Patent Publication Number: US-7909433-B2

Title: Liquid ejecting apparatus and raster line forming method

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     The present application claims priority from Japanese Patent Application No. 2007-241370 filed on Sep. 18, 2007, and Japanese Patent Application No. 2008-185235 filed on Jul. 16, 2008, which are herein incorporated by reference. 
     BACKGROUND 
     1. Technical Field 
     The present invention relates to liquid ejecting apparatuses and raster line forming methods. 
     2. Related Art 
     Inkjet printers that carry out printing by ejecting a liquid (ink) onto various media such as paper, cloth, and film are well known as an example of liquid ejecting apparatuses. These printers are provided with a head in which a plurality of nozzles for ejecting liquid onto a medium are arranged in a first direction (sub-scanning direction), and this head ejects liquid while moving in a second direction (main scanning direction) that intersects the first direction (International Publication WO 01/03930). 
     From a viewpoint of increasing picture quality, the above-mentioned printer carries out so-called overlap printing, for example. That is, the printer alternately moves the head a plurality of times in the second direction and the first direction, and forms a single raster line by causing two or more different nozzles to eject liquid. 
     Incidentally, from a viewpoint of increasing the printing speed, some printers are provided with a head unit that has a plurality of the aforementioned heads arranged along the first direction. In this case it is conceivable that the width in the first direction of the head unit is made wider than the width in the first direction of the medium such that liquid is ejected at one time across an entire width of the medium, for example. However, with this configuration, in the case where a total amount of movement of the head unit in the first direction during printing is large, it is necessary to increase the width of the head unit in the first direction in order to have liquid ejected across the entire width of the medium at a single time during movement in the second direction. 
     Further, it is known that liquid ejecting characteristics vary due to individual differences of the heads. For example, one head has a characteristic of ejecting liquid easily, while another head has a characteristic of ejecting liquid with difficulty. For this reason, in the case where the plurality of heads that constitute the head unit ejects liquid, a so-called density irregularity or the like may occur due to differences in the ejection characteristics of each of the heads and as a result, there is a risk for image quality to deteriorate. 
     SUMMARY 
     The present invention has been devised in light of these issues, and it is an advantage thereof to control an increase in the width in the first direction of the head unit as well as to curb deterioration in image quality. 
     A primary aspect of the invention is directed to a liquid ejecting apparatus such as the following. 
     A liquid ejecting apparatus including 
     a head unit that has a plurality of heads along a first direction, in which a plurality of nozzles that eject a liquid onto a medium are lined up in the first direction, and that ejects the liquid while moving relative to the medium in a second direction, which intersects the first direction,
         the head unit having a width in the first direction that is greater than a width of the medium in the first direction,       

     a movement mechanism that makes the head unit move relative to the medium a plurality of times alternately in the second direction and the first direction, and 
     a control section that
         forms a raster line group by forming each raster line by making two or more different nozzles that are different eject the liquid, respectively while making the movement mechanism move the head unit relative to the medium a plurality of times alternately in the second direction and the first direction,   makes the movement mechanism move the head unit relatively so that a total amount of movement of the head unit in the first direction when the head unit has moved relatively the plurality of times is less than an effective nozzle width of one of the heads in the first direction, and   forms the raster line group so that a number of the raster lines formed by making the nozzles of only one of the heads eject the liquid is not greater than a number of the raster lines formed by making the nozzles of two or more of the heads eject the liquid.       

     Other features of the invention will be made clear by reading the description of the present specification with reference to the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a block diagram showing an overall configuration of a printer  1 . 
         FIG. 2A  is a schematic cross-sectional view of the printer  1 , and  FIG. 2B  is a schematic top view of the printer  1 . 
         FIG. 3  is a diagram for describing a nozzle arrangement on a lower face of a head unit  40 . 
         FIG. 4A  to  FIG. 4I  are schematic diagrams for showing how the head unit  40  moves during printing. 
         FIG. 5A  and  FIG. 5B  are diagrams for describing density irregularities arising from ejection characteristic differences among heads  41 . 
         FIG. 6A  is a diagram showing the head unit  40  in the case where the total amount of sub-scanning is increased.  FIG. 6B  is a diagram showing the head unit  40  in the case where the total amount of sub-scanning is reduced. 
         FIG. 7  is a flowchart for describing the present printing process. 
         FIG. 8  is a diagram for describing overlap printing according to the present embodiment. 
         FIG. 9  is a diagram for describing overlap printing according to the present embodiment. 
         FIG. 10  is a diagram showing a head unit  40  according to a second embodiment. 
         FIG. 11  is a diagram for describing overlap printing according to the second embodiment. 
         FIG. 12  is a diagram for describing overlap printing according to a third embodiment. 
     
    
    
     DESCRIPTION OF EXEMPLARY EMBODIMENTS 
     At least the following matters will be made clear by the present specification and the accompanying drawings. 
     A liquid ejecting apparatus including: 
     a head unit that has a plurality of heads along a first direction, in which a plurality of nozzles that eject a liquid onto a medium are lined up in the first direction, and that ejects the liquid while moving relative to the medium in a second direction, which intersects the first direction,
         the head unit having a width in the first direction that is greater than a width of the medium in the first direction,       

     a movement mechanism that makes the head unit move relative to the medium a plurality of times alternately in the second direction and the first direction, and 
     a control section that
         forms a raster line group by forming each raster line by making two or more different nozzles that are different eject the liquid, respectively while making the movement mechanism move the head unit relative to the medium a plurality of times alternately in the second direction and the first direction,   makes the movement mechanism move the head unit relatively so that a total amount of movement of the head unit in the first direction when the head unit has moved relatively the plurality of times is less than an effective nozzle width of one of the heads in the first direction, and   forms the raster line group so that a number of the raster lines formed by making the nozzles of only one of the heads eject the liquid is not greater than a number of the raster lines formed by making the nozzles of two or more of the heads eject the liquid.       

     According to such a liquid ejecting apparatus, width in a first direction of the head unit can be controlled from increasing and the deterioration in image quality can be controlled as well. 
     Further, in the liquid ejecting apparatus, it is preferable that 
     in a case where a number of movements by the head unit in the second direction when the head unit moves relatively the plurality of times is set to an m number of times, 
     all the heads eject the liquid during each movement in the second direction. 
     In this case, the raster line groups can be formed while reducing the total amount of movement of the head unit with a minimum number of heads. 
