Abstract: A circuit includes a first power node having a first voltage level, and an output node. A driver transistor coupled between the first power and output nodes is turned on and off responsive to first and second input signal edge types, respectively. A driver transistor source is coupled with the first power node. A contending circuit includes a slew rate detection circuit that generates a feedback signal based on an output node signal, and a contending transistor between a driver transistor drain and a second voltage. A contending transistor gate receives a control signal based on the feedback signal. The second voltage has a level less than the first voltage level if the output node signal rises responsive to the first input signal edge type, and greater than the first voltage level if the output node signal falls responsive to the first input signal edge type.

Abstract: A transimpedance amplifier includes a first inverter having a first input node and a first output node. The first input node is configured to receive an input signal. A second inverter has a second input node and a second output node. The second input node connects to a reference voltage terminal. The first inverter and the second inverter are configured to provide a differential output voltage signal between the first output node and the second output node. A first amplifier is configured to provide feedback to the first input node and a second amplifier is configured to provide feedback to the second input node.

Abstract: A circuit includes a first power node, an output node, a driver transistor coupled between the first power node and the output node, and a contending circuit. The driver transistor is configured to be turned on responsive to an edge of a first type of an input signal and to be turned off responsive to an edge of a second type of the input signal. The driver transistor has a source, a drain, and a gate, and the source of the driver transistor is coupled with the first power node. The contending circuit includes a control circuit configured to generate a control signal based on a signal at a gate of the driver transistor; and a contending transistor between the drain of the driver transistor and a second voltage. The contending transistor has a gate configured to receive the control signal.

Abstract: A circuit includes a first power node, an output node, a driver transistor coupled between the first power node and the output node, and a contending circuit. The driver transistor is configured to be turned on responsive to an edge of a first type of an input signal and to be turned off responsive to an edge of a second type of the input signal. The driver transistor has a source, a drain, and a gate, and the source of the driver transistor is coupled with the first power node. The contending circuit includes a control circuit configured to generate a control signal based on a signal at a gate of the driver transistor; and a contending transistor between the drain of the driver transistor and a second voltage. The contending transistor has a gate configured to receive the control signal.

Abstract: A voltage supply unit includes a regulator unit, a current mirror, and a cascode unit. The regulator unit is configured to receive first and second voltage signals and generate a third voltage signal. The current mirror is configured to generate first and second current signals based on the third voltage signal. The cascode unit includes a first terminal configured to receive the first current signal, a second terminal configured to receive a first bias voltage signal, a third terminal configured to receive a second bias voltage signal, and a fourth terminal electrically connected to the regulator unit. An output voltage supply signal is controlled by the second current signal.

Abstract: A multi-stage transimpedance amplifier (TIA) which includes a common gate amplifier configured to receive a current signal, the common gate amplifier is configured to convert the current signal into an amplified voltage signal. The multi-stage TIA further includes a capacitive degeneration amplifier configured to receive the amplified voltage signal, the capacitive degeneration amplifier is configured to equalize the amplified voltage signal to form an equalized signal. The multi-stage TIA further includes an inverter configured to receive the equalized signal, the inverter is configured to increase a signal strength of the equalized signal to form an output signal. The multi-stage TIA further includes a feedback configured to receive the output signal, wherein the feedback is connected to an input and an output of the inverter.

Abstract: A circuit includes a capacitive-load voltage controlled oscillator having an input configured to receive a first input signal and an output configured to output an oscillating output signal. A calibration circuit is coupled to the voltage controlled oscillator and is configured to output one or more control signals to the capacitive-load voltage controlled oscillator for adjusting a frequency of the oscillating output signal. The calibration circuit is configured to output the one or more control signals in response to a comparison of an input voltage to at least one reference voltage.

Abstract: A voltage supply unit including a regulator unit, a voltage divider and a first current mirror. The regulator unit is configured to receive a first voltage signal and a second voltage signal, and is configured to generate a third voltage signal. The voltage divider is connected between the first current mirror and the regulator unit, and controls the second voltage signal. The first current mirror is connected to the regulator unit, an input voltage supply and the voltage divider. The first current mirror is configured to generate a first current signal and a second current signal, the second current signal is mirrored from the first current signal, the first current signal is controlled by the third voltage signal and the second current signal controls an output voltage supply signal.

Abstract: A circuit includes a summation circuit for receiving an input data signal and a feedback signal including a previous data bit. The summation circuit is configured to output a conditioned input data signal to a clock and data recovery circuit. A first flip-flop is coupled to an output of the summation circuit and is configured to receive a first set of bits of the conditioned input data signal and a first clock signal having a frequency that is less than a frequency at which the input data signal is received by the first summation circuit. A second flip-flop is coupled to the output of the summation circuit and is configured to receive a second set of bits of the conditioned input data signal and a second clock signal having a frequency that is less than the frequency at which the input data signal is received by the first summation circuit.

Abstract: An initialization device for a charge pump includes a driving circuit and a bias voltage circuit. The driving circuit is between two power supply nodes. The driving circuit includes a first node configured to be coupled to an output electrode of a capacitor in the charge pump. The bias voltage circuit is coupled to the two power supply nodes. The bias voltage circuit includes a second node coupled to a control terminal of the driving circuit. In response to an applied initialization signal, the bias voltage circuit is configured to output a bias voltage to the second node. The bias voltage has at least two levels that correspond to levels of the applied initialization signal. In response to the bias voltage, the driving circuit is configured to output an output signal having at least two levels that correspond to the at least two levels of the bias voltage.

