An apparatus is disclosed for pipelined analog-to-digital conversion. In an example aspect, the apparatus includes a pipelined analog-to-digital converter (ADC). The pipelined ADC includes a first stage and a second stage. The first stage includes a sampler and a quantizer coupled to the sampler. The first stage also includes a current distribution circuit coupled to the sampler. The second stage includes a sampler coupled to the current distribution circuit and a quantizer coupled to the sampler of the second stage.

In accordance with an embodiment, a method for monitoring a data converter configured to convert data using a calibration determined by a calibration data record includes calibrating the data converter in order to determine a corresponding multiplicity of time associated calibration data records at a multiplicity of different times; and determining a state of the data converter based on comparing at least one of the multiplicity of time associated calibration data records with a comparison data record.

A device for buffering a reference signal comprises a regulator circuit configured to generate at least two replicas of the reference signal as regulated output signals. The device further comprises a receiving circuit configured to receive the regulated output signals in a switchable manner. In this context, the regulated output signals are configured to have different performance characteristics.

An analogue to digital converter for converting the analogue output of a dual conversion gain pixel of an image sensor. The dual conversion gain pixel is operable to sequentially output a reset pixel value and a signal pixel value sequentially with both a first gain and a second gain different to the first gain. An image sensor comprising the analogue to digital converter, a system comprising the image sensor and a method are also described herein.

An example apparatus includes: an analog input; a resistor circuit including a first reference output and a second reference output; a first amplifier including a first analog input, a first reference input, and a first amplifier output, the first analog input coupled to the analog input, the first reference input coupled to the first reference output; a second amplifier including a second analog input, a second reference input, and a second amplifier output, the second analog input coupled to the analog input, the second reference input coupled to the second reference output; a first comparator including a first comparator input, the first comparator input coupled to the first amplifier output; and a second comparator including a second comparator input, the second comparator input coupled to the second amplifier output; a first multiplexer including a first multiplexer input and a first residue output, the first multiplexer input coupled to the first amplifier output; and a second multiplexer including a second multiplexer input and a second residue output, the second multiplexer input coupled to the second amplifier output.

A slope analog-to-digital converter, ADC, comprises: an input unit comprising a sampling capacitor, wherein the input unit is configured to during an initial period obtain a sampled value of an analog input signal and, during a conversion period, hold the sampled value across the sampling capacitor; and a comparator configured to determine a most significant bit of the analog input signal during the initial period; wherein the ADC during the conversion period is configured to receive a slope signal and to be adapted based on the determined most significant bit such that the comparator is further configured to adaptively compare the sampled value and the slope signal for converting the sampled value to a digital representation.

A communication unit receiver comprising: a multi-section analogue to digital converter, ADC, configured to receive an analogue signal and convert at least a first portion of the analogue signal into a digital signal using a first ADC dynamic range. A modem, coupled to the multi-section ADC, is configured to: process the digital signal; determine a signal-to-noise ratio, SNR, for sub-carriers of the analogue signal; and output an ADC selection signal to the multi-section ADC that selects a subset of sections of the multi-section ADC, where the selection signal is based at least partly on the determined SNR. Only the subset of sections of the multi-section analogue to digital converter, ADC is configured to convert a second portion of the analogue signal into a digital signal using a second ADC dynamic range that is less than the first dynamic range.

Systems and methods are provided for a pipelined analog-to-digital converter (ADC) circuit. The pipelined ADC circuit comprises a plurality of stages. Each stage comprises a differential input configured to receive a differential signal, a multiplying digital-to-analog converter (MDAC) electrically coupled to the input configured to stack voltages of a set of capacitors; a comparator electrically disposed after the MDAC to compare the differential voltages; and a source follower buffer electrically coupled to the first signal line and the second signal line and electrically disposed after the comparator, wherein the MDAC is configured to amplify an output voltage using passive multiplication; and an alignment circuit communicatively connected to a digital bit output of each stage of the plurality of stages, wherein the alignment circuit is configured to delay a digital bit output of each stage for one or more clock cycles and output a digitized representation of a sampled differential signal.

Herein disclosed are multiple embodiments of a signal-processing circuit that may be utilized in various circuits, including conversion circuitry. The signal-processing circuit may receive an input and produce charges on multiple different capacitors during different phases of operation based on the input. The charges stored on two or more of the multiple different capacitors may be utilized for producing an output of the signal-processing circuit, such as by combing the charges stored on two or more of the multiple different capacitors. Utilizing the charges on the multiple different capacitors may provide for a high level of accuracy and robustness to variations of environmental factors, and/or a low noise level and power consumption when producing the output.

Herein disclosed are multiple embodiments of a signal-processing circuit that may be utilized in various circuits, including conversion circuitry. The signal-processing circuit may receive an input and produce charges on multiple different capacitors during different phases of operation based on the input. The charges stored on two or more of the multiple different capacitors may be utilized for producing an output of the signal-processing circuit, such as by combing the charges stored on two or more of the multiple different capacitors. Utilizing the charges on the multiple different capacitors may provide for a high level of accuracy and robustness to variations of environmental factors, and/or a low noise level and power consumption when producing the output.