A fluidic die that includes at least one temperature sensor coupled to at least one zone of the fiuidic die, a setpoint register to receive a target temperature setpoint for the fiuidic die wherein a detected temperature presented by the at least one temperature sensor is compared to the target temperature setpoint using a comparator module to get a firing pulse adjustment value, and a firing pulse used to convey an amount of fluid within the die is adjusted using the firing pulse adjustment value.

In some examples, a fluidic die comprises a plurality of actuators and actuation control logic coupled to the plurality of actuators. The fluidic die also includes a multiplexer, coupled to the actuation control logic, to provide the actuation control logic with an actuation signal, the actuation signal to control operation of the plurality of actuators. The fluidic die also comprises an actuation signal generator, coupled to the multiplexer, to provide the multiplexer with a plurality of actuation signals. The fluidic die also includes actuation signal mapping logic to control the multiplexer and the actuation signal generator based on one of a plurality of stored modes, each mode mapping the plurality of actuation signals to the plurality of actuators.

A fluid ejection device may include fluid actuators and an actuation controller. Each fluid actuator may have an associated address. The actuation controller is to receive an address for a fluid actuator of the device to be actuated and is further to automatically transmit one of different fire pulses based upon the received address.

A liquid ejecting apparatus includes an ejection unit that ejects a liquid by a piezoelectric element being driven, a drive signal generation unit that generates a drive signal for driving the piezoelectric element, a residual vibration detection unit that detects a residual vibration of the ejection unit after the drive signal is applied to the piezoelectric element, and an inspection control signal generation unit that generates an inspection control signal for instructing start of detection of the residual vibration by the residual vibration detection unit. The inspection control signal when a temperature of the ejection unit is a first temperature differs from the inspection control signal when the temperature of the ejection unit is a second temperature lower than the first temperature.

Disclosed is a method of providing adjustment data for a droplet deposition head (such as a printhead), or a data processing component therefor. The method makes use of test data, which has been collected by operating the droplet deposition head (or a test droplet deposition head of substantially the same construction, e.g from the same batch), using a set of test waveforms, at a number of frequencies within a test range, and by recording the volume and velocity of the thus-ejected droplets, with these recorded values (vol.sub.r, vel.sub.r) being represented within the test data. Each of the set of test waveforms includes a basic drive waveform and a number of adjusted drive waveforms, each of which corresponds to the basic drive waveform, but with a particular waveform parameter adjusted by a corresponding amount. This waveform parameter is a continuous variable, such as pulse width or pulse amplitude. The method further includes, determining adjustment values corresponding to a number of adjustment frequencies, each adjustment value corresponding to an amount of adjustment for the waveform parameter that, based on the test data, is expected to result in adjusted values for droplet volume and velocity of, respectively, vol.sub.a and vel.sub.a, which are substantially equal to targeted values for droplet volume and velocity, vol.sub.T and vel.sub.T. The method outputs adjustment data representing such adjustment values and their associated adjustment frequencies, for example in the form of values for a look-up-table. Also disclosed is a droplet deposition apparatus that includes a droplet deposition head with data storage having stored thereon a set of adjustment data. The head uses the adjustment data to actuate its actuator elements with a drive waveform that is based on a basic drive waveform, but with a particular waveform parameter being adjusted by an adjustment value, which is represented by the set of adjustment data and which is determined based on it being associated with the current operating frequency of the actuator element in question. The waveform parameter is again a continuous variable. The adjustment data enable the head to eject droplets at frequencies within an operating range for the head whose values for droplet volume and velocity are substantially equal to targeted values for droplet volume and velocity, vol.sub.T and vel.sub.T.

An ink jet head includes a pressure chamber, an actuator, and an application unit. The chamber accommodates liquid. The actuator changes a volume of the chamber with a drive signal to be applied. The unit apply s the signal to the actuator. The signal includes a discharge pulse and a vibration pulse. The discharge pulse causes liquid to be discharged from a nozzle. A second discharge pulse is applied after a first discharge pulse. The vibration pulse is applied before the discharge pulse, has a potential having a polarity opposite to that of the discharge pulse. A period of the discharge pulse is 1.5 times to 2.5 times a half-period of a main acoustic resonance frequency of liquid in the chamber. A pulse width of the first pulse is closer to the half-period of the main acoustic resonance frequency than a pulse width of the second pulse.

There are provided a thermal transfer printer and a method for producing a printed matter capable of suppressing deterioration in printing quality. A first energizing pulse is generated at the beginning of one line period. The first energizing pulse causes each heating element to perform offset heating. Second energizing pulses whose number corresponds to a tone level are generated in one line period. The second energizing pulses cause each heating element to perform heating. When the timings at which the first energizing pulse and the second energizing pulses are generated can be evenly distributed within one line period, the timings are evenly distributed within one line period. When the timings cannot be evenly distributed within one line period, the timings are distributed within one line period such that an unevenly distributed portion included in the timings is arranged in an initial period of one line period.

A liquid discharging apparatus includes a nozzle, a drive signal generation unit that generates a drive signal for driving a piezoelectric element, and a discharge abnormality detection unit that detects a change of an electromotive force of the piezoelectric element, which is caused by residual vibration in a cavity after the drive signal is supplied. The drive signal generation unit generates a first drive signal for checking whether or not a first discharge abnormality caused by a foreign substance adhering to a surface on which the nozzle opens occurs and a second drive signal for checking whether or not a second discharge abnormality caused by a cause other than the foreign substance occurs. A potential of the first drive signal when the discharge abnormality detection unit performs checking is different from a potential of the second drive signal when the discharge abnormality detection unit performs checking.

An inkjet head comprises a pressure chamber that stores liquid; an actuator that changes a volume of the pressure chamber in response to an applied driving signal; and an applying section that applies the driving signal to the actuator. The driving signal includes a discharge pulse and an oscillation pulse. The discharge pulse enables liquid to be discharged from a nozzle communicating with the pressure chamber. The oscillation pulse is applied before the discharge pulse and has a potential opposite in polarity to that of the discharge pulse to generate pressure oscillation for promoting discharge of the liquid in the liquid. When the driving signal includes two or more successive discharge pulses, a cycle of the discharge pulse is 1.5 times or more and 2.5 times or less as long as a half cycle of a main acoustic resonance frequency of the liquid in the pressure chamber.

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.