An A/D converter of the present invention includes: a reference voltage generation section for generating a plurality of reference voltages; a differential amplification section for amplifying a voltage difference between each of the plurality of reference voltages and an input signal voltage so as to generate a plurality of output voltage sets, each of the plurality of output voltage sets including complementary non-inverted and inverted output voltages; and an operating section for receiving the plurality of output voltage sets, the operating section being operated according to a clock signal.

In an analog-to-digital converter, an analog-to-digital conversion stage comprising a comparator and an analog residual signal generator. The comparator is operable to compare an analog input signal or a sample of the analog input signal with a threshold to generate a bit signal. The analog residual signal generator is operable to generate an analog residual signal from signals comprising the sample of the analog input signal and the bit signal such that, at a level of the analog input signal equal to the threshold of the comparator, the analog residual signal has a level independent of the state of the bit signal. The analog residual signal generator comprises a summing element, a selective inverter and an amplifier in series. The summing element is operable to sum a signal input to it with a reference signal. The selective inverter precedes the summing element, and is operable in response to a first state of the bit signal to pass a signal input to it, and is operable in response to a second state of the bit signal to invert the signal input to it.

There is disclosed, a converter for converting an input signal from one form to another. The converter includes a slicing circuit adapted to slice a signal into levels. The slicing circuit includes at least one threshold for establishing slicing levels. Dither is employed to vary at least one slicing level in the slicing circuit.

Signal converters are provided that accurately process dc-coupled source signals in the presence of different predetermined voltage and current source requirements. Processing structures are described that satisfy these requirements while providing accurate control of common mode levels along a processing path and accurate reduction of converter offset errors.

A multistage converter and method for converting a sampled analog signal to a corresponding digital representation. Each stage of the converter receives an analog input signal and produces a partial digital output. A first stage receives the sampled analog signal as the analog input signal. Each stage provides a residue output, which is the analog input signal to a subsequent stage. The residue is the analog input signal to the stage, less the analog equivalent of the partial digital output from the stage, possibly with a gain change. A voltage range over which a sample of an analog signal can vary is defined by a lower limit and an upper limit. A lower comparator threshold is established within the voltage range. An upper comparator threshold is established within the voltage range, between the lower comparator threshold and the upper limit. The analog input to the stage is quantized based on the lower and upper comparator thresholds to generate a quantized sampled analog signal. When the quantizes sampled analog signal is between the lower and upper comparator thresholds, dither is added to the quantized sampled analog signal to produce the partial digital output. The partial digital outputs from each stage are provided to an error corrector circuit that removes redundancy and effects of the dither and generates the digital representation corresponding to the sampled analog input. The effect of dither is to improve the spurious free dynamic range (SFDR) of the digital representation of the analog input.