A method of operating an analog-to-digital converter includes in a first sampling stage, switching a swap signal to a first level for a first selection circuit to reset a first capacitor array according to a first voltage configuration and for a second selection circuit to reset a second capacitor array according to the first voltage configuration, and in a second sampling stage, switching the swap signal to a second level for the first selection circuit to reset the first capacitor array according to the second voltage configuration and for the second selection circuit to reset the second capacitor array according to the second voltage configuration. A control logic circuit is used to switch the swap signal between the first level and the second level in a uniform order in a plurality of sampling stages.

A successive approximation register analog to digital converter device includes first and second digital to analog converter (DAC) circuits, a comparator circuit, a controller circuit, and a dynamic element matching (DEM) circuit. The first and second DAC circuits samples an input signal. The comparator circuit and the controller circuit generate first and second bits according to outputs of the first and second DAC circuits. The DEM circuit encodes the first bits to generate third bits, in order to refresh the first DAC circuit. After the first DAC circuit is refreshed, the controller circuit resets partial bits in the second bits. After the partial bits are reset, the comparator circuit generates comparison results according to outputs of the first and second DAC circuits. The controller circuit generates fourth bits according to the comparison results, and generates a digital output according to the first, second, and fourth bits.

In an embodiment a semiconductor device includes a first diode and a second diode of specified sizing or biasing ratio, a negative voltage supply, a first resistor for a proportional to absolute temperature (PTAT) voltage drop, wherein the first diode is connected between the negative supply voltage and the first resistor, an array of dynamically matched current sources employing a dynamic element matching controller, wherein the first resistor is connected between the first diode and a first input of the array, and wherein the second diode is connected between the negative supply voltage and a second input of the array and a successive approximation register (SAR) feedback loop configured to drive a voltage difference to zero, wherein the voltage difference occurs between a first node present between the first resistor and the first input of the array and a second node present between the second diode and the second input of the array.

An analog to digital conversion (ADC) circuit includes a voltage-controlled oscillator (VCO)-based quantizer that receives a voltage input signal to be quantized and provides a digital output. A predictor samples the digital output, evaluates correlation between successive samples, and predicts a predicted input sample from the correlation to minimize voltage-to-frequency transfer of the VCO. A feedback loop L1 with a digital to analog converter (DAC) receives the predicted input sample, converts it and subtracts it from the voltage input signal. A feedback loop L2 adds the predicted sample to the digital output.

A method of operating an analog-to-digital converter includes in a first sampling stage, switching a swap signal to a first level for a first selection circuit to reset a first capacitor array according to a first voltage configuration and for a second selection circuit to reset a second capacitor array according to the first voltage configuration, and in a second sampling stage, switching the swap signal to a second level for the first selection circuit to reset the first capacitor array according to the second voltage configuration and for the second selection circuit to reset the second capacitor array according to the second voltage configuration. A control logic circuit is used to switch the swap signal between the first level and the second level in a uniform order in a plurality of sampling stages.

Noise and distortion reduction in a signal processed through analog circuitry includes providing noise reduction circuitry to reduce signal noise generated by at least one analog circuit element. The noise reduction circuitry is adaptively configured to adjust a rate to apply noise reduction to the signal without introducing unwanted distortion. Distortion reduction circuitry is adaptively configured to adjust a rate to apply distortion reduction to the signal without introducing unwanted noise. The signal is processed through the analog circuitry using the adaptively configured noise reduction circuitry and adaptively configured distortion reduction circuitry to reduce both noise and distortion in the signal.

In accordance with an embodiment, a circuit includes a current digital-to-analog converter (DAC) having a current switching network coupled to a current DAC output, a first cascode current source coupled between a first supply node and the current switching network, a second cascode current source between a second supply node and the current switching network, and a shorting switch coupled between a first cascode node of the first cascode current source, and a second cascode node of the second cascode current source.

Provided is a selection device including an acquisition section for acquiring digital selection signals, and an output section for outputting selection signals to respective unit cells, each unit cell capable of being commanded to output the value zero. The selection device is characterized in that: each selection signal is for commanding the unit cell to output a value corresponding to that selection signal; the sum of the values to be output as commanded by the respective selection signals, which are output to the respective unit cells, is a value determined in association with the digital selection signal; and if the output corresponding to the digital selection signal is the value zero, then selection signals each commanding to output a non-zero value (N) are output to some of the unit cells.

Systems and methods are provided for digital-to-analog converters (DACs) with enhanced dynamic element matching (DEM) and calibration. DEM may be adapted based on assessment of one or more conditions that may affect the DACs or DEM functions thereof. The one or more condition may comprise amount of signal backoff. The adaption may comprise switching the DEM function (as a whole, or partially—e.g., individual DEM elements) on or off based on the assess conditions. The DACs may incorporate use of calibration. The DEM and/or the calibration may be applied to only a portion of the DAC, such as a particular segment (e.g., a middle segment comprising bits between the MSBs and the LSBs).

Apparatuses and methods for analog-digital conversion and corresponding systems having a sensor and an apparatus of this type are provided. Demodulation is executed with no variable preamplification, followed by continuous-time analog-digital conversion, at least in time segments, which further employs chopper techniques.