1. Field of the Invention
The present invention relates to an ink jet printing apparatus, and more specifically, to an ink jet printing apparatus that executes printing by scanning a printing head in two directions.
2. Description of the Related Art
With the recent spread of personal computers, word processors, facsimile machines, and the like to offices and homes, printing apparatuses based on various printing systems have been provided as information output equipment for the above equipment. In particular, printing apparatuses such as printers which are based on an ink jet system can be relatively easily adapted to execute color printing using plural types of inks. The ink jet printing apparatus has various advantages; for example, it makes only a low noise during operation, can achieve high grade printing on a variety of print media, and is small in size. In this respect, the printer based on this system and the like are suitable for personal use at office or home. Of these ink jet system-based printing apparatuses, a serial type in which a printing head reciprocates to perform printing to a printing medium is very popular because it is inexpensive and can print high grade images.
In spite of its relatively low costs, the serial type printing apparatus is desired to exhibit a higher performance. The printing performance is typified by image quality or image grade, and printing speed.
One of factors that determine image quality or the like is the type of ink. In general, the use of more or appropriate types of inks allows a higher-quality image to be printed. The inks can be classified into dye inks, pigment inks, and the like on the basis of coloring materials used for the inks, or dark and light inks on the basis of the concentration of the coloring materials, or a special color such as orange, red, blue inks, and the like on the basis of ink colors.
Well-known printers use, for example, six types of inks including a dye black ink, a dye yellow ink, a dark and light dye magenta inks, and a dark and light dye cyan inks, or four types of inks including a pigment black ink, a dye yellow ink, a dye magenta ink, and a dye cyan ink. The former apparatus focuses on the output to gloss printing media of photographic images of high quality inputted using a digital camera, a scanner, or the like. The latter apparatus focuses on the high-grade output to ordinary paper of black lines such as black letters and charts.
In general, to obtain a high optical reflection density for black, pigment coloring materials such as carbon black are used to perform printing to an ordinary paper rather than using dye color materials as described above. This is because the pigment is dispersed in the ink and because when this ink is applied to the ordinary paper, the dispersion becomes unstable to cause coagulation, resulting in the effective coverage of the surface of the printing medium. Further, when the ink has a surface tension of about 40 dyne/cm, this prevents the ink from bleeding along fibers in the ordinary paper. Such ink designs enable the printing of letters and lines having a high contrast with respect to the surface of the paper as well as sharp edges. On the other hand, the dye dissolves in the ink at a molecular level, whereas the pigment is dispersed in the ink and thus has relatively large coloring material grains. Thus, the pigment cannot pass through a gloss layer in the surface of a glossy printing medium. The pigment accumulates in the surface of the gloss layer to reduce the glossiness.
Thus, when performing printing to a gloss printing medium, the above printing apparatus using a pigment black ink often expresses a black component of an image by using what is called a process black composed of three color inks, a dye yellow ink, a dye magenta ink, and a dye cyan ink, instead of using a pigment black ink. However, to improve the contrast of a black image in a print, it is more preferable to use a dye black ink than to use the three-color inks. In this case, only the dye black ink is used, thus enabling a reduction in the amount of ink applied per unit area of a printing medium. This prevents problems such as ink bleeding. Further, if a gray level is to be expressed in a print image, dots for a color of a relatively high gray level are generally formed by applying a black ink as well as a cyan, magenta, and yellow inks.
In this manner, combinations of various inks are used depending on the type of images to be printed or printing media used. For example, when ordinary paper is important, the apparatus is configured to use a pigment black ink. If gloss printing media are important, the printing apparatus uses a dye black ink.
In contrast, Japanese Patent Application Laid-open No. 11-001647 (1999) describes a configuration focusing on both ordinary paper and gloss printing media. According to this document, the configuration has printing means for a pigment black ink and printing means for a dye black ink. It does not use the pigment black ink but only the dye black ink to perform printing to printing media that have a gloss layer and an ink receiving layer and that are incompatible with the pigment black ink. It uses the pigment black ink to perform printing to the ordinary paper. In this manner, this configuration can print a high-quality or -grade image on both ordinary paper and gloss print media.
Bidirectional printing is known as a configuration that can improve the printing speed, belonging to the printing performance. With this printing system, in a serial type printing apparatus, the printing head is first scanned in a forward direction for printing. Then, paper is fed by a predetermined amount, and printing scan is subsequently executed again by moving the printing head in a backward direction. This printing system achieves an approximately double printing speed or throughput compared to unidirectional printing in which printing is to executed during forward scanning, whereas it is not executed while the printing head is moving in the backward direction. Other known printing systems include what is called one pass printing in which one scan completes printing of a scan area of a width equal to the arrangement width of ejection openings in the printing head, and what is called multi-pass printing in which printing is completed by a plurality of scans between which paper feeding is interposed. The above bidirectional printing system can also achieve the one pass printing and multi-pass printing. If the one pass printing is executed using the bidirectional printing system, the printing speed or throughput can be maximized.
The bidirectional printing system is effective means in improving the printing speed or the like as described above. However, this system is known to vary colors with scan areas, leading to non-uniform colors or color drifts in a printed image. This is because the application order of the color inks differs between the forward and backward directions of the bidirectional printing. In the printing apparatus, ejection opening rows for the respective color inks are commonly arranged in the scanning direction. However, in this case, the application order may be reversed between the forward scanning and the backward scanning depending on the arrangement of the ejection opening rows.
If dots of a predetermined color are to be formed by applying (ejecting) plural types of inks so that these inks are superposed on a pixel, inks applied to a printing medium earlier more favorably develop their colors. This is because the inks applied to the printing medium earlier easily color the material in a layer closer to the front surface of the printing medium, while the inks applied to the printing medium later less easily color the material in the front surface of the printing medium and permeates deeper through the printing medium in its thickness direction before they are settled. This phenomenon is significant if the ink receiving layer is composed of coat paper consisting of silica. However, it also occurs on ordinary paper or gloss printing media having a gloss layer formed in their front surface and an ink receiving layer formed inside the gloss layer.
Japanese Patent Application Laid-open Nos. 2000-318189 (for example,
These documents disclose the configuration in which nozzle rows c1 and c2 for a cyan ink, nozzle rows m1 and m2 for a magenta ink, and nozzle rows y1 and y2 for a yellow ink are each arranged symmetrically with respect to a predetermined axis of symmetry orthogonal to the scanning direction of the printing head, for example, as shown in
On the other hand, as shown in the same figure, the relationship between nozzle rows k1 and k2 for a black ink and the other ink nozzle rows is such that the inks are ejected in order of k1, k2, c1, m1, y2, m2, and c2. In this case, the superposition order of the black ink and the other inks varies depending on the scanning direction. If image data to be printed forms dots using only the black ink, the superposition of this ink on the other inks described above does not occur. However, for example, in expressing a gray tone, the black ink may be superposed on another color ink such as cyan to form dots in order to smooth a variation in gray level. In this case, the application or superimposition order of the black ink and the other color inks may vary depending on the scanning direction. This may result in non-uniform colors.
