A semiconductor circuitry includes an oscillator configured to output an oscillation signal whose frequency depends on a first input signal, a counter configured to count a number of cycles of the oscillation signal, first circuitry configured to output a first digital signal based on a first number of cycles counted by the counter within one of a clock cycle of a clock signal, wherein the first input signal is digitally converted into the first digital signal, and a second circuitry configured to output a second digital signal based on a second number of cycles counted by the counter in a period from a reference timing of the clock signal to an input timing of a second input signal within the one of the clock cycle of the clock signal, wherein the period is digitally converted into the second digital signal.

A clock calibration module, a high-speed receiver, and an associated calibration method are provided. The calibration method is applied to the high-speed receiver having the clock calibration module and a sampler. The sampler samples an equalized data signal with a sampler-input clock. The clock calibration module includes multiple clock generation circuits and a clock calibration circuit. Each of the clock generation circuits includes a phase interpolator, a duty cycle corrector, and a phase corrector. In a calibration mode, the phase interpolator interpolates a reference input clock and generates an interpolated clock accordingly. The duty cycle corrector generates a duty cycle corrected clock based on the interpolated clock. The phase corrector generates the sampler-input clock based on the duty cycle corrected clock. The phase interpolator is controlled by a phase interpolator calibration signal, and the phase corrector is controlled by a phase corrector calibration signal.

Embodiments of the present application provide a multi-channel signal synchronization system, circuit, and method. The multi-channel signal synchronization system comprises a clock signal generation module, a synchronization signal generation module, and signal receiving modules; the clock signal generation module is configured to generate a first clock signal; the synchronization signal generation module is configured to generate a synchronization signal based on the first clock signal and transmit the synchronization signal to the clock signal generation module; the clock signal generation module generates second clock signals on the basis of the synchronization signal and transmits the second clock signals to the signal receiving modules; the synchronization signal generation module transmits the synchronization signal to the signal receiving modules.

A circuit device includes an oscillation circuit configured to generate an oscillation signal, a first pre-driver disposed in a posterior stage of the oscillation circuit, a first output driver disposed in a posterior stage of the first pre-driver, a first regulator configured to supply a first regulated voltage to the first pre-driver, and a second regulator configured to supply a second regulated voltage to the first output driver, wherein the second regulator is shorter in transient response time than the first regulator.

Programming time delay data in an oversampled sensor includes determining whether to enter Programming Mode based on a value of a system parameter received by the oversampled sensor. Programming Mode is entered when the value of the system parameter corresponds to Programming Mode. The time delay data is programmed in the oversampled sensor during Programming Mode. The oversampled sensor uses the time delay data to time delay its output in an oversampled domain. Programming Mode is exited after a predetermined time has expired relative to when Programming Mode was entered. The system parameter can be a frequency of a sampling clock signal.

Programming time delay data in an oversampled sensor includes determining whether to enter Programming Mode based on a value of a system parameter received by the oversampled sensor. Programming Mode is entered when the value of the system parameter corresponds to Programming Mode. The time delay data is programmed in the oversampled sensor during Programming Mode. The oversampled sensor uses the time delay data to time delay its output in an oversampled domain. Programming Mode is exited after a predetermined time has expired relative to when Programming Mode was entered. The system parameter can be a frequency of a sampling clock signal.

A phase interpolator capable of preventing a glitch from being generated during a clock signal switching operation and a clock signal selector thereof are provided. The clock signal selector includes a selector and a selection signal generator. The selector receives multiple clock signals with different phases. The selector selects one of the clock signals according to a selection signal to generate a selected clock signal. The selection signal generator is coupled to the selector and generates the selection signal. When the selector switches from selecting a first clock signal to selecting a second clock signal as the selected clock signal, the selection signal generator generates a set time point according to a transition point of one of the first clock signal and the second clock signal whose phase lags behind a phase of the other, and generates the selection signal according to the set time point.

A phase interpolator capable of preventing a glitch from being generated during a clock signal switching operation and a clock signal selector thereof are provided. The clock signal selector includes a selector and a selection signal generator. The selector receives multiple clock signals with different phases. The selector selects one of the clock signals according to a selection signal to generate a selected clock signal. The selection signal generator is coupled to the selector and generates the selection signal. When the selector switches from selecting a first clock signal to selecting a second clock signal as the selected clock signal, the selection signal generator generates a set time point according to a transition point of one of the first clock signal and the second clock signal whose phase lags behind a phase of the other, and generates the selection signal according to the set time point.

Examples describe a duty cycle correction circuit for correcting duty cycle distortion from memory. One example is an integrated circuit for correcting an input clock signal. The integrated circuit includes a first leg circuit and a second leg circuit. The first leg circuit and the second leg circuit both comprise a charging circuit and a discharging circuit. Each charging circuit comprises a first plurality of transistors and each discharging circuit comprises a second plurality of transistors. The charging circuit is coupled to the discharging circuit in series. A number of transistors of the first plurality of transistors in the first leg circuit is different from a number of transistors of the first plurality of transistors in the second leg circuit.

Examples describe a duty cycle correction circuit for correcting duty cycle distortion from memory. One example is an integrated circuit for correcting an input clock signal. The integrated circuit includes a first leg circuit and a second leg circuit. The first leg circuit and the second leg circuit both comprise a charging circuit and a discharging circuit. Each charging circuit comprises a first plurality of transistors and each discharging circuit comprises a second plurality of transistors. The charging circuit is coupled to the discharging circuit in series. A number of transistors of the first plurality of transistors in the first leg circuit is different from a number of transistors of the first plurality of transistors in the second leg circuit.