An analog-to-digital converter (ADC) is described. This ADC includes a conversion circuit with multiple bit-conversion circuits. During operation, the ADC may receive an input signal. Then, the conversion circuit may asynchronously perform successive-approximation-register (SAR) analog-to-digital conversion of the input signal using the bit-conversion circuits, where the bit-conversion circuits to provide a quantized representation of the input signal. For example, the bit-conversion circuits may asynchronously and sequentially perform the SAR analog-to-digital conversion to determine different bits in the quantized representation of the input signal. Moreover, the ADC may selectively perform self-calibration of a global delay of the bit-conversions circuits. Note that the timing self-calibration may be iterative and subject to a constraint that a maximum conversion time is less than a target conversion time.

A ramp voltage generator includes: a ramping cell array including a plurality of ramping current cells; a calibration cell array including a plurality of calibration current cells; and a current-voltage converter suitable for converting a current supplied from activated ramping current cells among the ramping current cells and activated calibration current cells among the calibration current cells into a voltage to generate a ramp voltage.

Body text indent—does not have paragraph numbering turned on. Not needed in the Abstract. An integrated circuit device includes a digital sine wave generator configured to produce portions of a digital sine wave, a combiner circuit configured to output each of the portions of the digital sine wave combined with a respective calibration code during operation in a post-production dynamic test mode, a digital to analog converter (DAC) configured to output an analog sine wave based on the output of the combiner circuit, and a test analog to digital converter (ADC) including an input terminal directly connected to the output of the DAC, and configured to generate a second digital sine wave based on the analog sine wave.

Input circuitry for an analog-to-digital converter (ADC) is provided. The input circuitry includes a calibration signal source configured to output a calibration signal for the ADC and an analog circuitry configured to receive and process an analog input signal for the ADC. The analog circuitry is further configured to generate a combined signal by combining the analog input signal and the calibration signal. The input circuitry further includes a buffer amplifier coupled to the analog circuitry and configured to supply a buffered signal to the ADC based on the combined signal. Further, the input circuitry includes neutralization circuitry configured to generate, based on the calibration signal, a neutralization signal for mitigating an unwanted signal component related to a limited reverse isolation of the analog circuitry. The neutralization circuitry is further configured to supply the neutralization signal to at least one of an input node and an intermediate node of the analog circuitry.

The present invention discloses a DAC method having signal calibration mechanism is provided. Operation states of current sources are controlled to generate an output analog signal by a DAC circuit according to a codeword of an input digital signal. An echo signal is generated by an echo transmission circuit according to the output analog signal. The codeword is mapped to generate an offset signal by a calibration circuit according to a codeword offset mapping table. The offset signal is processed to generate an echo-canceling signal by an echo-canceling circuit. By a calibration parameter calculation circuit, offset amounts are generated according to a difference between the echo signal and the echo-canceling signal, the offset amounts are grouped to perform statistic operation according to the operation states and current offset values are calculated according to calculation among groups and converted to codeword offset values to update the codeword offset mapping table.

An analog-to-digital converter of one embodiment in the present disclosure may comprise a first conversion unit generating an internal clock signal, generating a first digital code and a residual signal by converting an input signal in a successive approximation register (SAR) method in response to the internal clock signal and generating a flash clock signal in response to an external clock signal, a second conversion unit generating a second digital code by converting the residual signal in a flash method in response to the flash clock signal, and an output circuit generating an output digital signal in response to the first digital code and the second digital code.

A segmented digital-to-analog converter (DAC) includes DAC segments, an overrange DAC, and a dither control circuit. Each DAC segment includes a plurality of DAC cells for generating an analog output signal based on input data to each DAC segment. The overrange DAC generates an analog output signal based on a control signal. The dither control circuit adds a dither to first input data supplied to a higher-order DAC segment, subtract a portion of the dither from second input data supplied to a lower-order DAC segment, and generate the control signal for subtracting a remaining portion of the dither from an output of the segmented DAC in an analog domain. The dither added to the first input data may be one of +1, 0, and −1 and the portion of the dither subtracted from the second input data may be a half of the dither added to the first input data.

A digital-to-analog conversion device and method are provided. The control module is configured to split the input digital signal into n intermediate digital portions, divide the n intermediate digital portions by the corresponding conversion coefficients to obtain n intermediate digital signals and transmit the n intermediate digital signals to the n conversion modules. The n intermediate digital portions increase progressively. The conversion module is configured to perform digital-to-analog conversion on an intermediate digital signal to obtain a result including the conversion coefficient of the conversion module. The adder is configured to add output signals of the n conversion modules to obtain an analog signal. The feedback module is configured to obtain a feedback signal according to the analog signal. The control module is further configured to adjust the allocation of the n intermediate digital portions according to a target digital signal and the feedback signal.

An oscillator-based sensor interface circuit includes first and second input nodes arranged to receive first and second electrical signals representative of an electrical quantity, respectively; an analog filter; a first oscillator arranged to receive a first oscillator input signal and a second oscillator different from the first oscillator and arranged to receive a second oscillator input signal; a comparator arranged to compare signals coming from the first and second oscillators; a first feedback element arranged to receive a representation of the digital comparator output signal and to convert the representation into a first feedback signal to be applied to the oscillation means; a digital filter arranged to yield an output signal, being an filtered version of the digital comparator output signal; a second feedback element arranged to receive the output signal and to convert the output signal into a second feedback signal.

Provided is a time-to-digital converter, comprising a phase frequency detector configured to receive a phase-locked loop input clock and a feedback clock, a ring oscillator configured to perform oscillation with multi-phase clocks of a first period, a counter array configured to count the number of oscillations in which the ring oscillator oscillates in a first period by the number of positive integers during the first pulse width, a multiplexer configured to divide the first period into a plurality of zones using edge information of the multi-phase clocks of the ring oscillator, and selects and outputs voltage information of a plurality of neighboring phase clocks included in a first zone from the plurality of zones, an analog-to-digital converter, a calibrator, and a first adder, wherein the calibrator comprises, an offset lookup table generation circuit, a gain-corrected analog-to-digital conversion output generator, and a second adder.