All The Claims

1. A digital-to-analog converter, comprising:
a first decoder configured to receive upper bits of a digital signal and upper reference voltages to output an upper voltage corresponding to the upper bits;
a second decoder configured to receive lower bits of the digital signal and lower reference voltages to output a lower differential voltage corresponding to the lower bits; and
a voltage summing buffer configured to generate an output voltage based on the upper voltage and the lower differential voltage, the output voltage corresponding to the digital signal including the upper bits and the lower bits.
2. The digital-to-analog converter as claimed in claim 1, wherein the first decoder selects one of the upper reference voltages in response to the upper bits to output the selected upper reference voltage as the upper voltage, and the second decoder selects a positive voltage and a negative voltage among the lower reference voltages in response to the lower bits to output the positive voltage and the negative voltage as the lower differential voltage.
3. The digital-to-analog converter as claimed in claim 2, wherein the first decoder selects a lowest voltage from among the upper reference voltages when the upper bits are all zero, and the second decoder selects a maximum voltage from among the lower reference voltages when a most significant bit of the lower bits is zero.
4. The digital-to-analog converter as claimed in claim 2, further comprising:
an upper reference voltage generator configured to generate 2n upper reference voltages with respect to n upper bits, n being a positive integer, the 2n upper reference voltages being uniformly spaced by a first voltage amount; and
a lower reference voltage generator configured to generate 2n-1+1 lower reference voltages with respect to m lower bits, m being a positive integer, the 2n-1+1 lower reference voltages being uniformly spaced by a second voltage amount smaller than the first voltage amount.
5. The digital-to-analog converter as claimed in claim 4, wherein the lower differential voltage is sequentially increased by Vg1 from \u2212Vgm2 to Vgm2 as a value of the lower bits is increased by one, Vgm being the first voltage amount and Vg1 being the second voltage amount.
6. The digital-to-analog converter as claimed in claim 4, wherein the second decoder includes:
a multiplexer configured to select a maximum voltage or a minimum voltage among the lower reference voltages in response to a most significant bit of the lower bits to output the selected voltage as the negative voltage of the lower differential voltage; and
a pass transistor logic configured to select one of the lower reference voltages in response to remaining bits of the lower bits, the remaining bits being the lower bits except the most significant bit of the lower bits, to output the selected voltage as the positive voltage of the lower differential voltage.
7. The digital-to-analog converter as claimed in claim 1, wherein the voltage summing buffer includes:
a first differential amplifier configured to receive the output voltage as feedback and receive the upper voltage, the fedback output voltage and the upper voltage being received as a first differential input, to generate a first differential current to a summing node pair;
a second differential amplifier configured to receive the positive voltage and the negative voltage of the lower differential voltage as a second differential input to generate a second differential current to the summing node pair; and
an output buffer configured to generate the output voltage based on a voltage or a current of at least one node of the summing node pair.
8. The digital-to-analog converter as claimed in claim 7, wherein a transconductance of the first differential amplifier is substantially equal to a transconductance of the second differential amplifier.
9. The digital-to-analog converter as claimed in claim 7, wherein the voltage summing buffer further includes a third differential amplifier configured to receive first and second voltages of a second differential input voltage as a third differential input to generate a third differential current to the summing node pair.
10. The digital-to-analog converter as claimed in claim 1, wherein the voltage summing buffer includes:
a P-type differential amplifier coupled between a first power supply voltage and a first summing node pair, the P-type differential amplifier being configured to receive the output voltage as feedback and receive the upper voltage, the fedback output voltage and the upper voltage being received as a first differential input, to generate a first differential current to the first summing node pair, the P-type differential amplifier being configured to receive the positive voltage and the negative voltage of the lower differential voltage as a second differential input to generate a second differential current to the first summing node pair;
