Some examples relate to a frequency synthesizer. The frequency synthesizer includes an oscillator including an input terminal and an output terminal. A frequency locked-loop or phase-locked loop (FLL/PLL) unit is arranged on a feedback path extending between the output terminal of the oscillator and the input terminal of the oscillator. A switching unit is configured to selectively switch between a first mode of operation in which the feedback path is closed and the FLL/PLL unit is coupled to the input terminal of the oscillator, and a second mode of operation in which the feedback path is open and a ramping unit is coupled to the input terminal of the oscillator while the feedback path is open.

An aspect relates to an apparatus including an input buffer including an input configured to receive an input voltage; a ramp voltage generator including an input coupled to an output of the input buffer; an evaluation circuit including an input coupled to an output of the ramp voltage generator, wherein the evaluation circuit includes a first resistor coupled in series with first field effect transistor (FET) between a first voltage rail and a second voltage rail; and an output buffer including an input coupled to a drain of the first FET and an output configured to generate an output voltage.

The present invention discloses a transceiver apparatus having phase-tracking mechanism. A phase detection circuit of a receiver circuit performs sampling and phase detection on an input data signal according to a sampling clock signal to generate a phase detection result. A proportional gain circuit of the receiver circuit applies a proportional gain operation on the phase detection result to generate a phase adjusting signal. A CDR circuit of the receiver circuit receives a source clock signal to generate the sampling clock signal and performs phase-adjusting according to the phase adjusting signal. The integral gain circuit apples an integral gain operation on the phase detection result to generate a frequency adjusting signal. The source clock generating circuit receives a reference clock signal to generate the source clock signal and perform frequency-adjusting according to the frequency adjusting signal. The transmitter circuit performs signal transmission according to the source clock signal.

A digital-to-time converter (DTC)-based open loop frequency synthesis and calibration circuit may be used to provide a precise clock signal. The DTC calibration circuit may include a DTC to generate a DTC clock signal based on a received input clock frequency and a received initial digital input code, a phase-lock loop (PLL) to generate a PLL clock signal based on a received PLL input, a binary phase-detector (PD) to generate a PD output based on a comparison between the DTC clock signal and the PLL clock signal, a plurality of calibration bins to generate a signed accumulated PD portion based on the PD output, and an adder to generate a calibrated DTC input code based on a combination of the signed accumulated PD portion and a subsequent digital input code, where the DTC generates a calibrated clock signal based on the calibrated DTC input code.

A method for controlling a phase-locked loop circuit, can include: acquiring values of a voltage-controlled oscillator capacitor array control signal respectively corresponding to desired values of a frequency control word signal and acquiring values of a charge pump current control signal respectively corresponding to the desired values of the frequency control word signal in a calibration mode, where the frequency control word signal characterizes a ratio of a desired locked frequency to a frequency of a reference signal; and determining a target value of the voltage-controlled oscillator capacitor array control signal corresponding to a target value of the frequency control word signal and a target value of the charge pump current control signal corresponding to the target value of the frequency control word signal in a phase-locked mode, in order to control the phase-locked loop circuit to achieve phase lock.

Systems and methods provide a fractional signal from a delta sigma modulator to a summer, a combination of an integer value and the fractional signal to a divider, and a divided clock signal from the divider in response to the combination and the input clock signal. The systems and methods also delay the divided clock signal in response to a truncation phase error and gain calibration factor from a calibration unit to provide an output clock signal having equal periods.

Described is an apparatus comprising: a multi-modulus divider; and a phase provider to receive a multiphase periodic signal and operable to rotate phases of the multiphase periodic signal to generate an output which is received by the multi-modulus divider.

An oscillator provides a plurality of clock signals, including a first clock signal having a first frequency and a first period, wherein each clock signal has the first frequency and is phase shifted from the first clock signal by an integer times a predetermined fractional amount of the first period. A multiphase frequency divider receives the plurality of clock signals and provides a divided clock output, and includes an integer frequency divider which provides the divided clock output based on a modified clock input and a clock selector which provides a current clock as the modified clock input during a first portion of the divided clock output and a next clock as the modified clock input during a subsequent portion of the divided clock output. The next clock is selected from the plurality of clock signals based on a selected fractional phase shift amount indicated by a sigma-delta modulator.

A plasma generation system includes a reference clock, a plurality of solid state generator modules, and a processing chamber. The reference clock is configured to generate a reference signal. Each solid state generator module is linked to an electronic switch and each electronic switch is linked to the reference clock. The solid state generator modules are each configured to generate an output based on the reference signal from the reference clock. The processing chamber is configured to receive the output of at least two of the solid state generator modules to combine the outputs of said solid state generator modules therein.

A phase-locked loop circuit includes a voltage controlled oscillator (VCO) that generates a VCO clock in response to a voltage control signal, a divider that divides the VCO clock to output a division clock, a phase-frequency error detector that receives a reference clock and outputs a first error compensation signal, a sampler that receives the reference clock and oversamples the reference clock at a rising edge or a falling edge to output a sampling clock, a window phase error detector that receives the reference clock and outputs a second error compensation signal, a residue phase error detector that outputs a third error compensation signal, an adder that accumulates the first error compensation signal, the second error compensation signal, and the third error compensation signal to output a final error compensation signal, and a loop filter that converts and output the final error compensation signal into the voltage control signal.