A method and/or apparatus for tuning a frequency synthesizer device toward a prescribed frequency may input a signal into the input of the frequency synthesizer to produce an output signal having an output frequency, select a first one of a set of the above noted prescribed coarse curves, and compare the magnitude of the difference between the prescribed frequency and the output frequency. Next, the method selects a second of the set of coarse curves as a function of the magnitude of the difference between the prescribed frequency and the output frequency. Preferably, the method selects the second of the set of coarse curves by selecting one or more of the coarse curves out of the sequential frequency order as a function of the magnitude of the difference between the prescribed frequency and the output frequency.

Described is an integrated circuit (IC) with a phase locked loop with capability of fast locking. The IC comprises: a node to provide a reference clock; a digitally controlled oscillator (DCO) to generate an output clock; a divider coupled to the DCO, the divider to divide the output clock and to generate a feedback clock; and control logic operable to reset the DCO and the divider, and operable to release reset in synchronization with the reference clock. An apparatus for zeroing phase error is provided which comprises a first node to provide a reference clock; a second node to provide a feedback clock; a time-to-digital converter, coupled to the first and second nodes, to measure phase error between the reference and feedback clocks; a digital loop filter; and a control unit to adjust the measured phase error, and to provide the adjusted phase error to the digital loop filter.

A digital phased lock loop includes a digital controlled oscillator configured to produce an output signal at an output signal frequency, and a phase comparator configured to compare the output signal or a signal derived from the output signal, with a reference signal at a reference signal frequency or a signal derived from the reference signal to produce a phase error signal. A first loop filter produces a first control signal for the digital controlled oscillator. A frequency error measuring circuit produces a frequency error signal that directly represents a frequency difference between the output signal frequency and the reference signal frequency. A second loop filter produces a second control signal for the digital controlled oscillator from an output of the frequency error measuring circuit. A circuit combines the first and second control signals and providing the combined control signals to the digital controlled oscillator.

A method of generating an output signal includes determining a sampling period N according to a number of most significant bits (MSBs) of a divider number control signal. The method also includes determining a first logic value of a control signal by a comparing circuit based on the sampling period N, and generating a coarse tuning signal by a code generating circuit based on a phase difference signal and the control signal. When an M-th least significant bit (LSB) of the number of MSBs of the divider number control signal equals a second logic value, the sampling period N is set based on the M-th LSB of the number of MSBs of the divider number control signal.

A method and apparatus and computer program product for calibrating a Phase Lock Loop (PLL) that reduces a PLL lock time for subsequent calibrations to thereby improve an overall system time and latency. The system and method for calibrating obviates effect of Process, Voltage and Temperature to achieve a faster PLL lock.

A time-to-digital converter (TDC) circuit generates a digital output indicating a time, known as a phase difference, from a phase of the generated signal to a corresponding phase of a reference signal. The digital output is used by the digitally controlled oscillator (DCO) to correct for the phase/frequency difference to synchronize the generated signal with the reference signal. In an aspect, an adaptive TDC circuit generates a first digital indication in a coarse mode when the offset time is above a threshold and generates a second digital indication in a fine mode when the offset time is below the threshold. The first digital indication and the second digital indication each comprise a same number of bits, and the first digital indication is normalized to the second digital indication for the digital output of the adaptive TDC circuit. A fractional bit may be employed to compensate for a quantization error.

Disclosed is technology related to a signal synthesis apparatus that corrects an offset between a closed loop and an open loop to output a frequency-modulated signal. The signal synthesis apparatus includes a VCO configured to modulate and output a frequency signal in response to an input voltage by including a modulation cap bank having a plurality of capacitors, an energy storage unit configured to output a voltage using stored energy, a VCO input selector configured to connect the VCO to input of the energy storage unit in the case of a closed loop mode and connect the VCO to output of the energy storage unit in the case of an open loop mode, and a digital controller configured to control an operation mode of the VCO input selector and transmit a modulation control signal for adjusting a connection state of the capacitors of the modulation cap bank to the VCO.

Methods and systems of real-time frequency calibration for a segmented-VCO-based PLL are disclosed. The calibration method includes: receiving a request to lock the PLL to an output frequency; looking up a segment selection signal corresponding to the output frequency and controlling operation of a VCO core according to the segment selection signal to lock the PLL to the output frequency; obtaining a tuning voltage input to the VCO core to determine whether the tuning voltage is normal. If the tuning voltage is abnormal, the segment selection signal is adjusted for segment switching or even VCO core switching. This invention allows frequency segment adjustment in advance by adjusting the segment selection signal when the tuning voltage is abnormal, thus ensuring that the output frequency of the VCO core always remains within a frequency segment having a matched frequency range.