an N-type differential amplifier coupled between a second power supply voltage and a second summing node pair, the N-type differential amplifier being configured to receive the output voltage as feedback and receive the upper voltage, the fedback output voltage and the upper voltage being received as a third differential input, to generate a third differential current to the second summing node pair, the N-type differential amplifier being configured to receive the lower differential voltage as a fourth differential input to generate a fourth differential current to the second summing node pair; and
an output buffer configured to generate the output voltage based on a sourcing differential current at the first summing node pair and a sinking differential current at the second summing node.
11. The digital-to-analog converter as claimed in claim 10, wherein the P-type differential amplifier is enabled in response to a switch signal and the N-type differential amplifier is enabled in response to an inversion signal of the switch signal, the switch signal being activated when a value of the upper bits is smaller than a center value of the upper bits.
12. A voltage summing buffer, comprising:
a first differential amplifier configured to receive an output voltage and a single-ended input voltage as a first differential input to generate a first differential current to a summing node pair;
a second differential amplifier configured to receive first and second voltages of a first differential input voltage as a second differential input to generate a second differential current to the summing node pair; and
an output buffer configured to generate the output voltage based on a voltage or a current at one of the summing node pair.
13. The voltage summing buffer as claimed in claim 12, wherein the first differential input voltage has a level for compensating an offset of the single-ended input voltage.
14. The voltage summing buffer as claimed in claim 12, further comprising:
a third differential amplifier configured to receive first and second voltages of a second differential input voltage as a third differential input to generate a third differential current to the summing node pair.
15. A source driver of a display device, the source driver comprising:
a reference voltage generator configured to generate upper reference voltages and lower reference voltages; and
a plurality of digital-to analog converters configured to convert a plurality of digital signals to a plurality of output voltages, respectively, wherein each digital-to analog converter includes:
a first decoder configured to receive upper bits of each digital signal and the upper reference voltages to output an upper voltage corresponding to the upper bits;
a second decoder configured to receive lower bits of each digital signal and the lower reference voltages to output a lower differential voltage corresponding to the lower bits; and
a voltage summing buffer configured to generate each output voltage of the plurality of output voltages based on the upper voltage and the lower differential voltage, each output voltage of the plurality of output voltages corresponding to one of the digital signals of the plurality of digital signals including the upper bits and the lower bits.
16. The source driver as claimed in claim 15, wherein the reference voltage generator includes:
an upper reference voltage generator configured to generate 2n upper reference voltages with respect to n upper bits, n being a positive integer, the 2n upper reference voltages being uniformly spaced by a first voltage amount; and
a lower reference voltage generator configured to generate 2n-1+1 lower reference voltages with respect to m lower bits, m being a positive integer, the 2n-1+1 lower reference voltages being uniformly spaced by a second voltage amount smaller than the first voltage amount.
17. The source driver as claimed in claim 15, further comprising:
a gamma correction circuit configured to receive a serial data signal and perform a gamma correction on the serial data signal to output a corrected serial data signal; and
a latch circuit configured to latch the corrected serial data signal sequentially and deserialize the latched values to generate the plurality of digital signals provided to the digital-to analog converters.
18. A display device comprising the source driver as claimed in claim 15.
19. The display device as claimed in claim 18, further comprising a gate driver, wherein the gate driver is configured to drive row lines of a display panel, and the source driver is configured to drive column lines of the display panel.
20. The display device as claimed in claim 19, wherein:
the display panel includes a plurality of pixels, the pixels being arranged in a matrix, each pixel including at least one transistor having a gate coupled to a row line and having an electrode coupled to a column line, and
a serial data signal is provided to the source driver, the serial data signal being converted by the source driver, the source driver outputting analog output voltages to the column lines so as to display images corresponding to the serial data signal.

