An IC that performs integer and fractional divisions is disclosed. The IC comprises a plurality of shift registers that forms a shift register ring. Consecutive shift registers are coupled to each other through a multiplexer. The IC also includes a multiplexer controller that determines the shift registers to be activated within the shift register ring. The multiplexer controller determines the activation based upon a divisional factor. The IC also includes a pattern controller that generates the control signal to program the shift register.

The sensor device includes a counter for counting the number of count commands used to perform measurements while maintaining among multiple sensor devices the ratio of measurement intervals; a ratio-holding-unit for setting the ratio to a desired ratio and holding respective values of the ratio for each of the multiple sensor devices; a sampling-timing-generating-unit for receiving a count value of the counter and the setting value of the ratio held by the ratio-holding-unit, and for generating a sampling timing signal based on the comparison result between the count value and the setting value; and a sampling-unit for sampling a detection signal detected by the detecting unit, by using the sampling timing signal generated by the sampling-timing-generating-unit.

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.

Embodiments relate to a system and method of generating a duty-cycle matched differential clock divider circuit. The duty-cycle matched differential clock divider circuit may include a primary latch, differential latch, and a first inverter. The primary latch may be coupled to receive a feedback signal and complementary input clock signals. The primary latch may be configured to produce a first output signal. The differential latch may be coupled to receive the first output signal produced by the primary latch and the complementary input clock signals. The differential latch may be configured to produce a second output signal and a third output signal. The first inverter may be coupled to receive the second output signal produced by the differential latch, and may be configured to produce the feedback signal applied to an input of the primary latch.

A monitoring circuit includes first and second oscillators, first and second frequency dividers, first and second counters, a determination portion, and an identification portion. The first and second frequency dividers respectively divide frequencies of first and second clock signals outputted from the first and second oscillators, respectively. The first and second counters respectively count the numbers of clocks of the second and first clock signals at first and second numbers of periods of first and second frequency-divided signals outputted from the first and second frequency dividers, respectively. The determination portion determines, based on results of counting by the first and second counters, whether or not an abnormality has occurred in either of the first and second clock signals. The identification portion identifies, at the occurrence of an abnormality in either of the first and second clock signals, which of the first and second clock signals is in an abnormal state.