Aspects of the description provide for an analog-to-digital converter (ADC) operable to convert an analog input signal to an output signal at an output of the ADC. In some examples, the ADC includes multiple sub-ADCs coupled in parallel, each of the multiple sub-ADCs coupled to the output of the ADC and operable to receive the analog input signal. The ADC is configured to operate the sub-ADCs in a consecutive operation loop including a transition phase in which the ADC operates each of the sub-ADCs sequentially for a first number of sequences, an estimation phase in which the ADC operates each of the sub-ADCs sequentially for a second number of sequences following the first number of sequences, and a randomization phase in which the ADC operates subsets of the sub-ADCs for a third number of sequences following the second number of sequences.

A dynamic element method includes the following operations: summing up most significant bits of a digital code in a previous period and a pointer signal in the previous period, in order to generate a first signal; outputting the first signal to be an adjusted pointer signal according to a clock signal; and decoding the adjusted pointer signal to be control signals, in which the control signals are configured to set corresponding relations of components of a first digital to analog converter circuits and the most significant bits, in order to utilize the components to convert the most significant bits.

An analog-to-digital converter includes a switch circuit, a first capacitor array, a second capacitor array and a comparator. A method of operating the analog-to-digital converter includes switching a swap signal to a first level in a first sampling period for the switch circuit to couple the first capacitor array to a first input terminal of the comparator and a first signal source, and couple the second capacitor array to a second input terminal of the comparator and a second signal source, and switching the swap signal to a second level in a second sampling period for the switch circuit to couple the first capacitor array to the second input terminal of the comparator and the second signal source, and couple the second capacitor array to the first input terminal of the comparator and the first signal source.

In some embodiments, a digital-to-analog converter (DAC) architecture can include an array having a total number of bit cells, and a control system configured to activate a selected number of the total number of bit cells and to deactivate the remaining bit cells. The selected number can be variable, such that the array consumes a quiescent current that depends on the selected number. The control system can be further configured to change the selected number when a signal condition exceeds a threshold duration.

A method of weight calibration in a DAC (25) is disclosed. The DAC (25) comprises an input port (100) for receiving a sequence of digital input words (x[n]), each representing a digital input sample, and a digital control circuit (110) configured to encode each digital input word (x[n]) into a control word (z[n]) representing the same digital input sample. Each bit (Z.sub.i) in the control word (z[n]) has a corresponding bit weight (w.sub.i) and is in the following considered to adopt values in {−1, 1}. Furthermore, the DAC (25) comprises a set (120) of analog weights, each associated with a unique one of the bits (Z.sub.i) in the control word (z[n]), and summation circuitry (130) configured to generate an analog sample corresponding to the digital input sample by summing the bits in the control word (Z.sub.i) weighted by the respective associated analog weights. The DAC (25) also has an output (140) for outputting the analog sample. The method comprises, during a measurement procedure, for a first set of at least one bit of the control word (z[n]), generating (300) the bits of the first set, such that a first sum of the bits in the first set weighted by their respective bit weights is, on average, above zero. Furthermore, the method comprises, during the measurement procedure, for a second set of at least one bit of the control word (z[n]), generating (310) the bits of the second set, such that a second sum of the bits in the second set weighted by their respective bit weights is, on average, below zero and such that the sum of the first sum and the second sum is, on average, equal to zero. The method also comprises detecting (330) a DC level at the output of the DAC during the measurement procedure. The method further comprises adjusting (340) at least one analog weight in response to the detected DC level. A corresponding DAC, a corresponding electronic apparatus, and a corresponding integrated circuit are also disclosed.

In some embodiments, a calibration circuit can include a first circuit configured to generate a first output voltage based on a first reference voltage, and a second circuit configured to compare the first output voltage and a second reference voltage. The calibration circuit can further include a calibration block configured to provide an adjustment to the first circuit based on the comparison of the first output voltage and the second reference voltage, with the adjustment being configured to compensate for a change in the first reference voltage. In some embodiments, such a calibration circuit can be utilized for and/or be a part of a digital-to-analog converter for wireless audio applications.

Aspects of the description provide for an analog-to-digital converter (ADC) operable to convert an analog input signal to an output signal at an output of the ADC. In some examples, the ADC includes multiple sub-ADCs coupled in parallel, each of the multiple sub-ADCs coupled to the output of the ADC and operable to receive the analog input signal. The ADC is configured to operate the sub-ADCs in a consecutive operation loop including a transition phase in which the ADC operates each of the sub-ADCs sequentially for a first number of sequences, an estimation phase in which the ADC operates each of the sub-ADCs sequentially for a second number of sequences following the first number of sequences, and a randomization phase in which the ADC operates subsets of the sub-ADCs for a third number of sequences following the second number of sequences.

A circuit having an array of Analog-to-Digital Converters (ADCs); a sampling order selector configured to select a sampling order of the ADCs and output corresponding sampling order control words; sampling pulse generators coupled between the sampling order selector and the respective ADCs, and configured to output respective sampling pulses based on the respective sampling order control words, wherein the ADCs are configured to sample and convert analog data into digital data in response to the sampling pulses; and a single clock generator configured to distribute a delay-matched clock to each of the ADCs in parallel, to each of the sampling pulse generators in parallel, and to the sampling order selector.

An analog-to-digital converter includes a switch circuit, a first capacitor array, a second capacitor array and a comparator. A method of operating the analog-to-digital converter includes switching a swap signal to a first level in a first sampling period for the switch circuit to couple the first capacitor array to a first input terminal of the comparator and a first signal source, and couple the second capacitor array to a second input terminal of the comparator and a second signal source, and switching the swap signal to a second level in a second sampling period for the switch circuit to couple the first capacitor array to the second input terminal of the comparator and the second signal source, and couple the second capacitor array to the first input terminal of the comparator and the first signal source.

Herein disclosed is an example analog-to-digital converter (ADC) and methods that may be performed by the ADC. The ADC may derive a first code that approximates a combination of an analog input value of the ADC and a dither value for the ADC sampled on a capacitor array. The ADC may further derive a second code to represent a residue of the combination with respect to the first code applied to the capacitor array. The ADC may combine the numerical value of the first code and the numerical value of the second code to produce a combined code applied to the capacitor array for deriving a digital output code. Combining the numerical value of the first code and the numerical value of the second code in the digital domain can provide for greater analog-to-digital (A/D) conversion linearity.