Abstract: The present invention provides a system, method, and apparatus for pairing a vehicle key or remote keyless entry device with a vehicle by a dongle connected to an OBD port of the vehicle. The OBD programming dongle operates without a connection to an external device and pairs one or more keys with a vehicle without user intervention after the pairing process has started. The OBD programming dongle may be linked to a specific vehicle by the VIN code of the specific vehicle.

Abstract: The present invention provides a system, method, and apparatus for pairing a vehicle key or remote keyless entry device with a vehicle by a dongle connected to an OBD port of the vehicle. The OBD programming dongle operates without a connection to an external device and pairs one or more keys with a vehicle without user intervention after the pairing process has started. The OBD programming dongle may be linked to a specific vehicle by the VIN code of the specific vehicle.

Abstract: The present invention provides a system, method, and apparatus for pairing a vehicle key or remote keyless entry device with a vehicle by a dongle connected to an OBD port of the vehicle. The OBD programming dongle operates without a connection to an external device and pairs one or more keys with a vehicle without user intervention after the pairing process has started. The OBD programming dongle may be linked to a specific vehicle by the VIN code of the specific vehicle.

Abstract: The present invention provides a system, method, and apparatus for pairing a vehicle key or remote keyless entry device with a vehicle by a dongle connected to an OBD port of the vehicle. The OBD programming dongle operates without a connection to an external device and pairs one or more keys with a vehicle without user intervention after the pairing process has started. The OBD programming dongle may be linked to a specific vehicle by the VIN code of the specific vehicle.

Abstract: A micro-fluid ejection head assembly and methods for fabricating micro-fluid ejection heads using separately fabricated electrical components. The micro-fluid ejection head has at least one base substrate, at least one fluid ejector actuator substrate attached to the base substrate; and at least a first logic component substrate hermetically sealed to the base substrate. The fluid ejector actuator substrate and the first logic component substrate are in electrical communication with each other.

Abstract: Methods and apparatuses for optimizing the energy supplied to a print head heater are disclosed. A resistance associated with the print head heater or actuator is determined. A range of fire pulse values is determined based at least in part on the determined resistance and a velocity optimization procedure is executed based at least in part on the determined range of fire pulse values. An optimal fire pulse for the print head heater is selected based at least in part on the results of the velocity optimization procedure.

Abstract: A micro-fluid ejection head assembly and methods for fabricating micro-fluid ejection heads using separately fabricated electrical components. The micro-fluid ejection head has at least one base substrate, at least one fluid ejector actuator substrate attached to the base substrate; and at least a first logic component substrate hermetically sealed to the base substrate. The fluid ejector actuator substrate and the first logic component substrate are in electrical communication with each other.

Abstract: Methods and apparatuses for optimizing the energy supplied to a print head heater are disclosed. A resistance associated with the print head heater or actuator is determined. A range of fire pulse values is determined based at least in part on the determined resistance and a velocity optimization procedure is executed based at least in part on the determined range of fire pulse values. An optimal fire pulse for the print head heater is selected based at least in part on the results of the velocity optimization procedure.

Abstract: A method is described for controlling the temperature of a fluid ejection head is a fluid ejection apparatus. The fluid ejection head includes heating elements for generating fluid-nucleating heat for fluid ejection purposes and for generating non-fluid-nucleating heat (NNH) for temperature control purposes. The fluid ejection head has heating elements disposed in a plurality of zones distributed across the fluid ejection head. The heating elements are assigned to a plurality of address groups that are activated during corresponding address windows. The method includes generating a bit intensity word corresponding to each zone, where the bit intensity word specifies a sequence for activating the address groups for generating NNH. Each bit of the bit intensity word controls the activation of a corresponding address group during a corresponding address window.

