Aspects of this disclosure relate to reducing settling time of a ramp signal in a phase-locked loop. An offset signal can be applied to adjust an input signal provided to an integrator of a loop filter of the phase-locked loop to cause the settling time to be reduced. Disclosed methods of reducing settling time of a ramp signal can improve settling time of a ramp signal independent of the profile of the ramp signal.

Aspects of this disclosure relate to reducing settling time of a ramp signal in a phase-locked loop. An offset signal can be applied to adjust an input signal provided to an integrator of a loop filter of the phase-locked loop to cause the settling time to be reduced. Disclosed methods of reducing settling time of a ramp signal can improve settling time of a ramp signal independent of the profile of the ramp signal.

Disclosed herein is an apparatus that includes a phase frequency detector configured to compare a phase difference between first and second clock signals to generate a phase detection signal, and a slew rate controller configured to lower a slew rate of the first clock signal when a selection signal is in a first state.

Disclosed herein is an apparatus that includes a phase frequency detector configured to compare a phase difference between first and second clock signals to generate a phase detection signal, and a slew rate controller configured to lower a slew rate of the first clock signal when a selection signal is in a first state.

Disclosed herein is an apparatus that includes a phase frequency detector configured to compare a phase difference between first and second clock signals to generate a phase detection signal, and a slew rate controller configured to lower a slew rate of the first clock signal when a selection signal is in a first state.

Disclosed herein is an apparatus that includes a phase frequency detector configured to compare a phase difference between first and second clock signals to generate a phase detection signal, and a slew rate controller configured to lower a slew rate of the first clock signal when a selection signal is in a first state.

A display device including: a timing controller outputting a reference clock signal and a data packet, wherein the data, packet includes a clock signal embedded in a data signal; a clock and data recovery (CDR) circuit receiving the reference clock signal and the data packet; and a display panel displaying an image based on the data packet, wherein, when the CDR circuit receives the reference clock signal, a frequency band of the reference clock signal is detected using a first internal clock signal, a parameter associated with jitter characteristics of the clock and data recovery circuit is adjusted according to the detected frequency band, and a second internal clock signal is output by adjusting a frequency of the first internal clock signal and when the CDR circuit receives the data packet, the data signal and a clock signal synchronized with the data signal are recovered from the data packet.

The system includes an intermediate-frequency (IF) synthesizer that generates an IF signal based on a reference signal, and a sub-sampling PLL (SSPLL) that generates a high-frequency output signal based on an input. A switch selects either the reference signal or the IF signal to be the input to the SSPLL. When the reference signal is the input to the SSPLL, the frequency synthesizer operates in a low-noise normal-operating mode, and when the IF signal is the input to the SSPLL, the frequency synthesizer operates in a higher-noise, frequency-acquisition mode. A sub-sampling lock detector (SSLD) determines whether the frequency synthesizer becomes unlocked during the normal-operating mode, and if so, activates the switch to move the system into the frequency-acquisition mode. It also determines whether the frequency synthesizer becomes relocked to the target frequency during the frequency-acquisition mode, and if so, activates the switch to move the system into the normal-operating mode.

In a computer system, a phase-locked loop circuit may generate a clock signal using a reference signal. The phase-locked loop circuit may include a programmable divider stage that includes multiple divider stages. When a frequency calibration is initiated on the phase-locked loop circuit, a control circuit may generate a pause signal in response to one or more of the divider stages reaching a particular logic state. The programmable divider stage may hold the one or more of the divider stages in the particular logic state using the pause signal.

An apparatus is provided to improve lock time of a phase locked loop, wherein the apparatus comprises: a ring oscillator including at least two delay stages, wherein each delay stage has a controllable delay; and a multiphase frequency monitor coupled to the ring oscillator to monitor frequency at an output of at least two delay stages of the ring oscillator.