     Furthermore, in the liquid ejecting apparatus, it is preferable that: 
     in a case where a number of movements by the head unit in the first direction when the head unit moves relatively the plurality of times is set to an n number of times, 
     each amount of movement in the first direction is a same. 
     In this case, deterioration in image quality can be effectively curbed. 
     Furthermore, a raster line forming method includes: 
     preparing a head unit that has a plurality of heads along a first direction, in which a plurality of nozzles that eject a liquid onto a medium are lined up in the first direction, and that ejects the liquid while moving relative to the medium in a second direction, which intersects the first direction, a width of the head unit in the first direction being greater than a width of the medium in the first direction, and 
     forming a raster line group by forming each raster line by making two or more of the nozzles that are different eject the liquid, respectively while making the head unit move relatively with respect to the medium a plurality of times alternately in the second direction and the first direction,
         the head unit made to move relatively so that a total amount of movement of the head unit in the first direction when the head unit has moved relatively the plurality of times is less than an effective nozzle width of one of the heads in the first direction, and   the raster line group formed so that a number of the raster lines formed by making the nozzles of only one of the heads eject the liquid is not greater than a number of the raster lines formed by making the nozzles of two or more of the heads eject the liquid.       

     With such a raster line forming method, width in a first direction of the head unit can be controlled from increasing and the deterioration in image quality can be curbed as well. 
     Configuration Example of an Inkjet Printer 
     An inkjet printer (hereinafter referred to as “printer  1 ”), which is one example of a liquid ejecting apparatus, is for printing by an inkjet system onto a band-shaped printing tape T, which is one example of a medium, unit images that are later cut out for use such as printing items that are affixed on wrapping film for fresh foods, for example. Here, the printing tape T is a rolled paper (continuous paper) with a release paper, and images for printed items are printed continuously in a direction in which the printing tape T is continuous. 
     Configuration of Printer  1   
       FIG. 1  is a block diagram showing an overall configuration of the printer  1 .  FIG. 2A  is a schematic cross-sectional view of the printer  1 , and  FIG. 2B  is a schematic top view of the printer  1 .  FIG. 3  shows a nozzle arrangement on a lower face of a head unit  40 . 
     Upon receiving print data, the printer  1  controls each unit (a transport unit  20 , a drive unit  30 , and the head unit  40 ) with a controller  10 , which is one example of a control section, and forms an image on the printing tape T. It should be noted that conditions within the printer  1  are monitored by a detector group  50 , and the controller  10  controls each unit based on detection results thereof. 
     The transport unit  20  is for transporting the printing tape T in a direction in which the printing tape T is continuous (hereinafter referred to as transport direction) from an upstream side to a downstream side. The transport unit  20  is provided with components such as feed rollers  21 , feed out rollers  22 , and a suction table  23 . The feed rollers  21  feed the printing tape T, which is in a roll form before printing, onto the suction table  23 , which is a printing region. The suction table  23  holds the printing tape T by performing vacuum suction on the printing tape T from below. The feed out rollers  22  feed out the printed printing tape T from the printing region. The printing tape T that has been fed out from the printing region is wound into a roll form by a winding mechanism. 
     The drive unit  30  is a movement mechanism that causes the head unit  40  to move freely in the main scanning direction, which corresponds to the transport direction, and the sub-scanning direction, which corresponds to the width direction of the printing tape T. The drive unit  30  is constituted for example by an X movement table, which causes the head unit  40  to move in the main scanning direction, and a Y movement table, which causes the X movement table holding the head unit  40  to move in the sub-scanning direction, and a motor that causes these tables to move (not shown). 
     The head unit  40  forms dot rows (raster lines) on the printing tape T by ejecting ink while moving in the main scanning direction. A collection of these dot rows forms an image and therefore an image is printed by forming these dot rows. The head unit  40  has ten heads  41  and the ten heads  41  are arranged in a staggered manner in the width direction (sub-scanning direction). And the ten heads are arranged so that ink can be ejected across the entire width of the printing tape T by a single movement of the head unit  40  in the main scanning direction, that is, arranged so that the width of the head unit  40  in the sub-scanning direction is wider than the width of the printing tape T. 
     Furthermore, a nozzle row Y that ejects yellow ink, a nozzle row M that ejects magenta ink, a nozzle row C that ejects cyan ink, and a nozzle row K that ejects black ink are formed on the lower face of each of the heads  41 . In each nozzle row, 360 uniformly spaced (360 dpi) nozzles are lined up in the width direction. Furthermore, of the two heads adjacent in the width direction (here description is given using head  41 ( 1 ) and head  41 ( 2 ) as an example), nozzles # 359  and # 360  at the nearest side of the back side head  41 ( 1 ) and nozzles # 1  and # 2  at the farthest side of the near side head  41 ( 2 ) are arranged on same lines (that is, the nozzles overlap). It should be noted that in the present embodiment, the sub-scanning direction corresponds to the first direction and the main scanning direction corresponds to the second direction. 
     Movement of the Head Unit  40  During Printing 
       FIG. 4A  to  FIG. 4I  are schematic diagrams for describing how the head unit  40  moves during printing. The printer  1  forms dot rows (raster lines) with the head unit  40  by moving four times in the main scanning direction. It should be noted that during printing, the printing tape T is in a state of being held on the suction table  23  without being transported. 
     Before printing, the head unit  40  is at a standby at a home position (a position shown in  FIG. 4A ). During printing, first the head unit  40  is moved by the drive unit  30  in the main scanning direction from the downstream side to the upstream side ( FIG. 4B ). Then, during this movement (pass  1 ), ink is ejected from the nozzles of the head unit  40  across the entire width of the printing tape T such that dot rows of pass  1  are formed on the printing tape T. Having been moved in the main scanning direction, the head unit  40  is then moved by the drive unit  30  in the sub-scanning direction from the back side to the near side ( FIG. 4C ), thereafter, the head unit  40  is moved in the main scanning direction (pass  2 ) from the upstream side to the downstream side ( FIG. 4D ) while ink is ejected from the nozzles across the entire width of the printing tape T to form dot rows of pass  2 . Here the term “pass” refers to a single movement of the head unit  40  along the main scanning direction, and the number attached to the term “pass” indicates the order in which the pass is carried out. 
