A printer includes a mount on which a print target is placed, a print device to print an image on the print target on the mount, a print area indicator around a periphery of the mount, the print area indicator to indicate a print area of the image to be printed on the print target on the mount, and control circuitry to control the print area indicator to indicate the print area according to a print start position from which the print device starts printing on the print target and a print size of the image to be printed on the print target.

A machine for digital printing of glass sheets on their entire surface, including their border, comprising a printing table (1), a printing carriage (2) that travels along the printing table (1) on a number of travel guides (3), and a printing bridge (4) associated with the printing carriage (2) on which printing modules or heads (5) travel, characterized in that it has a head controller (6) that manages up to four encoders, which allows four simultaneous printing modes: Modality 1 along the X axis in single pass. Modality 2 along the Y axis in single pass. Modality 3 along the X axis in multipass. Modality 4 along the Y axis in multipass.

A printer includes a print head and a processor. The print head ejects ink from nozzles to a printing medium while moving in a first direction, and also moves in a second direction intersecting with the first direction by a moving amount that is a dimension in the second direction of each of blocks into which the nozzles are divided in the second direction. Based on a position of the printing medium and the dimension, the processor determines whether to perform printing in a first mode or a second mode. A printing start position in the second direction of the print head is set such that a position in the second direction of one of boundaries between mutually adjacent blocks coincides, in the first mode, with a position of a back end of a printing region, and in the second mode, with a position of a front end of the printing region.

An ejection apparatus includes an ejection head having an ejection port, a droplet detection unit, an acquisition unit, a control unit, and a decision unit. The droplet detection unit detects that a droplet ejected from the ejection port has reached a predetermined position. The acquisition unit acquires information regarding a velocity of movement of the detected droplet. The control unit controls the ejection head to eject the droplet from the ejection port. The decision unit decides a number of consecutive ejections of a plurality of droplets from the ejection head based on the acquired information regarding the velocities of each of the plurality of droplets ejected consecutively and detected by the droplet detection unit. If the acquisition unit acquires the information regarding velocities of detected droplets, the control unit controls the ejection head to consecutively eject the droplets from the ejection head based on the decided number of consecutive ejections.

A discharge head includes an orifice surface in which orifices each configured to discharge a droplet are arrayed in a predetermined direction. A detecting unit includes a light emitting element and a light receiving element, and optically detects a droplet discharged from the orifice. A suppression unit is arranged between the light emitting element and the orifice surface, and suppresses the light emitted from the light emitting element from reaching the orifice surface by shielding at least some rays of the light which are emitted from the light emitting element and would otherwise propagate to the orifice surface.

A printing control apparatus includes a control unit configured to perform control so that a distribution ratio based on which color separation data separated as having a predetermined color is distributed into data for a first nozzle array and a distribution ratio based on which color separation data is distributed into data for a second nozzle array are different depending on a tone value in the color separation data, and a generation unit configured to generate printing data to be used for printing by the first nozzle array based on the distributed data for the first nozzle array and generate printing data to be used for printing by the second nozzle array based on the distributed data for the second nozzle array.

There is provided control system including: movement mechanism configured so that the movement mechanism is driven by motor; detector configured to detect position and speed of the movable member; and controller. The controller is configured to: control the motor so that the movement mechanism reciprocatively moves the movable member; and in a course to move the movable member to a returning point, control the movement of the movable member by controlling the motor based on the speed of the movable member so that the movable member is moved at a constant speed until a deceleration start point of time, and control the movement of the movable member by controlling the motor based on the position of the movable member so that the movable member is decelerated from the deceleration start point of time and stops at the returning point in accordance with a target position locus.

A liquid ejecting apparatus includes an ejecting section configured to eject liquid to a print medium, a movement mechanism configured to change the relative positional relationship between the print medium and the ejecting section, an encoder configured to include a scale, a light emitting element emitting light, and a light receiving element receiving light reflected by the scale or light transmitted through the scale in the emitted light and configured to output information changed in accordance with a change in the positional relationship, a signal generation section configured to generate a pulse signal including a pulse prescribing a timing when the ejecting section ejects liquid based on the information, a measurement section configured to measure a time length between pulses included in the pulse signal, and an ejection restriction section configured to restrict ejection of liquid from the ejecting section when the time length is larger than a threshold value.

A liquid discharge apparatus includes a liquid discharge head, a carriage which has the liquid discharge head mounted thereto and moves in a scanning direction, an encoder sensor mounted to the carriage, a slit member extending in the scanning direction and having encoder slits aligned in the scanning direction and detected by the encoder sensor, and a controller. The controller moves the carriage in the scanning direction, generates multiplied signals by multiplying a detection signal obtained based on a detection result of the encoder slits by the encoder sensor when a signal change occurs in the detection signal, and causes the liquid discharge head to discharge liquid from nozzles, based on the multiplied signals.

An inkjet printer includes a head, a drive voltage generating circuit, a carriage, and a magnet array. The head includes a nozzle and an ejection element. The ejection element is configured to be driven, when applied with a drive voltage, to eject ink from the nozzle. The drive voltage generating circuit is configured to generate the drive voltage to be applied to the ejection element. The carriage is configured to move in a moving direction to move the head and the drive voltage generating circuit in the moving direction. The magnet array includes a plurality of magnets arrayed in the moving direction. The drive voltage generating circuit includes a coil configured to produce an electromotive force by interlining with magnetic flux of the magnet array in accordance with movement of the carriage. The drive voltage generating circuit generates the drive voltage using the electromotive force produced by the coil.