A multibit flash quantizer circuit, such as included as a portion of delta-sigma conversion circuit, can be operated in a dynamic or configurable manner. Information indicative of at least one of an ADC input slew rate or a prior quantizer output code can be used to establish a flash quantizer conversion window. Within the selected conversion window, comparators in the quantizer circuit can be made active. Comparators outside the conversion window can be made dormant, such as depowered or biased to save power. An output from such dormant converters can be preloaded and latched. In this manner, full resolution is available without requiring that all comparator circuits within the quantizer remain active at all times.

A method of arranging a capacitor array of a successive approximation register analog-to-digital converter in a successive approximation process, the method including: splitting a binary capacitor array into unit capacitors, then sorting, grouping, and rotating the original binary capacitive array involved in successive approximation conversion.

A digital-to-analog converter (DAC) may have an encoder that generates a multi-bit output based on a multi-bit input, a plurality of first converter elements, with each first converter element generating an output according to a single bit of the multi-bit output of the encoder; and a combiner that generates a combined output based on combining outputs from the plurality of first converter elements. The number of bits in the multi-bit input being two or more and the number of bits in the multi-bit output being greater than the number of bits in the multi-bit input. The DAC may also have one or more second converter elements, with second converter element generating an output according to a single bit, and the combiner may generates the combined output based on combining outputs from the plurality of first converter elements with outputs from the one or more second converter elements.

Disclosed examples include a segmented DAC circuit, including an R-2R resistor DAC to convert a first subword to a first analog output signal, an interpolation DAC to offset the first analog output signal based on an N-bit digital interpolation code signal to provide the analog output signal, and a Sigma Delta modulator to modulate a modulator code to provide the N-bit digital interpolation code signal that represents a value of second and third subwords.

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.

Systems and methods are provided for managing dynamic element matching (DEM) in digital-to-analog converters (DACs). One or more parameters associated with the DAC and/or a signal being converted via the DAC; and based on the one or more parameters, conditions affecting dynamic element matching in the DAC may be assessed. Based on the assessing of the conditions, one or more adjustments may be determined and dynamically applied to the dynamic element matching in the DAC.

A D/A converter for converting a digital signal with a predetermined number of bits to an analog signal, the D/A converter includes a plurality of component groups that include a plurality of components included in the D/A converter and are connected to an output unit for outputting the analog signal in a predetermined order; and a start position change unit that changes a start position within the plurality of the component groups used for generating a single analog signal by using a predefined shift pattern when generating the single analog signal corresponding to the digital signal.

In a digital-to-analog converter (DAC) that includes one or more conversion circuits, with each conversion circuit configured to handle one or more bits in an input signal to the DAC, one or more types of errors that occur during operation of the DAC may be detected, and one or more adjustments may be determined for correcting the one or more types of errors that occur during operation of the DAC and/or for reducing effects resulting from the one or more types of errors. At least one of the one or more adjustments may applied, with the at least one of the one or more adjustments is applied to only a subset of one or more conversion circuits. The DAC may be adaptive switched among a plurality of modes, and adjustments may be applied only in one or more of the modes but not in all of the modes.

A data converter includes multiple subunits to convert an input such as a radio frequency (RF) signal. The subunits are selected to sample the input in an order that varies over time. Two or more subunits are enabled at the same time. The selected subunits are configured to convert the input from an analog signal to a digital signal or vice versa.

A linear continuous-time (CT) delaying summation block is one of the key building blocks for CT multi-stage analog-to-digital converters (ADCs) such as CT pipeline ADCs and CT multi-stage delta-sigma (MASH) ADCs. The CT summation block is typically used on a stage of a CT multi-stage ADC to subtract a digital-to-analog converter (DAC) output signal from an analog input signal of the stage. Rather than using a current-mode summation, the CT delaying summation block can be implemented with voltage-mode summation.