Methods and systems are described herein for driving droplet ejection devices with multi-level waveforms. In one embodiment, a method for driving droplet ejection devices includes applying a multi-level waveform to the droplet ejection devices. The multi-level waveform includes a first section having at least one compensating edge and a second section having at least one drive pulse. The compensating edge has a compensating effect on systematic variation in droplet velocity or droplet mass across the droplet ejection devices. In another embodiment, the compensating edge has a compensating effect on cross-talk between the droplet ejection devices.

Methods and systems are described herein for driving droplet ejection devices with multi-level waveforms. In one embodiment, a method for driving droplet ejection devices includes applying a multi-level waveform to the droplet ejection devices. The multi-level waveform includes a first section having at least one compensating edge and a second section having at least one drive pulse. The compensating edge has a compensating effect on systematic variation in droplet velocity or droplet mass across the droplet ejection devices. In another embodiment, the compensating edge has a compensating effect on cross-talk between the droplet ejection devices.

Systems and methods of mitigating the effects of crosstalk in an inkjet head. An inkjet head has ink channels that jet droplets of a liquid material using piezoelectric actuators. Drive waveforms provided to the piezoelectric actuators include jetting pulses that cause activation of the piezoelectric actuators to jet the droplets from the ink channels. When crosstalk exists between the ink channels of the inkjet head due to the piezoelectric actuators, the amplitude of the jetting pulses are modified to mitigate the crosstalk between the ink channels.

A liquid discharge apparatus including a liquid discharge head having a substrate, plural pressure chambers two-dimensionally provided on one surface of the substrate, a discharge port, a pressure generating unit to discharge liquid through the discharge port and a flow path connected to the pressure chamber which are provided correspondingly to each pressure chamber, a common liquid chamber provided on the other surface of the substrate, and plural supply paths provided between adjacent pressure chambers and connected to the common liquid chamber; a moving unit to relatively move the liquid discharge head and a recording object; and a driving unit to drive the pressure generating unit. Flow paths respectively corresponding to the pressure chambers adjacent to the supply paths are connected to the supply paths. The driving unit outputs drive signals to the pressure generating units respectively corresponding to the pressure chambers connected to the supply paths at different timings.

Methods and systems are described herein for driving droplet ejection devices with multi-level waveforms. In one embodiment, a method for driving droplet ejection devices includes applying a multi-level waveform to the droplet ejection devices. The multi-level waveform includes a first section having at least one compensating edge and a second section having at least one drive pulse. The compensating edge has a compensating effect on systematic variation in droplet velocity or droplet mass across the droplet ejection devices. In another embodiment, the compensating edge has a compensating effect on cross-talk between the droplet ejection devices.

In accordance with an embodiment, an inkjet head comprises a plurality of first driving elements containing a plurality of first pressure chambers respectively communicating with a plurality of first nozzles; a plurality of second driving elements containing a plurality of second pressure chambers respectively communicating with a plurality of second nozzles; a common liquid chamber configured to communicate with a plurality of the first pressure chambers and a plurality of the second pressure chambers; and a controller configured to apply an ejection pulse to the plurality of first driving elements and at least one non-ejection pulse to the plurality of second driving elements before an end time of the ejection pulse.

In accordance with an embodiment, an inkjet head comprises a plurality of first driving elements, a plurality of second driving elements, a common liquid chamber and a controller. A plurality of the first driving elements constitutes a plurality of first pressure chambers respectively communicating with a plurality of first integrated nozzles. A plurality of the second driving elements constitutes a plurality of second pressure chambers respectively communicating with a plurality of second integrated nozzles. The common liquid chamber communicates with a plurality of the first pressure chambers and a plurality of the second pressure chambers. The controller applies an ejection pulse to the first driving element and at least one non-ejection pulse to the second driving element before an end timing of the ejection pulse.

A fluid ejection apparatus includes a plurality of fluid ejectors. Each fluid ejector includes a pumping chamber, and an actuator configured to cause fluid to be ejected from the pumping chamber. The fluid ejection apparatus includes a feed channel fluidically connected to each pumping chamber; and at least one compliant structure formed in a surface of the feed channel. The at least one compliant structure has a lower compliance than the surface of the feed channel.

A liquid ejection method includes an ejection step for ejecting liquid from a liquid ejection head to a substrate such that an ejection pattern is formed on the substrate, a step for correcting a control value for a drive unit for each ejection nozzle of the liquid ejection head on the basis of a relation with another ejection nozzle in the ejection step, and a step for performing the ejection step a plurality of times by using the corrected control value while relatively moving the liquid ejection head and the substrate such that a drop pattern constituted by a plurality of the ejection patterns is formed in an ejection region on the substrate. In the ejection step for forming a first ejection pattern, a second ejection pattern different from the first ejection pattern is formed on the substrate.

A recording element substrate includes a substrate, an orifice plate stacked on the substrate and having a liquid chamber which stores liquid between the substrate and the orifice plate, the orifice plate having an ejection port for ejecting the liquid in the liquid chamber, and an energy generation element provided on the substrate and configured to generate energy for ejecting the liquid stored in the liquid chamber, and the orifice plate is provided with an opening which is different from the ejection port and a flexible member which seals the opening.