A phase-locked loop (PLL) includes a voltage-controlled oscillator (VCO) that generates a PLL output signal having an oscillation frequency controlled by a control signal; a phase detector that generates a phase signal representing a difference in phase between the PLL output signal and a reference signal; a loop filter coupled to receive the phase signal; a switch; and a sampling circuit switchably coupled to receive the control signal of the VCO via the switch, and generating a code representing the control signal.

There is disclosed in one example a digital phase-locked loop (DPLL) circuit adapted to avoid loop-bandwidth tradeoff, the circuit including: a frequency dimension frequency detector having an external frequency input and a feedback frequency input, the frequency dimension frequency detector including circuitry to measure a frequency difference between the external frequency input and the feedback frequency input and to drive an impulse signal, wherein the impulse signal is of a first species if the difference is positive and of a second species if the difference is negative; and a number-controlled oscillator (NCO) including circuitry to drive an output clock and to adjust the frequency of the output clock responsive to the impulse signal, wherein an output of the NCO provides the feedback frequency input of the frequency dimension frequency detector.

A circuit device includes a processing circuit and an oscillation signal generation circuit. The processing circuit performs Kalman filter processing for a result of phase comparison between an input signal based on an oscillation signal and a reference signal and performs loop filter processing for the result of phase comparison. The oscillation signal generation circuit generates the oscillation signal of an oscillation frequency set by frequency control data which is output data of the loop filter processing by using the frequency control data and a resonator. The processing circuit estimates a truth value for an observed value of the result of phase comparison by using the Kalman filter processing.

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.

Limiting frequency overshoot in a timing recovery loop involves using a proportional-integral (PI) control system to discipline a frequency of an output signal of a voltage controlled oscillator (VCO) in accordance with a time reference signal. A control signal output of the PI control system is monitored to detect conditions which will prospectively cause an excess deviation of the VCO frequency. In response to detecting such a condition, an output of an integral error term generator of the PI control system is locked or held constant. This will have the effect of preventing the excess frequency deviation of the VCO.

There is disclosed in one example a digital phase-locked loop (DPLL) circuit adapted to avoid loop-bandwidth tradeoff, the circuit including: a frequency dimension frequency detector having an external frequency input and a feedback frequency input, the frequency dimension frequency detector including circuitry to measure a frequency difference between the external frequency input and the feedback frequency input and to drive an impulse signal, wherein the impulse signal is of a first species if the difference is positive and of a second species if the difference is negative; and a number-controlled oscillator (NCO) including circuitry to drive an output clock and to adjust the frequency of the output clock responsive to the impulse signal, wherein an output of the NCO provides the feedback frequency input of the frequency dimension frequency detector.

A circuit device includes an oscillation signal generation circuit that generates an oscillation signal by using a resonator and a processing circuit that estimates an aging characteristic of the oscillation frequency of the resonator based on the result of comparison between the phase of a reference signal based on a satellite signal transmitted from a navigation satellite and the phase of a clock signal based on the oscillation signal. The processing circuit estimates the aging characteristic based on an index value representing the reliability of the state of the received satellite signal and the result of the phase comparison.

There is disclosed in one example a digital phase-locked loop (DPLL) circuit adapted to avoid loop-bandwidth tradeoff, the circuit including: a frequency dimension frequency detector having an external frequency input and a feedback frequency input, the frequency dimension frequency detector including circuitry to measure a frequency difference between the external frequency input and the feedback frequency input and to drive an impulse signal, wherein the impulse signal is of a first species if the difference is positive and of a second species if the difference is negative; and a number-controlled oscillator (NCO) including circuitry to drive an output clock and to adjust the frequency of the output clock responsive to the impulse signal, wherein an output of the NCO provides the feedback frequency input of the frequency dimension frequency detector.

An apparatus for providing a clock signal based on a received clock signal includes a time-to-digital converter configured to generate timestamp information based on the received clock signal. The apparatus includes a first filter configured to generate clock period information based on the timestamp information. The apparatus includes a phase monitor circuit. The phase monitor circuit includes a second filter configured to provide a mean period signal of the received clock signal based on the clock period information. The phase monitor includes a phase error detection circuit configured to generate a phase error indicator based on a threshold difference value and a difference between the clock period information and expected clock period information. The expected clock period information is based on the mean period signal.

A Bluetooth Low-Energy (BLE) transmitter is presented for used in ultra-low-power radios in short range IoT applications. The power consumption of state-of-the-art BLE transmitter has been limited by the relatively power-hungry local oscillator due to the use of LC oscillators for superior phase noise performance. This disclosure addresses this issue by analyzing the phase noise limit of a BLE TX and proposes a ring oscillator-based solution for power and cost savings. The proposed transmitter features: 1) a wideband all-digital phase locked loop (ADPLL) featuring an f.sub.RF/4 RO, with an embedded 5-bit TDC; 2) a 4 frequency edge combiner to generate the 2.4 GHz signal; and 3) a switch-capacitor digital PA optimized for high efficiency at low transmit power levels. These not only help reduce the power consumption and improve phase noise performance, but also enhance the transmitter efficiency for short range applications.