A print control apparatus that improves operability in readjusting a secondary transfer voltage that has been adjusted. The print control apparatus that communicates with an image forming apparatus. The print control apparatus includes an instruction unit that instructs the image forming apparatus to execute a process that prints a predetermined chart, reads the predetermined chart by the reading device, and sets a secondary transfer voltage, a reception unit that receives an adjustment value obtained by the process from the image forming apparatus, and a display control unit that controls a display unit to display an object that prompts a user to adjust at least the secondary transfer voltage based on reception of the adjustment value obtained by the process by the reception unit.

Examples relate to a method to print a print job. The method comprise comparing an operational parameter of the print job with a reference operational parameter and determining to perform a maintenance task during the print job based on at least a result of comparing the operational parameter with the reference operational parameter. If the maintenance task is to be performed, the method further comprises determining a safety area on a printable medium and performing a maintenance task on a printable medium.

An image processing apparatus includes a processor. The processor is configured to set an image position of a reference image in a transport direction of a recording medium to an arbitrary position on a specific page of the recording medium. The reference image is formed using a first color and serves as a reference for an image position of an image of a second color to be formed after the image of the first color is formed. The processor is also configured to adjust the image position for the second color on an adjacent page, located adjacently upstream of the specific page in the transport direction, by using image information of the reference image formed on the specific page.

In an example there is provided a printing method comprising receiving first and second image data for first and second images to be printed on a substrate, determining first print data for the first image on the basis of the first image data and a white layer to be printed between the first image and second image, to achieve a nominal color profile for the first image; determining second print data for the second image on the basis of the first image data, second image data, the white layer and one or more properties of the substrate to achieve a nominal color profile for the second image; communicating the print data for the first and second images to a printing device to print the first and second images and white layer on the substrate.

A media may comprise an alignment pattern on a surface of the media, the alignment pattern comprising a first set of marks of a first color, and a plurality of reference areas covering at least partially the first set of marks and the reference areas having a plurality of gaps. The reference areas may be a second colour, wherein the second colour is different to the first colour. The reference areas may be formed of an printing fluid such that the first set of marks underneath the reference areas are less detectable than one of the first set of marks in one of the plurality of gaps. The one of the first set of marks that is more detectable indicates a measure of alignment between the first set of marks and the reference areas.

A printing apparatus prints by discharging ink to a transfer member from a first printhead, discharging a transfer accelerator to the ink from a second printhead, and transferring an image formed on the transfer member to a print medium. When inspecting a discharge state of each of plural nozzles provided in each of the first and second printheads, the apparatus controls the second printhead so as to discharge the transfer accelerator from at least one nozzle of the second printhead to a discharge area of the transfer member to which the ink is discharged by the first printhead for inspection of the discharge states of the plural nozzles of the first printhead, while inspecting a discharge state of a nozzle different from the at least one nozzle of the second printhead by discharging the transfer accelerator from the nozzle.

An image forming apparatus includes an image forming device, a reading device, and circuitry. The image forming device discharges ink droplets through nozzles to form an image on a recording medium conveyed in a first direction. The reading device reads the image formed on the recording medium. The circuitry generates a correction chart that includes patches, located in the first direction and representing different densities from each other, and two marks located at different positions from each other in a second direction perpendicular to the first direction. The circuitry locates opposed end portions of the patches in the second direction outside the two marks in the second direction. The circuitry derives correction data, based on read data of an area of the patches existing inside the two marks in the second direction included in read data provided by the reading device reading the correction chart formed on the recording medium.

Method and devices for calibrating optical density reflective color fluids to be deposited on substrate are disclosed. Some methods comprise depositing a quantity of a keying color fluid on a first region of the substrate; applying a voltage level to a reflective color fluid application device; depositing, in response to the voltage level applied, a quantity of reflective color fluid on the first region of the substrate and on a second region of the substrate; performing reflectance measurements of the first region and of the second region; performing optical density calculations as a function of the reflectance measurements; varying the voltage level applied to the reflective color fluid application device in response to said optical density calculation until the optical density calculation is within a calibrated range of optical densities.

An image forming apparatus includes an image forming unit, first and second detectors, and a corrector. The image forming unit includes first and second image forming units disposed downstream of the first unit in a transport direction of a recording medium and causes the first and second units to form predetermined correction images onto the recording medium. The first detector is disposed downstream of the first unit and upstream of the second unit in the transport direction, and detects the correction image formed by the first unit. The second detector is disposed downstream of the second unit in the transport direction and detects the correction image formed by the second unit. The corrector corrects an image position of the second unit in a width direction of the recording medium by using the correction images formed by the first and second units and detected by the first and second detectors.

A printing apparatus for printing on a printing medium transported includes the following elements. A print head including a plurality of print head modules, a printing controller for controlling printing of a testing chart by selecting a reference print head module to provide a reference for recording positions, causing the reference print head module to print a reference chart, and causing one of the print head modules shifted relative to the reference print head module to print a comparison chart, a scanner for acquiring testing image data, an image processor for creating an extract reference chart, creating an extract comparison chart, and creating a composite testing chart by superimposing these charts, and a deviation amount calculator for calculating a deviation amount based on the composite testing chart.