An electronic circuit system with an input for receiving an analog signal having a frequency and comprising noise, that noise including input referred noise, and the noise fluctuates in a range. The system also comprises a signal path with: (i) an analog to digital converter for providing a digital output value in response to a clock period; (ii) a feedback node; and (iii) circuitry for limiting a signal swing at the feedback node, during a period of the clock period, to be no greater than an RMS value of the noise. The analog to digital converter is further for providing the digital output value in response to the analog signal and the signal swing at the feedback node.

An electronic circuit system with an input for receiving an analog signal having a frequency and comprising noise, that noise including input referred noise, and the noise fluctuates in a range. The system also comprises a signal path with: (i) an analog to digital converter for providing a digital output value in response to a clock period; (ii) a feedback node; and (iii) circuitry for limiting a signal swing at the feedback node, during a period of the clock period, to be no greater than an RMS value of the noise. The analog to digital converter is further for providing the digital output value in response to the analog signal and the signal swing at the feedback node.

A device for digitizing an analogue signal, wherein a distortion signal outlet of a distortion signal generator is only coupled to an analogue digital converter by passive components.

An audio in/out device includes an audible in/out transducer operable to convert an audible input signal to an audio receive (RX) signal and convert an audio transmit (TX) signal to an audible output signal. The audio in/out device further includes an audio receive/transmit (RX/TX) circuit operable to convert a digital TX signal to the audio TX signal for transmission to the audible in/out transducer, receive the audio RX signal from the audible in/out transducer, and convert the audio RX signal into a digital transmit/receive (Tx/Rx) signal. The digital Tx/Rx signal includes a representation of the audio RX signal.

A field device includes a detector and a converter communicative to the detector. The detector also may include, but is not limited to, a sensor, an analog-to-digital converter, and a first processor. The sensor may be configured to acquire an analog measurement signal. The analog-to-digital converter may be configured to convert the analog measurement signal to a digital signal. The first processor may be configured to convert the digital signal into a measurement value to generate a digital signal representing at least the measurement value. The converter may be configured to convert the digital signal representing at least the measurement value into an instrumentation signal to output the instrumentation signal. The detector may be configured to transmit the digital signal representing at least the measurement value and the analog measurement signal to the converter.

Disclosed examples include pipeline ADC, balancing circuits and methods to balance a load of a reference circuit to reduce non-linearity and settling effects for a reference voltage signal, in which balancing capacitors are connected to a voltage source in a pipeline stage ADC sample time period to precharge the balancing capacitors using a voltage above the reference voltage, and a selected set of the precharged balancing capacitors is connected to provide charge to the output of the reference circuit during the second time period.

Disclosed examples include pipeline ADC, balancing circuits and methods to balance a load of a reference circuit to reduce non-linearity and settling effects for a reference voltage signal, in which balancing capacitors are connected to a voltage source in a pipeline stage ADC sample time period to precharge the balancing capacitors using a voltage above the reference voltage, and a selected set of the precharged balancing capacitors is connected to provide charge to the output of the reference circuit during the second time period.

In one embodiment, an apparatus includes: a first voltage controlled oscillator (VCO) analog-to-digital converter (ADC) unit to receive a first portion of a differential analog signal and convert the first portion of the differential analog signal into a first digital value; a second VCO ADC unit to receive a second portion of the differential analog signal and convert the second portion of the differential analog signal into a second digital value; a combiner to form a combined digital signal from the first and second digital values; a decimation circuit to receive the combined digital signal and filter the combined digital signal into a filtered combined digital signal; and a cancellation circuit to receive the filtered combined digital signal and generate a distortion cancelled digital signal, based at least in part on a coefficient value.

Embodiments of a multi-channel analog to digital converter (ADC) include: a first multiplying digital to analog converter (MDAC) having: first and second switched capacitor circuit paths respectively coupled between first and second input nodes and an input node of a first gain element, a second MDAC having: third and fourth switched capacitor circuit paths respectively coupled between third and fourth input nodes and an input node of a second gain element, a third MDAC having: fifth and sixth switched capacitor circuit paths respectively coupled between a fifth input node and an input node of a third gain element, seventh and eighth switched capacitor circuit paths respectively coupled between a sixth input node and the input node of the third gain element, the fifth input node coupled to an output node of the first gain element, the sixth input node coupled to an output node of the second gain element.

Embodiments of a multi-channel analog to digital converter (ADC) include: a first multiplying digital to analog converter (MDAC) having: first and second switched capacitor circuit paths respectively coupled between first and second input nodes and an input node of a first gain element, a second MDAC having: third and fourth switched capacitor circuit paths respectively coupled between third and fourth input nodes and an input node of a second gain element, a third MDAC having: fifth and sixth switched capacitor circuit paths respectively coupled between a fifth input node and an input node of a third gain element, seventh and eighth switched capacitor circuit paths respectively coupled between a sixth input node and the input node of the third gain element, the fifth input node coupled to an output node of the first gain element, the sixth input node coupled to an output node of the second gain element.