Abstract: A printhead alignment test pattern has spaced-apart images at least partially aligned along an axis. Each image includes leading and trailing edge portions having respective image-outermost leading and trailing edges spaced apart along the axis and includes an intervening portion located between the leading and trailing edge portions. The leading and trailing edge portions have a higher print density than the intervening portion. A method for determining a printhead misalignment of a printer prints the test pattern, moves a sensor along the axis over the images, obtains data from the sensor, determines the locations along the printhead scan axis of the leading and/or trailing edges of the images using the data, and calculates the printhead misalignment from the determined locations of the leading and/or trailing edges of the images. The test pattern reduces cockling of the print media which improves the accuracy of the method.

Abstract: A method that provides printhead swath height measurement and compensation includes the steps of establishing a nominal printhead swath height to be associated with printheads of a particular type; printing a swath using a first printhead of the particular type; measuring a printhead swath height of the first printhead; determining a difference between the measured printhead swath height of the first printhead and the nominal printhead swath height; generating a printhead swath height correction value based on the difference; and storing the printhead swath height correction value in a printhead memory associated with the first printhead.

Abstract: A method of reducing printing defects in an ink jet printer including at least one printhead mounted to a printhead carrier for printing on a print media sheet, includes the steps of determining a vertical alignment error for at least one printhead and adjusting a sheet feed increment for the print media sheet based on the vertical alignment error.

Abstract: A printhead alignment test pattern has spaced-apart images at least partially aligned along an axis. Each image includes leading and trailing edge portions having respective image-outermost leading and trailing edges spaced apart along the axis and includes an intervening portion located between the leading and trailing edge portions. The leading and trailing edge portions have a higher print density than the intervening portion. A method for determining a printhead misalignment of a printer prints the test pattern, moves a sensor along the axis over the images, obtains data from the sensor, determines the locations along the printhead scan axis of the leading and/or trailing edges of the images using the data, and calculates the printhead misalignment from the determined locations of the leading and/or trailing edges of the images. The test pattern reduces cockling of the print media which improves the accuracy of the method.

Abstract: A method for determining the skew of a printhead of a printer. At least three images are printed which are at least partially aligned substantially along the printhead scan direction with the middle image printed from one of the upper and lower portions of the printhead and with the adjacent images printed from the other of the upper and lower portions of the printhead. A sensor is moved in the printhead scan direction over the images. A function is calculated from the sensor output, wherein the calculated function indicates the skew of the printhead.

Abstract: A method for determining a printhead misalignment of a printer. One step includes printing a printhead alignment test pattern including spaced-apart images at least partially aligned substantially along a printhead scan axis. A sensor is moved along the printhead scan axis at a known speed over the plurality of images. Sampled data points are obtained from the sensor at a known sampling rate. Another step includes determining the locations along the printhead scan axis of the edges of the images using the sampled data points, the known speed of the sensor, and the known sampling rate. An additional step includes calculating the printhead misalignment from the determined locations of the edges of the images.

Abstract: A method for determining a printhead misalignment of a printer. One step includes printing a printhead alignment test pattern including spaced-apart images at least partially aligned substantially along a printhead scan axis. A sensor is moved along the printhead scan axis at a known speed over the plurality of images. Sampled data points are obtained from the sensor at a known sampling rate. Another step includes determining the locations along the printhead scan axis of the edges of the images using the sampled data points, the known speed of the sensor, and the known sampling rate. An additional step includes calculating the printhead misalignment from the determined locations of the edges of the images.

Abstract: A method for determining the skew of a printhead of a printer. At least three images are printed which are at least partially aligned substantially along the printhead scan direction with the middle image printed from one of the upper and lower portions of the printhead and with the adjacent images printed from the other of the upper and lower portions of the printhead. A sensor is moved in the printhead scan direction over the images. A function is calculated from the sensor output, wherein the calculated function indicates the skew of the printhead.

Abstract: A method for determining vertical misalignment between first and second print heads involves printing a test pattern of first and second alternating slanted blocks extending horizontally. The first slanted blocks are printed by the first print head and the second slanted blocks are printed by the second print head. A known edge angle of the first and second slanted blocks is substantially the same. A sensor is moved across the test pattern for evaluating misalignment.