Methods and systems for an analog-to-digital converter with near-constant common mode voltage may comprise, in an analog-to-digital converter (ADC) having sampling switches on each of two input lines to the ADC, N double-sided and M single-sided switched capacitors on each input line: sampling an input voltage by closing the sampling switches, opening the sampling switches and comparing voltage levels between the input lines, iteratively switching the double-sided switched capacitors between a reference voltage (Vref) and ground, and iteratively switching the single-sided switched capacitors between ground and voltages that may equal Vref/2.sup.x where x ranges from 0 to m1 and m is a number of single-sided switched capacitors per input line. A common mode offset of the ADC may be less than V.sub.ADC.sub._.sub.fs/128+V.sub.ADC.sub._.sub.fs/256+V.sub.ADC.sub._.sub.fs/512+V.sub.ADC.sub._.sub.fs/1024 when m equals 4 and where V.sub.ADC.sub._.sub.fs is the full-scale voltage of the ADC.

An interleaved Analog-to-Digital Converter (ADC) has a reference channel receiving an attenuated analog input. The reference channel is also calibrated to remove capacitor-ratio mismatch, static, and dynamic mismatches and produces a linear replica of the data channels with negligible nonlinear errors due to attenuation. Nonlinear errors on the data channels are corrected by Harmonic Distortion HD2 and HD3 coefficients. A counter increments when the sign bit of a nonlinear-corrected channel code is negative. The count is doubled and reduced by a number of samples to generate a HD2 cost function that adjusts the HD2 coefficient in a LMS loop. A HD3 correlation is generated by multiplying the reference channel output by its difference with the nonlinear-corrected channel code. The sign of the correlation code increments a second counter which generates a HD3 cost function whose sign bit adjusts the HD3 coefficient. These 2 counters generate cost functions, eliminating sample storage.

A method for precise acquisition of a signal of a sensor, by an evaluation and control unit which has a multiplexer at whose inputs there is at least one reference voltage whose voltage value is known, a ground potential of the reference voltage, a measurement signal of the exhaust gas sensor, and a ground potential of the measurement signal. A computer is connected downstream from the multiplexer via a transmission path and via an ADC that converts a voltage between its two inputs into a digital value. The method provides that a plurality of individual measurements are carried out in which switching states of the multiplexer are modified, and digital values are subsequently acquired at the output of the ADC. The computer calculates a measurement value, corrected with regard to offset and gain, from these digital values.

An example analog-to-digital converter (ADC) comprising: sample and hold circuitry coupled to an analog input; a first sub-ADC coupled to the sample and hold circuitry; a multiplying digital-to-analog converter (M-DAC) coupled to the first sub-ADC; summation circuitry coupled to the sample and hold circuitry and the M-DAC; an amplifier coupled to the summation circuitry; a second sub-ADC coupled to the amplifier; and reference generation circuitry coupled to the first sub-ADC, the M-DAC, and the second sub-ADC, the reference generation circuitry including: reference voltage circuitry coupled to the M-DAC; a first resistor coupled to the reference voltage circuitry; a second resistor coupled to the first resistor; and a capacitor coupled in parallel to the second resistor by a switch.

This application relates to circuitry for processing sense signals generated by MEMS capacitive transducers for compensating for distortion in such sense signals. The circuitry has a signal path between an input (204) for receiving the sense signal and an output (205) for outputting an output signal based on said sense signal. Compensation circuitry (206, 207) is configured to monitor the signal at a first point along the signal path and generate a correction signal (Scorr); and modify the signal at at least a second point along said signal path based on said correction signal. The correction signal is generated as a function of the value of the signal at the first point along the signal path so as to introduce compensation components into the output signal that compensate for distortion components in the sense signal. The first point in the signal path may be before or after the second point in the signal path. The monitoring may be performed in an analogue or a digital part of the signal path and in either case the modification may be applied in an analogue or a digital part of the signal path.

Methods and systems for an analog-to-digital converter (ADC) with constant common mode voltage may include in an ADC comprising a sampling switch on a first input line to the ADC, a sampling switch on a second input line to the ADC, N switched capacitor pairs and M single switched capacitors on the first input line, and N switched capacitor pairs and M single switched capacitors on the second input line: sampling an input voltage by closing the sampling switches, opening the sampling switches and comparing voltage levels between the input lines, iteratively switching the switched capacitor pairs between a reference voltage (Vref) and ground based on the compared voltage levels, and iteratively switching the single switched capacitors between ground and voltages that are a fraction of Vref, which may equal Vref/2.sup.x where x ranges from 0 to m1 and m is a number of single switched capacitors per input line.

Methods and systems for an analog-to-digital converter (ADC) with constant common mode voltage may include in an ADC comprising a sampling switch on a first input line to the ADC, a sampling switch on a second input line to the ADC, N switched capacitor pairs and M single switched capacitors on the first input line, and N switched capacitor pairs and M single switched capacitors on the second input line: sampling an input voltage by closing the sampling switches, opening the sampling switches and comparing voltage levels between the input lines, iteratively switching the switched capacitor pairs between a reference voltage (Vref) and ground based on the compared voltage levels, and iteratively switching the single switched capacitors between ground and voltages that are a fraction of Vref, which may equal Vref/2.sup.x where x ranges from 0 to m1 and m is a number of single switched capacitors per input line.

When a level of a signal output from a pixel is higher than a comparison level, the signal output from the pixel is converted into a digital signal during a first period by using a first reference signal. If the level of the signal output from the pixel is lower than the comparison level, the signal output from the pixel is converted into a digital signal during a second period that is longer than the first period by using a second reference signal.

An analog to digital converter (ADC) system that includes a first amplifier configured to amplify an analog input signal to produce an amplified direct current (DC) signal, an ADC configured to receive the amplified DC signal and convert the amplified DC signal into a digital DC signal, a digital to analog converter configured to receive the digital DC signal and convert the digital DC signal into an analog DC signal, and a second amplifier configured to receive an analog alternating current (AC) signal comprising the analog DC signal subtracted from the analog input signal and amplify the analog AC signal to produce an amplified AC signal. The ADC is further configured to receive the amplified AC signal and produce a digital AC signal. The second amplifier has a gain greater than a gain of the first amplifier.

This application relates to circuitry for processing sense signals generated by MEMS capacitive transducers for compensating for distortion in such sense signals. The circuitry has a signal path between an input (204) for receiving the sense signal and an output (205) for outputting an output signal based on said sense signal. Compensation circuitry (206, 207) is configured to monitor the signal at a first point along the signal path and generate a correction signal (S.sub.corr); and modify the signal at at least a second point along said signal path based on said correction signal. The correction signal is generated as a function of the value of the signal at the first point along the signal path so as to introduce compensation components into the output signal that compensate for distortion components in the sense signal. The first point in the signal path may be before or after the second point in the signal path. The monitoring may be performed in an analogue or a digital part of the signal path and in either case the modification may be applied in an analogue or a digital part of the signal path.