     In this manner, the head unit  40  moves alternately with movements of the head unit  40  in the main scanning direction ( FIG. 4B ,  FIG. 4D ,  FIG. 4F , and  FIG. 4H ) and movements of the head unit  40  in the sub-scanning direction ( FIG. 4C ,  FIG. 4E , and  FIG. 4G ) to form dots. In this way, a plurality of dot rows (raster line groups) are formed across the entire width of the printing tape T. Then, after completing the movement in the main scanning direction for the fourth time (pass  4  in  FIG. 4H ), the head unit  40  moves in the sub-scanning direction to the back side ( FIG. 4I ) and is positioned in the home position shown in  FIG. 4A . In this way, a series of movements of the head unit  40  during printing is completed. 
     Density Irregularities Arising from Ejection Characteristic Differences Among the Heads  41   
     It is known that ink ejection characteristics vary due to individual differences of the heads  41 . For example, in contrast to the nozzles of a particular head  41  from which ink is ejected easily, ink may be ejected with difficulty from the nozzles of a different head  41 . Thus, in the case where printing is performed using the head unit  40 , which has ten heads  41  having individual differences, so-called density irregularities may occur arising from differences of ejection characteristics among the heads  41 . 
     Here, of the ten heads  41 , description is given using head  41 ( 3 ), head  41 ( 4 ), and head  41 ( 5 ) as examples. Suppose that the head  41 ( 3 ) has a characteristic of ejecting ink with difficulty (ink ejection amount is less than an appropriate amount), the head  41 ( 4 ) has a characteristic of ejecting ink normally (the ink ejection amount is appropriate), and the head  41 ( 5 ) has a characteristic of ejecting ink easily (the ink ejection amount is more than an appropriate amount). For this reason, suppose that when it is necessary to form dots with an appropriate ejection amount (hereinafter referred to as medium dots), the head  41 ( 3 ) forms dots with ejection amounts that are less than the appropriate amount (hereinafter referred to as small dots), the head  41 ( 4 ) forms medium dots, and the head  41 ( 5 ) forms dots with ejection amounts that are greater than the appropriate amount (hereinafter referred to as large dots). It should be noted that a majority of the other heads  41  of the ten heads  41  are considered to form medium dots in a same manner as the head  41 ( 4 ). 
       FIG. 5A  and  FIG. 5B  are diagrams for describing density irregularities arising from ejection characteristic differences among the heads  41 . The dot rows shown in  FIG. 5A  and  FIG. 5B  are formed by two passes, with  FIG. 5A  showing the dot rows after pass  1  and  FIG. 5B  showing the dot rows after pass  2 . 
     In the first dot row of the five dot rows, pass  1  and pass  2  are performed by head  41 ( 3 ). Thus, only small dots are aligned in the first dot row. In the second dot row, pass  1  is performed by head  41 ( 3 ) and pass  2  by head  41 ( 4 ). Thus, in the second dot row, small dots and medium dots are aligned alternately. In the third dot row, pass  1  and pass  2  are performed by head  41 ( 4 ), thus only medium dots are aligned. In the fourth dot row, pass  1  is performed by head  41 ( 4 ) and pass  2  by head  41 ( 5 ), thus medium dots and large dots are aligned alternately. In the fifth dot row, pass  1  and pass  2  are performed by the head  41 ( 5 ), thus only large dots are aligned. 
     In this case, the first dot row is formed by only small dots so that the first dot row appears lighter compared to dot rows formed by medium dots (dots with an appropriate ejection amount). In other words this is recognized as a density irregularity. Similarly, the fifth dot row is formed by only large dots and the fifth dot row appears darker compared to dot rows formed by medium dots. In other words, it is recognized as a density irregularity. And when the numbers of first dot rows and fifth dot rows increase, the density irregularities become apparent thereby resulting in an even greater reduction in image quality. 
     On the other hand, the third dot row is formed by only medium dots, and therefore it has an appropriate density. And in the second and fourth dot rows, even if there are small dots and large dots included therein, medium dots share a half to neutralize the density as a whole such that density irregularities is difficult to be recognized. 
     In this way, in a configuration in which a plurality of heads  41  having different ink ejection characteristics are used to form dot rows, a problem may occur in which density irregularities become apparent in the case where dot rows are formed by only a single head  41  (the above-mentioned head  41 ( 3 ) and head  41 ( 5 )). 
     Relationship Between Total Sub-Scanning Amount of the Head Unit and Width of the Head Unit During Printing 
     The printer  1  according to the present embodiment is configured to eject ink across the entire width of the printing tape T with the four movements in the main scanning direction (pass  1  to pass  4 ). Since the image resolution (for example, a sub-scanning direction resolution of 720 dpi) is smaller than the nozzle pitch (360 dpi), this is achieved by moving the head unit  40  in the sub-scanning direction by units of 720 dpi to form dot rows with intervals smaller than the nozzle pitch. 
     On the other hand, the head unit  40  moves three times in the sub-scanning direction ( FIG. 4C ,  FIG. 4E , and  FIG. 4G ) during the four passes  1  to  4 . And in order to eject ink across the entire width of the printing tape T with passes  1  through  4 , the sub-scanning direction width of the head unit  40  varies in response to the amount of total movement by the three moves (hereinafter referred to as “total sub-scanning amount”). Description is given regarding this point with reference to  FIG. 6A  and  FIG. 6B . 
       FIG. 6A  shows the width of the head unit  40  in the case where the total sub-scanning amount is increased.  FIG. 6B  shows the width of the head unit  40  in the case where the total sub-scanning amount is reduced. It should be noted that the head units  40  on the left-side indicated by chained double-dashed lines in  FIGS. 6A and 6B  are in a state immediately prior to the first time main scanning direction movement (pass  1 ) and the head units  40  on the right-side indicated by solid lines are in a state immediately before the fourth time main scanning direction movement (pass  4 ). Thus, the amount of shift in the sub-scanning direction between the head units  40  in the chained double-dashed line and the head units  40  in the solid line is the total sub-scanning amount of the head unit  40 . 
     As can be seen from  FIG. 6A  and  FIG. 6B , the larger the amount of scanning is, the larger the width of the head unit  40  in the sub-scanning direction is, so that ink is ejected across the entire width of the printing tape T. That is, the number of heads  41  constituting the head unit  40  increases. And when the width of the head unit  40  increases, there is a risk that upsizing of the printer  1  will be required to secure installation space for the head unit  40 . 
     Print Processing According to the Present Embodiment 
     In order to curb the above-mentioned problems, namely apparent density irregularities and increase of width in the sub-scanning direction of the head unit  40 , the printer  1  executes print processing in the following description. 
