRT of this embodiment has the above-described various effects by improving the dot formation mode for black. Of course, it is possible to provide many nozzles for colors other than black. However, in general, black dots are easily visible, and blurring and misalignment are likely to have a large effect on the image quality.Therefore, if the black dot formation mode is improved as in this embodiment, the effect of improving the image quality can be obtained. Very big.

(3) Second embodiment:
Next, a printer PRT as a second embodiment will be described. The hardware configuration and software configuration itself of the printer PRT as the second embodiment are the same as those in the above-described embodiments (FIGS. 1 to 4). In the second embodiment, the driving waveform output from the transmitter 51 is different from that of the first embodiment, and dots having different ink amounts can be formed.

  The principle of forming dots with different ink amounts will be described. FIG. 10 is an explanatory diagram showing the relationship between the drive waveform of the nozzle Nz and the ejected ink Ip when the ink is ejected. A drive waveform indicated by a broken line in FIG. 10 is a waveform when a normal dot is ejected. In the section d2, once a voltage lower than the reference voltage is applied to the piezo element PE, the piezo element PE is deformed in the direction in which the cross-sectional area of the ink passage 68 is increased, contrary to the case described above with reference to FIG. Since the ink supply speed to the nozzle is limited, the ink supply amount is insufficient for the expansion of the ink passage 68. As a result, as shown in the state A in FIG. 10, the ink interface Me is indented inside the nozzle Nz. When the drive waveform shown by the solid line in FIG. 10 is used and the voltage is rapidly lowered as shown in the section d2, the ink supply amount becomes further insufficient. Therefore, as shown in the state a, the ink interface is greatly indented compared to the state A.

  Next, when a high voltage is applied to the piezo element PE (section d3), ink is ejected based on the principle described above. At this time, a large ink droplet is ejected as shown in the state B and the state C from the state where the ink interface is not so inward (state A), and the state from the state where the ink interface is greatly indented (state a). Small ink droplets are ejected as shown in b and state c. Thus, the dot diameter can be changed according to the change rate when the drive voltage is lowered (sections d1, d2).

  The printer PRT continuously outputs two types of drive waveforms W1, W2 as shown in FIG. The drive waveform W1 is a waveform for forming small dots by discharging small ink droplets IPs, and the drive waveform W2 is a waveform for forming medium dots by discharging large ink droplets IPm. The flying speed of the ink droplet IPm is larger than the flying speed of the ink droplet IPs. Accordingly, if the drive waveforms W1 and W2 are continuously ejected while the carriage 31 moves in the main scanning direction, each ink droplet is ejected to the same pixel to form a large dot based on the difference in flight speed. be able to. In the printer PRT, the output timing of the drive waveform and the moving speed of the carriage 31 are adjusted so that three types of dots having different ink amounts can be formed on each pixel.

  FIG. 12 is an explanatory diagram showing a correspondence relationship between dots having different ink amounts and gradation values of print data as dot formation patterns. As shown in the figure, for colored ink in the monochrome printing mode and the color printing mode, the formation of small dots DS corresponds to the gradation value 1, and the formation of medium dots DM corresponds to the gradation value 2. Formation of large dots DL corresponds to tone value 3. For black ink in the color printing mode, a combination of small dot formation DS and non-dot formation DN corresponds to gradation value 1, and small dot formation DS and small dot formation correspond to gradation value 2. The combination with the formation DS corresponds, and for the gradation value 3, the combination of the formation DM of medium dots and the formation DM of medium dots corresponds.

  The printer PRT of the second embodiment executes printing according to such a formation pattern, so that, as in the case of the first embodiment, black dot bleeding and formation position deviation can be suppressed during color printing. High quality printing can be realized. In addition, it is possible to utilize the surplus nozzles provided in the black head during color printing.

