A method for modifying color density values in a dot-based printing system uses a control unit. The control unit implements the modification of the color density values after a raster image has been created and modifies the number and/or size of print dots to be applied to a printing substrate in order to attain pre-defined color density target values.

A liquid ejecting apparatus includes a wiring substrate; and a liquid ejecting head, in which the liquid ejecting head includes a plurality of electrodes, an ejecting unit, and a non-ejecting unit, the wiring substrate is connected to the plurality of electrodes, the ejecting unit includes a driven element which is displaced due to a signal waveform applied to an electrode which is provided so as to correspond to at least one of the plurality of electrodes, a pressure chamber, and nozzles, the non-ejecting unit is provided so as to correspond to at least another electrode among the plurality of electrodes, and does not include at least one of the nozzle, the driven element, and the pressure chamber, and the signal waveform which is applied to an electrode which corresponds to the non-ejecting unit is designated by a dummy signal in the printing data.

A liquid ejecting apparatus includes an ejecting unit that includes a piezoelectric element and ejects liquid by driving the piezoelectric element; a first drive circuit that is mounted on a front surface of a circuit substrate and generates a first drive signal; and a second drive circuit that is mounted on a rear surface of the circuit substrate and generates a second drive signal. The first drive circuit includes a first control circuit which is integrated into a first integrated circuit. The second drive circuit includes a second control circuit which is integrated into a second integrated circuit. The first integrated circuit includes a first terminal and a second terminal. The second integrated circuit includes a third terminal and a fourth terminal. A distance between the first terminal and the third terminal is shorter than a distance between the first terminal and the fourth terminal.

A liquid ejecting apparatus includes an ejecting unit that includes a piezoelectric element and ejects liquid by driving the piezoelectric element; a first drive circuit that generates a first drive signal; a second drive circuit that generates a second drive signal; and a circuit substrate having one surface on which the first drive circuit is mounted and the other surface on which the second drive circuit is mounted. The first drive circuit includes a first pair of transistors and a second pair of transistors. The second drive circuit includes a third pair of transistors and a fourth pair of transistors. A distance between the first pair of transistors and the third pair of transistors is shorter than a distance between the first pair of transistors and the fourth pair of transistors.

A liquid ejecting apparatus includes an ejecting unit that includes a piezoelectric element and ejects liquid by driving the piezoelectric element; a first drive circuit that generates a drive signal; and a circuit substrate in which the first drive circuit is disposed. The first drive circuit includes a first integrated circuit having a shape which includes a first side and a second side. The first integrated circuit includes, a first power supply terminal; a second power supply terminal; a first output terminal; and a second output terminal. The first power supply terminal and the second power supply terminal are disposed along the first side. The first output terminal and the second output terminal are disposed along the second side.

A liquid discharge apparatus has a head provided with discharge sections which discharge a liquid, a drive circuit configured to generate driving signals for driving the discharge sections and discharging the liquid, a carriage mounted with the head and the drive circuit, and a carriage support section configured and arranged to support the carriage. A shortest distance between the carriage support section and the drive circuit is shorter than a shortest distance between the carriage support section and the discharge section which is closest to the carriage support section.

A liquid discharge apparatus has a head provided with discharge sections which discharge a liquid, a drive circuit configured to generate driving signals for driving the discharge sections and discharging the liquid, a carriage mounted with the head and the drive circuit, a motor configured to move the carriage, and a flushing box configured and arranged to receive the liquid discharged from the discharge sections. The drive circuit is mounted at a position so as not to pass above the flushing box while the carriage is being moved.

A head driving device drives a liquid ejection head. The liquid ejection head includes a plurality of nozzles and a plurality of pressure generating devices provided respectively corresponding to the nozzles. The head driving device includes a driving-waveform correcting unit configured to correct driving waveform data that defines ejection characteristics of liquid to be ejected from the nozzle based on interference patterns expressing variations in the ejection characteristics caused by an interference occurring in the nozzle.

A liquid discharge apparatus uses a drive signal including a micro-vibration waveform which causes the piezoelectric element to micro-vibrate such that an ink is not discharged from the nozzle in a case of being applied to the piezoelectric element as the drive signal and a drive waveform which deforms piezoelectric element such that the ink is discharged from the nozzle in a case of being applied to the piezoelectric element as the drive signal. The presentation unit selectably presents the indirect information from which the ink discharge status can be estimated such as the types of ink and the usage status of the ink or the like. The control unit changes the strength of the micro-vibration caused by the micro-vibration waveform based on the indirect information selected on the presentation unit.

A maintenance method for a liquid discharging apparatus including a discharging portion that discharges liquid, the maintenance method includes acquiring first viscosity information related to viscosity of the liquid inside the discharging portion, discharging a first amount of the liquid from the discharging portion, acquiring second viscosity information related to viscosity of the liquid inside the discharging portion, and discharging a second amount of the liquid based on the first viscosity information and the second viscosity information, from the discharging portion.