A signal generator comprises (i) a first set of capacitors at least partially switchably connectable for adjusting a frequency of an oscillator as part of a phase-locked loop and (ii) a second set of capacitors comprised in one or more oscillator control subsystems. A method of controlling the signal generator comprises: (i) acquiring a frequency lock in the phase-locked loop, (ii) calculating, in conjunction with the acquiring of the frequency lock, a systematic capacitance error of the first set of capacitors due to process, voltage, and temperature variations based on the frequency of the oscillator and a switching state of the first set of capacitors, and (iii) calibrating the one or more oscillator control subsystems using the systematic capacitance error, thereby compensating for process, voltage, and temperature variations common between the first set of capacitors and the second set of capacitors.

A gate driving circuit includes a pull-up control part for applying a first previous carry signal to a first node in response to the first previous carry signal, a first pull-up part outputting a clock signal as an N-th gate output signal in response to a signal applied to the first node, a second pull-up part outputting the clock signal as the N-th gate output signal in response to the signal applied to the first node, a carry part outputting the clock signal as an N-th carry signal in response to the signal applied to the first node, a first pull-down part pulling down the signal at the first node to a second off voltage, and a second pull-down part pulling down the N-th gate output signal to a first off voltage, wherein one of the first pull-up part and the second pull-up part is selectively activated.

A circuit generates a clock signal with a tunable clock period. The circuit comprises capacitors, first tuning circuitry and second tuning circuitry. The first tuning circuitry is configured to adjust the clock period with a first period tuning step based on a first parameter and the second tuning circuit is configured to adjust the clock period with a second period tuning step based on a second parameter. The first period tuning step is different than the second period tuning step.

In an aspect of the disclosure, a method, a computer-readable medium, and an apparatus are provided. The apparatus may receive an otw signal that is associated with low-path pass information and transmission data. The apparatus may apply a cost function and an update function to the otw signal prior to sending the otw signal to an oscillator. The apparatus may determine a correction factor for use in estimating a gain of the oscillator based at least in part on an output of the update function.

Various embodiments relate to a method for calibration of a center frequency of a BPF in an FSK transceiver, the method including the steps of filtering a carrier frequency signal by the BPF to produce a filtered signal, detecting, by a phase-frequency detector (PFD), a difference in phase between the carrier frequency signal and the filtered signal from the BPF, sweeping a calibration code of the BPF, detecting a transition in the sign of the phase difference and capturing a calibration code associated with the transition in the sign of the phase difference for calibration of the BPF.

A frequency generator is disclosed. The frequency generator is for generating an oscillator clock according to a reference clock, and the frequency generator is used in a frequency hopping system that switches a carrier frequency among a plurality of channels, and the carrier frequency further carries a modulation frequency for data transmission. The frequency generator includes: a frequency hopping and modulation control unit, arranged for generating a current channel according to a channel hopping sequence and a frequency command word (FCW) based on the reference clock, a digital-controlled oscillator (DCO), arranged for to generating the oscillator clock according to an oscillator tuning word (OTW) obtained according to the estimated DCO normalization value. An associated method is also disclosed.

A clock gating system (CGS) includes a digital power estimator configured to generate indications of a predicted energy consumption per cycle of a clock signal and a maximum energy consumption per cycle of the clock signal. The CGS further includes a voltage-clock gate (VCG) circuit coupled to the digital power estimator. The VCG circuit is configured to gate and un-gate the clock signal based on the indications prior to occurrence of a voltage droop event and using hardware voltage model circuitry of the VCG circuit. The VCG circuit is further configured to gate the clock signal based on an undershoot phase associated with the voltage droop event and to un-gate the clock signal based on an overshoot phase associated with the voltage droop event.

A clock circuit includes a set of level shifters, and adjustment circuit and a calibration circuit. The set of level shifters is configured to output a first set of phase clock signals having a first duty cycle, and is coupled to the adjustment circuit. The adjustment circuit is configured to generate a first clock output signal responsive to a first phase clock signal and a second phase clock signal of the first set of phase clock signals, and adjust the first clock output signal and a second duty cycle of the first clock output signal responsive to a set of control signals. The calibration circuit is coupled to the adjustment circuit, and configured to perform a duty cycle calibration of the second duty cycle of the first clock output signal based on an input duty cycle, and to generate the set of control signals responsive to the duty cycle calibration.

The present disclosure relates to an imaging element and a method for controlling an imaging element, an imaging apparatus, and an electronic apparatus that can reduce the size of the imaging element and can reduce power consumption. First, a gray code corresponding to a P-phase pixel signal of each pixel is converted into a binary code. Then, a difference between a binary code corresponding to the converted same bit and a binary code of the pixel signal in which all bits are 0 and which is latched in a temporary latch is continuously calculated and is latched as the binary code of the P-phase pixel signal in the temporary latch. Then, a gray code corresponding to a D-phase pixel signal of each pixel is converted into a binary code. Then, a difference between a binary code corresponding to the converted same bit and the binary code of P-phase the pixel signal which is latched in the temporary latch is continuously calculated. The present disclosure can be applied to an imaging apparatus.

A synthesizer comprises a first two-point modulation phase locked loop, TPM PLL, circuit that receives a first reference clock signal at a first reference frequency and a feedback signal at a feedback frequency and generates a first chirp signal by applying a two-point modulation PLL on the first reference clock signal, a second integer-n TPM PLL circuit that receives a second reference clock signal at a second reference frequency lower than the first reference frequency and generates a second chirp signal by applying a TPM PLL on the second reference clock signal, a mixer that downconverts the first chirp signal by the second chirp signal to obtain the feedback signal at the feedback frequency corresponding to the difference of the frequency of the first chirp signal and the second chirp signal, and a feedback path that feeds back the feedback signal to the first TPM PLL circuit.