     Aspects of this print processing include (1) the head unit  40  moved by the drive unit  30  so that the total amount of movement of the head unit  40  in the sub-scanning direction during printing is smaller than an effective nozzle width (described later) in the sub-scanning direction of a single head  41 , and (2) raster line groups formed so that, of the raster line groups (a plurality of dot rows), the number of raster lines (dot rows) to be formed by ejecting ink from the nozzles of only one head  41  is not greater than the number of raster lines formed by ejecting ink from the nozzles of two or more heads  41 . 
     The various operations of the printer  1  during print processing are mainly achieved by the controller  10 . Particularly, in the present embodiment, the operations are achieved by a CPU  12  executing programs stored in a memory  13 . These programs are constituted by a program code for performing various operations that are described below. 
       FIG. 7  is a flowchart for describing the present print processing. The flowchart shown in  FIG. 7  begins when the controller  10  receives print data from a computer  90  ( FIG. 1 ) via an interface  11 . 
     In the present print processing, the controller  10  first feeds the printing tape T into the printing region (step S 2 ) with the transport unit  20 . In other words, the feed rollers  21  feed the printing tape T before printing onto the suction table  23 , which is the printing region. 
     Next, the controller  10  causes ink to be ejected from the nozzles while causing the drive unit  30  to move the head unit  40  ( FIG. 4B ) in the main scanning direction (step S 4 ). That is, the controller  10  forms dot rows by pass  1  on the printing tape T held on the suction table  23 . Since the image (print item) is formed by four passes, when the dot rows of pass  1  are formed, the controller  10  causes the drive unit  30  to move the head unit  40  in the sub-scanning direction by a certain sub-scanning amount ( FIG. 4C ) (step S 6 : no, step S 8 ). 
     Then, the controller  10  alternately carries out forming of dot rows accompanied by the main scanning direction movements ( FIG. 4D ,  FIG. 4F , and  FIG. 4H ) of the head unit  40 , and the sub-scanning direction movements ( FIG. 4E  and  FIG. 4G ) of the head unit  40  until the dot formation process finishes (steps S 4  to S 8 ). It should be noted that a so-called overlap printing is carried out in the present embodiment. 
     Here, description is given on overlap printing according to the present embodiment. Overlap printing is a printing method in which a single dot row (raster line) is formed with the use of two or more nozzles. Specifically, one nozzle forms an intermittent row of dots by forming dots at several dots interval in the main scanning direction. Then, a different nozzle forms a dot row so as to complement the already-formed intermittent row of dots. 
       FIG. 8  and  FIG. 9  are diagrams for describing overlap printing according to the present embodiment. However, for the sake of brevity, only nozzle row C of the four nozzle rows (nozzle row Y, nozzle row M, nozzle row C, and nozzle row K) in each of the heads  41  is shown, and the number of nozzles in each of the heads  41  is reduced to 16 nozzles. For this reason,  FIG. 8  shows the position of nozzle row C of the heads (head  41 ( 1 ), head  41 ( 2 ) and so on) on the farther side of the ten heads  41  in the sub-scanning direction during passes  1  through  4  and how the dots are formed thereby. And  FIG. 9  shows the position of nozzle row C of the heads (head  41 ( 10 ), head  41 ( 9 ) and so on) on the near side in the sub-scanning direction during passes  1  through  4  and how dots are formed thereby. Furthermore, in  FIG. 8  and  FIG. 9 , the dots formed by the nozzles of head  41 ( 1 ) and head  41 ( 7 ) are shown as white dots (∘), the dots formed by the nozzles of head  41 ( 2 ) and head  41 ( 8 ) are shown as black dots (●), the dots formed by the nozzles of head  41 ( 3 ) and head  41 ( 9 ) are shown as white triangles (Δ), and the dots formed by the nozzles of head  41 ( 4 ) and head  41 ( 10 ) are shown as black triangles (▴). 
     At passes  1  through  4 , dots are formed in the pixels of the printing region by the nozzles of nozzle row C. Here, “pixels” refers to square grids that are virtually determined on the printing tape T for limiting the positions at which dots are to be formed. Further still, since an explanation is made on specific pixels, pixels lined up in the main scanning direction are expressed as “lines” and pixels lined up in the sub-scanning direction are expressed as “rows”. It should be noted that the pixels shown in  FIG. 8  and  FIG. 9  are lined up with intervals of 720 dpi in both the main scanning direction and the sub-scanning direction. 
     First, in pass  1 , ink is ejected from the nozzles of each of the heads  41 . And dot rows are formed in the pixels of odd numbered lines (lines  1 ,  3 ,  5 , and so on) and odd numbered rows (rows  1 ,  3 ,  5 , and so on) as shown in  FIG. 8 . For example, ink is ejected from nozzle # 1  of the head  41 ( 1 ) to form dots in the pixels in the odd numbered rows of the first line. Similarly, ink is ejected from nozzle # 2  of the head  41 ( 1 ) to form dots in the pixels in the odd numbered rows of the third line. In this way, each nozzle forms dots in every other pixel in the main scanning direction at each line corresponding to their respective positions. 
     It should be noted that the manner in which ink is ejected from the overlapping nozzles of two adjacent heads in the width direction (here description is given using the head  41 ( 1 ) and the head  41 ( 2 ) as examples) is different from the manner in which ink is ejected from the nozzles that do not overlap (for example, nozzle # 1  of the head  41 ( 1 )). That is, in pass  1 , nozzle # 15  and nozzle # 16  on the back side of head  41 ( 1 ) in the width direction form dot rows in the pixels of rows  3 ,  7 ,  11 , and so on, and nozzle # 1  and nozzle # 2  of the near side of the head  41 ( 2 ) form dot rows in the pixels of rows  1 ,  5 ,  9 , and so on. In this way, the nozzles of two adjacent heads  41  eject ink alternately and form dot rows in pixels of the odd numbered rows. 
     After pass  1  ends, the head unit  40  moves by a predetermined sub-scanning amount F (specifically, 7/720 dpi) from the back side to the near side in the sub-scanning direction as a first time sub-scanning direction movement during printing. 
     In pass  2  after the movement of the head unit  40 , dot rows are formed in pixels of even numbered lines (lines  8 ,  10 ,  12 , and so on) and even numbered rows (rows  2 ,  4 ,  6 , and so on). For example, ink is ejected from nozzle # 1  of the head  41 ( 1 ) and dots are formed in the pixels in the even numbered rows of the eighth line. Similarly, ink is ejected from nozzle # 2  of the head  41 ( 1 ) and dots are formed in the pixels in the even numbered rows of the tenth line. Furthermore, in pass  2 , nozzle # 15  and nozzle # 16  on the back side of the head  41 ( 1 ) of the adjacent heads in the width direction form dot rows in the pixels of rows  4 ,  8 ,  12 , and so on, and nozzle # 1  and nozzle # 2  on the near side of the head  41 ( 2 ) form dot rows in the pixels of rows  2 ,  6 ,  10 , and so on. That is, in a same manner as in pass  1 , the nozzles of the two adjacent heads  41  eject ink alternately and form dot rows in pixels in the even numbered rows (the same is true in regard to the third pass and the fourth pass, which are described later). 
