The present disclosure relates to a phase-locked loop (PLL) based on a charge-sharing locking technique, capable of both fractional-N and integer-N operation. The PLL comprises a voltage pre-setting stage; an oscillator: a shared capacitive load; and a switching network configured for selectively connecting the voltage pre-setting stage to the shared capacitive load during a voltage pre-setting stage for applying an expectant voltage to the capacitive load. The switching network is being further configured for selectively connecting the capacitive load to the oscillator during a charge-sharing locking stage for correcting a phase error in response to a difference between the expected voltage of the capacitor and the voltage of the oscillator. Frequency-tracking and waveform-learning stages are also provided for maintaining PVT (process, voltage, temperature) robustness and for suppressing fractional-N spur, respectively.

A control arrangement is disclosed for providing a plurality of phase-coherent oscillating signals. It comprises a reference clock signal arrangement for providing a high-frequency reference clock signal and a plurality of modules each comprising a plurality of channels for providing the plurality of phase-coherent oscillating signals.

An apparatus can implement a frequency doubler with duty cycle correction in conjunction with, for instance, a phase-locked loop (PLL) to decrease phase noise. In an example aspect, an apparatus has a frequency doubler including a signal combiner, a first signal pathway, and a second signal pathway. The frequency doubler also includes a doubler input node and a doubler output node. The signal combiner is coupled to the doubler output node. The first signal pathway is coupled between the doubler input node and the signal combiner and includes a first adjustable delay cell. The second signal pathway is also coupled between the doubler input node and the signal combiner and includes a second adjustable delay cell.

Embodiments of the present disclosure provide systems and methods for realizing phase synchronization updates based on an input system reference signal SYSREF without the need to synchronously distribute the SYSREF signal on a high-speed domain. In particular, phase synchronization mechanisms of the present disclosure are based on keeping a first phase accumulator in the device clock domain and using a second phase accumulator in the final digital clock domain to asynchronously transmit phase updates to the final digital clock domain. Arrival of a new SYSREF pulse may be detected based on the counter value of the first phase accumulator, which value is asynchronously transferred and scaled to the second phase accumulator downstream. In this manner, even though the SYSREF signal itself is not synchronously transferred to the second phase accumulator, the phase updates from the SYSREF signal may be transferred downstream so that the final phase may be generated deterministically.

A method for providing a reference clock signal, comprising: generating, by an oscillator, a first clock signal having a first frequency, the first clock signal being coupled to a frequency synthesizer; generating, by the frequency synthesizer, a second clock signal based on the first clock signal, the second clock signal having a second frequency different from the first frequency; outputting a reference clock signal to one or more components of an electronic device, the reference clock signal being one of the first clock signal or the second clock signal; identifying one or more spurious frequency components; and monitoring the reference clock signal for a presence of the one or more spurious frequency components, the monitoring comprising: in response to determining the presence of at least one of the one or more spurious frequency components, selecting a different one of the first clock signal or the second clock signal to be the reference clock signal.

A frequency-locked loop (FLL) logic circuit, including a validity signal generator configured to receive an external clock signal and determine whether a glitch occurs in the external clock signal; a clock divider configured to generate a reference frequency clock signal based on the external clock signal and a determination result of the validity signal generator; a synchronizer configured to synchronize a phase of an oscillator clock signal with a phase of the reference frequency clock signal; a clock counter configured to count a number of pulses of the oscillator clock signal during a reference time; and a code limiter configured to determine a range of a frequency selection value for calibrating an operating frequency of the oscillator clock signal based on the counted number of pulses.

A clock integrated circuit is provided. The clock integrated circuit includes: a first clock generator which includes a crystal oscillator configured to generate a first clock signal; and a second clock generator which includes a resistance-capacitance (RC) oscillator and a first frequency divider, and is configured to: generate a second clock signal using the first frequency divider based on a clock signal output from the RC oscillator; perform a first calibration operation for adjusting a frequency division ratio of the first frequency divider to a first frequency division ratio based on the first clock signal; and perform a second calibration operation for adjusting the first frequency division ratio to a second frequency division ratio based on a sensed temperature.

Some examples relate to a frequency synthesizer. The frequency synthesizer includes an oscillator including an input terminal and an output terminal. A frequency locked-loop or phase-locked loop (FLL/PLL) unit is arranged on a feedback path extending between the output terminal of the oscillator and the input terminal of the oscillator. A switching unit is configured to selectively switch between a first mode of operation in which the feedback path is closed and the FLL/PLL unit is coupled to the input terminal of the oscillator, and a second mode of operation in which the feedback path is open and a ramping unit is coupled to the input terminal of the oscillator while the feedback path is open.

The present disclosure provides a real-time correction method for an Oven Controlled Crystal (Xtal) Oscillator (OCXO) and an electromagnetic receiver. The real-time correction method for an OCXO includes: performing frequency multiplication on a reference clock signal to generate a first measurement signal and a second measurement signal; identifying a rising edge of each pulse per second on the basis of the first measurement signal to obtain a gate time T; obtaining a frequency of the second measurement signal according to the gate time T; and adjusting a frequency of the reference clock signal at least on the basis that an absolute value of a difference between two adjacent frequencies obtained of the second measurement signal is greater than a standard frequency difference.

A dual-output microelectromechanical system (MEMS) resonator can be operated selectively and concurrently in an in-plane mode of vibration and an out-of-plane mode of vibration to obtain, respectively, a first electrical signal having a first frequency and a second electrical signal having a second frequency that is less than the first frequency. The first and second electrical signals are mixed to obtain a third electrical signal having a third frequency, where the third frequency is proportional to a temperature of the MEMS resonator. The temperature is determined based on the third frequency. Values of the first and second frequencies can be adjusted based on the determined temperature to compensate for frequency deviations due to temperature deviations. Also described herein are methods and systems for determining the temperature of the dual-output MEMS and for performing frequency compensation, as well as a method of manufacturing the dual-output MEMS.