A method for compensating for position-dependent density fluctuations of print nozzles in any inkjet printer by a computer. The computer produces, for all substrates used, compensation profiles for the position-dependent density fluctuations over all print heads of the inkjet printer and applies the compensation profiles to compensate for the position-dependent density fluctuations in the inkjet printer. The computer determines in each case printer-specific or print head-specific influences and print substrate-specific influence factors with a generic reference print substrate, from which a reference compensation profile is produced which depends on the surface coverage and location. From this the computer produces a total compensation profile which is used to compensate for position-dependent density fluctuations.

A networked product imaging system includes devices that provide the production of imaged goods. Customer requirements are provided to a central computing device (CCD) that has two-way communication with a plurality of geographically separated image forming devices. The central computing device determines specifications for forming the image on the blank product in accordance with the customer's order. The central computing device selects an image forming device from the plurality of geographically separated image forming devices for fulfilling the order, based upon factors that include the specification of the image forming device available, the image forming inventory and the blank product inventory available at the geographic location of the image forming device. The selected image forming device forms the image on the blank product at the remote location.

Density unevenness accompanying a variation in an ejection characteristic of each nozzle is reduced without worsening granularity of an image. To this end, an image processing apparatus generates first corrected data by correcting image data by using a first correction table common to the plurality of nozzles. Further, the image processing apparatus generates second corrected data by correcting the image data by using a second correction table for each of the plurality of nozzles. Furthermore, the image processing apparatus generates first quantized data by quantizing the first corrected data and generates second quantized data by quantizing the second corrected data. After that, the image processing apparatus generates N-valued print data based on the first quantized data and the second quantized data.

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.

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.

An ink-jet printing device according to the present invention includes at least one nozzle configured to discharge an ink droplet onto a recording medium conveyed in a conveyance direction, and a control unit to control flushing operation of the nozzle. Candidate regions are disposed at a plurality of places separated from each other in a conveyance direction of a cut sheet. The control unit controls the nozzle to perform the flushing operation in the candidate regions at a plurality of places in the conveyance direction of the cut sheet. With this configuration, the ink jet printing device can efficiently perform the flushing operation on a recording medium with reduced restriction on imposition.

A printing control apparatus is configured to control printing using a print head provided with, on different head chips, a plurality of nozzle groups including a first nozzle group and a second nozzle group configured to eject ink of a same color, with at least a portion of a formation range of each of the nozzle groups overlapping each other. The different head chips is disposed in a direction that crosses an alignment direction of nozzles. The printing control apparatus includes a halftone processing unit configured to generate halftone data specifying a presence or absence of dots for each pixel serving as data to drive the nozzle groups based on image data. The halftone processing unit is configured to generate first halftone data to drive the first nozzle group and second halftone data to drive the second nozzle group in an uncorrelated manner.

In a print head, a plurality of ejection ports for ejecting metallic ink, including a solvent and particles for imparting a metallic gloss, are arranged in a predetermined direction. A plurality of printing scans are performed to the same area of the print medium to print an image on the print medium. In the printing scan, the metallic ink being ejected from the print head to a print medium while moving the print head in a scanning direction intersecting the predetermined direction. At least one of the plurality of printing scans is set as a first scan having a higher print ratio than the other printing scans.

An object of the present disclosure is to reduce density unevenness and streaks of an image that is printed in a case where it is not possible to implement sufficient correction only by the correction for a defective nozzle. One embodiment of the present invention is an image processing apparatus that performs processing for an input image for an image forming apparatus performing printing on a printing medium by using a print head in which a plurality of printing elements is arrayed, the image processing apparatus including: a storage unit configured to store density characteristic information indicating an output density for each tone for each of the printing elements; a target value acquisition unit configured to acquire a target characteristic indicating a target value for each tone; and a first correction unit configured to correct the input image based on the density characteristic information and the target value.

A printing control apparatus configured to control a printing apparatus including an acquisition unit configured to acquire discharge characteristic information including a characteristic of discharging ink for each of nozzles, a correction amount calculation unit configured to calculate a correction amount for correcting an amount of the ink discharged onto a printing medium based on the discharge characteristic information for each of printing modes having mutually different relative movement amounts of the sub scanning movements, and a printing data generation unit configured to generate printing data for executing printing in accordance with the printing mode based on the correction amount.