This will be described in further detail in connection with under color removal commonly executed as image processing for generation of the above data.
The process black ink is used when the gray level is relatively low because the cyan ink, the magenta ink, and the yellow ink are lighter and give a less significant granular impression than the black ink, thus enabling a smooth gray level expression. Both process black ink and black ink are used when the density is higher than the medium density (187 or more) because the formation of a black image using the black ink requires less inks to be applied to a printing medium than the printing of a black image using the process black ink, thus preventing problems such as the overflow of the inks during printing. Furthermore, the use of the black ink enables the printing of a black image with a higher optical reflection density and a higher contrast.
Thus, when the gray level is between the medium density and the maximum density, the black ink and the process black ink are superposed on each other. The conventional printing head configuration shown in
However, between the medium density level, at which the black starts to be used, and the vicinity of the maximum density level, at which only the black ink is used, there exists an area in which dots are formed with the cyan ink, magenta ink, and yellow ink, constituting the process black, and the black ink being superposed. In an image of a density level within this area, the non-uniformity of the colors may be significant which is attributed to the application order varying depending on the scanning direction.
The inventors of the present invention have found out that a dot formed by superposing one, two, or all of the cyan ink, magenta ink, and yellow ink and the black ink is differently colored depending on an overlapping manner, that is, the order of superposing the black ink in relation to the other color inks, or to which color ink the black ink is superposed to be adjacent. Specifically, in the conventional arrangement of the ejection openings for the black ink and other color inks such as the one shown in
A configuration has been proposed in which like the nozzle rows for the cyan, magenta, and yellow inks, the nozzle rows for the black ink are symmetrically arranged in order of, for example, k1, c1, m1, y1, y2, m2, c2, and k2. However, in this case, supply liquid chambers must be provided to supply the nozzle rows k1 and k2 with the corresponding inks. This increases the size of the printing head. In contrast, with two adjacent nozzle rows, only one ink supply liquid chamber is required, suppressing an increase in size.
It is an object of the present invention to provide an ink jet printing apparatus configured to execute bidirectional printing using many types of inks and which achieves high-grade printing by reducing the non-uniformity of the colors attributed to the bidirectional printing, while preventing an increase in the size of a printing head.
In the first aspect of the present invention, there is provided an ink jet printing apparatus that uses a printing head and scans the printing head over a printing medium in forward and backward directions so that during each of a forward scan and a backward scan of the printing head, dots are formed by superposing a plurality types of ink ejected from ejection openings of the printing head so as to perform printing to the printing medium,
wherein the printing head arranges the ejection openings for the plurality types of ink in the forward and backward scan directions, the ejection openings for the plurality types of ink include symmetrically arranged ejection openings in the arrangement of the ejection openings and an ejection opening located between predetermined two ejection openings of different types of ink among the symmetrically arranged ejection openings, and
the type of ink ejected from the ejection opening between predetermined two ejection openings of different types of ink is black ink.
In the second aspect of the present invention, there is provided an ink jet printing apparatus that uses a printing head and performs forward and backward scans of the printing head over a printing medium in a main scan direction so that during each of a forward scan and a backward scan of the printing head, dots are formed by superposing a plurality types of ink ejected from ejection openings of the printing head so as to perform printing to the printing medium,
wherein the printing head has a group of ejection opening rows that arrange the ejection openings respectively corresponding to the plurality types of ink along the main scan direction, each of the ejection opening rows arranging a plurality of ejection openings along a direction different from the main scan direction,
a plurality of ejection opening rows in the group of ejection opening rows, except ejection opening row of at least one type of ink, are symmetrically arranged along the main scan direction, and
the at least one type of ink includes black ink.
With the above configuration, the ejection openings of the printing head are arranged so that between ejection openings for two predetermined different inks included in the predetermined symmetrically arranged ejection openings for which the manner of overlapping can be controlled to remain unchanged between the forward scanning and the backward scanning, an ejection opening except the predetermined symmetrical ejection openings is located. This reduces the difference in the color of a dot formed when the manner of superposing the ink ejected from the ejection opening except the predetermined symmetrical ejection openings and the inks ejected from the predetermined symmetrically arranged ejection openings varies between the forward scanning and the backward scanning.
The above and other objects, effects, features and advantages of the present invention will become more apparent from the following description of embodiments thereof taken in conjunction with the accompanying drawings.
Embodiments of the present invention will be described below with reference to the drawings.
(First Embodiment)
For an ink jet printing apparatus according to a first embodiment of the present invention, a detailed description will be given of inks used, the configuration of a printing head, the configuration of a printer, and the like.
Inks
First, description will be given of inks used in an ink jet printer operating as the ink jet printing apparatus according to the first embodiment of the present invention.
In the present embodiment, two types of inks are used as a black ink in accordance with a print mode as described later. A first black ink is obtained by using a pigment composed of carbon black as a coloring material. The surface of the pigment is treated using a carboxyl group so as to be dispersed in the ink. Further, to inhibit the evaporation of moisture from the ink, it is preferable to add polyalcohol such as glycerin as a humetant. Moreover, since the pigment ink is used to print characters, it is important to prevent the degradation of the edge of black ink dots formed on ordinary paper. However, an acetylene glycol-based surfactant may be added to adjust the permeability of the ink to the extent that the edge is not degraded. Further, polymer may be added as a binder to improve the binding capacity between the pigment and a printing medium.
On the other hand, a second black ink uses a black dye as a coloring material. Further, a critical micelle concentration or higher of acetylene glycol-based surfactant is added to allow the ink to permeate through the front surface of the printing medium at a sufficiently high speed. Also for this ink, it is preferable to add polyalcohol such as glycerin as a humectant to inhibit the evaporation of moisture from the ink. Additionally, urea may be added to improve the solubility of the color material.
In the present embodiment, the color inks include a cyan ink, a magenta ink, and a yellow ink. These inks are composed of a cyan, magenta, and yellow dyes, respectively. It is preferable to add a humectant, a surfactant, and an additive similar to those for the second black ink to these inks.
Further, the surfactant is desirably adjusted so that the second black ink, the cyan ink, the magenta ink, and the yellow ink have approximately the same surface tension. By setting uniform permeability for ordinary paper, it is possible to inhibit the bleeding between areas on a sheet which are printed using different inks. Other characteristics such as the permeability and viscosity of the ink can be equally adjusted for the second black ink, cyan ink, magenta ink, and yellow ink.