The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.

What is claimed is:

1. An image generating apparatus having a plurality of exposure means for optically modulating image data to record a plurality of main scanning lines of the image data on a recording medium through a single main scanning operation, comprising:
image data selective output means for selecting the image data corresponding to said plurality of exposure means from the image data forming one of said main scanning lines and outputting the selected image data to said respective exposure means; and
control means for controlling operation of said image data selective output means in such a manner that said plurality of exposure means perform sequential scanning operation over said one main scanning line based on the image data issued from said image data selective output means to record the image data.
2. An image generating apparatus as set forth in claim 1, wherein
a plurality of image data selective output means are provided for said plurality of exposure means; and
said control means performs control operation in such a manner that, as a main scanning position of said plurality of exposure means advances by one line in a sub-scanning direction perpendicular to the main scanning direction, said plurality of exposure means record the image data simultaneously on a plurality of main scanning lines based on the image data issued from said image data selective output means.
3. An image generating apparatus as set forth in claim 1, wherein said image data selective output means includes change-over means for switching between a first mode in which a plurality of main scanning lines of image data to be simultaneously recorded are output to said associated exposure means and a second mode in which said image data selective output means selects image data corresponding to said plurality of exposure means from the image data of one main scanning line and outputs the selected image data to said respective exposure means.
4. An image generating apparatus as set forth in claim 2, wherein said image data selective output means includes change-over means for switching between a first mode in which a plurality of main scanning lines of image data to be simultaneously recorded are output to said associated exposure means and a second mode in which said image data selective output means selects image data corresponding to said plurality of exposure means from the image data of one main scanning line and outputs the selected image data to said respective exposure means.
5. An image generating apparatus having a plurality of exposure means for optically modulating image data to record a plurality of main scanning lines of the image data on a recording medium through a single main scanning operation, comprising:
image data divisionoutput means for dividing the image data forming one of said main scanning lines into predetermined gray shade levels of image data and outputting the divided image data to said respective exposure means; and
control means for controlling operation of said image data divisionoutput means in such a manner that said plurality of exposure means perform sequential scanning operation over said one main scanning line based on the image data issued from said image data divisionoutput means to record the image data.
6. An image generating apparatus as set forth in claim 5, wherein said plurality of exposure means irradiate exposure light beams having different exposure energies on said recording medium on the basis of image data received from said image data divisionoutput means and overlap the exposure light beams issued from the plurality of exposure means with respect to predetermined pixels to record the image data of the different gray shade levels.
7. An image generating apparatus as set forth in claim 5, wherein a plurality of image data divisionoutput means are provided for said plurality of exposure means.
8. An image generating apparatus as set forth in claim 6, wherein a plurality of image data divisionoutput means are provided for said plurality of exposure means.
9. An image generating apparatus as set forth in claims 5, wherein said image data divisionoutput means includes change-over means for switching between a first mode in which a plurality of main scanning lines of image data to be simultaneously recorded are output to said associated exposure means and a second mode in which said image data divisionoutput means divides image data of one of the main scanning lines into predetermined gray shade levels of image data and outputs the divided image data to said respective exposure means.
10. An image generating apparatus as set forth in claims 6, wherein said image data divisionoutput means includes change-over means for switching between a first mode in which a plurality of main scanning lines of image data to be simultaneously recorded are output to said associated exposure means and a second mode in which said image data divisionoutput means divides image data of one of the main scanning lines into predetermined gray shade levels of image data and outputs the divided image data to said respective exposure means.
11. An image generating apparatus as set forth in claims 7, wherein said image data divisionoutput means includes change-over means for switching between a first mode in which a plurality of main scanning lines of image data to be simultaneously recorded are output to said associated exposure means and a second mode in which said image data divisionoutput means divides image data of one of the main scanning lines into predetermined gray shade levels of image data and outputs the divided image data to said respective exposure means.

