A physical layer transceiver for a serial data channel includes receiver circuitry having a local clock. Received signals arrive on the channel according to a remote clock. Clock-data recovery circuitry aligns the local clock with the remote clock by correcting phase and frequency error between the local and remote clocks. The clock-data recovery circuitry includes digital phase error detection circuitry operating according to a digital clock to detect phase error between the local and remote clocks, analog phase rotation circuitry to correct the detected phase error, distribution circuitry to divide the detected phase error into multiple phase error steps, and an analog clock source configured to provide the local clock to the analog phase rotation circuitry, and to provide to the distribution circuitry a distribution clock that is slower than the local clock, to correct the local clock by at least one step during one digital clock period.

Systems, apparatuses, and methods for implementing a deskewing method for a physical layer interface on a multi-chip module are disclosed. A circuit connected to a plurality of communication lanes trains each lane to synchronize a local clock of the lane with a corresponding global clock at a beginning of a timing window. Next, the circuit symbol rotates each lane by a single step responsive to determining that all of the plurality of lanes have an incorrect symbol alignment. Responsive to determining that some but not all of the plurality of lanes have a correct symbol alignment, the circuit symbol rotates lanes which have an incorrect symbol alignment by a single step. When the end of the timing window has been reached, the circuit symbol rotates lanes which have a correct symbol alignment and adjusts a phase of a corresponding global clock to compensate for missed symbol rotations.

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.

A clock generator circuit includes: first to N.sup.th nodes, where N is an even number equal to or greater than 2; and a parallel-to-serial conversion circuit suitable for parallel-to-serial converting signals of the first to N.sup.th nodes to output a clock through an output node, wherein, in an activation section of the clock, the signals of even-numbered nodes among the first to N.sup.th nodes have a first level, and the signals of odd-numbered nodes among the first to N.sup.th nodes have a second level which is different from the first level, and wherein, in a deactivation section of the clock, the signals of the first to N.sup.th nodes have the same level.

Generating a composite interpolated phase-error signal for clock phase adjustment of a local oscillator by forming a summation of weighted phase-error signals generated using a matrix of partial phase comparators, each of which compare a phase of the local oscillator with a corresponding phase of a reference clock.

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.

A circuit for performing clock recovery according to a received digital signal. The circuit includes at least an edge sampler and a data sampler for sampling the digital signal, and a clock signal supply circuit. The clock signal supply circuit provides edge clock and data clock signals offset in phase from one another to the respective clock inputs of the edge sampler and the data sampler. A digital phase detector determines if the data clock is early, late or synchronized with respect to data value transitions in the digital signal, and based on that determination provides a phase adjustment signal to the clock signal supply circuit, which is operable to vary phases of the data and edge clock signals accordingly.

A memory controller includes a clock signal generator generating a clock signal; a first data receiving circuit receiving a serial signal having a plurality of logic values from a memory, using the serial signal to compensate for a phase error of the clock signal, and generating a phase-compensated clock signal as a first clock signal; and at least one second data receiving circuit receiving data from the memory, receiving the first clock signal from the first data receiving circuit, and using the first clock signal to recover the data.

A clock and data recovery circuit, a memory storage device and a signal adjustment method are disclosed. The method includes: detecting a phase difference between a first signal and a clock signal; generating a vote signal according to the phase difference and a first clock frequency; sequentially outputting a plurality of adjustment signals according to the vote signal and a second clock frequency, wherein the first clock frequency is different from the second clock frequency; and generating the clock signal according to the sequentially output adjustment signals.

A clock and data recovery circuit, a memory storage device and a signal adjustment method are disclosed. The method includes: detecting a phase difference between a first signal and a clock signal; generating a vote signal according to the phase difference and a first clock frequency; sequentially outputting a plurality of adjustment signals according to the vote signal and a second clock frequency, wherein the first clock frequency is different from the second clock frequency; and generating the clock signal according to the sequentially output adjustment signals.