The application provides a calibration method, a calibration device and a multi-phase clock circuit. The method includes: gating each of multi-phase clock signals as a first primary clock signal and gating a corresponding clock signal as a first auxiliary clock signal according to a first preset rule; gating each of the multi-phase clock signals as a second primary clock signal and gating a corresponding clock signal as a second auxiliary clock signal according to a second preset rule; obtaining a time difference between each primary clock signal and its corresponding auxiliary clock signal under the first preset rule and the second preset rule; determining a delay adjustment amount of each primary clock signal according to the time difference, and obtaining a phase error between the multi-phase clock signals according to the delay adjustment amount; and obtaining a calibration amount of the multi-phase clock signals according to the phase error.

The application provides a calibration method, a calibration device and a multi-phase clock circuit. The method includes: gating each of multi-phase clock signals as a first primary clock signal and gating a corresponding clock signal as a first auxiliary clock signal according to a first preset rule; gating each of the multi-phase clock signals as a second primary clock signal and gating a corresponding clock signal as a second auxiliary clock signal according to a second preset rule; obtaining a time difference between each primary clock signal and its corresponding auxiliary clock signal under the first preset rule and the second preset rule; determining a delay adjustment amount of each primary clock signal according to the time difference, and obtaining a phase error between the multi-phase clock signals according to the delay adjustment amount; and obtaining a calibration amount of the multi-phase clock signals according to the phase error.

A clock synthesizer is provided. The Clock synthesizer includes a Phase Locked Loop (PLL) configured to generate a clock signal based on a reference signal. A clock buffer is connected to the PLL. The clock buffer stores the clock signal. A Duty Cycle Controller and Phase Interpolator (DCCPI) circuit is connected to the clock buffer. The DCCPI circuit receives the clock signal from the clock buffer, adjusts a duty cycle of the clock signal to substantially equal to 50%, performs phase interpolation on the clock signal, and provides the clock signal as an output after adjusting the duty cycle substantially equal to 50% and performing the phase interpolation.

A clock synthesizer is provided. The Clock synthesizer includes a Phase Locked Loop (PLL) configured to generate a clock signal based on a reference signal. A clock buffer is connected to the PLL. The clock buffer stores the clock signal. A Duty Cycle Controller and Phase Interpolator (DCCPI) circuit is connected to the clock buffer. The DCCPI circuit receives the clock signal from the clock buffer, adjusts a duty cycle of the clock signal to substantially equal to 50%, performs phase interpolation on the clock signal, and provides the clock signal as an output after adjusting the duty cycle substantially equal to 50% and performing the phase interpolation.

A system and corresponding method that achieves coherency and deterministic latency (CDL) autonomously upon power on is disclosed. The system, for example, a multi-channel RF system, may require CDL with respect to the digital-to-analog converters (DACs) and analog-to-digital converters (ADCs) assigned to the channels in the system. CDL is achieved through a timed combination of external reference and synchronization signals, resetting and disabling of various clock dividers, and enabling clock generation. In addition to synchronizing all of the clocks, the data acquisition sequence must be synchronized across all of the channels, whether they are on chips, cards, or chassis. Data acquisition synchronization may be implemented using an initiator/target or a wired OR mode configuration.

A system and corresponding method that achieves coherency and deterministic latency (CDL) autonomously upon power on is disclosed. The system, for example, a multi-channel RF system, may require CDL with respect to the digital-to-analog converters (DACs) and analog-to-digital converters (ADCs) assigned to the channels in the system. CDL is achieved through a timed combination of external reference and synchronization signals, resetting and disabling of various clock dividers, and enabling clock generation. In addition to synchronizing all of the clocks, the data acquisition sequence must be synchronized across all of the channels, whether they are on chips, cards, or chassis. Data acquisition synchronization may be implemented using an initiator/target or a wired OR mode configuration.

The present invention provides a clock signal generation circuit including a global PLL and a plurality of local PLLs. In the operation of the clock signal generation circuit, the global PLL is configured to receives a reference clock signal to generate a synchronization clock signal, and the plurality of local PLLs receive the synchronization clock signal to generate a plurality of clock signals, respectively, and the plurality of clock signals are used to generate a plurality of output clock signals.

The present invention provides a clock signal generation circuit including a global PLL and a plurality of local PLLs. In the operation of the clock signal generation circuit, the global PLL is configured to receives a reference clock signal to generate a synchronization clock signal, and the plurality of local PLLs receive the synchronization clock signal to generate a plurality of clock signals, respectively, and the plurality of clock signals are used to generate a plurality of output clock signals.

A phase-locked loop (PLL) device includes a first phase detector to receive an in-phase reference clock and an in-phase feedback clock, the first phase detector to output a first phase error; a second phase detector to receive a quadrature reference clock and a quadrature feedback clock, the second phase detector to output a second phase error; a proportional path component to generate first current pulses from the first phase error and second current pulses from the second phase error; an integrator circuit coupled to the proportional path component, the integrator circuit to sum, within a current output signal, the first current pulses and the second current pulses; a ring oscillator to be driven by the current output signal; and a pair of phase interpolators coupled to an output of the ring oscillator, the pair of phase interpolators to respectively generate the in-phase feedback clock and the quadrature feedback clock.

A phase-locked loop (PLL) device includes a first phase detector to receive an in-phase reference clock and an in-phase feedback clock, the first phase detector to output a first phase error; a second phase detector to receive a quadrature reference clock and a quadrature feedback clock, the second phase detector to output a second phase error; a proportional path component to generate first current pulses from the first phase error and second current pulses from the second phase error; an integrator circuit coupled to the proportional path component, the integrator circuit to sum, within a current output signal, the first current pulses and the second current pulses; a ring oscillator to be driven by the current output signal; and a pair of phase interpolators coupled to an output of the ring oscillator, the pair of phase interpolators to respectively generate the in-phase feedback clock and the quadrature feedback clock.