A signaling system is disclosed. The signaling system includes a first integrated circuit (IC) chip to receive a data signal and a strobe signal. The first IC includes circuitry to sample the data signal at times indicated by the strobe signal to generate phase error information and circuitry to output the phase error information from the first IC device. The system further includes a signaling link and a second IC chip coupled to the first IC chip via the signaling link to output the data signal and the strobe signal to the first IC chip. The second IC chip includes delay circuitry to generate the strobe signal by delaying an aperiodic timing signal for a first time interval and timing control circuitry to receive the phase error information from the first IC chip and adjust the first time interval in accordance with the phase error information.

There are provided examples of receivers, controller units and related methods, wherein one receiver includes: an adjustable sample provider configured to provide samples of an input signal using an adjustable sample timing; a feedback path configured to provide a feedback signal to the adjustable sample provider on the basis of a timing error, wherein the feedback path includes a loop filter configured to provide sample timing information to the adjustable sample provider; and a replacement value provider configured to provide a replacement sample timing information replacing the sample timing information provided by the feedback path when an input signal does not fulfil a predetermined requirement for a feedback-based sample timing adaptation, wherein the replacement value provider is configured to provide the replacement sample timing information considering a timing error information, or a quantity derived from the timing error information, over a longer time period when compared to a time period considered by the loop filter for a provision of the sample timing information.

A clock recovery circuit includes a multi-phase sampling circuit, a phase comparison circuit, a recovery clock generation circuit, and a phase shifter. The multi-phase sampling circuit includes edge samplers and data samplers. A data signal is input to each of the edge samplers and each of the data samplers. The phase comparison circuit is disposed at an output side of the multi-phase sampling circuit. The recovery clock generation circuit is configured to output multi-phase clock signals. The phase shifter is disposed between the recovery clock generation circuit and the multi-phase sampling circuit and configured to generate a plurality of clock signals to be supplied to the multi-phase sampling circuit by shifting a phase of a first one of the multi-phase clock signals output from the recovery clock generation circuit by a shift amount different from a shift amount of a second one of the multi-phase clock signals.

A clock recovery circuit includes a multi-phase sampling circuit, a phase comparison circuit, a recovery clock generation circuit, and a phase shifter. The multi-phase sampling circuit includes edge samplers and data samplers. A data signal is input to each of the edge samplers and each of the data samplers. The phase comparison circuit is disposed at an output side of the multi-phase sampling circuit. The recovery clock generation circuit is configured to output multi-phase clock signals. The phase shifter is disposed between the recovery clock generation circuit and the multi-phase sampling circuit and configured to generate a plurality of clock signals to be supplied to the multi-phase sampling circuit by shifting a phase of a first one of the multi-phase clock signals output from the recovery clock generation circuit by a shift amount different from a shift amount of a second one of the multi-phase clock signals.

An apparatus includes a slicer circuit, a frequency acquisition circuit, a phase acquisition circuit and an oscillator circuit. The slicer circuit may be configured to (i) generate an output signal by slicing a data signal in response to a clock signal and (ii) generate a crossing signal in response to the data signal and the clock signal. The frequency acquisition circuit may be configured to generate a first control signal and a second control signal in response to the data signal and the clock signal. The phase acquisition circuit may be configured to generate a third control signal in response to the first control signal and the data crossing signal. The oscillator circuit may be configured to generate the clock signal in response to the second control signal and the third control signal. The second control signal may shift an adjustable frequency range of the clock signal.

A short-reach data link receiver includes an edge detector configured to generate a pulse on an edge of a data input, a first clock-data recovery path coupled to an output of the edge detector for recovering a clock and data from the output of the edge detector, a second clock-data recovery path coupled to the output of the edge detector for recovering the clock and data from the output of the edge detector, and a controller configured to alternate between the first and second clock-data recovery paths to recover the clock and data using one of the paths while calibrating the other path. The controller may swap the paths whenever calibration of one path is completed. That may include beginning calibration of the next path immediately after swapping of the paths. Alternatively, power consumption may be reduced by delaying calibration of the next path after swapping of the paths.

A communication system according to one aspect of the present disclosure is a communication system in which a plurality of communication devices are connected to a network. The plurality of communication devices include a time master including a master clock that manages time of the communication system and a plurality of time slaves each of which includes a slave clock time-synchronized with the master clock. Each of the plurality of time slaves includes a synchronization unit that performs time synchronization with another communication device connected adjacent to a master side on the network and a communication unit that notifies the time master of time synchronization information indicating time synchronization accuracy of the own device obtained by the synchronization unit.

A circuit includes a phase and frequency detector circuit to generate a first phase detect signal indicative of whether a polarity of a first clock is the same as a polarity of a second clock upon occurrence of an edge of a data signal. The second clock being 90 degrees out of phase with respect to the first clock. A lock detect circuit determines, based on the first phase detect signal, that a third clock is one of frequency and phase locked to the data signal, frequency and quadrature locked to the data signal, and not frequency locked to the data signal.

There are provided examples of receivers, controller units and related methods, wherein one receiver includes: an adjustable sample provider configured to provide samples of an input signal using an adjustable sample timing; a feedback path configured to provide a feedback signal to the adjustable sample provider on the basis of a timing error, wherein the feedback path includes a loop filter configured to provide sample timing information to the adjustable sample provider; and a replacement value provider configured to provide a replacement sample timing information replacing the sample timing information provided by the feedback path when an input signal does not fulfil a predetermined requirement for a feedback-based sample timing adaptation, wherein the replacement value provider is configured to provide the replacement sample timing information considering a timing error information, or a quantity derived from the timing error information, over a longer time period when compared to a time period considered by the loop filter for a provision of the sample timing information.

A timing lock identification method is provided according to an embodiment of the disclosure. The method includes: generating one or more first phase adjustment pulses and one or more second phase adjustment pulses by a timing recovery circuit, where the one or more first phase adjustment pulses are configured to increase a phase of an output signal of an oscillator, and the one or more second phase adjustment pulses are configured to decrease the phase of the output signal; and obtaining a difference value between the number of the one or more first phase adjustment pulses and the number of the one or more second phase adjustment pulses in a detection window and determining whether the timing recovery circuit reaches a locking state of timing recovery according to the difference value. Furthermore, a signal receiving circuit is provided according to an embodiment of the disclosure.