A system (and associated method) includes an input flip-flop, a counter, and a clock tree. The input flip-flop includes a clock input terminal configured to be coupled to a device clock, or a clock generated from a phase-locked loop, and a data input terminal configured to be coupled to a first reference signal. The input flip-flop is configured to use the device clock to latch the reference signal to produce a latched reference signal. The counter is configured to count pulses of the device clock starting upon detection of the latched reference signal and to output a second reference signal comprising a pulse for every L pulses of the device clock. The clock tree is configured to divide down the device clock to generate a first output clock. The clock tree is configured to be synchronized by a pulse of the second reference signal.

An electronic device includes a first sample circuit configured to generate a first sampling signal by sampling an input signal in response to edges of a clock signal, a first comparator configured to generate a first logic decision signal by comparing a voltage level of the first sampling signal with a reference voltage level, an analog bang-bang phase detector configured to generate a first detection signal by executing an exclusive OR (XOR) operation on successive samples of the first logic decision signal, and a digitally controlled oscillator configured to vary a frequency of the clock signal according to the first detection signal.

An electronic device includes a first sample circuit configured to generate a first sampling signal by sampling an input signal in response to edges of a clock signal, a first comparator configured to generate a first logic decision signal by comparing a voltage level of the first sampling signal with a reference voltage level, an analog bang-bang phase detector configured to generate a first detection signal by executing an exclusive OR (XOR) operation on successive samples of the first logic decision signal, and a digitally controlled oscillator configured to vary a frequency of the clock signal according to the first detection signal.

An apparatus is described. The apparatus includes a counter circuit having ordered state element circuits where a respective clock input of a state element circuit is fed by a data output of a preceding lower ordered bit state element. The counter circuit also being programmable to enable different amounts to be counted by the counter circuit, wherein respective reload values for the amounts are received at the state elements as a respective asynchronous set or reset.

A back side illuminated image sensor may operate using the single-photon avalanche diode (SPAD) concept in a Geiger mode of operation for single photon detection. The image sensor may be implemented using two layer stacking with a silicon on insulator (SOI) chip. The chip-to-chip electrical connections between the top level image sensing chip and the second level ASIC circuit chip may be realized at each pixel with a single bump connection per pixel. A light level signal may be obtained from pixels that have photon counting capabilities while a distance measurement signal for 3-dimensional imaging may be obtained from pixels that have time-of-flight (ToF) detection capabilities. Both types of pixels may be integrated within the same array and use the same SPAD structure placed on the top chip.

A counter includes: a computing module (100) and N counting modules (101). Each counting module includes a plurality of counting spaces corresponding to different counting entries, and counting spaces of the same counting entry in different counting modules have the same address, wherein the counting module is arranged to provide a value for computing to the computing module in response to a counting application of a counting application source. The computing module is arranged to read values of the same counting entry in different counting modules and accumulate the read values to obtain a total count value of the counting entry, N being an integer not less than 1. Also disclosed is a counting method.

A counter includes: a computing module (100) and N counting modules (101). Each counting module includes a plurality of counting spaces corresponding to different counting entries, and counting spaces of the same counting entry in different counting modules have the same address, wherein the counting module is arranged to provide a value for computing to the computing module in response to a counting application of a counting application source. The computing module is arranged to read values of the same counting entry in different counting modules and accumulate the read values to obtain a total count value of the counting entry, N being an integer not less than 1. Also disclosed is a counting method.

Illustrated are a switched-capacitor DC-DC convertor and a control method thereof. The switched-capacitor DC-DC convertor includes a switched-capacitor circuit, a latched comparator and a clock generating module. The switched-capacitor circuit converts an input voltage into an output voltage through a phase switching operation. The latched comparator receives a clock signal, and compares the output voltage and a reference voltage according to the clock signal, to generate the control signal, which triggers a phase switching operation of the switched-capacitor circuit. The clock generating module generates the clock signal, and adjusts a frequency of the clock signal according to variation of the control signal.

A semiconductor device includes a clock divider that receives a clock signal and generates even and odd clock signals. The clock signal includes a first frequency, while the even and odd clock signals each includes a second frequency that is half the first frequency. The semiconductor device also includes even and odd command paths coupled to the clock divider each having a set of logic and a set of flip-flops. The even command path receives a command and the even clock signal and outputs an even output signal. The odd command path receives the command and the odd clock signal and outputs an odd output signal. The semiconductor device also includes combination circuitry coupled to the even and odd command paths that combines the even and odd output signals.

A pulse counting circuit receives pulses supplied by a source circuit having at least two inverted pulse signal supply terminals. The circuit includes a first counter to count pulses of a first pulse signal and supply a first count and a second counter to count pulses of a second pulse signal and supply a second count. A selection circuit selects one of the first and second counts.