     After pass  2  ends, the head unit  40  moves by a predetermined sub-scanning amount of F (7/720 dpi) as a second time sub-scanning direction movement. 
     Similarly, in pass  3 , dot rows are formed in pixels of odd numbered lines (lines  15 ,  17 ,  19 , and so on) and even numbered rows (rows  2 ,  4 ,  6 , and so on). As a result, a dot row in the twenty-third line, for example, is completed by pass  1  and pass  3 . 
     After pass  3  ends, the head unit  40  moves by a sub-scanning amount of F (7/720 dpi), which is the same amount as that of the first time and second time sub-scanning, as a third time sub-scanning direction movement. In this way, the amount of movement F in each of the three times of movement by the head unit  40  in the sub-scanning direction is of the same. Furthermore, a total of the three times of sub-scanning amounts of the head unit  40  (total sub-scanning amount 3F) has a relationship in that it is smaller than an effective nozzle width of a single head  41 , which is described later. 
     First, description is given regarding effective nozzles. The idea of effective nozzles is different depending on whether or not there are overlapping nozzles (mentioned earlier) between adjacent heads  41 . In the case where there are no overlapping nozzles, effective nozzles of heads  41  refer to all the nozzles of the nozzle rows (see  FIG. 11 ). On the other hand, in the case where there are overlapping nozzles, the effective nozzles of the heads  41  are determined by taking the overlapping nozzles into consideration. Specifically, the effective nozzles of a head  41  are constituted by non-overlapping nozzles among nozzle rows within the head  41 , and overlapping nozzles within the head  41  that are evenly distributed in relation with a different head  41 . 
     Here, description is given regarding how the overlapping nozzles are evenly distributed. For example, in  FIG. 8 , nozzle # 15  and nozzle # 16  of the head  41 ( 1 ) overlap nozzle # 1  and nozzle # 2  of the head  41 ( 2 ). In this case, the overlapping nozzles are distributed evenly such that it is the nozzle # 15  of nozzle # 15  and nozzle # 16  that is included in the effective nozzles of the head  41 ( 1 ), and it is the nozzle # 2  of nozzle # 1  and nozzle # 2  that is included in the effective nozzles of the head  41 ( 2 ). In this way, half the nozzles of the overlapping nozzles of the head  41  are distributed to that head  41  so as to be included as effective nozzles. 
     Each of the ten heads  41  of the present embodiment have overlapping nozzles, and the effective nozzles of the heads  41  are as follows. The effective nozzles in the head  41 ( 1 ) are the 15 nozzles being, nozzle # 1  to nozzle # 14 , and nozzle # 15  of nozzle # 15  and nozzle # 16  that overlap with nozzle # 1  and nozzle # 2  of the head  41 ( 2 ). On the other hand, the effective nozzles in the head  41 ( 2 ) are the 14 nozzles being, nozzle # 2  of nozzle # 1  and nozzle # 2  that overlap with nozzle # 15  and nozzle # 16  of the head  41 ( 1 ), nozzle # 3  to nozzle # 14 , and nozzle # 15  of nozzle # 15  and nozzle # 16  that overlap with nozzle # 1  and nozzle # 2  of the head  41 ( 3 ). As in the head  41 ( 2 ), the effective nozzles of the head  41 ( 3 ) to head  41 ( 9 ) are nozzle # 2  to nozzle # 15 . On the other hand, the effective nozzles in the head  41 ( 10 ) are the 15 nozzles being, nozzle # 2  of nozzle # 1  and nozzle # 2  that overlap the nozzles of the head  41 ( 9 ), and nozzle # 3  to nozzle # 16 . 
     Next, description is given regarding the effective nozzle width, which is determined from the aforementioned effective nozzles. The effective nozzle width is the width between effective nozzles in the sub-scanning direction (the effective nozzles are lined up with an interval of 2/720 dpi in the sub-scanning direction). In the present embodiment, the effective nozzle width in the head  41 ( 1 ) and the head  41 ( 10 ) is 30/720 dpi since there are 15 effective nozzles. On the other hand, the effective nozzle width in the head  41 ( 2 ) to the head  41 ( 9 ) is 28/720 dpi since there are 14 effective nozzles. And in the printer  1 , the total sub-scanning amount 3F (21/720 dpi) during printing by the head unit  40  is set to be smaller than the effective nozzle width that is smaller (28/720 dpi) of the two effective nozzle widths. 
     Description on overlap printing continues. In pass  4 , dot rows are formed in pixels in even numbered lines (lines  22 ,  24 ,  26 , and so on) and odd numbered rows (rows  1 ,  3 ,  5 , and so on). As a result, a dot row of the twenty-second line, for example, is completed by pass  2  and pass  4 . In this manner, in overlap printing of the present embodiment, a single dot row is formed by two different nozzles. 
     Here, discussion will follow on which nozzles of the heads  41  are used to form the dot rows (raster lines) of the printing region. Here, dot rows of the printing region refer to dot rows that are completed as in the dot row of the twenty-second line, and in the present embodiment refer to dot rows of line  22  to line L ( FIG. 9 ). 
     First, attention is given to the 28 dot rows (raster lines) from line  22  to line  49 . These dot rows are formed by the nozzles of the head  41 ( 1 ) and head  41 ( 2 ). Examining this in detail, the ten dot rows of lines  22  to  28 , line  30 , line  32 , and line  34  are formed by two different nozzles of the head  41 ( 1 ), and the two dot rows of lines  47  and  49  are formed only by two different nozzles of the head  41 ( 2 ). On the other hand, of the 28 dot rows, the dot rows (16 dot rows) other than those mentioned above are formed by nozzles of both the head  41 ( 1 ) and the head  41 ( 2 ). In this way, in the dot rows of lines  22  to  49 , the number of dot rows (12 rows) formed by nozzles of only a single head  41  is less than the number of dot rows (16 rows) formed with nozzles of two heads  41 . 
