A circuit arrangement for charge integration may include an input for applying a signal representing charge pulses, an output for providing an integrated signal, and an integrating circuit connected between the input and the output, comprising a resistive circuit and a capacitor and having an RC time constant which is a function of the resistive circuit and the capacitor. The circuit arrangement may include a feedback control circuit connected at its input, to the output of the circuit arrangement and providing, at its output, a control signal, where at least one of the resistive circuit and the capacitor has a variable value based on the control signal.

The present invention provides a fractional frequency divider, wherein the fractional frequency divider includes a plurality of registers, a counter, a control signal generator and a clock gating circuit. Regarding the plurality of registers, at least a portion of the registers are set to have values The counter is configured to sequentially generate a plurality of counter values, wherein the plurality of counter values correspond to the at least a portion of the registers, respectively, and the plurality of counter values are generated repeatedly The control signal generator is configured to generate a control signal based on the received counter value and the value of the corresponding register. The clock gating circuit is configured to refer to the control signal to mask or not mask an input clock signal to generate an output clock signal.

A time measurement device measures a time interval between input timings of first and second pulsed target signals. The device includes: a processor; a number-of-periods detector that detects, by using a clock signal with a predetermined clock frequency and a predetermined clock period, the time interval in units of the clock period; and a phase detection unit including a band-pass filter. The band-pass filter receives at least one of the first and second target signals as a filtering target signal and extracts a signal component of the clock frequency from the filtering target signal. The phase detection unit detects a phase difference between the extracted signal and the clock signal. The processor derives, by using a result detected by the number-of-periods detector and the detected phase difference, the time interval at a resolution finer than the clock period.

An electronic circuit includes an oscillator circuit, a first divider circuit, a synchronization control circuit, and a peripheral circuit. The oscillator circuit is configured to generate a base frequency clock. The first divider circuit is configured to divide the base frequency clock by a first selectable divisor to generate a divided clock. The synchronization control circuit is configured to generate a synchronization pulse that controls a change of the first selectable divisor in the first divider circuit from a first value to a second value. A pulse width of the synchronization pulse is based on the first value of the first selectable divisor. The peripheral circuit is coupled to the first divider circuit and the synchronization control circuit. The peripheral circuit includes a second divider circuit. The second divider circuit divides the divided clock by a second selectable divisor, and change the second selectable divisor responsive to the synchronization pulse.

A frequency divider circuit can achieve multi-modulus operation. The frequency divider includes clocking transistor devices, memory transistor circuits, write transistor devices, and a current source bias. The clocking transistor devices receive a differential input signal having a first frequency at an input of the frequency divider. The memory transistor circuits store signals based on the differential input signal from the clocking transistor devices. The write transistor devices make a divided frequency signal available at an output terminal. The current source bias is coupled to the clocking transistor devices. The current source bias applies a bias current to adapt the frequency divider to a common-mode at the input of the frequency divider.

A frequency divider circuit can achieve multi-modulus operation. The frequency divider includes clocking transistor devices, memory transistor circuits, write transistor devices, and a current source bias. The clocking transistor devices receive a differential input signal having a first frequency at an input of the frequency divider. The memory transistor circuits store signals based on the differential input signal from the clocking transistor devices. The write transistor devices make a divided frequency signal available at an output terminal. The current source bias is coupled to the clocking transistor devices. The current source bias applies a bias current to adapt the frequency divider to a common-mode at the input of the frequency divider.

An apparatus is disclosed, including a driver circuit, a comparator circuit, and a counter circuit. The driver circuit may be configured to source a current to a load circuit. The comparator circuit may be configured to perform a comparison of a reference voltage to a voltage across the load circuit. The counter circuit may be configured to modify a digital count value based on the comparison. The driver circuit may be further configured to adjust a value of the current using the digital count value.

In described examples, a pulse width modulation (PWM) system includes an initiator and a receiver. The initiator includes an initiator counter and an initiator PWM signal generator. The initiator counter advances an initiator count in response to an initiator clock signal. The initiator PWM signal generator generates an initiator PWM signal in response to the initiator count. The receiver includes a receiver counter, a receiver PWM signal generator, and circuitry configured to reset the receiver count. The receiver counter advances a receiver count in response to a receiver clock signal. The receiver PWM signal generator generates a receiver PWM signal in response to the receiver count. The circuitry resets the receiver count in response to a synchronization signal and based on an offset.

In described examples, a pulse width modulation (PWM) system includes an initiator and a receiver. The initiator includes an initiator counter and an initiator PWM signal generator. The initiator counter advances an initiator count in response to an initiator clock signal. The initiator PWM signal generator generates an initiator PWM signal in response to the initiator count. The receiver includes a receiver counter, a receiver PWM signal generator, and circuitry configured to reset the receiver count. The receiver counter advances a receiver count in response to a receiver clock signal. The receiver PWM signal generator generates a receiver PWM signal in response to the receiver count. The circuitry resets the receiver count in response to a synchronization signal and based on an offset.

In described examples, a pulse width modulation (PWM) system includes an initiator and a receiver. The initiator includes an initiator counter and an initiator PWM signal generator. The initiator counter advances an initiator count in response to an initiator clock signal. The initiator PWM signal generator generates an initiator PWM signal in response to the initiator count. The receiver includes a receiver counter, a receiver PWM signal generator, and circuitry configured to reset the receiver count. The receiver counter advances a receiver count in response to a receiver clock signal. The receiver PWM signal generator generates a receiver PWM signal in response to the receiver count. The circuitry resets the receiver count in response to a synchronization signal and based on an offset.