Configuration of Printing head
Now, with reference to
As shown in this figure, the printing head according to the present embodiment is formed by attaching a color ink chip 1100 and a black ink chip 1200 on a substrate 1000. The black ink chip 1200 is composed of ejection openings (also referred to nozzles in the specification) through which the first black ink is ejected. This chip is longer than the color ink chip 1100 in the direction in which print media are conveyed (sub-scanning direction), that is, the ejection openings in this chip are arranged over a longer distance than those in the color ink chip 1100. Furthermore, the ejection opening row on this chip positionally deviate from the ejection opening row for each ink in the color ink chip by a predetermined amount in the sub-scanning direction. As illustrated in
The color ink print chip according to the present embodiment is provided with a plurality of openings for the cyan, magenta, yellow, and second black inks, and heaters that correspond to the respective ejection openings and that generate thermal energy utilized for ejection. Two ejection opening rows are provided for each color ink. The ejection opening rows are symmetrically arranged for the cyan, magenta, and yellow inks as previously described. However, such an arrangement is not used for the second black ink; ejection opening rows k1 and k2 are arranged between the ejection opening row y2 for the yellow ink and the ejection opening row m2 for the magenta ink. As described later in
The specific configuration of the color ink chip is such that six grooves are formed in the same chip 1100, made of silicon, and that each of the grooves is formed with the above ejection openings for the corresponding ink. That is, the following are formed: the ejection openings, ink channels in communication with the ejection openings, heaters each formed in apart of the corresponding ink channel, and a supply channel common to these ink channels.
Further, driving circuits (not shown) are provided between the grooves in the chip 1100 to drive the heaters. The heaters and driving circuits are manufactured during a process of forming a semiconductor film. Furthermore, the ink channels and the ejection openings are formed of resin. Moreover, ink supply channels are formed in the back surface of the silicon chip to supply the ink to the respective grooves.
The six grooves, a first groove 1001, a second groove 1002, a third groove 1003, a fourth groove 1004, a fifth groove 1005, and a sixth groove 1006 are sequentially arranged in the scanning direction so that the first groove 1001 is closest to the left end of the figure. Then, in the present embodiment, the cyan ink is supplied to the first groove 1001 and sixth groove 1006. The magenta ink is supplied to the second groove 1002 and fifth groove 1005. The yellow ink is supplied to the third groove 1003. The second black ink, made using a dye as a color material, is supplied to the fourth groove 1004.
The nozzle row c1 for the cyan ink, composed of 64n (n is an integer equal to or larger than 1; for example, n=4) ejection openings, is formed in the first groove 1001. The nozzle row m1 for the magenta ink, composed of 64n ejection openings, is formed in the second groove 1002. The nozzle row y1 for the yellow ink, composed of 64n ejection openings, is formed in the side of the third groove 1003 closer to the second groove. The nozzle row y2 for the yellow ink, composed of 64n ejection openings, is formed in the side of the third groove 1003 closer to the fourth groove. The nozzle row m2 for the magenta ink, composed of 64n ejection openings, is formed in the fifth groove 1005. The nozzle row c2 for the cyan ink, composed of 64n ejection openings, is formed in the sixth groove 1006. The nozzle row k1 for the dye black ink (second black ink), composed of 64n ejection openings, is formed in the side of the fourth groove 1004 closer to the third groove. The nozzle row k2 for the same dye black ink, composed of 64n ejection openings, is formed adjacent to the nozzle row k1 in the fourth groove 1004.
The ejection openings are arranged in each nozzle row at an approximately equal pitch. The nozzle rows for the same color ink are positionally deviate from each other by half an ejection opening arrangement pitch in the sub-scanning direction. This is to obtain the maximum efficiency of coverage of print media with print dots for each pixel during one printing scan.
In the present embodiment, the combination of the cyan magenta, and yellow inks is referred to as a first ink combination. The combination of the cyan, magenta, yellow, and second black inks is referred to as a second ink combination. As is apparent from the symmetric arrangement shown in
With reference to
As is apparent from
Likewise, for green (C+Y), which is a secondary color obtained by combining the cyan ink and the yellow ink together, two types of pixels, pixels for which the yellow ink is applied after the cyan ink and pixels for which the cyan ink is applied after the yellow ink, can be generated using the set of the nozzle rows c1 and y1 and the set of the nozzle rows c2 and y2. For red (M+Y), which is a secondary color obtained by combining the magenta ink and the yellow ink together, two types of pixels, pixels for which the yellow ink is applied after the magenta ink and pixels for which the magenta ink is applied after the yellow ink, can be generated using the set of the nozzle rows m1 and y1 and the set of the nozzle rows m2 and y2. Furthermore, for a tertiary color obtained using the cyan, magenta, and yellow inks, two types of pixels, pixels using the application order of cyan, magenta, and yellow and pixels using the application order of yellow, magenta, and cyan, can be generated using the set the nozzle rows c1, m1, and y1 and the set of nozzle rows c2, m2, and y2.
For the second black ink, similar two types of superimposition manners are possible for cyan and magenta. However, since the cyan and yellow nozzle rows are not symmetrically arranged, the application orders in the two types of superimposition manners are not completely opposite to each other as shown in
Configuration of Printer
As shown in
The carriage 2 is formed with ink supply channels through which the inks from the corresponding cartridges are supplied to the grooves in the black ink chip 1200 and color ink chip 1100, show in
The printer also comprises a paper feeding mechanism that conveys (feeds)) print paper P that is a printing medium. The paper feeding mechanism feeds paper by a predetermined amount in accordance with the scanning of the printing head. Moreover, a recovery device 10 is provided at one end of the movement range of the carriage 2 to execute an ejection recovery process for the printing head 3.
In this ink jet printer, the paper feeding mechanism feeds the print paper P into a scanning area of the printing head 3. The printing head 3 is scanned to print images, characters, or the like on the print paper P.
The configuration of this apparatus will be described in further detail. The carriage 2 is connected to a part of a driving belt 7 constituting a transmission mechanism 4 that transmits the driving force of the carriage motor M1. The carriage 2 is guided and supported so as to slide along a guide shaft 13 in the direction of the arrow A. This allows the driving force of the carriage motor M1 to be transmitted to the carriage 2 to move it. In this case, the carriage 2 can be moved forward or backward by rotating the carriage motor M1 forward or backward, respectively. In
In the scanning area of the printing head 3, platens (not shown) are provided in respective areas that lie opposite the corresponding ejection opening rows during the scanning of the printing head 3. The appropriate ink is ejected to the print paper P being conveyed on the platen to print the print paper 8 the flat surface of which is maintained by the platen.