     Next, attention is given to the 28 dot rows from line  50  to line  77 . It should be noted that the reason for giving attention to every 28 dot rows is because dot rows of the printing region are formed by repeating, as a single cycle, the 28 dots rows according to the sub-scanning amount F (7/720 dpi) of the head unit  40  being a quarter of the effective nozzle width (28/720 dpi), (in other words, a combination of nozzles forming each dot row are determined for each 28 dot rows). That is, in a same manner as the 28 dot rows of lines  50  to  77 , the following 28 dot rows (for example, dot rows of lines  78  to  105 ) are also formed in a same manner as the 28 dot rows of lines  22  to  49 . 
     And the dot rows of lines  50  to  77  are formed by the nozzles of the head  41 ( 1 ), head  41 ( 2 ), and head  41 ( 3 ). Examining this in detail, the eight dot rows of line  51 , line  53  to line  56 , line  58 , line  60 , and line  62  are formed by two different nozzles of the head  41 ( 2 ), and the two dot rows of line  75  and line  77  are formed by two different nozzles of the head  41 ( 3 ). On the other hand, the dot rows (18 dot rows) of the 28 dot rows other than those mentioned above are formed by nozzles of two heads among the head  41 ( 1 ), head  41 ( 2 ), and head  41 ( 3 ). 
     In this way, even in the case of the dot rows of lines  50  to  77  (that is, the 28 dot rows corresponding to a single cycle in the case where the combination of nozzles used are repeated cyclically), the number of dot rows (10 rows) formed by nozzles of only a single head  41  is less than the number of dot rows (18 rows) formed by nozzles of two heads  41 . And in the present print processing, of the dot rows included in the printing region, the number of dot rows formed by nozzles of only a single head  41  is less than the number of dot rows formed by nozzles of two heads  41 . 
     Description was given above concerning overlap printing according to the present embodiment. Returning to the flowchart shown in  FIG. 7 , description on the present print processing will continue. When dot formation processing is completed by forming the dot rows in pass  4  (step S 6 : yes) or in other words, when the item to be printed (image) is printed on the printing tape T, the controller  10  causes the drive unit  30  to move the head unit  40  in the sub-scanning direction ( FIG. 4I ) so as to be positioned at the home position (step S 10 ). 
     Next, the controller  10  uses the transport unit  20  to feed out from the printing region the printing tape T on which dots have been formed (printed printing tape T) (step S 12 ). That is, the feed out rollers  22  feed out the printed printing tape T from the printing region. 
     In the case where there is further print data to be printed (step S 14 : yes), the controller  10  repeats the above-described operation (steps S 2  to S 12 ) to carry out printing on the printing tape T. On the other hand, in the case where there in no more print data (step S 14 : no), the controller  10  finishes the present print processing. 
     Effectiveness of the Present Print Processing 
     In the above-described print processing, the controller  10  causes the head unit  40  to move in a way that the total sub-scanning amount 3F (21/720 dpi) in the sub-scanning direction of the head unit  40  is smaller than the effective nozzle width (28/720 dpi) in the sub-scanning direction of a single head  41 , thereby enabling to control the width of the head unit  40  in the sub-scanning direction from increasing. 
     That is, as described above, the larger the total sub-scanning amount of the head unit  40  is, the wider the width of the head unit  40  in the sub-scanning direction becomes (see  FIG. 6 ). Therefore, by making the total sub-scanning amount of the head unit  40  smaller than the effective nozzle width of a single head  41 , overlap printing can be achieved while reducing the total sub-scanning amount of the head unit  40  ( FIG. 8 ,  FIG. 9 ). And as a result, increase in the width of the head unit  40  (increase in the number of heads  41 ) can be controlled even in the case where ink is ejected across the entire width of the printing tape T by each of the passes in overlap printing. 
     Furthermore, deterioration in image quality can be controlled by forming raster line groups with the controller  10  so that, of the raster line groups (the raster lines within the printing region in  FIG. 8  and  FIG. 9 ), the number of raster lines formed by ejecting ink from the nozzles of only a single head  41  is not greater than the number of raster lines formed by ejecting ink from the nozzles of two or more heads  41 . 
     That is, as described above, density irregularities tend to become more apparent (see  FIG. 5 ) with an increase in the number of raster lines formed by the nozzles of only a single head  41  (the head  41 ( 3 ) having a small ejection amount or the head  41 ( 5 ) having a large ejection amount, as described in  FIG. 5 ). Hence, by keeping the number of raster lines formed by the nozzles of only a single head  41  equal or less than the number of raster lines formed by the nozzles of two or more heads  41 , the proportion of raster lines (raster lines causing density irregularities) formed by nozzles of only a single head  41  (which of the ten heads  41  are heads  41  having a small ejection amount or heads  41  having a large ejection amount) can be reduced ( FIG. 8 ,  FIG. 9 ). For this reason, density irregularities can be kept from becoming apparent and, as a result, deterioration in image quality can be curbed. 
     It should be noted that by keeping the total sub-scanning amount 3F smaller than the effective nozzle width of a single head  41 , density irregularities arising from linkages between adjacent heads  41  can be controlled from becoming apparent. That is, since head unit  40  is a component in which ten heads  41  are linked in the sub-scanning direction, it is known that density irregularities may occur when the positional accuracy of the linkages is poor. And in the case where an image is formed by a plurality of passes, when the linkages in pass  1  and the linkages in pass  2  overlap in the sub-scanning direction for example, density irregularities arising from the linkages become apparent. In contrast, by keeping the total sub-scanning amount 3F smaller than the effective nozzle width of a single head  41  as in the present print processing, density irregularities can be kept from becoming apparent owing to the linkages between the heads in passes  1  to  4  being scattered as shown in  FIG. 8  and  FIG. 9 . 
     Consequently, with the above-described print processing, the width of the head unit  40  in the sub-scanning direction can be controlled from increasing and deterioration in image quality can be curbed as well. 
     Furthermore, in the above-described print processing, the controller  10  causes ink to be ejected from all the heads  41  in the four passes of passes  1  to  4  (corresponding to m number movements). In this way, the total sub-scanning amount by the head unit  40  can be reduced while achieving overlap printing with a minimum number of heads  41 . 
     Further still, in the above-described print processing, the controller  10  controls the three movements in the sub-scanning direction by the head unit  40  (corresponding to n times of movement) so that each amount of movement are the same. Therefore, the dot rows are formed cyclically and the position where the density irregularities occur are made to be scattered systematically, thereby enabling to curb density irregularities from becoming apparent in an effective manner. 
