In an image processing apparatus, a processor sets a target printing method for printing a target image to one of a bidirectional printing method and a unidirectional printing method. In a case where the bidirectional printing method is set as the target printing method: the processor executes both a first generation process and a second generation process. The first generation process generates first partial print data by converting a set of partial image data using a first color conversion profile. The second generation process generates second partial print data by converting another set of partial image data using a second color conversion profile. In a case where the unidirectional printing method is set as the target printing method, the processor executes a third generation process generating third partial print data by converting a set of partial image data using a third color conversion profile.

Applying a metallic ink, then applying a chromatic color ink with high dye aggregability, and then applying a chromatic color ink with low dye aggregability improve the color development of the chromatic color ink with low dye aggregability.

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.

An image processing apparatus configured to generate, using a target image data, multiple pieces of partial print data respectively for multiple partial printings such that, in a particular case where the color difference indicated by the evaluation value of the each of the partial images is larger than a particular reference value, a controller causes the image processing apparatus to identify, using the difference information, compensation target pixels including a pixel causing the color difference from among multiple pixels within the particular partial image, perform, using the difference information, a compensating process of converting a color of the compensation target pixel to a color of which color difference is small, and generate the partial print data using the particular partial image data to which the compensating process has been applied.

An image formation device includes a plurality of nozzles, a processor which forms an image on the basis of print data, and a memory which stores computer-readable instructions that, when executed by the processor, perform processes including, performing first ejection control which ejects a first amount of the ink at a timing of one of a forward path and a return path in the main scan direction, when printing is performed by a multi-pass method in which each of pixel arrays is printed by a plurality of main scans and, in each of the plurality of main scans, the ink is ejected onto the same pixel array from the respectively different nozzles, and performing second ejection control configured to eject a second amount of the ink at a timing different from the previous timing of the ejection of the ink, the second amount being smaller than the first amount.

There is provided an image recording apparatus, including: a conveyer; a carriage; a recording head having at least three nozzle rows; and a controller. When a moving direction of the carriage in one of two continuous recording passes is different from that in the other of the two continuous recording passes, the image recording apparatus conveys a recording medium in the conveyance direction so that two recording areas partially overlap with each other. When a line image, which belongs to an overlap area, is recorded, the image recording apparatus executes recording so that the two continuos recording passes complement each other, and forms at least part of dots in the line image in accordance with a landing order different from a landing order used when the image is recorded in a non-overlap area included in the recording areas and different from the overlap area.

A liquid discharging apparatus includes a print head unit including a nozzle array with a plurality of nozzles in a sub-scanning direction, each nozzle being configured to discharge liquid onto a print medium. The liquid discharging apparatus includes a moving unit configured to move the print head unit in a scanning direction perpendicular to the sub-scanning direction with respect to the print medium, while causing discharge of the liquid onto the print medium. The moving unit is configured to move, without discharge of liquid, the print medium or the print head unit in the sub-scanning direction. The liquid discharging apparatus includes a line-pitch setting unit configured to set a line pitch by which the print head unit moves, per scan with respect to the sub-scanning direction.

An ink jet method includes causing a treatment liquid to adhere to a recording medium; a white ink to adhere to the recording medium; and a non-white ink to adhere to the recording medium. The treatment liquid, white ink, and non-white ink are applied by main scans of a recording head and sub-scans of the recording medium that intersect the main scans. The recording head includes a first nozzle group arranged in the sub-scanning direction and discharging the treatment liquid, a second nozzle group arranged in the sub-scanning direction and discharging the white ink, and a third nozzle group arranged in the sub-scanning direction and discharging the non-white ink. The second and third nozzle groups have non-overlapping portions in the main scanning direction, and one or both of the second and third nozzle groups have a portion overlapping the first nozzle group in the main scanning direction.

An ink jet recording method includes a white ink adhesion step of causing a white ink containing a white pigment to adhere to a recording medium by an ink jet method; a non-white ink adhesion step of causing a non-white ink containing a non-white coloring material to adhere to the recording medium by the ink jet method; and a drying step of drying the white ink and the non-white ink adhering to the recording medium in the white ink adhesion step and the non-white ink adhesion step by a blowing type or radiation type drying unit, in which the white ink adhesion step and the non-white ink adhesion step are performed in a state where the recording medium is supported on a support member including a suction hole sucking the recording medium, and are performed by plural times of main scanning in which a recording head discharging the white ink and a recording head discharging the non-white ink discharge each ink while moving in a main scanning direction and plural times of sub-scanning in which the recording medium moves in a sub-scanning direction intersecting the main scanning direction.

A head unit includes heads arranged in a body. Each head includes a nozzle row arranged along a first direction. The heads are arranged along a second direction intersecting with the first direction. Two or more heads that include a nozzle row corresponding to a first color, are provided in each of a first region and a second region. A color corresponding to the nozzle row at an nth position from a first side is the same as a color corresponding to the nozzle row at an nth position from a second side, n being a positive integer, the first side being one side of the body in the second direction and the second side being another side of the body in the second direction.