Print data is organized over rows and columns. The columns of each row are selectively assigned to calibration tables respectively corresponding to printheads of a pagewide array in accordance with a substrate advancement skew relative to the pagewide array. The calibration tables are applied to the columns of each row respectively assigned to the calibration tables. The columns of each row to which the calibration tables have been applied are printed using the printheads respectively corresponding to the calibration tables.

An inkjet printing apparatus is configured to print the image in N (N is an integer of four or more) print scanning operations of a print head for a unit region of the print medium by using N mask patterns used in the N print scanning operations. The inkjet printing apparatus includes: an obtaining unit configured to obtain defective nozzle information specifying a defective nozzle; and a correction unit configured to divide the N mask patterns into mask groups each corresponding to two or more print scanning operations and correct the mask patterns based on the defective nozzle information in each of the divided mask groups.

A printer includes a controller to exercise control so as to print a print layer on or over a medium. The print layer includes a first print region including first protrusions, and a second print region including second protrusions. Any one or more of a size, a height, a planar shape, an arrangement interval, and an arrangement direction of the first protrusions is/are different from a corresponding one or more of a size, a height, a planar shape, an arrangement interval, and an arrangement direction of the second protrusions. An extracted area of about 3 cm by about 3 cm is extracted from any location in the print layer. The first and second print regions are in the extracted area. At least either a number of first print regions or a number of second print regions in the extracted area is more than one.

Examples relate to computer-implemented methods for a printing system comprising a printhead, and to printing systems. A method for a printing system comprises retrieving a stored first offset applied to the printhead to align the printhead, the first offset determined based on a first user input signal; and further aligning the printhead according to a further offset determined based on a further user input signal, the further offset indicating a difference from the first offset.

An object is to enable highly accurate density unevenness correction while suppressing a reduction in productivity of printing accompanying correction value calculation for density unevenness correction. In the image processing apparatus, density correction information that specifies an output tone value for implementing a target density for an input tone value for each nozzle and which does not include the influence by a non-ejectable nozzle that cannot eject ink normally is acquired. In a case where a non-ejectable nozzle is detected during printing processing, output tone values corresponding to the detected non-ejectable nozzle and peripheral nozzles thereof among output tone values specified in the density correction information are changed.

Disclosed is a printing device including at least one processor and a print head. The processor detects a nail region based on an image obtained by photographing a finger or a toe, sets at least a part of the detected nail region as a preceding print setting region, detects a region on which the preceding print is printed as a succeeding print region based on an image obtained by photographing the finger or the toe on which the preceding print is printed, sets a succeeding print region reference point corresponding to the succeeding print region, or sets a preceding print setting region reference point corresponding to the preceding print setting region and the succeeding print region reference point, and causes the print head to print a succeeding print on the nail region based on information on the preceding print setting region and a reference point that is set.

In image forming apparatus, a recording head is configured to eject ink corresponding to an image to be printed, using arranged nozzles. A control unit is configured to determine nozzles corresponding to the image to be printed, correspondingly to a position of a print sheet, and cause the recording head to eject ink from the nozzles. A correction processing unit is configured to perform a correction process corresponding to each of the plural ink ejection malfunction positions in the image. A head cleaning processing unit is configured to perform head cleaning for the recording head. Further, if the number of the detected ink ejection malfunction positions exceeds a predetermined upperlimit value when using a predetermined ink droplet size, the correction processing unit causes the head cleaning processing unit to perform head cleaning for the recording head and thereby decreases the number of the ink ejection malfunction positions.

Provided is a method for determining print paths to be applied when ink is ejected to a substrate. The method for determining the print paths includes a substrate information receiving step of receiving substrate information of the substrate, a head information receiving step of receiving head information of a head that ejects the ink, and a print path determining step of determining the print paths based on the substrate information and the head information, in which in the print path determining step, the smallest number of print paths satisfying a target printing condition for the substrate may be determined.

An integrated circuit to drive a plurality of fluid actuation devices includes a plurality of first non-volatile memory cells and control logic. Each first non-volatile memory cell stores a customization bit. The control logic configures an operation of the integrated circuit based on the customization bits.

A controller acquires image recording data for recording a plurality of passes; determines a first movement distance of a carriage for recording each of the plurality of passes; determines a non-usage ratio that is a ratio of a number of unused nozzles in a last pass of the plurality of passes to a total number of the plurality of nozzles arranged in a conveyance direction; determines a second movement distance in a particular pass which is recorded before the last pass, the second movement distance being a movement distance of the carriage assuming that the particular pass is recorded without using nozzles of a first ratio smaller than or equal to the non-usage ratio; and in response to determining that the second movement distance is shorter than the first movement distance, performs image recording of the particular pass without using the nozzles of the first ratio.