  In the first and second embodiments described above, the nozzle arrangement of the head can be variously arranged in addition to the arrangement shown in FIG. In the example shown in FIG. 3, the nozzles are arranged so that the nozzle pitch of the black head is half of the nozzle pitch of the color head. On the other hand, as shown in FIG. 13, with respect to the black head, a plurality of nozzle rows provided at the same nozzle pitch as that of the color head may be provided in the main scanning direction. With this arrangement, black dots can be formed with two nozzles for each pixel in one main scan.

  In the example shown in FIG. 3, the color heads of the respective colors are arranged in the main scanning direction. On the other hand, as shown in FIG. 14, the color heads of the respective colors may be arranged in the sub-scanning direction, and the black heads may be arranged so that the color ink thus arranged matches the width in the sub-scanning direction. . FIG. 14 shows an example in which three color heads of cyan, magenta, and yellow are provided. In this example, the black head has three times as many nozzles as the color head. Of course, a similar configuration is possible for a color head including five colored inks.

  In the first and second embodiments, an example in which the number of nozzles is large for some colors has been described. However, the present invention may be applied to a printer having the same number of nozzles for all colors. As an application in such a case, for example, it is also possible to adopt a mode in which black dots are formed in both directions during main scanning forward and backward movement, and other colors are formed only in any one direction.

(4) Third embodiment:
Next, a third embodiment will be described. The printer PRT of the third embodiment has the same hardware configuration as that of the second embodiment, and can form dots having different ink amounts using the same drive waveform as that of the second embodiment. In the first and second embodiments, a formation pattern different from that of the colored ink is applied to black in the color printing mode. In the first embodiment and the second embodiment, a formation pattern is used in which the amount of ink ejected to each pixel is substantially the same for all colors.

  In the third embodiment, a formation pattern different from other colors is applied to yellow ink. A formation pattern in the third embodiment is shown in FIG. Here, the formation pattern in the color printing mode is shown. As shown in the figure, for yellow, the state DY1 in which one small dot is formed corresponds to the gradation value 1 of the print data, and the state DY2 in which two medium dots are formed corresponds to the gradation value 2. The state DY3 in which four large dots are formed corresponds to the gradation value 3. For other inks, the state D1 in which one small dot is formed corresponds to the gradation value 1, and the state D2 in which two small dots are formed corresponds to the gradation value 2, and the gradation value 3 Corresponds to a state D3 in which four small dots are formed. In the third embodiment, the amount of ink ejected to each pixel for yellow is thus different from other colors.

  In general, yellow ink has high lightness, so dot visibility is low. Further, the influence on the density due to the change in the ink amount is small. If each dot is formed with the formation pattern shown in the third embodiment, an appropriate density corresponding to the change in the gradation value can be expressed by setting the amount of change in the ink amount large for yellow. On the other hand, for other colors, small dots with a small amount of ink are mainly used, and the amount of ink ejected to each pixel is set to be lower than yellow, whereby dot visibility and bleeding can be suppressed. As a result, the printer PRT of the third embodiment can improve the graininess of the image, enrich the gradation expression, and realize high-quality printing.

  Of course, the computer 90 generates print data to be used for printing by halftoning the original print data in consideration of the relationship between the gradation value of the print data and the density evaluation value expressed by the formed dots. Therefore, even if the change amount of the ink amount is set large as described above for yellow, the color tone of the image is not impaired.

  In the above embodiment, various formation patterns in which the number of main scans required for forming dots, the amount of ink, and the like are set differently from those of other colors for some specific colors have been exemplified. The formation pattern can be set in various combinations with respect to the number of main scans, the amount of ink, the number of dots formed in each pixel, and the like. In any of the embodiments, a different formation pattern is applied to any one color ink provided in the printer. However, a different pattern may be applied to a plurality of colors.

  Although various embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and various embodiments can be implemented without departing from the spirit of the present invention. For example, some or all of the various control processes described in the above embodiments may be realized by hardware.

