A Phase-locked loop circuit including: a local oscillator, configured to generate a timing signal; a variable-length shift register, controlled by the timing signal; and a feedback control circuit, which receives a pulsed input signal and receives a local signal from the shift register. The feedback control circuit detects whether each pulse of the input signal respects a condition of temporal proximity with a corresponding pulse of the local signal and detects, for each pulse of the input signal that respects the proximity condition, whether the edge falls early, late, or within a predefined portion of the corresponding pulse of the local signal. The feedback control circuit controls the length of the shift register and the frequency of the timing signal, as a function of the detections made.

A clock and data recovery circuit which includes a phase detector, a digital loop filter and a phase interpolator is provided according to an exemplary embodiment of the disclosure. The phase detector is configured to detect a phase difference between a data signal and a clock signal. The phase interpolator is configured to generate the clock signal according to an output of the digital loop filter. The digital loop filter is configured to operate automatically according a default value stored in the digital loop filter under an initial status, so as to establish a default phase shift or a default frequency difference of the clock signal with respect to the data signal before the data signal and the clock signal are compared.

A clock and data recovery circuit which includes a phase detector, a digital loop filter and a phase interpolator is provided according to an exemplary embodiment of the disclosure. The phase detector is configured to detect a phase difference between a data signal and a clock signal. The phase interpolator is configured to generate the clock signal according to an output of the digital loop filter. The digital loop filter is configured to operate automatically according a default value stored in the digital loop filter under an initial status, so as to establish a default phase shift or a default frequency difference of the clock signal with respect to the data signal before the data signal and the clock signal are compared.

A Phase-locked loop circuit including: a local oscillator, configured to generate a timing signal; a variable-length shift register, controlled by the timing signal; and a feedback control circuit, which receives a pulsed input signal and receives a local signal from the shift register. The feedback control circuit detects whether each pulse of the input signal respects a condition of temporal proximity with a corresponding pulse of the local signal (Voce) and detects, for each pulse of the input signal that respects the proximity condition, whether the edge falls early, late, or within a predefined portion of the corresponding pulse of the local signal. The feedback control circuit controls the length of the shift register and the frequency of the timing signal, as a function of the detections made.

A Phase-locked loop circuit including: a local oscillator, configured to generate a timing signal; a variable-length shift register, controlled by the timing signal; and a feedback control circuit, which receives a pulsed input signal and receives a local signal from the shift register. The feedback control circuit detects whether each pulse of the input signal respects a condition of temporal proximity with a corresponding pulse of the local signal (Voce) and detects, for each pulse of the input signal that respects the proximity condition, whether the edge falls early, late, or within a predefined portion of the corresponding pulse of the local signal. The feedback control circuit controls the length of the shift register and the frequency of the timing signal, as a function of the detections made.

Provided are a method and apparatus for controlling a skew between multiple data lanes. In the method and apparatus, a first data lane control stage controls control outputting first data over a first data lane based on a first data lane clock and a second data lane control stage controls outputting second data over a second data lane based on a second data lane clock. In the method and apparatus, a first device is associated with a system clock and is configured to generate the first and second data for outputting over the first and second data lanes. A clock control stage causes the first and second data lane clocks to be offset from each other by a fixed time duration that is an integer fraction of a cycle duration of the system clock.

Provided are a method and apparatus for controlling a skew between multiple data lanes. In the method and apparatus, a first data lane control stage controls control outputting first data over a first data lane based on a first data lane clock and a second data lane control stage controls outputting second data over a second data lane based on a second data lane clock. In the method and apparatus, a first device is associated with a system clock and is configured to generate the first and second data for outputting over the first and second data lanes. A clock control stage causes the first and second data lane clocks to be offset from each other by a fixed time duration that is an integer fraction of a cycle duration of the system clock.

Aspects of the present disclosure provide techniques and apparatus for synchronizing phase-locked loop (PLL) circuits. An example method of operating PLL circuits includes obtaining an indication to perform a synchronizing action at a first PLL circuit and a second PLL circuit; and performing the synchronizing action at the first PLL circuit and the second PLL circuit in response to obtaining the indication.

The subject technology provides for removing a source of delay in a phase-locked loop (PLL) by causing the output rising edge to occur at the same time as the input rising edge. The subject technology replicates the amount of delay experienced along an input reference signal path to the PLL as close as possible using a same circuit configuration and bias circuits as in the input reference signal path. For example, a timing alignment circuit containing a replica circuit adds compensation delay to a negative feedback loop signal to match the feedback loop delay with the reference path delay. The delay of the reference signal path is estimated and added into the replica circuit. The delay characteristics of these two paths negate one another such that the phases of the input reference signal and the feedback loop signal become phase-locked at the input to the PLL.

The subject technology provides for removing a source of delay in a phase-locked loop (PLL) by causing the output rising edge to occur at the same time as the input rising edge. The subject technology replicates the amount of delay experienced along an input reference signal path to the PLL as close as possible using a same circuit configuration and bias circuits as in the input reference signal path. For example, a timing alignment circuit containing a replica circuit adds compensation delay to a negative feedback loop signal to match the feedback loop delay with the reference path delay. The delay of the reference signal path is estimated and added into the replica circuit. The delay characteristics of these two paths negate one another such that the phases of the input reference signal and the feedback loop signal become phase-locked at the input to the PLL.