Provided are a digitally controlled oscillator and an electronic device including the digitally controlled oscillator. The digitally controlled oscillator includes a digital control unit and a power control oscillation unit. The digital control unit compensates for a difference between a feedback signal of an output power and a reference power set based on an input digital control signal and outputting an output power. The power control oscillation unit receives a signal related to the output power, and generates an output clock having an oscillation frequency in response to the signal related to the output power.

Apparatuses, systems, and methods that provide a delayed output signal with reduced sampling error are described. Embodiments include a clock circuit that generates a sample clock signal having a predetermined sample clock period. A sampling circuit may generate samples of a received signal during each sample clock period. An interpolation circuit may estimate a value of the received signal at times between the samples of the received signal based on at least a first sample and a second sample of the received signal. The interpolation circuit may estimate a time that the received signal crosses a threshold, and determine a time delta between the first sample and the estimated time that the received signal crosses the threshold. A delay circuit to generate a time delay substantially equal to the time delta is also included. An output signal changes state after the generated time delay.

Apparatuses, systems, and methods that provide a delayed output signal with reduced sampling error are described. Embodiments include a clock circuit that generates a sample clock signal having a predetermined sample clock period. A sampling circuit may generate samples of a received signal during each sample clock period. An interpolation circuit may estimate a value of the received signal at times between the samples of the received signal based on at least a first sample and a second sample of the received signal. The interpolation circuit may estimate a time that the received signal crosses a threshold, and determine a time delta between the first sample and the estimated time that the received signal crosses the threshold. A delay circuit to generate a time delay substantially equal to the time delta is also included. An output signal changes state after the generated time delay.

The present disclosure is directed to mitigating voltage droops. An aspect includes outputting, by a clock module coupled to a multiplexor, a first clock signal to the multiplexor, the first clock signal generated by a clock delay component of the clock module, receiving, by the clock module, a second clock signal from a phase-locked loop (PLL), wherein the PLL outputs a third clock signal to a processor coupled to the PLL and the multiplexor, selecting, by the multiplexor, the first clock signal to output to the processor based on detecting a droop in voltage on a power supply, and selecting, by the multiplexor, the third clock signal to output to the processor based on detecting that the droop in the voltage on the power supply has passed, wherein the clock module and the processor are coupled to the power supply.

The present disclosure is directed to mitigating voltage droops. An aspect includes outputting, by a clock module coupled to a multiplexor, a first clock signal to the multiplexor, the first clock signal generated by a clock delay component of the clock module, receiving, by the clock module, a second clock signal from a phase-locked loop (PLL), wherein the PLL outputs a third clock signal to a processor coupled to the PLL and the multiplexor, selecting, by the multiplexor, the first clock signal to output to the processor based on detecting a droop in voltage on a power supply, and selecting, by the multiplexor, the third clock signal to output to the processor based on detecting that the droop in the voltage on the power supply has passed, wherein the clock module and the processor are coupled to the power supply.

A sensor is provided including: an element outputting detection signals according to magnitude of physical quantity; a drive circuit outputting a driving signal to the element and receiving a monitor signal from the element; a detection circuit that includes amplifiers amplifying the detection signals and a first synchronous demodulation circuit performing synchronous demodulation on a signal from the amplifier, receives the detection signals, and outputs a physical quantity signal according to the physical quantity; a processing circuit processing a signal from the first synchronous demodulation circuit; a first diagnostic circuit that receives a signal into the processing circuit and a signal from the processing circuit, and outputs a first error signal when abnormalities occur in the processing circuit; and a second diagnostic circuit that outputs a diagnostic signal to the first diagnostic circuit, instead of the signal into the processing circuit or instead of the signal from the processing circuit.

A sensor is provided including: an element outputting detection signals according to magnitude of physical quantity; a drive circuit outputting a driving signal to the element and receiving a monitor signal from the element; a detection circuit that includes amplifiers amplifying the detection signals and a first synchronous demodulation circuit performing synchronous demodulation on a signal from the amplifier, receives the detection signals, and outputs a physical quantity signal according to the physical quantity; a processing circuit processing a signal from the first synchronous demodulation circuit; a first diagnostic circuit that receives a signal into the processing circuit and a signal from the processing circuit, and outputs a first error signal when abnormalities occur in the processing circuit; and a second diagnostic circuit that outputs a diagnostic signal to the first diagnostic circuit, instead of the signal into the processing circuit or instead of the signal from the processing circuit.

A resonator is supplied with voltage from a constant-voltage source, and the constant-voltage source outputs output voltage adjusted by a voltage adjustment signal to the resonator. The resonator outputs a clock signal having a frequency varied by varying capacitance in accordance with a received control signal and a frequency adjustment signal, and a frequency of the clock signal is varied by voltage output from the constant-voltage source.

An improved noise-corrected phase-locked loop frequency synthesizer configured to reduce noise, such as phase noise and spurious signals, without the use of switching circuits. The synthesizer uses a phase shifter device configured to accept a noise containing frequency signal from a voltage controlled oscillator (VCO) circuit, such as an integer-N single loop PLL synthesizer, as well as noise reducing control signals from a noise detecting sensor or circuit, and output a noise reduced VCO frequency signal. In some embodiments, the noise reducing sensor may be formed from a second, lower noise, phase locked loop circuit. The frequency synthesizer circuit, noise detecting sensor, and the phase shifter device are configured to all run continuously, with the noise reducing sensor and frequency shifter continually acting to reduce noise, produced by higher noise integer-N PLL frequency synthesizer.

A locked loop circuit includes a controlled oscillator generate an output signal having a frequency set by an analog control signal. The analog control signal is generated by a first digital-to-analog converter (DAC) in response to a digital control signal and a bias compensation current signal. The bias compensation current signal is generated by a second DAC in response to a compensation control signal and a bias reference current. A compensation circuit adjusts the compensation control signal during compensation mode in response to a comparison of a frequency of the output signal to a frequency of a reference signal so as to drive the frequency of the output signal toward matching a desired frequency. The bias compensation current signal associated with the frequency match condition during compensation mode is then used during locked loop mode.