Incremental printing of symbolic information – Ink jet – Controller
Reexamination Certificate
2002-07-22
2004-04-13
Meier, Stephen D. (Department: 2853)
Incremental printing of symbolic information
Ink jet
Controller
C327S389000
Reexamination Certificate
active
06719387
ABSTRACT:
TECHNICAL FIELD OF THE INVENTION
This invention relates to driver circuits for inkjet printers, and more particularly relates to a method for controlling propagation delay in inkjet print head drivers.
BACKGROUND OF THE INVENTION
Inkjet printers are common adjuncts to personal computers. Such printers operate by placing extremely small droplets of ink (typically between 50 and 60 microns in diameter) onto paper to create an image. The placement of these droplets is very precise, allowing resolutions of up to 1440×720 dots per inch. The unit of the inkjet printer that actually delivers the droplets of ink to the paper is the print head assembly, which includes the print head, one or more ink cartridges, the print head stepper motor, a belt and a stabilizer bar. The stepper motor moves the print head assembly back and forth across the paper, with the stabilizer bar ensuring precise and controlled movement of the print head. The belt attaches the print head to the stepper motor. The ink cartridges serve as portable containers for the ink, and typically attach to the print head in a manner allowing for their easy replacement when the ink is spent.
The print head is the component that actually delivers the droplets of ink. It includes a series of nozzles that are used to spray the droplets of ink. The most widely used technologies to form the droplets are thermal bubble and piezo-electric.
In thermal bubble technology, ink is directed from the cartridge to a small reservoir at the location of a nozzle. Tiny resistors in contact with the small reservoir have an electrical pulse applied to them, causing them to rapidly create heat. This heat vaporizes some of the ink in the reservoir, creating a bubble. The expanding bubble pushes some of the ink out of the nozzle onto the paper. The heat is only generated for a small interval, sufficient to create the proper size droplet and propel it out of the nozzle to the paper. When the resistor cools, the bubble collapses and a vacuum is created, drawing more ink into the small reservoir for the next cycle.
In piezo-electric technology, as with thermal bubble technology, ink is directed from the cartridge to a small reservoir at the location of a nozzle. However, a piezo-electric crystal is located at the back of the ink reservoir, opposite the nozzle. The crystal receives an electrical pulse that causes it to vibrate. When the crystal vibrates into the reservoir, it pushes some of the ink out of the nozzle onto the paper. When it vibrates back out of the reservoir, it draws in more ink for the next cycle.
Both of these technologies require that the electrical pulse be generated in a controlled manner, such that the pulse has minimal propagation delay, but with carefully controlled timing. To this end, the integrated circuits including the electrical drivers that generate these electrical pulses have included expedients to accomplish this control. Such expedients include 1) quickly discharging the gate of the output driver transistor through a clamp to ground, and then slewing the discharge, 2) quickly and temporarily discharging the gate of the output driver transistor to its source, 3) providing a floating gate drive, 4) quickly discharging the gate of the output driver transistor to its drain, prior to slewing off.
The first of these approaches is shown in
FIG. 1
, in which a predrive circuit
12
charges the gate of NMOS transistor M
1
at turn-on. At turn-off, diode D
1
provides a low impedance path to quickly pull the gate of M
1
down to reduce turn-off propagation delay. The gate of M
1
is then discharged to ground through resistor R
S
, thus controlling the fall time. However, this approach does not work well with a varying V
DD
.
The second of these approaches is shown in
FIG. 2
, in which, again, predrive circuit
12
charges the gate of NMOS transistor M
1
at turn-on. At turn-off, one shot
14
is activated for the time period of the one shot when input IN goes high, thus closing relay
16
and discharging the gate of transistor M
1
to its source for that time period. The fall time is then controlled by slewing the gate to ground through resistor R
S
. However, this approach requires more chip area to implement, as does the fourth approach listed above. The third approach makes the fall time solely controlled by the load.
SUMMARY OF THE INVENTION
It would therefore be desirable to have an inkjet print head driver providing minimal propagation delay, while providing controlled rise and fall time, but without the problems described above. The present invention provides such a print head driver. In accordance with the present invention there is provided an improved inkjet print head driver. The driver includes a source of predrive charge for a first, drive transistor coupled by its source and drain between an output node and a power supply, and having its gate coupled to the source of predrive charge. A second transistor is provided, adapted to receive in input signal at its gate. A third, control transistor is coupled by its source and drain between the gate of the first transistor and the second transistor, the second transistor being coupled by its source and drain between the third transistor and ground.
REFERENCES:
patent: 3959782 (1976-05-01), Dunn
Theodore F. Bogart, Jr., Electronic Devices and Circuits, 1986, Merrill Publishing Company, pp. 292-296.
Rahman Md Abidur
Smith Brett E.
Brady III W. James
Meier Stephen D.
Moore J. Dennis
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