Systems and methods for an asynchronous successive approximation register analog-to-digital converter (SAR ADC) with word completion algorithm may include a SAR ADC comprising a plurality of switched capacitors, a comparator, a metastability detector including a timer having a tunable time interval, and a successive approximation register. The SAR ADC may sample input signals at inputs of the switched capacitors; compare signals at outputs of the switched capacitors, each for a respective bit; sense whether a metastability condition exists for the comparator using the timer and setting a metastability flag upon each metastability detection for each bit; increase a value of the tunable time interval if more than one metastability flag is set during conversion of a sampled input signal; decrease a value of the tunable time interval if no metastability flags are set; and use the flags for a word completion in the cases when not all the bits have been evaluated.

A method and circuit for recovering data from a digital bitstream received from an analog to digital converter includes asynchronously oversampling the digital bitstream at a sampling rate dictated by an estimate of a clock rate of the analog to digital converter and a nominal oversampling factor. The method and circuit also includes calculating widths of bits of the digital bitstream, and calculating a learned oversampling factor using the calculated widths of a predetermined number of bits of the digital bitstream and a minimization function. The method and circuit also includes calculating data bits to be inserted to a digital filter for digestion using the calculated widths of the bits of the digital bitstream and the learned oversampling factor.

A successive-approximation-register (SAR) analog-to-digital converter (ADC) is provided in the invention. The SAR ADC includes an analog circuit and a digital control circuit. The digital control circuit is coupled to the analog circuit. The digital control circuit includes a calibration circuit, a memory device, and an asynchronous control circuit. The calibration circuit is configured to perform a calibration operation. The memory device is coupled to the calibration circuit and stores calibration information generated by performing the calibration operation. The asynchronous control circuit is coupled to the memory device, and reads the calibration information from the memory device in an asynchronous control mode. In the asynchronous control mode, before the asynchronous control circuit performs the operations of the SAR ADC, the asynchronous control circuit removes the non-idea effects of the SAR ADC according to the calibration information.

Systems and methods are related to a successive approximation analog to digital converter (SAR ADC). The SAR ADC includes a sample and digital to analog conversion (DAC) circuit configured to sample an input voltage, a comparator circuit coupled to the sample and DAC circuit and having an output, a first set of storage circuits, and a comparator driver. The comparator driver is disposed between the output and the first set of storage circuits (e.g., ratioed latched. The first set of storage circuits are coupled to the comparator circuit and the sample and DAC circuit. The comparator driver can include a first driver and second driver. The first driver is coupled to a first input of a first storage circuit of the first set of storage circuits, and the second driver is coupled to first inputs of a second set of storage circuits within the first set of storage circuits.

This invention is related to the method providing computation of the signal frequency components in an acceptable accuracy in contravention of the shifts in the phase and the magnitude information caused by asynchronous sampling of the signals in the process of asynchronous sampling of metal detectors wherein the received signal by the receiver unit (4) divided into time intervals, say timing values those are far shorter than the sampling period and correspond to nearest probable sampling of the ADC (6); providing the computation of the sine and cosine coefficients or exponents of time constant coefficients of the said timing value from previously located or dynamically generated coefficient table; resulting the elimination of the requirement of synchronous sampling and the requirement of the signal period is multiple of the sampling period.

A circuit portion comprising a clock domain is disclosed. A first clock is arranged to clock components in the clock domain. An analogue to digital converter is clocked by a second clock with a duty cycle. The second clock is derived from the first clock. The analogue to digital converter is arranged to output a feedback signal upon finishing a conversion of a sample, and the feedback signal is arranged to control the duty cycle.

A motor driver includes an analog-to-digital converter (ADC) which, when a voltage sensing signal detected at a phase voltage of a specific coil in a floating period is input, samples the input voltage sensing signal at each of a plurality of sampling points and converts the voltage sensing signal into digital voltage sampling data and a back electromotive force voltage determination unit which determines a back electromotive force voltage of the specific coil on the basis of a plurality of pieces of the digital voltage sampling data.

A method of enhancing SAR ADC performance includes employing PVT processor to correct process, voltage and temperature (PVT) variation. The PVT processor senses process, supply voltage and temperature information then maximize the time for SAR binary search process. The PVT processor first applies coarse optimization to correct process and voltage variation then applies fine optimization to correct the temperature variation. The SAR ADC is operated at its optimized PVT condition and its performance is enhanced after PVT optimization.

Disclosed is a bit error rate (BER) forecast circuit for successive approximation register analog-to-digital conversion. The BER forecast circuit includes an N bits successive approximation register analog-to-digital converter (N bits SAR ADC) and an estimation circuit. The N bits SAR ADC is configured to carry out a regular operation at least N times and an additional operation at least X time(s) in one cycle of conversion time, in which the N is an integer greater than 1 and the X is an integer not less than zero. The estimation circuit is configured to generate a test value according to total times the N bits SAR ADC carrying out the additional operation in Y cycles of the conversion time, in which the Y is a positive integer and the test value is related to the bit error rate of the N bits SAR ADC.

A digital signal processing circuit includes an analog gain compensator that compensates for an analog gain of a baseband signal including a plurality of component carriers (CCs) to output a compensated baseband signal; an analog-to-digital converter (ADC) that converts the compensated baseband signal into a first digital signal; a plurality of filtering circuits that generate a second digital signal from the first digital signal; and a control circuit. Each filtering circuit sequentially filters the first digital signal so that a corresponding one of the second digital signals retains one CC among the CCs, compensates for a digital gain, and a performs down-sampling. The control circuit generates an analog gain control signal for controlling the analog gain based on the second digital signals and a digital gain control signal for controlling the digital gain.