     Second Embodiment 
       FIG. 10  shows a head unit  40  according to a second embodiment. Unlike the head unit  40  according to the first embodiment shown in  FIG. 3 , this head unit  40  does not have overlapping nozzles. It should be noted that other than this, the configuration of the second embodiment is equivalent to that of the first embodiment and therefore description thereof is omitted. 
     In the second embodiment too, the controller  10  (1) causes the drive unit  30  to move the head unit  40  so that the total movement amount of the head unit  40  in the sub-scanning direction during printing is less than the effective nozzle width in the sub-scanning direction of a single head  41 , and (2) forms raster line groups so that, of the raster line groups, the number of raster lines formed by ejecting ink from the nozzles of only a single head  41  is not greater than the number of raster lines formed by ejecting ink from the nozzles of two or more heads  41 . 
       FIG. 11  is a diagram for describing overlap printing according to the second embodiment. As in  FIG. 8 , only nozzle row C is shown in  FIG. 11  and the number of nozzles in each head  41  is also 14. And dots formed by the nozzles of the head  41 ( 1 ) are shown as white dots (∘), the dots formed by the nozzles of the head  41 ( 2 ) are shown as black dots (●), the dots formed by the nozzles of the head  41 ( 3 ) are shown as white triangles (Δ), and the dots formed by the nozzles of the head  41 ( 4 ) are shown as black triangles (▴). And the effective nozzles of each of the heads  41  shown in  FIG. 11  are the 14 nozzles being nozzle # 1  to nozzle # 14  respectively, and the effective nozzle width in each head  41  is equivalent being 28/720 dpi. 
     As shown in  FIG. 11 , a one time sub-scanning amount F of the head unit  40  is 7/720 dpi, which is the same as that in the first embodiment ( FIG. 8 ), and the total sub-scanning amount 3F is 21/720 dpi. Thus, the total sub-scanning amount 3F (21/720 dpi) is smaller than the effective nozzle width (28/720 dpi). Therefore, the width of the head unit  40  in the sub-scanning direction can be controlled from increasing in the same manner as that in the first embodiment. 
     It should be noted that, in  FIG. 11  the number of raster lines formed by ejecting ink from the nozzles of only a single head  41  is equivalent to the number of raster lines formed by ejecting ink from the nozzles of two or more heads  41 . This is because there are no overlapping nozzles in the second embodiment, which is different from  FIG. 8 . 
     First, attention is given to the 28 dot rows in line  22  to line  49 . The ten dot rows of line  22  to line  28 , line  30 , line  32 , and line  34  are formed by the nozzles of only the head  41 ( 1 ), and the four dot rows of line  43 , line  45 , line  47 , and line  49  are formed by the nozzles of only the head  41 ( 2 ). That is, there are 14 dot rows formed by the nozzles of only a single head  41 . On the other hand, the dot rows (14 dot rows) of the 28 dot rows other than those mentioned above are formed by nozzles of both the head  41 ( 1 ) and the head  41 ( 2 ). Similarly, in the 28 dot rows of lines  50  to  77 , the number of dot rows formed by only a single head  41  is 14 and the number of dot rows formed by two heads  41  is 14. 
     In this way, by forming raster line groups so that the number of raster lines formed by ejecting ink from the nozzles of only a single head  41  is equal or less than the number of raster lines formed by ejecting ink from the nozzles of two or more heads  41 , the proportion of raster lines in the raster line groups formed by nozzles of only a single head  41  (which are heads  41  having a small ejection amount or heads  41  having a large ejection amount, as described in  FIG. 5 ) can be reduced in a same manner as the first embodiment. For this reason, even in a case where there are raster lines formed by nozzles of only a single head  41 , the number of raster lines causing density irregularities can be reduced, and as a result, density irregularities can be curbed from becoming apparent. 
     Third Embodiment 
     Next, description is given regarding overlap printing according to a third embodiment.  FIG. 12  is a diagram for describing overlap printing according to the third embodiment. 
     In the third embodiment too, a single raster line is completed by four passes (overlap printing) as shown in  FIG. 12 . That is, ink is ejected from the heads during the four passes to complete a single raster line. Specifically, dots of the first row and the fifth row are formed by pass  1 , dots of the second row and the sixth row are formed by pass  2 , dots of the third row and the sixth row are formed by pass  3 , and dots of the fourth row and the eighth row are formed by pass  4 . It should be noted that in  FIG. 12 , dots up to the eighth row are shown, but actually dots are formed in more rows. 
     It should be noted that the head unit  40  in the present embodiment is equivalent to the head unit  40  of the first embodiment ( FIG. 3 ). That is, there are overlapping nozzles in two adjacent heads  41 . And the nozzle pitch between the nozzles is 1/360 dpi. 
     Incidentally, in contrast to the spacing of the raster lines in the first and second embodiments of 1/720 dpi (see  FIG. 8  and  FIG. 11 ), the spacing of the raster lines shown in  FIG. 12  is 2/720 dpi (=1/360 dpi), (namely, the same as the nozzle pitch). Thus, unlike the first and second embodiments, in the third embodiment, interlaced printing is not carried out. Here, as shown in  FIG. 8  and  FIG. 11 , interlaced printing refers to a print mode in which there is a non-formed raster line between a pair of raster lines formed by a single pass. 
     Furthermore, as in  FIG. 8 , only nozzle row C is shown and the number of nozzles in each head  41  is also 16 in  FIG. 12 . It should be noted that for the sake of convenience, description is given here assuming that the head unit  40  has three heads, the head  41 ( 1 ) to head  41 ( 3 ). And dots formed by the nozzles of head  41 ( 1 ) are shown as white dots (∘), the dots formed by the nozzles of head  41 ( 2 ) are shown as black dots (●), and the dots formed by the nozzles of head  41 ( 3 ) are shown as white triangles (Δ). 
     Furthermore, similar to the first embodiment, the effective nozzles of the heads  41  shown in  FIG. 12  are as follows. The effective nozzles of the head  41 ( 1 ) are the 15 nozzles of nozzle # 1  to nozzle # 15 , and the effective nozzle width thereof is 30/720 dpi. The effective nozzles of the head  41 ( 2 ) are the 14 nozzles of nozzle # 2  to nozzle # 15 , and the effective nozzle width thereof is 28/720 dpi. The effective nozzles of the head  41 ( 3 ) are the 15 nozzles of nozzle # 2  to nozzle # 16 . The effective nozzle width thereof is 30/720 dpi. 
