A pipelined analog-to-digital converter (ADC) using a multiplying digital-to-analog converter (MDAC) and two sub-range analog-to-digital converters (sub-range ADCs) is disclosed. The MDAC samples an analog input and performs multiplication on the sampled analog input based on control bits. The first sub-range ADC provides the MDAC with the control bits. The second sub-range ADC is coupled to the MDAC for conversion of a multiplied signal output from the MDAC. The first sub-range ADC samples the analog input to generate the control bits for the MDAC as well as pre-estimated bits for the second sub-range ADC. The second sub-range ADC operates based on the pre-estimated bits and thereby a first section of digital bits are generated by the second sub-range ADC. A second section of digital bits are provided by the first sub-range ADC. The first and second sections of digital bits represent the analog input.

A switched capacitor circuit, including a metal-oxide-semiconductor field-effect transistor-based switch comprising: a first metal-oxide-semiconductor field-effect transistor having a gate, a source and a drain, wherein the source is connected to a first node and the drain is connected to a second node or wherein the drain is connected to the first node and the source is connected to the second node; a second metal-oxide-semiconductor field-effect transistor having a gate, a source and a drain, wherein the source is connected to the drain and the source and the drain are together connected to the second node; a first capacitor connected between the first node and a third node; and a second capacitor connected between the second node and the third node.

A receiver system that includes an ADC for converting analog values to digital representations. A digital representation is a sum of discrete values some of which are non-binary scaled and the other are binary scaled. The ADC includes dedicated comparators to determine whether to add or to subtract the non-binary scaled values. A comparator is used to determine whether to add or to subtract the binary scaled values. The ADC further calibrates offset voltages of the comparators to substantially remove dead zone and conversion errors, without compromising the conversion speed. The calibration can be performed both in foreground and background.

A receiver system that includes an ADC for converting analog values to digital representations. A digital representation is a sum of discrete values some of which are non-binary scaled and the other are binary scaled. The ADC includes dedicated comparators to determine whether to add or to subtract the non-binary scaled values. A comparator is used to determine whether to add or to subtract the binary scaled values. The ADC further calibrates offset voltages of the comparators to substantially remove dead zone and conversion errors, without compromising the conversion speed. The calibration can be performed both in foreground and background.

An Analog to Digital (ADC) is provided, where the ADC may include a sample and hold circuitry to sample an analog input signal, and a summation block to iteratively generate a subtraction signal. The subtraction signal may be based on a difference between the analog input signal and a feedback signal. The ADC may further include a common input stage to receive the subtraction signal, and a plurality of comparison and latch circuitries arranged in parallel, where individual ones of the plurality of parallel comparison and latch circuitries may sequentially receive an output of the common input stage.

A receiver system that includes an ADC for converting analog values to digital representations. A digital representation is a sum of discrete values some of which are non-binary scaled and the other are binary scaled. The ADC includes dedicated comparators to determine whether to add or to subtract the non-binary scaled values. A comparator is used to determine whether to add or to subtract the binary scaled values. The ADC further calibrates offset voltages of the comparators to substantially remove dead zone and conversion errors, without compromising the conversion speed. The calibration can be performed both in foreground and background.

A receiver system that includes an ADC for converting analog values to digital representations. A digital representation is a sum of discrete values some of which are non-binary scaled and the other are binary scaled. The ADC includes dedicated comparators to determine whether to add or to subtract the non-binary scaled values. A comparator is used to determine whether to add or to subtract the binary scaled values. The ADC further calibrates offset voltages of the comparators to substantially remove dead zone and conversion errors, without compromising the conversion speed. The calibration can be performed both in foreground and background.

An all-digital operational amplifier architecture, that does not have the constraint of maintaining devices in their saturation region, can leverage the high speed achievable by deeply scaled technology to replace traditional linear current referenced continuous-time operational amplifier circuits with CMOS-like dynamic circuits that require no referencing structure, have no static power consumption, and are compatible with ultra-low supply voltages. Techniques are described to replace analog continuous-time linear operational amplifier input and output stages by a discrete-time comparator circuit, e.g., CMOS-style, and a switched capacitor charge pump circuit, respectively.

A pipelined analog-to-digital converter (ADC) using a multiplying digital-to-analog converter (MDAC) and two sub-range analog-to-digital converters (sub-range ADCs) is disclosed. The MDAC samples an analog input and performs multiplication on the sampled analog input based on control bits. The first sub-range ADC provides the MDAC with the control bits. The second sub-range ADC is coupled to the MDAC for conversion of a multiplied signal output from the MDAC. The first sub-range ADC samples the analog input to generate the control bits for the MDAC as well as pre-estimated bits for the second sub-range ADC. The second sub-range ADC operates based on the pre-estimated bits and thereby a first section of digital bits are generated by the second sub-range ADC. A second section of digital bits are provided by the first sub-range ADC. The first and second sections of digital bits represent the analog input

Methods and systems for analog-to-digital conversion using two side branches that may be operated with overlapped timing such that a sampling phase may be overlapped with a previous conversion phase. Some embodiments provide a method of successive approximation A/D converting, comprising sampling a first signal onto a first capacitor that is configured to selectively couple to an analog input of a comparator, sampling a second signal onto capacitors that are coupled to a second analog input of the comparator and configured for charge redistribution successive approximation A/D conversion; carrying out, based on the first signal and the second signal, a charge redistribution successive approximation A/D conversion using the capacitors; and while carrying out the charge redistribution successive approximation A/D conversion based on the first and second signals, sampling a third signal onto a third capacitor that is configured to selectively couple to the analog input of a comparator.