A charge sharing circuit includes a charge source having an accumulated first charge and a charge load having an accumulated second charge, where during a charge sharing interval the second charge is less than the first charge. A charge sharing regulator selectively couples between the charge source and the charge load along a charge sharing path. The charge sharing regulator regulates transfer of a shared amount of charge from the charge source to the charge load during the charge sharing interval.

A method of operation in an analog-to-digital converter (ADC) includes performing a calibration operation. The calibration operation includes sampling an input analog reference voltage. A sequence of charge sharing transfers is then performed with a charge sharing regulator to transfer an actual amount of charge between a charge source and a charge load based on the input analog reference voltage. The transferred actual amount of charge is compared to a reference charge value corresponding to the reference voltage. A control input to the charge sharing regulator is adjusted to correspondingly adjust charge sharing of a subsequent amount of charge based on the comparing.

An analog-to-digital converter (ADC) including input circuitry to receive an input analog signal having an analog signal level. Sampling circuitry couples to the input circuitry and includes first and second capacitor circuits to sample the received input analog signal. The first and second capacitor circuits exhibit a relative charge imbalance as a result of the sampling that corresponds to the analog signal level. Regulated charge sharing circuitry regulates charge sharing transfers during multiple charge sharing transfer sequences with the first and second capacitor circuits. A digital output generates multiple bit values based on the charge sharing transfer sequences.

An integrated circuit including a first passive component of capacitive, resistive, or inductive type, including: a plurality of second and third passive components of said type, each having a same first theoretical value Compu_t, the second components being connected together so that their values add, and each third component being associated with a first switch having its state determining whether the value of the third component adds to the values of the second components; and a plurality of fourth passive components of said type, each associated with a second switch having its state determining whether the value of the fourth component adds to the values of the second components, at least one of the fourth passive components having a second theoretical value equal to (1P).Compu_t or to (1+P).Compu_t, P being positive and smaller than .

The present application discloses an ADC (10). The ADC has an A/D conversion operation mode and a measurement operation mode. The ADC includes an input terminal (100), a DAC (104), and an output terminal (102). The input terminal is configured to receive an analog signal. The output terminal is configured to output a digital signal. The DAC includes a plurality of D/A conversion units. When the ADC operates in the A/D conversion operation mode, the ADC is configured to convert the analog signal into the digital signal, and when the ADC operates in the measurement operation mode, the digital signal related to a ratio of a capacitance of the D/A conversion unit to be measured to a total capacitance of the plurality of D/A conversion units.

A digital-to-analog converter is provided. The digital-to-analog converter includes a first plurality of digital-to-analog converter cells configured to generate a first analog signal. Further, digital-to-analog converter includes a second plurality of digital-to-analog converter cells configured to generate a second analog signal. The first analog signal and the second analog signal form a differential signal pair. Further, the digital-to-analog converter includes a transmission line transformer comprising a first input node coupled to the first plurality of digital-to-analog converter cells, a second input node coupled to the second plurality of digital-to-analog converter cells, and a first output node. The transmission line transformer is configured to present a first impedance at the first and second input nodes and to present a second impedance at the first output node.

A digital-to-analog converter is provided. The digital-to-analog converter includes a first plurality of digital-to-analog converter cells configured to generate a first analog signal. Further, digital-to-analog converter includes a second plurality of digital-to-analog converter cells configured to generate a second analog signal. The first analog signal and the second analog signal form a differential signal pair. Further, the digital-to-analog converter includes a transmission line transformer comprising a first input node coupled to the first plurality of digital-to-analog converter cells, a second input node coupled to the second plurality of digital-to-analog converter cells, and a first output node. The transmission line transformer is configured to present a first impedance at the first and second input nodes and to present a second impedance at the first output node.

A method for reducing data-dependent loading on a voltage reference pre-charges a capacitor of the capacitive digital-to-analog converter to configure the capacitor in a pre-charged state during a first interval. The method selectively discharges the capacitor from the pre-charged state according to a value of an input digital signal to configure the capacitor in a selectively discharged state during a second interval. The method holds an output node of the capacitive digital-to-analog converter at a reset voltage level during the first interval and the second interval. The output node is coupled to a first terminal of the capacitor. The method discharges any remaining charge on the capacitor and providing an output voltage signal to an output node of the capacitive digital-to-analog converter according to the selectively discharged state during a third interval. The output voltage signal has a voltage level corresponding to a value of the input digital signal.

The disclosure includes a successive approximation register (SAR) analog to digital converter (ADC). The SAR ADC includes a sampling network to store a sample of an analog signal. The SAR ADC also includes a comparator to successively compare the sample to reference values to determine a digital value corresponding to the sample of the analog signal. The comparator employs a plurality of comparator preamplifiers. The comparator also includes a programmable trim filter. The programmable trim filter is selectively set to adjust a bandwidth of the comparator preamplifiers to a bandwidth value corresponding with a preamplifier settling time subceeding a preamplifier settling threshold.

The disclosure includes a successive approximation register (SAR) analog to digital converter (ADC). The SAR ADC includes a sampling network to store a sample of an analog signal. The SAR ADC also includes a comparator to successively compare the sample to reference values to determine a digital value corresponding to the sample of the analog signal. The comparator employs a plurality of comparator preamplifiers. The comparator also includes a programmable trim filter. The programmable trim filter is selectively set to adjust a bandwidth of the comparator preamplifiers to a bandwidth value corresponding with a preamplifier settling time subceeding a preamplifier settling threshold.