An example apparatus includes: nonlinearity function selection circuitry with an output, the nonlinearity function selection circuitry to select a type of a nonlinearity function, the nonlinearity function to model nonlinearity portions of data output from an analog-to-digital converter, nonlinearity function term generation circuitry with a first input coupled to the output, the nonlinearity function term generation circuitry to generate one or more nonlinearity function terms of the nonlinearity function based on the type of the nonlinearity function and the data, and coefficient determination circuitry with a second input coupled to the output, the coefficient determination circuitry to determine one or more nonlinearity function coefficients based on the one or more nonlinearity function terms, the nonlinearity portions of the data to be compensated based on the one or more nonlinearity function coefficients.

According to an embodiment, a digital microphone includes an analog-to-digital converter (ADC) for receiving an analog input signal; a DC blocker component coupled to the ADC; a digital low pass filter coupled to the DC block component; and a nonlinear compensation component coupled to the digital low pass filter for providing a digital output signal.

One or more embodiments of a successive approximation type analog-to-digital converter that converts an analog input into a digital conversion value and outputs the digital conversion value, may include: a capacitance DAC that generates a bit-by-bit potential based on an analog input; a comparator that compares the potential generated by the capacitance DAC, wherein the comparator is a memory cell rewriting type, the comparator includes a first stage current mirror type operational amplifier; and a second stage memory cell; a conversion data generator that generates conversion data of resolution bits based on a comparison result of the comparator; and a correction circuit that corrects an output error of the conversion data caused by an offset error of the comparator by adding or subtracting an offset correction value that is a fixed value, and outputs the conversion data as a digital conversion value.

VCO ADCs consume relatively little power and require less area than other ADC architectures. However, when a VCO ADC is implemented by itself, the VCO ADC can have limited bandwidth and performance. To address these issues, the VCO ADC is implemented as a back end stage in a VCO-based continuous-time (CT) pipelined ADC, where the VCO-based CT pipelined ADC has a CT residue generation front end. Optionally, the VCO ADC back end has phase interpolation to improve its bandwidth. The pipelined architecture dramatically improves the performance of the VCO ADC back end, and the overall VCO-based CT pipelined ADC is simpler than a traditional continuous-time pipelined ADC.

The present invention discloses a digital-to-analog conversion apparatus having signal calibration mechanism is provided. A digital-to-analog conversion circuit includes conversion circuits to generate an output analog signal and echo-canceling analog signals. An echo transmission circuit processes an echo-transmitting path to generate an echo signal. An echo calibration circuit generates an output calibration signal and echo-canceling calibration signals according to an input digital circuit through calibration circuits corresponding to the conversion circuits. A calibration parameter calculating circuit generates a plurality of offsets according to an error signal of the echo signal relative to the calibration signals and path information related to the echo calibration circuit. The echo calibration circuit makes response coefficients converge according to the error signal and pseudo-noise transmission path information from the digital-to-analog conversion circuit to the echo transmission circuit, and updates codeword offset table according to the offset.

A time-interleaved Analog-to-Digital Converter, ADC, system is provided. The time-inter- leaved ADC system includes time-interleaved first and second ADC circuits and a switching circuit. The switching circuit is configured to selectively supply an analog input signal for digitization to at least one of the first ADC circuit, the second ADC circuit or ground, and to selectively supply an analog calibration signal to at least one of the first ADC circuit, the second ADC circuit or ground. Further, the time-interleaved ADC system includes an output circuit configured to selectively generate, based on least one of a first digital signal output by the first ADC circuit and a second digital signal output by the second ADC circuit, a digital output signal.

This inhalation component generation device comprises: a load which vaporizes or atomizes an inhalation component source using power from a power supply; and a control unit. The control unit comprises: a voltage sensor which uses a predefined correlation to convert the analog voltage value of a power supply to a digital voltage value and outputs the digital voltage value; and a power control unit which controls the supply of power from the power supply to the load on the basis of the digital voltage value. The control unit is configured to be capable of calibrating the correlation on the basis of changes in the digital voltage value or the analog voltage value obtained during charging of the power supply.

This inhalation component generation device comprises: a load which vaporizes or atomizes an inhalation component source using power from a power supply; and a control unit. The control unit comprises: a voltage sensor which uses a predefined correlation to convert the analog voltage value of a power supply to a digital voltage value and outputs the digital voltage value; and a power control unit which controls the supply of power from the power supply to the load on the basis of the digital voltage value. The control unit is configured to be capable of calibrating the correlation on the basis of changes in the digital voltage value or the analog voltage value obtained during charging of the power supply.

An analog-to-digital converter (ADC) includes a digital-to-analog converter (DAC) and a comparator having a first input coupled to receive an output voltage of the DAC, a second input, and a comparison output. The ADC also includes successive-approximation-register (SAR) circuitry having an input to receive the comparison output, and an output to provide an uncalibrated digital value. The DAC includes a Most Significant Bits (MSBs) sub-DAC including a set of MSB DAC elements and a Least Significant Bits (LSBs) sub-DAC including a set of LSB DAC elements. The ADC also includes calibration circuitry which receives the uncalibrated digital value and applies one or more calibration values to the uncalibrated digital value to obtain a calibrated digital value. The calibration circuitry obtains a calibration value for each MSB DAC element using the set of LSB DAC elements, the termination element, and at least one of the one or more redundant DAC elements.

An analog-to-digital conversion (ADC) system is operated with a duty cycle. During the ON period, the ADC circuits perform analog-to-digital conversions of an analog input signal. During the Standby period, the ADC system is in either a standby state or a foreground calibration state. The ADC system operates in a reduced-power mode in the standby state. In the foreground calibration state, the ADC system performs a portion of a foreground calibration cycle during a calibration time slot. The foreground calibration cycle is performed over multiple calibration time slots. The foreground calibration cycle and the calibration time slots are configurable by changing the values of control registers that represent calibration parameters.