A method for transferring first and second encoded client clock signals over a carrier clock domain between integrated circuits, including in a first integrated circuit encoding a phase change of the first client clock signal from a last recorded phase onto the carrier clock signal in first bit positions, encoding a phase change of the second client clock signal from a last recorded phase onto the carrier clock signal in second bit positions different from the first bit positions, and transmitting the carrier clock signal with the encoded phases of the first client clock signal and the second client clock signal over a single wire from the first integrated circuit to a second integrated circuit.

Embodiments of the present disclosure describe methods, apparatuses, and systems for phase-lock loop (PLL) configuration and realization to provide various reference clock frequencies to computing core(s) and processor(s), and other benefits. A post digitally-controlled oscillator (DCO) divider (PDIV) of the PLL may be configured with a dedicated PDIV threshold value corresponding to a dedicated target reference frequency.

A clock and data recovery (CDR) system includes a correlator configured to receive data, determine a first value of the received data, and output a second value corresponding to the received data, an accumulator configured to generate an accumulation value by accumulating the second value output from the correlator and output the accumulation value, and a state machine configured to determine whether a repeating pattern is present in the CDR system based on the accumulation value.

A first clock signal is generated from a reference clock signal. A first frequency associated with the first clock signal is less than a reference clock frequency associated with the reference clock signal. The first clock signal is propagated towards a first component of an integrated circuit through a clock tree. A second clock signal having a second frequency is generated from the first clock signal at a terminal point of the clock tree. The second clock signal is provided to the first component.

A phase detector using nonlinearities to distort and compress waveforms of the reference and the unknown sources. This waveform distortion creates a region of phase in which the slew rate is greater than that of the input sinusoid, enabling a larger phase detector constant.

A first clock signal is generated from a reference clock signal. A first frequency associated with the first clock signal is less than a reference clock frequency associated with the reference clock signal. The first clock signal is propagated towards a first component of an integrated circuit through a clock tree. A second clock signal having a second frequency is generated from the first clock signal at a terminal point of the clock tree. The second clock signal is provided to the first component.

Apparatus and associated methods relate to implementing an analog auxiliary clock and data recovery (CDR) path to provide a high bandwidth CDR in a transceiver that supports both PAM4 and NRZ signaling. In an illustrative example, the auxiliary CDR path may include a phase-frequency detector (PFD)-based phase-locked loop (PLL) and a phase detector (PD)-based PLL. When the PFD-based PLL is locked to a reference clock signal of the transceiver, the PFD-based PLL may be then disabled and the PD-based PLL may be then enabled. Implementing the auxiliary CDR path may advantageously enable the transceiver to implement much larger parts per million (ppm) acquisition and tracking, and thus enable the transceiver to advantageously support new standards such as Peripheral Component Interconnect Express (PCIe) 5.0 and PCIe 6.0, for example.

A transponder communicates with a reader using active load modulation. The transponder includes a digital phase locked loop (DPLL), which, in operation, generates an active load modulation (ALM) carrier clock synchronized to carrier clock of the reader. Between transmission of data frames, the DPLL is placed in a lock mode of operation in which a feedback loop of the DPLL is closed. Within a transmitted data frame having a duration, the DPLL is placed, for the duration of the transmitted data frame, in a hold mode of operation in which the feedback loop is opened. A phase of the ALM carrier clock is adjusted at least once during the duration of the transmitted data frame.

The present disclosure discloses a low voltage differential signal transmitter, a method for generating a low voltage differential signal, and a data transmission device, the low voltage differential signal transmitter includes a controller and a physical layer chip connected with each other, the controller is configured to receive a first clock signal, process the first clock signal to obtain a second clock signal, read a first data signal under drive of the second clock signal, and output a third clock signal and a second data signal; the physical layer chip is configured to receive the first clock signal and the signals output by the controller, sample the third clock signal and the second data signal according to the first clock signal, and output a serial low voltage differential clock signal and a serial low voltage differential data signal.

There is provided a demodulator that makes it possible to reduce or avoid deterioration in demodulation performance due to nonlinearity of input amplitude-frequency characteristics of a variable capacitive element included in an analog control signal input section of a frequency variable oscillator, while suppressing an influence of noise. The demodulator includes: a low-resolution A/D converter that performs analog-digital conversion of a first phase difference signal to generate a second phase difference signal that is digital; a low-resolution D/A converter that performs digital-analog conversion of the second phase difference signal to generate a third phase difference signal; an analog subtractor that subtracts the third phase difference signal from the first phase difference signal to generate a first control signal; an ADPLL that generates a second control signal; and an FVO that generates the oscillation signal on the basis of the first control signal and the second control signal.