Reference numeral 14 denotes a conveying roller driven by a conveying motor M2 (not shown). Reference numeral 15 denotes a pinch roller that abuts the print sheet against the conveying roller 14 using a spring (not shown). Reference numeral 16 denotes a pinch roller holder that rotatably supports the pinch roller 15. Reference numeral 17 denotes a conveying roller gear attached to one end of the conveying roller 14. The conveying roller 14 is driven by transmitting rotation of the conveying motor M2 to the conveying roller gear 17 via an intermediate gear (not shown). Reference numeral 20 denotes a discharge roller that discharges the print paper on which an image has been formed by the printing head 3, out of the apparatus. The discharge roller 20 is similarly driven by transmitting rotation of the conveying motor M2 to the roller 20. On the discharge roller 20, a spur roller (not shown) is abutted against the print paper by the pressure of a spring (not shown). Reference numeral 22 denotes a spur holder that rotatably supports the spur roller.
As described above, the recovery device 10 is provided at a predetermined position (for example, a position corresponding to a home position) outside the range (scanning range) of reciprocation of the carriage 2 for a printing operation. The recovery device 10 maintains the ejection performance of the printing head 3. The recovery device 10 comprises a capping mechanism 11 that caps an ejection opening surface of the printing head 3 and a wiping mechanism 12 that cleans the ejection opening surface (the surface provided with the ejection opening rows for the respective colors) of the printing head 3. An ejection recovery process can be executed by, for example, using a suction mechanism (a suction pump or the like; not shown) in the recovery device to force the ink to be discharged from the ejection openings in unison with the capping of the ejection openings by the capping mechanism 11, thus removing more viscous ink, bubbles, and the like from the ink channels in the printing head 3. Further, by capping the ejection opening surface of the printing head 3 during non-printing or the like, it is possible to protect the printing head, while preventing the ink from being dried. The wiping mechanism 12 is disposed close to the capping mechanism 11 to clean the printing head 3 by wiping off ink droplets attached to the ejection opening surface of the printing head 3. The capping mechanism 11 and the wiping mechanism 12 enable the printing head 3 to maintain normal ejections.
As shown in
Reference numeral 610 denotes a host computer (or an image reader or a digital camera) operating as a source of image data. The host computer transmits and receives image data, commands, status signals, and the like to and from the controller 600 via an interface (I/F) 611.
Reference numeral 620 denotes a group of switches that accepts instruction inputs from an operator; the switches include a power switch 621, a switch 622 that instructs on the start of printing, and a recovery switch 623 that instructs on the activation of a recovery process for the printing head 3. Reference numeral 630 denotes the group of sensors, composed of, for example, a photo coupler 631 combined with the scale 8 to detect that the printing head 3 has been moved to its home position h and a temperature sensor 632 provided at an appropriate position in the printer to detect an environmental temperature. Moreover, reference numeral 640 denotes a driver that drives the to carriage motor M1. Reference numeral 642 denotes a driver that drives the paper feeding motor M2.
With the above configuration, the printer according to the present embodiment analyzes a command for print data transferred via the interface 611 and expands image data to be printed into the RAM 602. The area (expansion buffer) into which the image data is expanded has a horizontal size of the number Hp of pixels corresponding to a printable area in the main scanning direction and a vertical size of 64n (n is an integer equal to or larger than 1; for example, n=4), the number of pixels in the vertical direction which are printed during one scan using the nozzle rows in the printing head. The expansion buffer is provided on a storage area of the RAM 602. A storage area (print buffer) on the RAM 602 which is referenced in order to send data to the printing head during print scanning has a horizontal size of the number Vp of pixels corresponding to the printable area in the main scanning direction and a vertical size of 64n, the number of pixels in the vertical direction which are printed during one print scan of the printing head. The print buffer is provided on the storage area of the RAM 602.
When the printing head executes print scanning, the ASIC 603 acquires data on the driving of the heater for each ejection opening in the printing head while directly accessing the storage area (print buffer) of the RAM 620. The ASIC 603 transfers the data acquired to the printing head 3 (to the driver for the printing head 3).
Data Processing
In the present embodiment, multi-valued data for red (R), green (G), and blue (B) is subjected to predetermined image processing and thus converted into binary or three-valued data into which cyan, magenta, yellow, and black, the ink colors used in the present printer, are quantized. In the present embodiment, this process is executed by the host apparatus 610 but may be executed by a controller for the printer or the like.
The data processing according to the present embodiment is executed depending on a print mode described later. Specifically, print data is converted into binary or three-valued data depending on the print mode. In a print mode with a high printing speed, the print data is converted into binary data. In a print mode for a higher-quality image, the print data is converted into three-valued data. In the above data processing and printing operation, the unit or size of a pixel for processing corresponds to each ink dot that can be formed using two ejection openings (ejection openings in different ejection opening rows) in two ejection opening rows for the same ink color which openings are adjacent to each other in the sub-scanning direction with a spacing corresponding to half the ejection opening arrangement pitch of each ejection opening row. Such pixels cause dots to be formed at separate positions. More specifically, the unit of a pixel corresponds to an area having two dots formed at a lattice point.
Moreover, for bidirectional printing, the data processing distributes data in association with the two ejection opening rows for each color ink. Specifically, a print buffer is provided for each ejection opening row, and the binary or three-valued data is stored in the corresponding print buffer. Then, for each scan, data is read from the print buffer corresponding to each ejection opening row and transferred so as to eject the ink from the ejection opening in the ejection opening row.
(Binary Data)
If the data into which cyan, magenta, and yellow are quantized is binary, the same print buffer is used for the pair of two ejection opening rows (nozzle rows) for the same ink color.
Specifically, the same cyan first print buffer is assigned to the cyan nozzle row c1 and cyan nozzle row c2. Likewise, a magenta first print buffer is assigned to the magenta nozzle row m1 and magenta nozzle row m2. A yellow first print buffer is assigned to the yellow nozzle row y1 and yellow nozzle row y2. That is, in the case of, for example, cyan ink, all the binarized data is expanded into the cyan first print buffer. Then, during a forward scan, the binary data expanded into the cyan first print buffer is referenced and transferred in association with both cyan nozzle row c1 and cyan nozzle row c2 in the printing head. Thus, the ink is ejected from the corresponding ejection openings. Similarly, during a backward scan, the binary data expanded into the cyan first print buffer is referenced and transferred in association with both cyan nozzle row c1 and cyan nozzle row c2 in the printing head. Thus, the ink is ejected from the corresponding ejection openings.
