A measurement method of nozzle overlapping width, in a main scanning direction intersecting a conveying direction of a recording medium, in an inkjet recording apparatus including a plurality of heads each having a plurality of nozzles that eject ink, includes a first step (S120), a second step (S130), and a third step (S140). The first step (S120) includes forming an image for measurement on the recording medium, using image data including combination patterns of droplet sizes, different with respect to each of blocks extending along the main scanning direction. The second step (S130) includes selecting the block having uniform density along the main scanning direction, in the image for measurement. The third step (S140) includes determining the nozzle overlapping width using a droplet size ratio adopted to form the image for measurement, on a basis of a position of the selected block.

A printing system is disclosed. The printing system includes at least one physical memory device to store drop size logic and one or more processors coupled with the at least one physical memory device to execute the drop size logic to generate drop size data associated with a printing system based on ink deposition data for a print medium and ink drop count data.

A printing system is disclosed. The printing system includes at least one physical memory device to store ink model estimation logic and one or more processors coupled with the at least one physical memory device to execute the ink model estimation logic to generate color space ink model parameter data for a print system based on an ink deposition data and color space measurement data for one of a plurality of inks for the print system.

In a printing apparatus, in a first mode a head ejects a first type of liquid onto a printing medium and an energy applying device applies energy to the first type of liquid to form a background, and subsequently the head ejects a second type of liquid onto the background and the energy applying device applies energy to the second type of liquid on the background so that an image is formed on the background. In a second mode the head ejects the second type of liquid onto the printing medium without forming a background, and the energy applying device applies energy to the second type of liquid. The controller performs setting a quantity of the second type of liquid to be used in the first mode, to be greater than a quantity of the second type of liquid to be used in the second mode.

An liquid ejecting device includes an inkjet head, a scanning driving unit, a storage, an influence degree storage that stores influence degree information, and a control unit. The influence degree information indicates a magnitude of an influence generated at one ejection position by forming dots of the liquid at each of a plurality of ejection positions. The control unit causes other nozzles to eject a larger amount of liquid than at a normal time with respect to at least a part of the ejection position where the liquid is ejected by the other nozzles in the vicinity of an abnormal nozzle at the time of main scan, and selects an ejection position to which the other nozzle ejects a larger amount of the liquid than the normal time based on the influence degree information.

A liquid discharge apparatus includes a liquid discharge head, a scanning device, a storage device, and circuitry. The liquid discharge head discharges liquid from a plurality of nozzles onto a recording medium. The scanning device moves at least one of the recording medium and the liquid discharge head to perform scanning. The storage device stores a plurality of mask patterns to change a discharge amount and a discharge size of the liquid from the liquid discharge head. The circuitry acquires image data, creates dot data from the image data, and determines the discharge size of the liquid to be discharged from the liquid discharge head, based on the dot data and one of the plurality of mask patterns.

A method for printing sheet-type substrates to prevent streaks during the ink-jet paint coating of substrates, includes moving a substrate in a feed direction past an application device by means of a conveying device, applying with the application device, during the movement of the substrate, a fluid application material drop by drop to the surface of the substrate in a pattern with a pre-defined contour, in particular leaving out regions, through a plurality of ink-jet nozzles arranged in a row transversely to the feed direction, in response to computer-controlled switching signals, and during the application of the pattern and during the movement of the substrate, moving the ink-jet nozzles back and forth transversely to the feed direction, preferably in the longitudinal direction of the arranged row of ink-jet nozzles, such that the paths travelled by the nozzles over the substrate by the overlap of the movement back and forth with the movement in the feed direction have direction components running perpendicular to the feed direction.

A printing apparatus operating as a liquid ejecting device is provided and includes: an inkjet head including a plurality of nozzles, a scanning driver that causes the inkjet head to perform a main scan, and a controller. When an abnormal nozzle is present, the controller causes another nozzle in the vicinity of the abnormal nozzle to eject the liquid of a larger amount than that in a normal time to a part of an ejecting position where the liquid can be ejected by the other nozzle based on a mask prepared in advance, so that an amount of liquid to be ejected at the time of the main scanning direction by the other nozzle becomes larger than that in the normal time. The mask is data specifying the ejecting position to increase an ejection amount of the liquid and an ejection amount to be increased at the ejecting position.

A printing system is provided and includes an image processing portion that generates a generated image by image processing, and a printing portion that performs printing on a medium based on the generated image. The image processing portion generates the generated image by performing a quantization processing that performs quantization by comparing the pixel value of each pixel in the input image with a threshold, and in the quantization processing, calculates a dot influence value indicating to what extent a position corresponding to a selected pixel is covered by the ink dots formed at the position set on the medium in correspondence with the peripheral pixels of the selected pixel, performs adjustment of reflecting the dot influence value on at least one of the pixel value of the selected pixel or the threshold, and compares the pixel value and the threshold based on a value after adjustment.

An image processing apparatus generates dot data for printing an image on a printing medium by using dots of different sizes formed by a plurality of nozzles ejecting ink. The image processing apparatus includes a first acquisition unit that acquires dot data specifying printing or non-printing of each of the dots of a plurality of sizes for each pixel, a specification unit that specifies a dot having a strong possibility of being pulled by a dot having landed earlier on the printing medium of dots in the dot data, and a correction unit that corrects a dot specified by the specification unit in the dot data. The image processing apparatus can output an image whose banding is unlikely to be recognized by suppressing image defect due to a change of dots accompanying liquid droplet interference.