A liquid ejecting apparatus includes a drive circuit that outputs a drive signal, a criterion voltage circuit that outputs a criterion voltage signal from a criterion voltage-signal output terminal, a piezoelectric element that includes a first electrode to which the drive signal is supplied and a second electrode to which the criterion voltage signal is supplied, a cavity, and a vibration plate which is provided between the cavity and the piezoelectric element. The criterion voltage circuit includes a voltage generation unit that generates the criterion voltage signal, and a voltage detection unit that detects a voltage value of the criterion voltage signal. In a case where the voltage value of the criterion voltage signal is greater than a first threshold, the voltage detection unit stops an operation of the voltage generation unit and electrically connects the criterion voltage-signal output terminal and a ground terminal to each other.

A liquid ejecting apparatus includes a piezoelectric element that includes a first electrode to which a drive signal is supplied and a second electrode to which a criterion voltage signal is supplied, and performs displacement by a potential difference between the first electrode and the second electrode, a cavity which is filled with a liquid, a vibration plate provided between the cavity and the piezoelectric element, and a first switching circuit that includes a first terminal to which the drive signal is supplied and a second terminal which is electrically connected to the first electrode and controls a supply of the drive signal to the first electrode. The liquid ejecting apparatus has a first mode in which charges at a first node at which the first electrode and the second terminal are electrically connected to each other are released via a parasitic diode of the first switching circuit.

In a liquid discharge apparatus, a print head includes a supply port to which liquid is supplied; a nozzle plate that includes a nozzle for discharging the liquid; a substrate that includes first side, a second side, a first surface, and a second surface which is different from the first surface; a connector that is provided on the first surface; and an integrated circuit that is provided on the first surface, the substrate is provided between the nozzle plate and the supply port, the connector is provided along the first side, the integrated circuit is provided in a place which is not adjacent to the connector, and a shortest distance between the supply port and the first surface is longer than a shortest distance between the supply port and the second surface.

A print head control circuit includes a first diagnosis signal propagation wiring for propagating a first diagnosis signal, a fifth diagnosis signal propagation wiring for propagating a fifth diagnosis signal indicating a diagnosis result, and a second voltage signal propagation wiring for propagating a second voltage signal. The fifth diagnosis signal propagation wiring and the second voltage signal propagation wiring are electrically coupled to each other via a fifth terminal and a seventh terminal, and the first diagnosis signal propagation wiring and the second diagnosis signal propagation wiring are located to be aligned. The first diagnosis signal propagation wiring and the second voltage signal propagation wiring are located to be adjacent to each other in a direction in which the first diagnosis signal propagation wiring and the second diagnosis signal propagation wiring are aligned.

A drop ejector array device includes a first plurality and a second plurality of drop ejectors that are alternatingly disposed along an array direction on the substrate surface. A voltage input terminal and a current return terminal are disposed on the substrate surface. A first power bus line connects the first plurality to the voltage input terminal. A second power bus line connects the second plurality to the voltage input terminal. The second power bus line is electrically connected to the first power bus line by a primary power bus connector line. A first current return bus line connects the first plurality to the current return terminal. A second current return bus line connects the second plurality to the current return terminal. The second current return bus line is electrically connected to the first current return bus line by a primary current return bus connector line.

In one example in accordance with the present disclosure, a fluid ejection device is described. The fluid ejection device includes a number of nozzles to eject an amount of fluid. A first field-effect transistor (FET) activates a first fluidic operation component and a second FET activates a second fluidic operation component. The first FET and the second FET are selected from among a high-side switch FET, a low-side switch FET, and a hybrid FET and the first FET and the second FET are different from one another.

Provided is a liquid discharging apparatus including a drive signal output circuit outputting a drive signal that displaces between a first potential and a second potential, and a discharging portion including a piezoelectric element that is driven based on the drive signal and discharging liquid, in which the drive signal output circuit includes a modulation circuit that outputs a modulation signal obtained by modulating a base drive signal that is a base of the drive signal, an amplification circuit that outputs an amplified modulation signal obtained by amplifying the modulation signal, and a demodulation circuit that includes a capacitor and outputs the drive signal obtained by demodulating the amplified modulation signal, the first potential is 25 V or higher, and the capacitor is a surface mounting component including a laminated portion in which a resin thin film layer and a metal thin film layer are laminated.

Fluid ejection devices with multiple activation modes are disclosed. An example printhead assembly includes a fluid ejection nozzle, a first resistor fluidically coupled to the fluid ejection nozzle, and a second resistor fluidically coupled to the fluid ejection nozzle. The example printhead also includes an addressing circuit to receive a nozzle address and an activation mode to activate the fluid ejection nozzle. The activation mode determines which of the first resistor and the second resistor are to be energized.

There is provided a liquid discharge device including: a printing head; and a head driving circuit that is connected to the printing head via an FFC and outputs a driving signal, in which the driving circuit includes a signal output unit which outputs an analog signal, a transistor pair which is connected to the signal output unit and the FFC and driven with the analog signal output from the signal output unit to output the driving signal to the FFC, a return path which is connected to the FFC and feeds back the driving signal output from the transistor pair to the signal output unit, and an oscillation suppression unit which suppresses oscillation of input from the return path to the signal output unit.

A liquid-droplet ejecting apparatus includes: N nozzles; N driving elements; M power supply circuits that create a driving signal to be selectively supplied to the N driving elements; and N selecting circuits that selectively connect one of the M power supply circuits to a corresponding one of the N driving elements. The N driving elements are connected to the M power supply circuits in a first combination until a particular condition is satisfied. The first combination is a combination between the M power supply circuits and an M driving element groups, into which the N driving elements are divided based on a voltage of the supplied driving signal. The N driving elements are connected to the M power supply circuits in a second combination after the particular condition is satisfied. The second combination is another combination between the M driving element groups and the M power supply circuits.