In this manner, in the present embodiment, the cyan nozzle row c1 and the cyan nozzle row c2 print the same image on a printing medium. That is, a pixel with binary data of 1 is composed of two dots formed using the ink ejected from the ejection openings in the different ejection opening rows for the same ink color. Similarly, for magenta or yellow, the magenta first print buffer or the yellow first print buffer, respectively, is referenced to print an image using two ejection opening rows.
In this case, the two dots constituting each pixel (with binary data of 1) are obtained from the different nozzle rows. Accordingly, as shown in
As described later, the first black ink, a pigment ink, may be used depending on the print mode. The corresponding binary data is stored in one print buffer as in the case of normal printing. Further, for printing, the data is referenced and transferred in association with each ejection opening in the black ink chip 1200. This also applies to three-valued data.
(Three-Valued Data)
If the data into which cyan, magenta, and yellow are quantized has three values, dots are formed at three levels: no dots, 1 dot, and 2 dots. Correspondingly, the contents of the three-valued data are 0, 1, and 2; three-valued data of 0 corresponds to no data, three-valued data of 1 corresponds to 1 dot, and three-valued data of 2 corresponds to 2 dots.
In this case, the storage area is divided into a first print buffer and a second print buffer in association with the nozzle rows for each ink color for management. Specifically, the cyan first print buffer is assigned to the cyan nozzle row c1. The magenta first print buffer is assigned to the magenta nozzle row m1. The yellow first print buffer is assigned to the yellow nozzle row y1. The yellow second print buffer is assigned to the yellow nozzle row y2. The magenta second print buffer is assigned to the magenta nozzle row m2. The cyan second print buffer is assigned to the cyan nozzle row c2.
If the quantized three-valued data is 0, 0 indicating no data is expanded into both first and second print buffers. If the quantized three-valued data is 2, 1 indicating 1 dot data is expanded into both first and second print buffers. Thus, if the three-valued data for an ink color is 2, two dots from the different nozzle rows are formed for each pixel with three-valued data of 2 during either a forward or backward scan. If the quantized three-valued data is 1, 1 is expanded into one of the first and second print buffers, with 0 expanded into the other. In this case, every time the three-valued data has a value of 1 for the same ink color, data is stored indicating into which print buffer 1 has been expanded. Then, next time the three-valued data has a value of 1, the data expansion is controlled so as to switch the print buffer into which the data is expanded. Thus, during either a forward or backward scan, one dot is formed for a pixel with three-valued data of 1 using one of the different nozzle rows.
As a result of the distribution of three-valued data, each of the different nozzle rows is used to print the same number of dots when a large number of pixels are viewed in a macro manner. Accordingly, there are a number of dots formed with one of the two application orders as well as the same number of dots formed with the other application order. Consequently, the non-uniformity of the colors is relatively difficult to recognize.
As described above, the data processing executed if to the quantized data is binary is suitable for the high-speed print mode because it involved a smaller amount of data to be processed than the data processing for three-valued data. Further, for the data processing for binary data, since two dots are formed for each pixel in the present embodiment, the resultant image has a lower grade in terms of a granular impression than one obtained through the processing for three-valued data, which uses 1 dot for a lower density portion of the print image. Accordingly, three-valued data is used in the high-quality print mode. In this connection, yellow, which is unlikely to be degraded in terms of the granular impression, may be subjected to binary quantization, while the other colors may be subjected to three-valued quantization.
Even if the gray level is expressed using four or more values, the same correspondences between the ejection opening rows and the print buffers as those for the distribution of three-valued data are used. As in the case of three-valued data, if an even number of dots are used for the expression, the data is expanded so that the same number of dots are printed in each of the first and second print buffers. If an odd number of dots are used for the expression, the data is expanded so that the number of dots printed in one of the first and second print buffers is one dot larger than that printed in the other print buffer. Then, every time the number of dots for the gray level expression for the same ink color is odd, data is stored indicating into which print buffer one-dot-larger data has been expanded. Next time the number of dots for a pixel is odd, the data is expanded so as to switch the print buffer into which one-dot-larger data is expanded.
For the black ink (second black ink), as shown in
Specifically, if the quantized data is binary, the two nozzle rows share the same print buffer. If the quantized data has three values, the storage area is divided into the first and second print buffers in association with each nozzle row for management. That is, for management, the black first print buffer is assigned to the black nozzle row k1, whereas the black second print buffer is assigned to the black nozzle row k2. The three-valued data is distributed in the same manner as that used for the distribution of three-valued data for cyan, magenta, and yellow.
However, in contrast to cyan, magenta, and yellow, the ejection opening rows k1 and k2 for the second black ink are not symmetrically arranged as shown in
One-pass Printing
In the present embodiment, as described later in connection with the print mode, bidirectional printing is executed for one pass or multiple passes depending on the print mode. First, description will be given of one-pass printing according to the present embodiment.
In the figure, reference numeral 1100 denotes the color ink chip shown in
The one-pass printing according to the present embodiment has the mode in which both black ink chip and color ink chip are used and the mode in which only the color ink chip is used, as described later for the print mode. In the description below, both chips are used. However, clearly, a printing operation similar to the one shown below is also performed in the mode in which only the color ink chip is used. Accordingly, its description is omitted. Further, in the mode in which both chips are used, the ejection rows k1 and k2 for the second black ink in the color ink chip 1100 are not used.
First, in a forward scan S201, a print area 1 is printed using the pigment black ink chip 1200.
Then, the printing medium is conveyed by a distance corresponding to 64n pixels. Then, in a backward scan S202, a print area 2 is printed using the pigment black ink chip 1200.
Then, the printing medium is conveyed by the distance corresponding to 64n pixels. Then, in a forward scan S203, a print area 3 is printed using the pigment black ink chip 1200. At the same time, the print area 1 is printed using the color ink chip 1100.
In the subsequent forward and backward scans S204, to S205, . . . between which conveyance by the distance corresponding to 64n pixels is interposed, two print areas are printed using the respective chips as in the case of the scan S203. Thus, an image is completed.
According to the present printing operation, the same print area can be printed one printing scan earlier with the pigment black ink than with the color inks. This allows the color inks to be applied after the pigment black ink has sufficiently permeated through the printing medium. It is thus possible to suppress the possible bleeding between black and the other colors. Furthermore, the non-uniformity of the colors attributed to the application order of the color inks can be reduced because there are a number of dots formed with one of the two application orders as well as the same number of dots formed with the other application order, as described above.
