A phase correcting device includes a local oscillator that includes an all digital phase-locked loop configured to output a local oscillation signal, a first phase detector configured to detect a phase of the local oscillation signal to output the phase of the local oscillation signal, a reference phase device configured to generate a quasi-reference phase corresponding to a reference phase of the local oscillation signal to output the quasi-reference phase, based on a reference clock, a second phase detector configured to detect a fluctuation amount of a phase of the local oscillator, based on the phase detected by the first phase detector and the quasi-reference phase, and a correction circuit configured to correct the phase of the inputted signal by using a detection result of the second phase detector.

A framework for power management. The framework includes at least one power distribution board disposed within a radio-frequency (RF) cabin of a medical imaging system and coupled to an external reference clock. The power distribution board may include a clock circuit that generates one or more output clock signals based on a reference clock signal from the external reference clock. One or more switching regulators may be coupled to the clock circuit. The one or more switching regulators may be synchronized to the one or more output clock signals and provide power to one or more endpoint loads.

A clock stretcher includes a digital DLL that derives delayed versions of an input clock signal, and a combiner that cyclically selects the delayed versions to generate a modified clock signal. The combiner uses a hop code, dependent on a sensed condition, to determine the step size for the cyclical selection. The digital DLL corrects its delay speed at discrete times, during which it may be active. If the DLL delay line becomes slower while it is active, the modified clock signal would incur a glitch. The clock stretcher corrects for this glitch by using an increased hop code when a speed change occurs. The clock stretcher may operate from a sensed power supply without intervening voltage regulation.

A clock stretcher includes a DLL that derives delayed versions of an input clock signal. The clock stretcher has passive and stretching modes. It operates from a sensed power supply without intervening voltage regulation. In passive mode, it forwards input clock pulses to the clock stretcher output. The input clock pulses are delayed by fewer than 10 DLL delay line delay stages. In stretching mode, a combiner cyclically selects the delayed versions of the input clock signal to generate a modified clock signal. The combiner uses a hop code, dependent on a sensed condition, to determine the step size for the cyclical selection. To enter passive mode, the clock stretcher tests if a passive mode entry threshold is met. The threshold includes two conditions: the hop code must be zero, and phase selection must have reached a wraparound point that may have been corrected for a delay line offset.

The disclosure provides a signal synchronizing device and a digital signal output device. A digital circuit counts a first frequency signal to generate a count value, and generates an output voltage according to the count value. An analog circuit generates a feedback signal according to the output voltage. A synchronization circuit samples the feedback signal according to a second frequency signal to generate a synchronization signal. A control circuit generates a voltage control signal according to the second frequency signal and the synchronization signal to control the digital circuit to stop counting the first frequency signal, and a frequency of the first frequency signal is lower than a frequency of the second frequency signal.

In described examples, a first clock generator generates an output clock signal in response to an input reference signal and in response to a feedback signal that is generated in response to the output clock signal. A code generator generates a code in response to the input reference signal. A loss detector generates an indication of a loss of the input reference signal in response to the feedback signal and at least two codes generated by the code generator.

A clock stretcher includes a DLL that derives delayed versions of an input clock signal, and a combiner that cyclically selects the delayed versions to generate a modified clock signal. The combiner uses a hop code, dependent on a sensed condition, to determine the step size for the cyclical selection. The DLL may have a phase error that would cause a glitch in the modified clock during phase selection wraparound. The clock stretcher proactively increases the step size during wraparound by adding an offset skip parameter value to the hop code. The clock stretcher may operate from a sensed power supply without intervening voltage regulation.

A phase-locked loop (PLL) performs hitless switching from a first reference clock (ref1) to a second reference clock (ref2) by entering holdover mode (418), and aligning the feedback clock (fbclk) to the second reference clock while in holdover mode. The alignment is performed by adjusting a divisor input (D) for the multi-mode divider (128) that divides the output clock frequency (PLLout) to generate the feedback clock. Other features are also provided.

A clock generator receives first and second clock signals, and input representing a desired frequency ratio. A comparison is made between frequencies of an output clock signal and the first clock signal, and a first error signal represents the difference between the desired frequency ratio and this comparison result. The first error signal is filtered. A comparison is made between frequencies of the output clock signal and the second clock signal, and a second error signal represents the difference between the filtered first error signal and this comparison result. The second error signal is filtered. A numerically controlled oscillator receives the filtered second error signal and generates an output clock signal. As a result, the output clock signal has the jitter characteristics of the first input clock signal over a useful range of jitter frequencies and the frequency accuracy of the second input clock signal.

A clock generator receives first and second clock signals, and input representing a desired frequency ratio. A comparison is made between frequencies of an output clock signal and the first clock signal, and a first error signal represents the difference between the desired frequency ratio and this comparison result. The first error signal is filtered. A comparison is made between frequencies of the output clock signal and the second clock signal, and a second error signal represents the difference between the filtered first error signal and this comparison result. The second error signal is filtered. A numerically controlled oscillator receives the filtered second error signal and generates an output clock signal. As a result, the output clock signal has the jitter characteristics of the first input clock signal over a useful range of jitter frequencies and the frequency accuracy of the second input clock signal.