A method of operating a selective deposition-based additive manufacturing system capable of building a three-dimensional (3D) part includes developing a first layer using at least one electrostatographic engine, conveying the first layer from the at least one EP engine to a transfusion assembly, determining an anticipated transfusion overlay error for the first layer, determining whether the anticipated transfusion overlay error exceeds an overlay error specification, discarding the first layer after determining that the anticipated transfusion overlay error exceeds the overlay error specification, developing a successive layer using the at least one electrostatographic engine, conveying the successive layer from the at least one electrostatographic engine to the transfusion assembly, and transfusing the successive layer on a part build surface using the transfusion assembly to build the 3D part in a layer-by-layer manner on a part build platform.

An image forming apparatus includes an image forming device to form an image on a sheet, and an image reading device to read an image from the sheet. A processing unit causes the image forming device to perform a predetermined image formation to form a first image for position correction of an output image and a second image for tone correction. A value of the position correction is obtained, based on a read image, and a tone correction value is obtained based on a read image from a second image sheet.

Example implementations relate to a system comprising a memory resource to store instructions executable by a processing resource. In some examples, the processing resource can execute instructions to perform a calibration procedure for a printing device including a printing component. Responsive to the calibration procedure, the processing resource can execute instructions to deliver a print material arranged in a compound shape to a calibration image on the printing component included in the printing device. Responsive to performing the delivery, the processing resource can execute instructions to measure a print material density of the print material on the calibration image of the compound shape during the calibration procedure via a density sensor included in the printing device. Furthermore, the processing resource can execute instructions to detect an abnormality in the print material density via signal analysis instructions and provide a notification regarding the print material density abnormality.

According to examples, an apparatus may include a processor and a memory on which are stored machine-readable instructions that when executed by the processor, may cause the processor to print a first indicia at a first region on a first side of a print medium. The instructions may also cause the processor to print a second indicia at a second region on the first side of the print medium, in which the second region may be spaced a prescribed distance from the first region along a first edge of the print medium. In some examples, a relative position of the first indicia to the second indicia may correlate to a skew correction value for the first edge of the print medium.

An image forming apparatus includes an image bearing member, a transfer belt, a secondary transfer member, a voltage source, a current detecting portion, and a controller. The controller is operable in a first mode in which when a recording material is absent in a secondary transfer portion, a current flowing through the secondary transfer member under application of a first test voltage is detected by the current detecting portion and then information on a current-voltage characteristic of the secondary transfer member is acquired, and in a second mode in which a predetermined test image is transferred from the transfer belt onto the recording material under application of second test voltages and then a test chart for adjusting a transfer voltage set during transfer is outputted. On the basis of the information, the controller changes an interval of the second test voltages applied in the operation in the second mode.

An image forming device includes an image forming unit, a fuser, a memory, and a control circuit. The image forming unit forms an image on a recording medium with a decolorable toner based on image data. The decolorable toner decolorizes at a first temperature and does not decolorize at a second temperature that is lower than the first temperature. The fuser has a plurality of regions extending in a direction orthogonal to a direction of conveyance of the recording medium. The fuser generates heat in each of the plurality of regions to fuse the image onto the recording medium. The memory stores a correspondence between the plurality of regions and positions of a plurality of areas positioned along a main scanning direction in the image data. The control circuit changes the correspondence based on a degree of color development or decolorization of the image.

An image forming apparatus is provided. The image forming apparatus includes an image forming part to form a pattern including at least one white dot line and at least one black dot line on an image forming medium using a photoconductive drum. A registration sensor is to sense an amount of light reflected from the image forming medium. A processor is to determine a state of the photoconductive drum based on the amount of sensed light in the pattern.

It is an object of the present invention to diagnose image quality of a print image without using an open communication network and output the print image, a diagnosis result of image quality, and information of the print parameters while avoiding disclosure of confidential information to users. A test print control portion causes a print device to execute a test print process to form a test image on a sheet. An image quality diagnosis portion diagnoses image quality of the test image included in the image read by an image reading device. A code image generating portion generates a code image that represents information of print parameters adopted in the test print process. An output control portion causes an output device to output a diagnosis image that includes an image representing a diagnosis result of image quality of the test image, and the code image.

A digital printing system having a linear printhead includes corrections for in-track position errors. A data processing system implements a method for determining an in-track position function which includes printing a test target including a plurality of alignment marks, automatically analyzing a captured image of the printed test target to determine a measured in-track position for each of the alignment marks, comparing the measured in-track positions for the alignment marks to reference in-track positions to determine measured in-track position errors, and determining an in-track position correction function responsive to the measured in-track position errors. The in-track position correction function specifies in-track position corrections to be applied as a function of cross-track position. A corrected digital image is determined by resampling an input digital image responsive to the in-track position correction function.

An image forming apparatus, which is configured to execute calibration for controlling an image forming condition, includes a detection unit configured to detect an environmental state in which the image forming apparatus is installed; a prediction unit configured to predict, based on a plurality of detection results detected by the detection unit in a first period, a change in the environmental state in a second period after the first period; and a setting unit configured to set a timing of executing the calibration in the second period based on the change in the environmental state predicted by the prediction unit.