Multi-Pass Printing
In the present embodiment, a random mask is used to generate data for each of a plurality of scans that complete a predetermined print area in multi-pass printing. Then, printing is controlled on the basis of the data generated. The print control will be described below on the basis of the random mask and the data generated using the random mask. The multi-pass printing is in the mode in which the pigment black ink that is the first black ink and the dye black ink that is the second black ink are used in addition to the cyan, magenta, and yellow inks, as described later for the print mode.
(Creation of Random Mask)
The mask is composed of four areas named a mask A, a mask B, a mask C, and a mask D. Each of the masks A, B, C, and D is composed of 16 kilobytes (1 kilobyte is 16,000 bits). Specifically, as shown in
In step S1000, a random mask starts to be created.
Then, in step S1001, a position to start mask setting is set at the leading position of the mask. That is, the mask A is set at (H, V)=(0, 0). The mask B is set at (H, V)=(16,000, 0). The mask C is set at (H, V)=(16,000×2, 0). The mask D is set at (H, V)=(16,000×3, 0). Then, in step S1002, a random number composed of 0, 1, 2, or 3 is generated. Then, in steps S1003, S1004, and S1005, printing or non-printing is set for each mask on the basis of the value of the random number.
If the random number is 0, this is determined in step S1003 and the processing in steps S1006, S1007, S1008, and S1009 is executed. Specifically, in step S1006, 1 is set for the mask A as a print bit. Here, the print bit enables the data on a pixel in the image data which corresponds to a pixel in the mask. If for example, the binary data on that pixel is 1, this means that a dot is formed in that pixel. In contrast, a non-print bit means that the data on a corresponding pixel is disabled. Then, in steps S1007, S1008, and S1009, 0 is set for the masks B, C, and D as a non-print bit. Likewise, if the random number is 1, the print bit is set for the mask B, while the non-print bit is set for the other masks. If the random number is 2, the print bit is set for the mask C, while the non-print bit is set for the other masks. If the random number is 3, the print bit is set for the mask D, while the non-print bit is set for the other masks. After the mask setting has been processed for each pixel, it is determined in step S1022 whether or not the entire area has been set. That is, it is determined whether or not the current setting position is (H, V)=(16,000, 16). If it is determined in step S1022 that not the entire area has been set, the process proceeds to step S1023. In step S1023, a position on the mask is specified which is to be set next time. At this time, 1 is added to the current V coordinate. However, if the current V coordinate is 16, V is set at 1 and 1 is added to the H coordinate for each of the masks A, B, and C, and D. After the process in step S1023, the process proceeds to step S1002 to repeat the above process. If it is determined in step S1022 that the entire area of the mask has been set, the process proceeds to step S1024 to finish the process of generating a random mask.
(Print Control)
The random mask can be set for a printable area on a printing medium. The coordinates of the printable area on the printing medium are defined as Hp in the main scanning direction and Vp in the sub-scanning direction. In the present embodiment, multi-pass printing is executed to complete the image in the same print area via four scans.
The present printer analyzes a command for print data transferred via the I/F 611 (
The ASIC of the present printer has a function to specify the start portion of a random mask as the H coordinate in the horizontal direction of the print buffer for every 16 pixels in the vertical direction of the print buffer. The ASIC also has a function to return to the leading position of the random mask upon reaching the terminal of the random mask in the horizontal direction of the print area. That is, for the horizontal direction of the print area, the ASIC repeats H=0 to 16,000 in the horizontal direction of the random mask.
On the basis of the above configuration, during a scan of the printing head, the ASIC associates the image data in the print buffer with the data for the random mask, while directly referencing the storage area to subject both data to AND. The ASIC then transfers driving data to the printing head.
In the present embodiment, an image is completed via four scans, so that an image corresponding to one fourth of the vertical width of the printing head is completed during one scan of the printing head. Accordingly, on the downstream side in the printing medium conveying direction, one fourth of the image data expanded into the print buffer during one scan of the printing head is unwanted. Thus, the unwanted area of the print buffer is used as the expansion buffer to expand the image data, while the storage area that has been used as the expansion buffer is used as one fourth of the print buffer. That is, the storage area is managed for every one fourth of the width printed by a scan of the printing head. Then, the five managed areas are used as the expansion buffer and print buffer in a rotational manner.
In the figure, broken lines indicate the amount of printing medium conveyed during one sub-scan. According to the present embodiment, the amount of printing medium conveyed during one sub-scan is 16n pixels, one fourth of the vertical width printed during one scan of the printing head. Additionally, the lateral direction of the sheet of the drawing corresponds to the scanning direction of the printing head. The upper side of the sheet of the drawing corresponds to the downstream side of the conveying direction of the printing medium.
In
Overlapping of Black Ink
On the basis of the positions of the ejection opening rows for the second black ink in the printing head shown in
As described above, in an embodiment of the present invention, in contrast to the conventional example shown in
Specifically, the arrangement of the ejection opening rows shown in
In the present embodiment, two types of dots based on different superimposition manners are arranged on one pixel as shown in
In the description below, modeling will be used to consider the difference in the coloring of a dot attributed to the bidirectional printing or the position of the black ink in a stack of the superposed inks.
The coloring of color ink dots will be considered using a color space based on the optical reflection densities of cyan, magenta, yellow. The optical reflection densities (hereinafter simply referred to as densities) of dots of the cyan, magenta, yellow, and black inks are expressed using the color space as follows:
Vc=(vc,0,0)
Vm=(0,vm,0)
Vy=(0,0,vc)
Vk=(A×vc,B×vm,C×vc)
Here, in each of these color components, the black ink is used to increase the density above the cyan, magenta, and yellow inks. Accordingly, the following expression is established.
A≦1, B≦1, C≦1 (1)
The components of the optical reflection densities of cyan, magenta, and yellow are shown to have a value of zero because the other components have relatively small values.
