Abstract: A fluid ejecting printhead including a substrate having a surface, and a columnar group of drop generators formed on the surface that are arranged into subgroups, each subgroup being fluidically isolated from other subgroups on the surface. Firing pulses are provided to the drop generators such that no two drop generators in the same subgroup are activated in sequence.

Abstract: The present invention includes as one embodiment an inkjet printing method for decreasing dot placement artifacts of an inkjet printhead having at least two substrates, each with overlapping and non-overlapping nozzle rows, the method including selectively disabling at least one ink ejection element associated with at least one nozzle in the overlapping nozzle rows based on a swath height error of the substrate.

Abstract: The present invention includes as one embodiment an inkjet printing method for decreasing dot placement artifacts of a thermal inkjet printhead having at least one substrate having nozzle rows each associated with a print data row, the method including variably mapping each nozzle row to a print data row based on a swath height error of the substrate to reduce the artifacts caused by the swath height error.

Abstract: The present invention includes as one embodiment an inkjet printing method for decreasing dot placement artifacts of an inkjet printhead having at least two substrates, each with overlapping and non-overlapping nozzle rows, the method including selectively disabling at least one ink ejection element associated with at least one nozzle in the overlapping nozzle rows based on a swath height error of the substrate.

Abstract: A fluid ejection device having storage and methods of forming and using such fluid ejection devices are described. In one embodiment, a substrate comprises multiple heater resistors supported thereby, and configured for ejecting fluid onto a medium. One storage structure is supported by the substrate and configured to store data.

Abstract: An inkjet printhead includes a substrate having an ink feed slot formed therein. The inkjet printhead includes drop generators and ink feed channels. Each drop generator has a nozzle and a vaporization chamber. At least one ink feed channel is fluidically coupled to each vaporization chamber and is fluidically coupled to the ink feed slot. A thin-film structure is supported by the substrate and defines a first portion of each ink feed channel. An orifice layer supported by the substrate defines the nozzles and the vaporization chambers in the drop generators. The orifice layer defines a second portion of each ink feed channel.

Abstract: An fluid ejection device includes nozzles and includes firing resistors which correspond to the nozzles. Each firing resistor and corresponding nozzle are located in zones on the fluid ejection device where each zone has at least one firing resistor and corresponding nozzle. Addressable select logic responsive to a select address couples fire pulses to the firing resistors in the zones so that each firing resistor in each zone is coupled to the same fire pulse.

Abstract: Systems, including apparatus and methods, for microfluidic processing and/or analysis of samples. The systems include a microfluidic device having a substrate and a thin-film layer formed on the substrate. The thin-film layer may be included in electronics formed on the substrate. The electronics may provide electronic devices configured to sense or modify a property of the sample. The thin-film layer defines an opening for routing movement of fluid and/or sample within the device.

Abstract: An fluid ejection device includes nozzles and includes firing resistors which correspond to the nozzles. Each firing resistor and corresponding nozzle are located in zones on the fluid ejection device where each zone has at least one firing resistor and corresponding nozzle. Addressable select logic responsive to a select address couples fire pulses to the firing resistors in the zones so that each firing resistor in each zone is coupled to the same fire pulse.

Abstract: The present invention includes as one embodiment an inkjet printing method for decreasing print banding in a thermal inkjet printhead having a plurality of substrates with adjacent overlapping and non-overlapping regions between the substrates, the method comprising synchronizing a difference in time delay between ink ejected from the adjacent overlapping and non-overlapping regions of each substrate to reduce the difference.

Abstract: An fluid ejection device includes nozzles and includes firing resistors which correspond to the nozzles. Each firing resistor and corresponding nozzle are located in zones on the fluid ejection device where each zone has at least one firing resistor and corresponding nozzle. Addressable select logic responsive to a select address couples fire pulses to the firing resistors in the zones so that each firing resistor in each zone is coupled to the same fire pulse.

Abstract: An inkjet printhead is provided with a high nozzle packing density. The printhead has ink feed holes for each firing chamber that are individually tuned such that the pressure drop from the reservoir to the firing chamber is held constant for all firing chambers on said printhead.

Abstract: An inkjet printhead assembly includes at least one inkjet printhead including N primitives and an address having M possible address values. Each primitive includes a group of at most M drop generators. The address is cycled through all M address values to control a sequence of which one drop generator in the primitive is fired at a given time. One drop generator in the primitive can be fired simultaneously with one drop generator in each of the other primitives. A primitive to address ratio (N/M) of the printhead is at least 10 to 1.

Abstract: An inkjet printhead assembly includes a substrate having an ink feed slot formed therein including a first side and second side along a vertical length of the ink feed slot. A first column of drop generators is formed along the first side of the ink feed slot. A second column of drop generators is formed along the second side of the ink feed slot. Each drop generator includes a nozzle. A nozzle packing density for nozzles in the first and second columns of drop generators including the area of the ink feed slot is at least approximately 100 nozzles per square millimeter (mm2).

Abstract: An inkjet printhead includes a substrate having an ink feed slot formed therein. The inkjet printhead includes drop generators and ink feed channels. Each drop generator has a nozzle and a vaporization chamber. At least one ink feed channel is fluidically coupled to each vaporization chamber and is fluidically coupled to the ink feed slot. A thin-film structure is supported by the substrate and defines a first portion of each ink feed channel. An orifice layer supported by the substrate defines the nozzles and the vaporization chambers in the drop generators. The orifice layer defines a second portion of each ink feed channel.

Abstract: An inkjet printhead assembly includes a substrate having an ink feed slot formed therein including a first side and second side along a vertical length of the ink feed slot. A first column of drop generators is formed along the first side of the ink feed slot. A second column of drop generators is formed along the second side of the ink feed slot. Each drop generator includes a nozzle. A nozzle packing density for nozzles in the first and second columns of drop generators including the area of the ink feed slot is at least approximately 100 nozzles per square millimeter (mm2).

Abstract: An inkjet printhead is provided with a high nozzle packing density. The printhead has ink feed holes for each firing chamber that are individually tuned such that the pressure drop from the reservoir to the firing chamber is held constant for all firing chambers on said printhead.

Abstract: An inkjet print cartridge that includes a substrate having a plurality of ink ejection chambers with an ink ejection element in each of the ink ejection chambers, an ink channel connecting at one end to an inlet passage connected to one of the ink ejection chambers for refilling the one of the ink ejection chambers with ink, a group of the ink ejection chambers in adjacent relationship forming a primitive in which a maximum of only one of the ink ejection chambers in the primitive is activated at a time, first circuit on the substrate coupled to the ink ejection elements in the ink ejection chambers, wherein the first circuit applying primitive select signals to select one or more of the primitives and applying address line select signals to enable devices associated with the ink ejection elements in one or more selected primitives such that a maximum of one of the ink ejection chambers in each of the selected primitive is energized at a time causing a plurality of ink drops to be ejected from the one of the

Abstract: A fluid ejecting printhead including a substrate having a surface, and a columnar group of drop generators formed on the surface that are arranged into subgroups, each subgroup being fluidically isolated from other subgroups on the surface. Firing pulses are provided to the drop generators such that no two drop generators in the same subgroup are activated in sequence.

Abstract: An apparatus and method for detecting ink leakage in a print head. Conductive material is provided on a print head substrate that functions as a detector for ink that has leaked out of the established ink well or conduit. The detector conductive material is preferably arranged in proximity to power and/or control signal conductors and senses when leaked ink is threatening these conductors.