1. A switch adapted to be positioned on a pushrod of a hydraulic cylinder assembly and including a housing adapted to be positioned proximate an end of the hydraulic cylinder assembly and a plunger mounted for axial sliding movement in the housing, the housing and plunger being adapted to be fitted over the pushrod with a driving connection between the pushrod and the plunger whereby the plunger is moved slidably forwardly in the housing in response to forward movement of the pushrod for selective coaction between contact structure carried by the plunger and contact structure carried by the housing to generate a control signal, characterized in that:
the driving connection between the pushrod and the plunger includes anti-rotation structure on the plunger precluding rotation of the plunger relative to the pushrod.
2. A switch according to claim 1 wherein the plunger anti-rotation structure includes an anti-rotation pocket defined in the plunger and adapted to receive an anti-rotation structure on the pushrod.
3. A switch according to claim 2 wherein the pocket comprises a notch opening in a rear face of the plunger and adapted to receive a lug formed on the pushrod and sized to fit in the notch.
4. A switch according to claim 3 wherein:
the plunger and the housing define downwardly opening channels to facilitate fitting of the housing and plunger over the pushrod; and
the notch is defined in surrounding relation to the channel in the plunger.
5. A hydraulic master cylinder assembly including a master cylinder, a piston mounted in the master cylinder, a pushrod projecting at its forward end into the rear end of the master cylinder for connection to the piston, and a switch assembly positioned on the pushrod and including a hollow switch housing defining switch means and a plunger assembly mounted on and driven by the pushrod for sliding movement in the housing in response to forward movement of the pushrod to coact with the switch means to generate a control signal, characterized in that:
the driving connection between the pushrod and the plunger includes anti-rotation structure precluding rotation of the plunger relative to the pushrod.
6. A master cylinder assembly according to claim 5 wherein the anti-rotation structure includes an anti-rotation pocket defined in the plunger and an anti-rotation structure on the pushrod received in the pocket.
7. A hydraulic master cylinder assembly according to claim 6 wherein the pocket comprises a notch opening in a rear face of the plunger and the anti-rotation structure on the plunger comprises a lug sized to fit in the notch.
8. A hydraulic master cylinder assembly according to claim 7 wherein:
the driving connection comprises a shoulder on the pushrod pushingly engaging the plunger; and
the lug is formed at the shoulder.
9. A hydraulic master assembly according to claim 8 wherein:
the pushrod has a circular cross-sectional configuration and defines a central axis; and
the lug is constituted as an eccentricity formed on the pushrod proximate the shoulder.
10. A hydraulic master cylinder assembly according to claim 7 wherein:
the plunger and the housing define downwardly opening grooves to accommodate positioning of the switch assembly on the pushrod; and
the notch is formed in the rear face of the plunger in surrounding relation to the downwardly opening groove in the plunger.

The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.

1. A system (10) for synchronizing records of duty status, RODS, information of a vehicle with a stationary unit, comprising:
at least one mobile unit (100) configured to generate RODS, store the generated RODS, and transmit RODS; and
a stationary unit (300) configured to receive and store RODS transmitted by the at least one mobile unit,
wherein the at least one mobile unit (100) is further configured to transmit a newly generated first RODS to the stationary unit in an initial synchronization step of a synchronization process of synchronizing the RODS stored on the at least one mobile unit and the RODS stored on the stationary unit,
wherein the at least one mobile unit (100) is further configured to generate a checksum of the first RODS after transmission of the first RODS to the stationary unit and to transmit only the checksum of the first RODS to the stationary unit in a subsequent synchronization step of the synchronization process,
wherein the stationary unit (300) is configured to generate a checksum of the RODS received from the at least one mobile unit (100), wherein in the event of any discrepancy between the checksum generated by the at least one mobile unit (100) and the checksum generated by the stationary unit (300), the RODS from the stationary unit overrules the RODS from the mobile unit (100), and
wherein the checksum is generated according to a first checksum generation algorithm.
2. The system (10) according to claim 1,
wherein the at least one mobile unit is configured to store RODS of a multitude of operators and to identify an operator according to an operator identity.
3. The system (10) according to claim 1,
wherein the at least one mobile unit is configured to start the synchronization process after a login-event of an operator.
4. The system (10) according to claim 3,
wherein the at least one mobile unit and the stationary unit are configured to synchronize only the RODS of an operator logged on to the at least one mobile unit during the synchronization process.
5. The system (10) according to claim 1,
wherein the stationary unit (300) is configured to modify a RODS stored on the stationary unit.
6. The system (10) according to claim 1,
wherein the stationary unit (300) is configured to generate a checksum of the RODS stored on the stationary unit according to the first checksum generation algorithm.
7. The system (10) according to claim 6,
wherein the stationary unit (300) is configured to compare the generated checksum of the first RODS and the checksum of the first RODS transmitted by the at least one mobile unit and, if these checksums are not identical, transmit the first RODS from the stationary unit to the at least one mobile unit.
8. The system (10) according to claim 7,
wherein the at least one mobile unit is configured to overwrite the first RODS in case the stationary unit transmits a modified first RODS.
9. The system (10) according to claim 1,
wherein the at least one mobile unit (100) has a transmission element (130) configured to wirelessly transmit RODS to the stationary unit (300).
10. The system (10) according to claim 1,
wherein the at least one mobile unit (100) is mounted to a vehicle (200).
11. The system (10) according to claim 1,
wherein the stationary unit (300) is configured to receive RODS from a multitude of mobile units (100).