Then, the contribution efficiency of the ink application order to the coloring (density) is numerically expressed as f1, f2, f3, and f4, where f1 corresponds to the earliest application. Here, as previously described, for common print media, the contribution rate to the coloring is higher as the application is earlier. Accordingly, the following expression is established:
f1>f2>f3>f4>0 (2)
Under the above modeling, the coloring of the dots shown in
First, the coloring E1 of the dot shown in
E1=f1×Vk+f2×Vc+f3×Vm+f4×Vy (3)
The coloring E2 of the dot obtained by superposing the inks k2, y2, m2, and c2 on one another is:
E2=f1×Vk+f4×Vc+f3×Vm+f2×Vy (4)
Thus, the coloring E3 of the two dots shown in
E3=E1+E2=(2×f1)×Vk+(f2+f4)×Vc+(2×f3)×Vm+(f2+f4)×Vy (5)
On the other hand, the coloring E4 of the dot shown in
E4=f4×Vk+f3×Vc+f2×Vm+f1×Vy (6)
The coloring E5 of the dot obtained by superposing the inks c2, m2, y2, and k2 on one another is:
E5=f4×Vk+f1×Vc+f2×Vm+f3×Vy (7)
The coloring E6 of the two dots shown in
E6=2×f4×Vk+(f1+f3)×Vc+(2×f2)×Vm+(f1+f3)×Vy (8)
As a result, a difference ΔEa in coloring attributed to bidirectional printing is:
ΔEa=|E3−E6|=|2(f1−f4)×Vk+(f2−f1+f4−f3)×Vc+2(f3−f2)×Vm+(f2−f1+f4−f3)×Vy| (9)
Here, it is assumed that f1−f2=F1, f2−f3=F2, and f3−f4=F3. Then, on the basis of Expression (2),
F1>0, F2>0, F3>0
Accordingly, ΔEa is:
ΔEa=|2(F1+F2+F3)×Vk−(F1+F3)×Vc−2×F2×Vm−(F1+F3)×Vy| (10)
As described above,
Similarly, the same modeling is used to consider the difference in the coloring of a dot between the two directions of the bidirectional printing.
The coloring E7 of the dot shown in
E7=f4×Vk+f1×Vc+f2×Vm+f3×Vy (11)
The coloring E8 of the dot obtained by superposing the inks y2, k2, m2, and c2 on one another is:
E8=f2×Vk+f4×Vc+f3×Vm+f1×Vy (12)
Thus, the coloring E9 of these two dots shown is expressed as the sum of the above colorings as follows:
E9=E7+E8=(f2+f4)×Vk+(f1+f4)×Vc+(f2tf3)×Vm+(f1+f3)×Vy (13)
On the other hand, the coloring E10 of the dot shown in
E10=f1×Vk+f4×Vc+f3×Vm+f2×Vy (14)
The coloring E11 of the dot obtained by superposing the inks c2, m2, k2, and y2 on one another is:
E11=f3×Vk+f1×Vc+f2×Vm+f4×Vy (15)
The coloring E12, the sum of the colorings of the two dots, is:
E12=E10+E11=(f1+f3)×Vk+(f1+f4)×Vc+(f2+f3)×Vm+(f2+f4)×Vy (16)
Thus, the difference ΔEa in coloring between the two directions of the bidirectional printing according to the present embodiment is:
ΔEa=|E9−E12|=|−(f1−f2+f3−f4)×Vk+(f1−f2+f3−f4)×Vy|
or
ΔEb=(F1+F3)×|Vy−Vk| (17)
Then, the determined density difference ΔEa according to the conventional example is compared with the determined ΔEb according to the present embodiment. The densities ΔEa and ΔEb are expressed using the components Vc, Vm, and Vy. Then, on the basis of Equation (10), the following equation is given:
ΔEa2={(2A−1)×(F1+F3)+2A×F2}2×vc2+{2B×(F1+F3)+2(B−1)×F2}2×vm2+{(2C−1)×(F1+F3)+2C×F2}2×vy2 (18)
Likewise, on the basis of Equation (17), the following equation is given:
ΔEb2={A×(F1+F3)}2×vc2+{B×(F1+F3)}2×vm2+{(C−1)×(F1+F3)}2×vy2 (19)
Thus, the difference between ΔEa2 and ΔEb2 is:
ΔEa2−ΔEb2={(3A−1)×(F1+F3)+2A×F2}×{(A−1)×(F1+F3)+2A×F2}×vc2+{3B×(F1+F3)+2(B−1)×F2}×{B×(F1+F3)+2(B−1)×F2}×vm2+{(3C−2)×(F1+F3)+2C×F2}×{C×(F1+F3)+2C×F2}×vy2 (20)
When the relationship in Expression (1) is applied to Equation (20), the following expression is established. ΔEa2−ΔEb2>0, that is, ΔEa>ΔEb.
With such estimations based on the modeling, the printing head with the arrangement of the ejection opening rows according to the present embodiment shown in
Equation (17) indicates that the difference ΔEb is determined by the difference in coloring (density) between the black ink and the yellow ink. That is, as is apparent from the arrangement of the ejection opening rows shown in
If for example, the coloring of the cyan ink is the closest to the coloring of the black ink, the difference in coloring attributed to the bidirectional printing is minimized using the arrangement of the ejection opening rows shown in
In the present embodiment, the printing head with the above described arrangement of the ejection openings is used, and bidirectional multi-pass printing is carried out using this printing head. This also reduces the non-uniformity of the colors in an image which may result from a difference in coloring between the two scanning directions.
Print Mode
In the present embodiment, in a configuration that executes bidirectional printing using many types of inks, different print modes are executed depending on the types of inks used in order to suppress the non-uniformity of the colors or color drifts attributed to the bidirectional printing.
In the present embodiment, as shown in Table 1 below, if only the ejection opening rows for the cyan, magenta, and yellow inks in the color ink chip 1100 (
On the other hand, if the ejection opening for the dye black ink in the color ink chip 1100 is used in addition to the ejection openings for the color inks such as the cyan ink, multi-pass printing is executed on the basis of three-valued data. Specifically, in the present embodiment, to more favorably express, for example, the gray level, the dye black is superposed on the other color inks at a relatively high gray level. In this case, as shown in
As described above, the dye black ink is used when the multi-pass printing is executed taking the application order into account. However, for example, the gray level can of course be expressed by superposing the pigment black ink on the other inks. In such a mode, the multi-pass printing may be executed as described above.
Table 1 below shows a specific example of the use of the print modes according to the present embodiment described above.
In Table 1, a mode 1 is a print mode in which the cyan, magenta, yellow, and pigment black inks are used to print ordinary paper at high speed without using the dye black. In the mode 1, one-pass bidirectional printing is executed.
In a mode 2, the same inks as those in the mode 1 are used to print ordinary paper so as to achieve a high grade. In this case, it is possible to execute the one-pass bidirectional printing taking the possible non-uniformity of the colors into account. However, since the multi-pass printing generally provides a high-quality image, the multi-pass bidirectional printing is executed. Further, in addition to the pigment black ink, the dye black ink may be used to, for example, smooth the expression of the gray level. The dye black is suitable for the gray level expression because dye print dots have a lower optical density than pigment print dots.
In a mode 3, the cyan, magenta, and yellow inks are used to print coat paper at high speed. Thus, the one-pass bidirectional printing is executed.
In a mode 4, the dye black, cyan, magenta, and yellow inks are used to print coat paper so as to obtain a high-quality image. Thus, the multi-pass bidirectional printing is executed.
