A phase-rotating phase locked loop (PLL) may include first and second loops that share a loop filter and a voltage controlled oscillator in order to perform the operation of a phase-rotating PLL, the first and second loops configured to activate in response to an enable signal. The PLL may further include a phase frequency detection controller configured to provide the enable signal to the first and second loops in response to a transition of a coarse signal that may be applied as a digital code.

Systems and methods are provided for a phase locked loop. A phase/frequency detector is configured to receive a reference signal and a feedback signal. A charge pump is configured to receive outputs from the phase/frequency detector and to generate pulses. An oscillator is configured to generate an output waveform based on the charge pump pulses. A realignment path is configured to generate a clock realignment signal that is provided to the oscillator based on the outputs from the phase/frequency detector.

Systems and methods are provided for a phase locked loop. A phase/frequency detector is configured to receive a reference signal and a feedback signal. A charge pump is configured to receive outputs from the phase/frequency detector and to generate pulses. An oscillator is configured to generate an output waveform based on the charge pump pulses. A realignment path is configured to generate a clock realignment signal that is provided to the oscillator based on the outputs from the phase/frequency detector.

Semiconductor devices for synchronizing networks are described. A semiconductor device can include a phase lock loop of a timing circuit. The phase lock loop includes a voltage-controlled oscillator, a sub-sampling phase lock loop circuit and a frequency correction loop circuit. The frequency correction loop circuit is configured to activate a charge pump to inject a charge into the voltage-controlled oscillator based on a phase difference between a reference signal and a feedback signal being greater in magnitude than a deadzone delay parameter plus a hysteresis delay parameter and de-activate the charge pump based on the magnitude of the phase difference between the reference signal and the feedback signal falling below the deadzone delay parameter.