A method of using an automated system to position a fabric piece. A pattern is printed onto a fabric piece with fluorescent ink, and detected with a fluorescence-detecting camera, such as a UV camera. The detected pattern is stored in a controller as a pattern signature and compared to a stored target pattern. The results of the comparing step are used to generate control signals for the automated system to move the piece into the position of the target pattern.

A method of using an automated system to position a fabric piece. A pattern is printed onto a fabric piece with fluorescent ink, and detected with a fluorescence-detecting camera, such as a UV camera. The detected pattern is stored in a controller as a pattern signature and compared to a stored target pattern. The results of the comparing step are used to generate control signals for the automated system to move the piece into the position of the target pattern.

Various embodiments of systems and methods facilitate the calibration of a printer. The printer can print a calibration target and cut the calibration target using an inline slitter. The printer can determine a calibration offset based on the position of the cut on the calibration target. The printer can then be calibrated according to gross amounts on the slitter and fine amounts at an ink applicator.

Various embodiments of systems and methods facilitate the calibration of a printer. The printer can print a calibration target and cut the calibration target using an inline slitter. The printer can determine a calibration offset based on the position of the cut on the calibration target. The printer can then be calibrated according to gross amounts on the slitter and fine amounts at an ink applicator.

An information processing device includes a storage portion storing a learned model, a reception portion receiving air pressure information and temperature information at a time of ejecting ink, and a processing portion controlling a pressurization pump based on the received air pressure information and temperature information and the learned model. The learned model is a learned model trained by performing machine learning of a condition of a pressurization force with which a determination that an ejection failure does not occur is made, based on a data set in which the air pressure information in a usage environment of a printing apparatus including a printing head, the temperature information in the usage environment, and pressurization force information about the pressurization pump supplying the ink to the printing head are associated.

A printing device includes: a casing having a cover configured to open and close; an operation unit provided in the casing, the operation unit not being exposed outside the casing when the cover is closed, the operation unit being exposed outside the casing when the cover is open; and a holding unit whose state switches to one of a hold state configured to hold an information processing device and a release state configured to release the information processing device, in response to an operation accepted by the operation unit.

A printing device includes: a casing having a cover configured to open and close; an operation unit provided in the casing, the operation unit not being exposed outside the casing when the cover is closed, the operation unit being exposed outside the casing when the cover is open; and a holding unit whose state switches to one of a hold state configured to hold an information processing device and a release state configured to release the information processing device, in response to an operation accepted by the operation unit.

A liquid surface detector includes an electrode pad, a coil, a memory, and a detection control circuit. The electrode pad is attached to an outer side surface of a tank of the image forming apparatus. The coil is connected to the electrode pad. The memory stores initial values. The detection control circuit determines a capacitance (first capacitance) of a first resonance circuit including the coil and the tank with the electrode pad. When determining a liquid surface level value, the detection control circuit subtracts an error value from the first capacitance so as to determine a first corrected capacitance, and determines the liquid surface level value based on the first corrected capacitance and the initial value.

A liquid surface detector includes an electrode pad, a coil, a memory, and a detection control circuit. The electrode pad is attached to an outer side surface of a tank of the image forming apparatus. The coil is connected to the electrode pad. The memory stores initial values. The detection control circuit determines a capacitance (first capacitance) of a first resonance circuit including the coil and the tank with the electrode pad. When determining a liquid surface level value, the detection control circuit subtracts an error value from the first capacitance so as to determine a first corrected capacitance, and determines the liquid surface level value based on the first corrected capacitance and the initial value.

The recording device includes an upstream transport roller pair capable of transporting a medium, a recording head configured to record an image by discharging ink at a predetermined timing on the medium transported downstream in a Dl direction by a predetermined transport amount by the upstream transport roller pair while moving in a Y-axis direction intersecting the D1 direction, an image capturing unit configured to read the image recorded on the medium by the recording head, and a control unit, wherein the control unit has a function of performing maintenance for a discharge failure of the ink, a correction of the transport amount, and a correction of the discharge timing of the ink based on the reading result of the image read by the image capturing unit.