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 fractional dividing module includes an output clock generating circuit, for receiving an input clock signal and generating an output clock signal according to a first control signal, comprising a first delay unit, for delaying the input clock signal to generate a delayed input clock signal; and a selecting unit, for selecting one of the input clock signal and the delayed input clock signal to generate the output clock signal according to the first control signal; and a control circuit, for dividing the output clock signal to generate the first control signal according to a dividing control signal, wherein the dividing control is adjusted to control a frequency ratio between the output clock signal and the input clock signal.

An electronic device includes a control logic portion suitable for generating a hold control signal based on a count enable signal, and a counting portion suitable for performing a counting operation while a latch operation stops during a counting section and performing the latch operation while the counting operation stops during a holding section based on the hold control signal and a counting clock signal.

A frequency divider may include the following elements: a first inverter, a second inverter, and a third inverter, which are connected in a ring structure, wherein the second inverter is connected to an output terminal of the frequency divider; a fourth inverter connected to a first input terminal of the frequency divider and to a power supply terminal of the first inverter; a fifth inverter connected to a second input terminal of the frequency divider and to a power supply terminal of the third inverter; a first transistor connected to the second input terminal of the frequency divider and to a ground terminal of the first inverter; and a second transistor connected to the first input terminal of the frequency divider and to a ground terminal of the third inverter. The second inverter, the fourth inverter, and the fifth inverter may receive a power supply voltage.

An electronic device includes a control logic portion suitable for generating a hold control signal based on a count enable signal, and a counting portion suitable for performing a counting operation while a latch operation stops during a counting section and performing the latch operation while the counting operation stops during a holding section based on the hold control signal and a counting clock signal.

An integrated circuit (IC) device includes a first IC chip, a second IC chip, and a chip-to-chip interface connected between the first IC chip and the second IC chip. The chip-to-chip interface communicates an interface clock signal and a logic clock signal between the first IC chip and the second IC chip. The interface clock signal is synchronous with a data signal received by one of the first IC chip and the second IC chip. The logic clock signal is asynchronous with the data signal.

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.

An in-memory computation circuit includes a memory array with memory cells arranged in a matrix in rows and columns. Groups of memory cells store computational weights for an in-memory compute (IMC) operation that is performed with a first multiply and accumulate (MAC) elaboration to produce a first analog signal and a second MAC elaboration to produce a second analog signal. An analog-to-digital converter circuit operates to: increment a count value in a counter circuit in response to the first analog signal; convert the count value in the counter circuit to a negated count value; and increment the count value in the counter circuit starting from the negated count value in response to the second analog signal.

An electronic device includes a control logic portion suitable for generating a hold control signal based on a count enable signal, and a counting portion suitable for performing a counting operation while a latch operation stops during a counting section and performing the latch operation while the counting operation stops during a holding section based on the hold control signal and a counting clock signal.

A medical device with a self-sustaining power source is disclosed herein. The medical device includes a pump and at least one mechanical activation mechanism for engaging the pump to cause a dose event. An energy generator coupled to the activation mechanism generates energy each time the activation mechanism is actuated. The generated energy is supplied to a dose counter of the infusion device.