A differential-logic logic circuit chained with another differential-logic circuit comprises a first logic cell composed of back-gate transistors, the first cell having a first input for receiving a first input signal and having an output for delivering a first output signal, and a second logic cell complementary to the first cell, composed of back-gate transistors, the second cell having as many inputs as the first cell, each input able to receive an input signal complementary to the respective input signal of the first cell, the second cell having an output for delivering a second output signal complementary to the first output signal of the first cell. The first output signal of the first cell is applied to the back gate of each transistor of the second cell, and the second output signal of the second cell is applied to the back gate of each transistor of the first cell.

An area efficient amplifier that amplifies a continuous-time continuous-amplitude signal and converts it to a discrete-time discrete-amplitude signal. The amplifier includes a first oscillator having an input and a plurality of N outputs and a second oscillator having an input and N outputs. The amplifier includes N phase detectors, each phase detector has a first input, a second input, a first output, and a second output, where each first input of each phase detector is coupled to respective one of the N outputs of the first oscillator, where each second input of each phase detector is coupled to respective one of the N outputs of the second oscillator. The amplifier includes N quantizers, each quantizer has a data input, a clock input, and an output, where each data input of each quantizer is coupled to respective one first output or one second output of the N phase detectors.

Time measuring circuitry has a ring oscillator, a time-to-digital converter, a time measurer and a phase randomizer. The ring oscillator has a plurality of delay circuitries connected in a ring shape, the ring oscillator adjusting delay times of the plurality of delay circuitries based on an oscillation control signal to generate an oscillation signal. The time-to-digital converter quantizes a phase of the oscillation signal at a transition timing of a reference signal. The phase synchronizing circuitry to generate the oscillation control signal based on an output signal of the time-to-digital converter so that a phase of the oscillation signal coincides with a phase of the reference signal. The time measurer to measure a time interval based on the output signal of the time-to-digital converter. The phase randomizer to randomly shift the phase of the oscillation signal to be locked by the phase synchronizing circuitry.

An area efficient amplifier that amplifies a continuous-time continuous-amplitude signal and converts it to a discrete-time discrete-amplitude signal. The amplifier includes a first oscillator having an input and a plurality of N outputs and a second oscillator having an input and N outputs. The amplifier includes N phase detectors, each phase detector has a first input, a second input, a first output, and a second output, where each first input of each phase detector is coupled to respective one of the N outputs of the first oscillator, where each second input of each phase detector is coupled to respective one of the N outputs of the second oscillator. The amplifier includes N quantizers, each quantizer has a data input, a clock input, and an output, where each data input of each quantizer is coupled to respective one first output or one second output of the N phase detectors.

An oscillation circuit includes: an oscillator configured to generate N phase clocks (where N is an integer of 2 or more) including a first phase clock to Nth phase clock whose phases are shifted by 360/N at regular intervals; a pulse generating part configured to receive a plurality of the N phase clocks and generate a plurality of intermediate pulses each having a duty ratio of 25%; and a clock synthesizing part configured to synthesize the plurality of intermediate pulses to generate a single phase output clock or multi-phase output clocks, the single phase output clock and the multi-phase output clocks having a frequency that is twice an oscillation frequency of the oscillator.

Systems and methods are disclosed for wide frequency range voltage controlled oscillators. For example, an apparatus includes a Voltage Controlled Oscillator (VCO) including a delay cell which includes first and second current sources provided in parallel with one another. The first current source is controlled by a voltage control input connected to a voltage control terminal and the second current source is controlled by a bias voltage input connected to a bias voltage terminal. The first current source provides an alternate current path in the delay cell when the second current source is off. The delay cell is operable to receive an input and produce an output using the alternate current path.

A time delay circuit comprising a plurality of differential delay cells each having a respective time delay and being arranged in series. Each delay cell comprises first and second inverter sub-cells, each comprising a respective PMOS transistor and an NMOS transistor arranged in series such that their respective drain terminals are connected at a drain node. Each of the transistors has a back-gate terminal and is arranged such that a respective voltage applied to said back-gate terminal linearly controls its respective threshold voltage. The back-gate terminal of the PMOS transistor in each inverter sub-cell is connected to the drain node of the other sub-cell and/or the back-gate terminal of the NMOS transistor in each inverter sub-cell is connected to the drain node of the other sub-cell. A control signal varies the time delay of the delay cell by adjusting a voltage supplied to a back-gate terminal of a transistor.

The present disclosure relates to a ring-oscillator with glitch-free frequency-tuning. The disclosed ring-oscillator at least includes multiple delay stages coupled in series within a ring loop and having a first delay stage, a capacitor bank coupled between an output of the first delay stage and ground, and a timing block configured to receive an output signal of the first delay stage and at least one controlling signal. The at least one controlling signal determines at least one capacitor in the capacitor bank connecting or disconnecting to the ring loop. The timing block is configured to pass or not pass the at least one controlling signal to the capacitor bank based on whether the output signal of the first delay stage meets a certain condition. Therefore, the connection or disconnection of the at least one capacitor does not cause a significant voltage change at the output of the first delay stage.

An RF power amplifier includes a quadrature coupler, an in-phase amplifier, a quadrature amplifier, and a feed-forward signal path. The quadrature coupler includes an in-phase input node, a quadrature input node, an isolated node, and an RF signal output node. The in-phase amplifier includes an in-phase amplifier output node coupled to the in-phase input node. The quadrature amplifier includes a quadrature amplifier output node coupled to the quadrature input node. The feed-forward signal path is configured to couple and condition a signal from one of the in-phase amplifier and the quadrature amplifier in order to provide a feed-forward output signal that when provided at the feed-forward output node cancels one or more harmonic signals.

Representative implementations of devices and techniques provide reduced jitter for a controlled oscillator. An edge of a reference signal is injected at various points within the oscillator, and is replaced for an edge of the generated oscillation signal at the injection point.