An imaging apparatus includes a print engine having a printhead that generates ink drops, and a printhead carrier that carries the printhead in a first direction and in a second direction opposite the first direction. A controller determines an initial print direction based on ink drop information obtained by printing patches in the first direction and in the second direction, wherein the ink drop information includes a respective chromatic value of each of the patches. The controller is operatively coupled to the print engine to print an image based on the initial print direction.

In an embodiment of the present invention, even though there is a print shift due to a gap between a nozzle in an upstream side and a nozzle in a downstream side of a printhead, a printing apparatus capable of precisely adjusting a slant of a printhead with respect to a conveyance direction in a nozzle surface of the printhead is provided. According to the embodiment, two adjustment patterns are printed at two different carriage speeds, respectively, and a print shift due to a slant of the nozzle surface of the printhead with respect to a conveyance direction of a print medium is adjusted based on these two print results.

A liquid discharging apparatus includes a head unit arranged in a main scanning direction includes head arrays each having nozzles discharging liquid are arranged in a sub scanning direction, a moving unit that alternately performs a main scanning operation while discharging the liquid and a sub scanning operation causing the head unit or the recording medium to move in the sub scanning direction without discharging the liquid, and a gradation setting unit that sets a first pattern setting a gradation to increase a center printing ratio at a center and decrease an end printing ratio at both ends for a whole area of the head array in the sub scanning direction and a second pattern in which a gradation is set so as to increase the printing ratio setting a gradation to increase the center printing ratio and decrease the end printing ratio for an arbitrary number of the heads.

A printing apparatus is provided with a print head having at least a first type nozzles and a second type nozzles positioned on a first direction side with respect to the first type of nozzles and a controller. The controller is configured to perform a first ejection control with performing a main scanning. The first ejection control includes a control of performing flushing when the print head is in a first state where the second type of nozzles are located at a position corresponding to an ink receiver and the first type of nozzles are located at a position corresponding to the medium range, and a control of causing the first type nozzles to eject the ink toward the printing medium during a period where the ink is ejected from the second type of nozzles toward the ink receiver when the print head is in the first state.

White-balance is improved when printing on colored media, while minimizing the time and use of costly materials required by present approaches. In an embodiment, the typical solid white fill or background layer is altered by including in the white layer one or more of the other colors already available in the printer to shade this layer. Thus, a small amount of cyan, for example, helps balance a pink-ish (red) media; yellow is used for blue media; and magenta is used for green media; as well as combinations thereof. A combination of transparent process inks and opaque white helps to maintain brightness (luminosity).

An ultraviolet (UV) inkjet printing method providing a stacked printing edge with a smooth effect is disclosed. After an inkjet head is controlled to print an image X on a substrate, a distance between the inkjet head and a surface of the substrate is kept unchanged, and the inkjet head is again controlled to print bi-directionally for at least once on the image X. After completing the above steps, the inkjet head is further controlled to print an image X on the image X on the substrate, wherein the image X consists of pixels expanded from the image X, such that the image X completely covers the image X, forming a smooth arc surface at peripheral edges of the image X.

There is provided a printing apparatus including: a conveyer; a platen configured to support the a medium; a head; a carriage; a sensor configured to detect the medium supported by the platen; a liquid receiver; and a controller. The controller is configured to execute flushing, in which liquid is discharged from nozzles to the liquid receiver, after executing printing in a certain printing pass, which is executed before a last printing pass for printing on a certain medium and during which the carriage moves in a first direction. The controller is configured not to execute the flushing at timing between the last printing pass for the printing on the certain medium and a first printing pass for printing on the next medium.

A method for determining a working gap includes a first recording step for ejecting ink from a recording head onto a first recording medium to record a test pattern, a first imaging step for capturing the test pattern recorded on the first recording medium in each of a state where a distance between the recording head and the first recording medium is a first distance, and a state where a distance between the recording head and the first recording medium is a second distance, a function calculating step, a second recording step for recording the test pattern on a second recording medium, a second imaging step for capturing the test pattern recorded on the second recording medium, and a working gap determining step for determining, based on the number of pixels of the captured test pattern and a function, a distance between the recording head and the second recording medium.

Ink containing metal particles is ejected from a print head, in accordance with a plurality of print ratios corresponding to a plurality of scans of the print head relative to a unit region of a print medium. At least one of the plurality of print ratios is set as a high print ratio which is higher than others. A height of the high print ratio, in a case where a scan corresponding to the high print ratio is a Lth (L: integral number) scan in the plurality of print scans, is higher than a height of the high print ratio, in a case where a scan corresponding to the high print ratio is a Nth (N>L; N: integral number) scan in the plurality of print scans.

A liquid discharging apparatus includes a head unit arranged in a main scanning direction includes head arrays each having nozzles discharging liquid are arranged in a sub scanning direction, a moving unit that alternately performs a main scanning operation while discharging the liquid and a sub scanning operation causing the head unit or the recording medium to move in the sub scanning direction without discharging the liquid, and a gradation setting unit that sets a first pattern setting a gradation to increase a center printing ratio at a center and decrease an end printing ratio at both ends for a whole area of the head array in the sub scanning direction and a second pattern in which a gradation is set so as to increase the printing ratio setting a gradation to increase the center printing ratio and decrease the end printing ratio for an arbitrary number of the heads.