     Furthermore, in the third embodiment, a one time sub-scanning amount F of the head unit  40  is 8/720 dpi, and the total sub-scanning amount 3F of the four passes is 24/720 dpi. And in the third embodiment too, the total sub-scanning amount 3F (24/720 dpi) is set to be smaller than the effective nozzle width that is smaller (28/720 dpi) of the two effective nozzle widths. For this reason, an increase in the width of the head unit  40  in the sub-scanning direction can be controlled in a same manner as that in the first embodiment. 
     Here, discussion will follow on which nozzles of the heads  41  are used to form the raster lines of the printing region. Here, the raster lines of the printing region in the present embodiment are indicated as the raster lines from line R 1  to R 30 , as shown in  FIG. 12 . 
     First, the raster lines of lines R 1  to R 3  are formed only by the nozzles of the head  41 ( 1 ). The raster lines of lines R 4  to R 15  are formed by the nozzles of the head  41 ( 1 ) and head  41 ( 2 ). The raster lines of lines R 16  and R 17  are formed only by the nozzles of the head  41 ( 2 ). The raster lines of lines R 18  to R 29  are formed by the nozzles of the head  41 ( 2 ) and head  41 ( 3 ). And the raster line of line R 30  is formed only by the nozzles of the head  41 ( 3 ). 
     Further still, taking a look at the range of the aforementioned effective nozzle width (28/720 dpi) (here description is given using the raster lines of lines R 4  to R 27  as an example), the number of raster lines formed by ejecting ink from the nozzles of only a single head  41  is the 12 raster lines from line R 4  to R 15 , and the number of raster lines formed by ejecting ink from nozzles of two heads  41  is the two raster lines of lines R 16  and R 17 . 
     In this way, the number of raster lines formed by ejecting ink from the nozzles of only a single head  41  is less than the number of raster lines formed by ejecting ink from the nozzles of two or more heads  41 . In this way, in a manner similar to the first embodiment, even in a case where there is a raster line formed by nozzles of only a single head  41 , the number of raster lines causing density irregularities can be reduced, and as a result, density irregularities can be curbed from becoming apparent. 
     It should be noted that in the foregoing description, each sub-scanning amount F of the four passes was set to be the same at 8/720 dpi, but the sub-scanning amount may be varied each time. Furthermore, in the foregoing description, dots of the first row (fifth row) are formed by pass  1 , dots of the second row (sixth row) are formed by pass  2 , dots of the third row (seventh row) are formed by pass  3 , and dots of the fourth row (eighth row) are formed in the pass  4 . But there is no limitation to this as long as the dots of the adjacent rows are formed by different passes. 
     Further still, in the foregoing description, a single raster line is formed by four passes. But there is no limitation to this as long as the single raster line is formed by at least two passes (two or more integer number of passes), for example a single raster line may be formed by three passes (the same is true for the first embodiment and the second embodiment). 
     Other Embodiments 
     A liquid ejecting apparatus or the like according to the invention has been described above, based on the embodiments, but the foregoing embodiments of the invention are for the purpose of elucidating the invention and are not to be interpreted as limiting the invention. The invention can of course be altered and improved without departing from the gist thereof and equivalents are intended to be embraced therein. 
     Furthermore, in the foregoing embodiments, the liquid ejecting apparatus was realized in an inkjet printer, but there is no limitation to this, and it can also be realized in a liquid ejecting apparatus that ejects (discharges) different liquids other than ink (for example, liquid substances in which particles of functional materials are dispersed, and fluid substances such as gels). To be specific, a liquid ejecting apparatus that ejects a liquid substance containing a dispersed or dissolved material such as an electrode material or coloring material or the like used in manufacturing or the like of liquid crystal displays, color filters, EL (electroluminescence) displays, and surface-emitting optical displays, a liquid ejecting apparatus that ejects a bioorganic substance used in manufacturing biochips, and a liquid ejecting apparatus that ejects a liquid used as a precision pipette for a specimen, for example, can be used. Further still, a liquid ejecting apparatus that performs pinpoint ejection of a lubricant to precision machinery such as watches and cameras and the like, a liquid ejecting apparatus that ejects a transparent resin liquid such as an ultraviolet curing resin or the like onto a substrate in order to form a minute hemispherical lens (optical lens) or the like used in optical communications devices or the like, a liquid ejecting apparatus that ejects an etching liquid such as an acid or an alkali in order to perform etching on a substrate or the like, and a fluid ejecting apparatus that ejects a gel can be used. The invention can be applied to an ejecting apparatus of any type among these. 
     Furthermore, in the foregoing embodiments, the raster lines were formed by moving the head unit  40  four times in the main scanning direction and three times in the sub-scanning direction while the printing tape T was kept stationary ( FIG. 8  and  FIG. 9 ), but there is no limitation to this. For example, the raster lines may be formed by moving the head unit  41  only in the main scanning direction and moving the printing tape T in the sub-scanning direction or the raster lines may be formed by moving the printing tape T in the main scanning direction and the sub-scanning direction while the head unit  41  stays still. That is, raster lines may be formed by moving the head unit  40  relative to the printing tape T in the main scanning direction and the sub-scanning direction. 
     Furthermore, in the foregoing embodiments, overlapping nozzles of adjacent heads  41  (for example, nozzle # 15  of the head  41 ( 3 ) and nozzle # 1  of the head  41 ( 4 )) ejected ink alternately to form a single raster line (that is, ink is ejected from both of the two nozzles that overlap), but there is no limitation to this. 
     For example, ink may be ejected from only one of the overlapping nozzles of the adjacent heads  41 . Specifically, in regard to the head  41 ( 3 ), of the overlapping nozzles (nozzles # 1 , # 2 , # 15 , and # 16 ), there may be a case where ink is ejected from the nozzles # 1  and # 2  and ink is not ejected from the nozzles # 15  and # 16 . Similarly, in regard to the head  41 ( 4 ) too, of the overlapping nozzles (nozzles # 1 , # 2 , # 15 , and # 16 ), there may be a case where ink is ejected from the nozzles # 1  and # 2  and ink is not ejected from the nozzles # 15  and # 16 . In this case, the number of effective nozzles (14 nozzles) in each of the heads  41  is the same. 
     Furthermore, in the above-described case, usage conditions are the same for nozzles at linkages between the adjacent heads  41  (mainly the overlapping nozzles) and therefore the raster lines corresponding to the linkage areas of the heads  41  are also formed equally spaced (that is, formed regularly), thereby controlling density irregularities arising at linkages.