1 is a schematic configuration diagram of a printing system to which a printer PRT of an embodiment is applied. FIG. 2 is a schematic configuration diagram of a printer PRT. It is explanatory drawing which shows the example of nozzle arrangement | positioning in printer PRT. FIG. 3 is an explanatory diagram illustrating a dot formation principle in a printer PRT. It is explanatory drawing which shows the formation pattern of the dot in an Example. It is explanatory drawing which shows the correspondence of a printing mode and a formation pattern. It is explanatory drawing which shows the internal structure of the control apparatus of printer PRT. It is a flowchart of a dot formation routine. It is explanatory drawing which shows the mode of formation of the dot in an Example. It is explanatory drawing of the principle which forms the dot from which the ink amount differs. It is explanatory drawing of the principle which forms a large dot from a small dot and a medium dot. It is explanatory drawing which shows the formation pattern in 2nd Example. It is explanatory drawing which shows the nozzle arrangement | positioning as a 1st modification. It is explanatory drawing which shows the nozzle arrangement | positioning as a 2nd modification. It is explanatory drawing which shows the formation pattern in 3rd Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 23 ... Motor 24 ... Carriage motor 26 ... Platen 28 ... Print head 31 ... Carriage 32 ... Operation panel 34 ... Sliding shaft 36 ... Drive belt 38 ... Pulley 39 ... Position detection sensor 40 ... Control circuit 41 ... CPU
42 ... PROM
43 ... RAM
44 ... PC interface 45 ... PIO
46 ... Timer 47 ... Driving buffer 48 ... Bus 51 ... Transmitter 55 ... Distributor 61-66 ... Head 68 ... Ink passage 71 ... Cartridge 72 ... Cartridge 91 ... Input section 92 ... Buffer 93 ... Main scanning section 94 ... Sub-scanning Part 95: Head drive part 96 ... Formation pattern table

Claims (9)

The level of print data that has been halftoned to more than three values for each pixel while performing main scanning in which a head capable of forming multicolor dots is reciprocally moved in one direction in a print medium in accordance with a drive signal. A printing apparatus that prints an image on the print medium by forming dots according to a tone value,
Storage means for storing a correspondence relationship between the gradation value and the dot to be formed, wherein at least one specific color of the multiple colors is set differently from other colors;
A printing apparatus comprising: a driving unit that outputs the driving signal to the head during the main scanning and forms the multi-colored dots for each pixel in a forming mode corresponding to the correspondence relationship. The printing apparatus according to claim 1,
The correspondence relationship is a printing apparatus in which, for the specific color, the number of dots formed by main scanning more than other colors corresponds to the gradation value.   The printing apparatus according to claim 2, wherein the head is a head provided with more dot forming elements for forming the dots for the specific color than for other colors.   The printing apparatus according to claim 1, wherein the head is a head that forms dots by discharging liquid ink droplets onto the printing medium.   The printing apparatus according to claim 4, wherein the head is a head capable of forming two or more types of dots by changing an ink amount of the ink droplets according to the drive signal.   The printing apparatus according to claim 1, wherein the driving unit is a unit that expresses a density of three or more values for each pixel by changing the number of driving signals output for each pixel.   The printing apparatus according to claim 1, wherein the specific color is black. The level of print data that has been halftoned to more than three values for each pixel while performing main scanning in which a head capable of forming multicolor dots is reciprocally moved in one direction in a print medium in accordance with a drive signal. A printing method for printing an image on the print medium by forming dots according to a tone value,
(A) inputting the print data;
(B) The driving signal is output to the head during the main scanning, and the multiplicity for each pixel is formed according to a predetermined correspondence relationship stored in advance for the gradation value and the dot to be formed. Forming a color dot,
The printing method is a printing method in which at least one specific color among the multiple colors is set differently from the other colors. The level of print data that has been halftoned to more than three values for each pixel while performing main scanning in which a head capable of forming multicolor dots is reciprocally moved in one direction in a print medium in accordance with a drive signal. A recording medium in which a program for driving a printing apparatus that forms dots according to tone values is recorded in a computer-readable manner,
The data used in the program is a correspondence relationship between the gradation value and the dot to be formed, and at least one specific color among the multiple colors is set differently from the other colors A recording medium on which is recorded.

Images