Various embodiments of the present technology may comprise methods and apparatus for an amplifier circuit. Methods and apparatus for an amplifier circuit according to various aspects of the present invention may comprise a first cross-connect circuit configured to receive an input signal at an input terminal and transmit the input signal to an input stage circuit. The amplifier circuit may further comprise a second cross-connect circuit connected between the input stage circuit and an output stage circuit, and a voltage adjustment circuit connected to the input stage circuit. Each cross-connect circuit may comprise a plurality of switches.

A multi-phase clock generator circuit includes a phase reference generator circuit configured to generate a phase reference signal in response to a phase selection signal and a peak ramp signal. A phase error correction circuit is configured to provide an error signal based on a synchronization clock signal and a multi-phase clock signal. The error signal is applied to the phase reference signal to correct for phase errors in the multi-phase clock signal. A comparator is configured to compare a ramp signal and the phase reference signal to produce the multi-phase clock signal.

The present disclosure relates to a circuit and method of operation thereof for linearized time amplifier architecture for sub-picosecond resolution. More particularly, the disclosure is directed to an asymmetric edge manipulator whose output is fed to four series of transistors and is operatively coupled to a reset. The disclosure relates to outputting a pair of signals that correspond to a first input and second input of a known and measured clock that may be adjustable with gain to be perceptible to an external device that can then correct for the gain to allow measurement of sub-picosecond resolution.

A clock generation circuit includes: a two-phase clock generation circuit including first and second branches correspondingly configured to generate a first phase clock signal and a second phase clock signal based correspondingly on a non-inverted clock signal and an inverted clock signal, the first and second branches being cross-coupled with each other; an inverter configured to generate the inverted clock signal based on an input clock signal; and a delay circuit which is non-inverter-based and which is configured to generate the non-inverted clock signal based on the input clock signal, the delay circuit having a predetermined delay.

Methods and apparatus to increase efficiency of a power converter using a bias voltage on a low side drive gate are disclosed. An example power converter includes an inductor; a transistor coupled to the inductor; and a driver coupled to a gate of the transistor, the driver to apply (A) a first voltage to the gate to enable the transistor, (B) a second voltage to the gate to disable the transistor, and (C) a third voltage to the gate during a transition between applying the first voltage and the second voltage, the third voltage being between the first voltage and the second voltage.

A circuit system may include a first stage circuit configured to generate two pairs of signals in response to an input signal. The circuit system may also include a second stage circuit that is configured to combine a first signal of a first pair with a first signal of a second pair to generate a first combined signal, and to combine a second signal of the first pair with a second signal of the second pair to generate a second combined signal. Transistors of the second stage circuit may be sized in relation to transition timings of the first and second pairs of signals such that skew and duty cycle distortion is minimized between the first and second combined signals.

A clock synchronization signal generator generates a dead time in which gates of both of two switching elements included in a switching circuit are in an off state, and generates the dead time for controlling a plurality of pulses having different widths to pulses having a constant width, which is output by the switching circuit.

Various embodiments of the present technology may comprise methods and apparatus for an amplifier circuit. Methods and apparatus for an amplifier circuit according to various aspects of the present invention may comprise a first cross-connect circuit configured to receive an input signal at an input terminal and transmit the input signal to an input stage circuit. The amplifier circuit may further comprise a second cross-connect circuit connected between the input stage circuit and an output stage circuit, and a voltage adjustment circuit connected to the input stage circuit. Each cross-connect circuit may comprise a plurality of switches.

A multi-phase clock generator circuit includes a phase reference generator circuit configured to generate a phase reference signal in response to a phase selection signal and a peak ramp signal. A phase error correction circuit is configured to provide an error signal based on a synchronization clock signal and a multi-phase clock signal. The error signal is applied to the phase reference signal to correct for phase errors in the multi-phase clock signal. A comparator is configured to compare a ramp signal and the phase reference signal to produce the multi-phase clock signal.

The disclosure relates to technology for generating multi-phase signals. An apparatus includes 2{circumflex over ()}n phase signal generation stages. The apparatus also includes a controller configured to provide a mode input of each of the 2{circumflex over ()}n stages with an active periodic binary signal with remaining inputs of each of the 2{circumflex over ()}n stages provided with another periodic binary signal to collectively generate a 2{circumflex over ()}n phase signal in a first mode. The controller is further configured to provide the mode input of each of 2{circumflex over ()}(n1) odd stages with a first steady state signal and the mode input of each of 2{circumflex over ()}(n1) even stages with a second steady state signal with remaining inputs of each of the 2{circumflex over ()}n stages provided with the same periodic binary signal as in the first mode to cause either the 2{circumflex over ()}(n1) odd stages or the 2{circumflex over ()}(n1) even stages to collectively generate a 2{circumflex over ()}(n1) phase signal in a second mode.