Provided is an inkjet printing apparatus including: a print head configured to eject a metallic ink containing silver particles; a carriage configured to scan the print head; and a control unit configured to control the print operation so as to print an image on a print medium by causing the print head to eject the metallic ink onto the print medium and thereby form dots on the print medium while causing the carriage to scan the print head a plurality of times over a predetermined region on the print medium, wherein the control unit controls the print operation so as to print the image by causing the print head to eject the metallic ink at the same pixel position on the print medium in two or more printing scans and thereby generate a superimposed dot.

One embodiment of the present invention is a printing apparatus including: a print head having a printing element column in which a plurality of printing elements for ejecting ink from ejection ports is arrayed and performing printing on a printing medium by ejecting ink based on print data; a sensor that detects temperature of the print head; an acquisition unit configured to acquire information indicating a number of dots to be printed by printing elements corresponding to a predetermined area in the printing element column; and a control unit configured to control a printing operation of the print head based on temperature detected by the sensor and the number of dots acquired by the acquisition unit, and the printing apparatus performs printing on the printing medium by ejecting ink from the print head while the print head and the printing medium are moving relatively.

A printing system is disclosed. The printing system includes at least one physical memory device to store halftone calibration logic and one or more processors coupled with the at least one physical memory device to execute the halftone calibration logic determine an uncalibrated deposition distribution for each of a plurality of pel forming elements, determine a calibrated deposition distribution for each of the plurality of pel forming elements and determine calibration values for each of the plurality of pel forming elements.

Broadly speaking, embodiments of the present technique provide apparatus and methods to print an image using masking techniques that control the operation of a droplet deposition head having at least one faulty nozzle. More specifically, an image is analysed to determine a pixel colour density for each pixel of the image. A masking technique is provided which may distribute the droplets (or sub-droplets) that a faulty nozzle is assigned to print among one or more neighbouring, functioning nozzles.

A method for locally adjusting the glossiness of a printed image includes printing an image onto a recording medium in multiple swaths and locally adjusting the ink volume for each swath. A printer for printing an image onto a recording medium includes a control unit configured to perform the method.

When a correction request is received, a printing correction pattern is printed. Thereafter, a screen prompting to scan the printed correction pattern is displayed. When the scan notification screen is displayed, if the scanning request is received, an image is scanned. Next, the driving information is corrected based on a scanned image. When a particular standby condition is satisfied without the scanning request being received, a process of setting non-completion information is performed. When a particular standby release condition is satisfied without the scanning request is received, a screen corresponding to the satisfied standby release condition is displayed at a particular timing. When the correction request is input when a screen different from the scan notification screen is displayed, information regarding necessity determination of the pattern printing process is received. When the pattern printing process is unnecessary, the notification displaying process is performed without performing the pattern printing process.

An image processing apparatus includes at least one memory storing instructions and at least one processor executing the instructions to provide an input unit configured to input image data representing a color of an image, and information identifying high gloss and low gloss areas in the image, a first determination unit configured to determine, based on the image data, a recording amount of a printing material for forming the image on a recording medium, and a second determination unit configured to determine a dot arrangement of the printing material by halftone processing for the recording amount according to the information.

A liquid discharge apparatus includes a liquid discharger, a curing device, a multi-scanning device, and processing circuitry. The multi-scanning device causes the discharger to relatively scan a non-permeable recording medium multiple times in each of two intersecting directions to form an image that includes pixels with different discharge amounts of an active energy ray curable liquid in a region of the medium. The circuitry generates thinned image data for forming the image for each relative scanning in a first direction, using a mask in which pixels allowing image formation are arrayed. The circuitry generates the thinned data such that a spatial frequency of an array of the pixels allowing image formation in the mask for a first discharge amount is uniform in relative scanning in a second direction and the spatial frequency for a second discharge amount decreases toward a downstream side in the relative scanning in the second direction.

In order to prevent streaks during the ink-jet paint coating of substrates, the invention provides a method for printing sheet-type substrates, in which a substrate (3) is moved in a feed direction (4) past an application device (7) by means of a conveying device (5) and during the movement of the substrate the application device (7) applies a fluid application material (9) drop by drop to the surface (30) of the substrate (3) in a pattern (14) with a pre-defined contour (15), in particular leaving out regions (16), through a plurality of ink-jet nozzles (70) arranged in a row transversely to the feed direction, in response to computer-controlled switching signals, wherein during the application of the pattern (14) and during the movement of the substrate (3) the ink-jet nozzles (70) are moved back and forth transversely to the feed direction (4), preferably in the longitudinal direction of the arranged row of ink-jet nozzles (70), such that the paths (72) traveled by the nozzles (70) over the substrate by the overlap of the movement back and forth with the movement in the feed direction (4) have direction components running perpendicular to the feed direction (4).

A printing system is disclosed. The printing system includes at least one physical memory device to store halftone calibration logic and one or more processors coupled with the at least one physical memory device to execute the halftone calibration logic determine an uncalibrated deposition distribution for each of a plurality of pel forming elements, determine a calibrated deposition distribution for each of the plurality of pel forming elements and determine calibration values for each of the plurality of pel forming elements.