Single-stage and multiple-stage current-mode Analog-to-Digital converters (iADC)s utilizing apparatuses, circuits, and methods are described in this disclosure. The disclosed iADCs can operate asynchronously and be free from the digital clock noise, which also lowers dynamic power consumption, and reduces circuitry overhead associated with free running clocks. For their pseudo-flash operations, the disclosed iADCs do not require their input current signals to be replicated which saves area, lowers power consumption, and improves accuracy. Moreover, the disclosed methods of multi-staging of iADCs increase their resolutions while keeping current consumption and die size (cost) low. The iADC's asynchronous topology facilitates decoupling analog-computations from digital-computations, which helps reduce glitch, and facilitates gradual degradation (instead of an abrupt drop) of iADC's accuracy with increased input current signal frequency. The iADCs can be arranged with minimal digital circuitry (i.e., be digital-light), thereby saving on die size and dynamic power consumption.

An analog to digital converting module includes a comparator, at least one digital to analog convertor, and a reference buffer. The comparator is configured to compare a first input signal and a second input signal so as to output a comparing signal. The at least one at least one digital to analog convertor includes at least one capacitor. The reference buffer is configured to provide a reference signal. The at least one digital to analog convertor receives the reference signal such that a ripple signal is generated according to a change of a voltage of the reference signal. The capacitance of the capacitor of the at least one digital to analog convertor is adjusted based on the ripple signal.

An analog-to-digital converter includes a low voltage power supply rail, a high voltage power supply rail, successive approximation circuit, a level shifter, and a capacitive digital-to-analog converter (CDAC). The successive approximation circuitry is coupled to the low voltage power supply rail. The level shifter is coupled to the high voltage power supply rail and includes inputs coupled to first outputs of the successive approximation circuitry. The CDAC includes a first segment and a second segment. The first segment includes a first plurality of capacitors, and a first plurality of switches coupled to outputs of the level shifter. The second segment includes a second plurality of capacitors, and a second plurality of switches coupled to second outputs of the successive approximation circuitry.

An electronic device includes a digital-to-analog converter coupled to receive a reference voltage and a binary-encoded digital input signal. The electronic device provides an analog output signal that represents the value of the binary-encoded digital input signal and a transmission gate is coupled to pass the analog output signal. A blank pulse generator is coupled to receive selected bits of the binary-encoded digital input signal and to pulse the transmission gate off when the selected bits change value, thus providing a blanked analog output signal.

A device includes: a capacitor having first and second terminals; a first switch; a second switch coupled to the second terminal; a first multiplier coupled between the first and second terminals; a second multiplier coupled between the first and second terminals; and a buffer having an input terminal and an output terminal. The first switch is coupled between the output terminal and the first terminal.

A reference ripple suppression circuit adaptable to a successive approximation register (SAR) analog-to-digital converter (ADC) includes a plurality of code-dependent compensation cells, each including a logic circuit and a compensation capacitor. A first plate of the compensation capacitor is coupled to receive a reference voltage to be compensated, and a second plate of the compensation capacitor is coupled to receive an output of the logic circuit performing on an output code of the SAR ADC and at least one logic value representing a bottom-plate voltage of a switched digital-to-analog converter (DAC) of the SAR ADC. (k1) of the code-dependent compensation cells are required maximally for k-th switching of the SAR ADC.

A device and a method for digital to analog conversion are provided. The device contains a signal generation circuit and a conversion circuit. The signal generation circuit generates two reset signals which are a first reset signal and a second reset signal. The two reset signals are mutually inverted digital signals and contain the same number of bits. The conversion circuit converts a digital data signal into an analog data signal when a first clock signal is at a first level, and generates the analog data signal at two reset levels respectively according to the two reset signals when the first clock signal is at a second level.

A voltage-mode digital-to-analog converter (DAC) includes multiple bit processing circuits to generate an output voltage responsive to a binary input. Each of the multiple bit processing circuits includes a first switch circuit and a second switch circuit. The first switch circuit is to selectively couple one of multiple reference voltages to a first output load in response to receiving a first input bit during a first bit time. The first output load has a value proportional to d. The second switch circuit is to selectively couple one of the multiple reference voltages to a second output load in response to receiving a second input bit during a second bit time. The second output load has a value corresponding to the first output load. The first and second output loads are disposed in parallel, and serially couple to a third output load having a value proportional to (1-d).

A method includes using a first feedback loop to compensate for a first excess loop delay (ELD) associated with a first quantizer and a first DAC of the first feedback loop. The first quantizer provides a first quantizer output to a second feedback loop. A second feedback loop compensates for a second ELD associated a second quantizer and a second DAC of the second feedback loop. The second quantizer reduces a metastability error associated with the first quantizer output.

Apparatus and associated methods relate to a circuit that is configured to keep a comparator input voltage stable. In an illustrative example, the circuit may include a first differential path coupled to a first switched-capacitor network's output, a second differential path coupled to a second switched-capacitor network's output. A comparator may have a first input coupled to the first differential path and a second input coupled to the second differential path. The comparator may be controlled by a clock signal to perform comparison. A first capacitor may be coupled from the clock signal to the first differential signal path and a second capacitor may be coupled from the clock signal to the second differential signal path. By introducing the first capacitor and the second capacitor, the comparator input common-mode may keep stable, and the comparator may be less sensitive to kickback effects.