Abstract: A circuit includes a first power node, a second power node, an output node, a plurality of first transistors and a plurality of second transistors. The plurality of first transistors is serially coupled between the first power node and the output node. The plurality of second transistors is serially coupled between the second power node and the output node.

Abstract: A delay line circuit includes a plurality of delay circuits and a variable delay line circuit. The plurality of delay circuits receives an input signal and to generate a first output signal. The first output signal corresponds to a delayed input signal or an inverted input signal. The variable delay line circuit receives the first output signal. The variable delay line circuit includes an input end, an output end, a first and a second path. The input end is configured to receive the first output signal. The output end is configured to output a second output signal. The first path includes a first plurality of inverters and a first circuit. The second path includes a second plurality of inverters and a second circuit. The received first output signal is selectively transmitted through the first or second path based on a control signal received from a delay line controller.

Abstract: A circuit includes a first power node configured to carry a voltage K·VDD, a second power node configured to carry a zero reference level, an output node, K P-type transistors serially coupled between the first power node and the output node, and K N-type transistors serially coupled between the second power node and the output node. Gates of the K P-type transistors are configured to receive biasing signals set at one or more voltage levels in a manner that one or more absolute values of source-gate voltages or absolute values of drain-gate voltages are equal to or less than VDD. Gates of the K N-type transistors are configured to receive biasing signals set at one or more voltage levels in a manner that one or more absolute values of gate-source voltages or gate-drain voltages are equal to or less than VDD.

Abstract: A current value of a first pixel and/or a current value of a second pixel of a display are adjusted until a value of a current difference is within a predetermined range. The current value of the first pixel corresponds to a brightness level of the first pixel. The current value of the second pixel corresponds to a brightness level of the second pixel. Adjusting the current value of the first pixel involves adjusting a threshold voltage value of a transistor of the first pixel. Adjusting the current value of the second pixel involves adjusting a threshold voltage value of a transistor of the second pixel.

Abstract: In an initialization phase of a charge pump, an input signal is supplied to an input electrode of a capacitor of the charge pump and to an initialization device of the charge pump. An initialization signal is supplied to the initialization device of the charge pump. The initialization device supplies an output signal to an output electrode of the capacitor. The output signal has a high level and a low level corresponding to a high level and a low level of the input signal, the input signal and the output signal causing a charge to be accumulated in the capacitor. In a pumping operation phase following the initialization phase, the initialization signal is removed from the initialization device to place the output electrode of the capacitor in a floating state, and a pumping action is performed with the charge accumulated in the capacitor.

Abstract: A delay line circuit comprises a plurality of delay units configured to receive an input signal and modify the input signal to produce a first output signal. The delay line circuit also comprises a variable delay line unit that comprises an input end configured to receive the first output signal; an output end configured to output a second output signal; a first line between the input end and the output end, the first line comprising, in series, a first inverter, a second inverter, a first speed control unit, and a third inverter; a second line between the input end and the output end, the second line comprising, in series, a fourth inverter, a second speed control unit, a fifth inverter, and a sixth inverter. The delay line circuit is also configured to selectively transmit the received first output signal through one of the first line or the second line.

Abstract: A voltage supply unit including a regulator unit, a voltage divider and a first current mirror. The regulator unit is configured to receive a first voltage signal and a second voltage signal, and is configured to generate a third voltage signal. The voltage divider is connected between the first current mirror and the regulator unit, and controls the second voltage signal. The first current mirror is connected to the regulator unit, an input voltage supply and the voltage divider. The first current mirror is configured to generate a first current signal and a second current signal, the second current signal is mirrored from the first current signal, the first current signal is controlled by the third voltage signal and the second current signal controls an output voltage supply signal.

Abstract: In an initialization phase of a charge pump, an input signal is supplied to an input electrode of a capacitor of the charge pump and to an initialization device of the charge pump. An initialization signal is supplied to the initialization device of the charge pump. The initialization device supplies an output signal to an output electrode of the capacitor. The output signal has a high level and a low level corresponding to a high level and a low level of the input signal, the input signal and the output signal causing a charge to be accumulated in the capacitor. In a pumping operation phase following the initialization phase, the initialization signal is removed from the initialization device to place the output electrode of the capacitor in a floating state, and a pumping action is performed with the charge accumulated in the capacitor.

Abstract: A delay line circuit comprises a plurality of delay units configured to receive an input signal and modify the input signal to produce a first output signal. The delay line circuit also comprises a variable delay line unit that comprises an input end configured to receive the first output signal; an output end configured to output a second output signal; a first line between the input end and the output end, the first line comprising, in series, a first inverter, a second inverter, a first speed control unit, and a third inverter; a second line between the input end and the output end, the second line comprising, in series, a fourth inverter, a second speed control unit, a fifth inverter, and a sixth inverter. The delay line circuit is also configured to selectively transmit the received first output signal through one of the first line or the second line.

Abstract: A circuit includes a first power node configured to carry a voltage K·VDD, a second power node configured to carry a zero reference level, an output node, K P-type transistors serially coupled between the first power node and the output node, and K N-type transistors serially coupled between the second power node and the output node. Gates of the K P-type transistors are configured to receive biasing signals set at one or more voltage levels in a manner that one or more absolute values of source-gate voltages or absolute values of drain-gate voltages are equal to or less than VDD. Gates of the K N-type transistors are configured to receive biasing signals set at one or more voltage levels in a manner that one or more absolute values of gate-source voltages or gate-drain voltages are equal to or less than VDD.