In a mode 5, the dye black, cyan, magenta, and yellow inks are used to print gloss paper so as to obtain a high-quality image. Thus, the multi-pass bidirectional printing is executed.
The print mode may be selected by the operator via the group of switches 620 or the host apparatus 610. Alternatively, for example, the present printer or the host apparatus may determine the type of a printing medium and the type of an image to be printed (for example, a document, a graph, or a photograph) and select the print mode in accordance with the determinations.
(Second Embodiment)
As described above in the first embodiment, the difference in coloring between the forward printing and the backward printing can be reduced when the asymmetrically arranged ejection opening rows for the (black) ink are arranged adjacent to the most inside one of the symmetrically arranged ink ejection opening rows. In the present embodiment, asymmetrically arranged ejection opening rows for two ink colors are added to the symmetrically arranged ejection opening rows for the cyan, magenta, and yellow inks.
As shown in
In the present embodiment, according to estimations based on modeling similar to those described above in the first embodiment, the nozzle rows c3, c4, m3, and m4, for which the application order cannot be controlled between the forward scanning and the backward scanning, that is, the asymmetrically arranged nozzle rows c3, c4, m3, and m4, are arranged adjacent to the most inside nozzle rows y1 and y2 of the other symmetrically arranged nozzle rows. Then, it is possible to reduce the difference in color between the forward scanning and the backward scanning. Consequently, the difference in color between the yellow ink and the light cyan or magenta ink determines the difference in color between the forward scanning and the backward scanning. In terms of lightness, the coloring of the light cyan and magenta inks is closer to the coloring of the yellow ink than the coloring of the cyan and magenta inks. Accordingly, the present embodiment uses the arrangement of the ejection opening rows shown in
In the first embodiment, the ink (black ink) ejected from the nozzle rows k1 and k2 for which the ink application order varies depending on the scanning direction is achromatic. Accordingly, the nozzle rows a plurality of which have the application order controlled can be efficiently used to reduce the difference in coloring between the two scanning directions.
Here, the printing head with the arrangement of the ejection rows shown in
ΔEc=2×F1×|Vy−Vk|
In actual printing, the tendency is that F1>>F2 and F3.
Then, the difference for the yellow and black inks is compared with the difference for the process black and black ink.
ΔEc/ΔEb2≅2
In the former case, a difference occurs in the scanning direction which is nearly double that which occurs in the latter case.
In the present embodiment, a color difference occurs between the light cyan ink and the light magenta ink and the yellow ink. Accordingly, the impact of the difference is lighter than that of the difference for the yellow and black inks. However, in the present embodiment, it is difficult to avoid the above combination of the inks through image processing as described in the first embodiment. It is thus effective to also use a multi-pass printing configuration using a plurality of printing scans as previously described.
The present embodiment also uses print modes in accordance with the types of inks. Table 2 below shows a specific example of the use of the print modes.
In a mode 1, the cyan, magenta, yellow, and pigment black inks are used to print ordinary paper at high speed. In the mode 1, the one-pass bidirectional printing is executed.
In a mode 2, the cyan, magenta, yellow, and pigment black inks as well as the light cyan and magenta inks are used to print ordinary paper so as to achieve a high grade. Thus, in the mode 1, the multipass bidirectional printing is executed.
In a mode 3, the cyan, magenta, and yellow inks are used to print coat paper at high speed. Thus, the one-pass bidirectional printing is executed.
In a mode 4, the cyan, magenta, yellow, light cyan, and light magenta inks are used to print coat paper so as to obtain a high-quality image. Thus, the multi-pass bidirectional printing is executed.
In a mode 5, the cyan, magenta, yellow, light cyan, and light magenta inks are used to print gloss paper so as to obtain a high-quality image. Thus, the multi-pass bidirectional printing is executed.
(Other Embodiments)
In the above first embodiment, the dye black ink is added to the cyan, magenta, and yellow inks to enable the gray level to be appropriately expressed. In the second embodiment, the light cyan and magenta inks are used to enlarge a color reproduction area for a low-lightness part. However, of course, the inks added to the cyan, magenta, and yellow inks are not limited to these black inks or the inks of low color material densities.
For example, instead of the black ink or the like, a special color ink such as an orange, green, or blue ink may be used to enlarge a color reproduction area for orange, green, or blue. Further, inks may be added to the cyan, magenta, and yellow inks in order to improve the gray level. For example, to improve the expression of a low-lightness yellow part, a low-lightness yellow or gray ink may be used in place of the black ink.
In this case, the difference in color between the forward scanning and the backward scanning can be reduced by asymmetrically arranging the ejection opening rows adjacent to the most inside rows of the other symmetrically arranged ejection opening rows.
As described above, in a configuration for bidirectional printing, it is possible to achieve high-speed and high-grade printing particularly with the reduced non-uniformity of the colors, while minimizing an increase in the size of the printing head even if special inks are used to enlarge the color reproduction area or improve the gray level.
As described above, according to the embodiments of the present invention, the ejection openings of the printing head are arranged so that between ejection openings for two predetermined different inks included in the predetermined symmetrically arranged ejection openings for which the manner of overlapping can be controlled to remain unchanged between the forward scanning and the backward scanning, an ejection opening except the predetermined symmetrical ejection openings is located. This reduces the difference in the color of a dot formed when the manner of superposing the ink ejected from the ejection opening except the predetermined symmetrical ejection openings and the inks ejected from the predetermined symmetrically arranged ejection openings varies between the forward scanning and the backward scanning.
As a result, in an ink jet printing apparatus using many types of inks to execute bidirectional printing, it is possible to achieve high-speed and high-grade printing particularly by reducing the non-uniformity of colors attributed to the bidirectional printing, while minimizing an increase in the size of the printing head.
The present invention has been described in detail with respect to preferred embodiments, and it will now be apparent from the foregoing to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspect, and it is the intention, therefore, in the apparent claims to cover all such changes and modifications as fall within the true spirit of the invention.
Number | Date | Country | Kind |
---|---|---|---|
2003-169969 | Jun 2003 | JP | national |
This application claims priority from Japanese Patent Application No. 2003-169969 filed Jun. 13, 2003, which is incorporated hereinto by reference. The present application is a divisional of U.S. patent application No. 12/580,738 filed Oct. 16, 2009, which in turn is a divisional of 10/864,356, filed on Jun. 10, 2004, now U.S. Pat. No. 7,621,621, issued Nov. 24, 2009, the entire disclosure of each of which is incorporated by reference herein.
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Number | Date | Country | |
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Parent | 12580738 | Oct 2009 | US |
Child | 13196349 | US | |
Parent | 10864356 | Jun 2004 | US |
Child | 12580738 | US |