Methods and systems are described for generating a process-voltage-temperature (PVT)-dependent reference voltage at a reference branch circuit based on a reference current obtained via a band gap generator and a common mode voltage input, generating a PVT-dependent output voltage at an output of a static analog calibration circuit responsive to the common mode voltage input and an adjustable current, adjusting the adjustable current through the static analog calibration circuit according to a control signal generated responsive to comparisons of the PVT-dependent output voltage to the PVT-dependent reference voltage, and configuring a clocked data sampler with a PVT-calibrated current by providing the control signal to the clocked data sampler.

An analog-to-digital converter (“ADC”) includes an input terminal configured to receive an analog input voltage signal. A first ADC stage is coupled to the input terminal and is configured to output a first digital value corresponding to the analog input voltage signal and a first analog residue signal corresponding to a difference between the first digital value and the analog input signal. An inverter based residue amplifier is configured to receive the first analog residue signal, amplify the first analog residue signal, and output an amplified residue signal. The amplified residue signal is converted to a second digital value, and the first and second digital values are combined to create a digital output signal corresponding to the analog input voltage signal.

The value range for which an error in a digital signal can be corrected is expanded. A control unit generates characteristic information indicating the relationship between an input and an output of an A/D converter and sets a value range. The control unit, in a case in which a value indicated by a first digital signal obtained by the A/D converter converting a first analog voltage signal is within the value range, A/D converts the first analog voltage signal and generates corrected digital information on the basis of the first digital signal and characteristic information, and in a case in which a value indicated by the first digital signal is not within the value range, A/D converts the first analog voltage signal and generates corrected digital information on the basis of a second digital signal obtained by the A/D converter converting the second analog voltage signal and characteristic information.

Non-idealities of input circuitry of a receiver signal chain can significantly degrade the overall performance of the receiver signal chain. To meet high performance requirements, the input circuitry is typically implemented with power hungry circuitry in a different semiconductor technology from the analog-to-digital converter that the input circuitry is driving. With suitable optimization techniques, performance requirements on the input circuitry can be reduced while meeting target performance of the receiver signal chain. Specifically, optimization techniques can compensate for input frequency-dependent properties and/or amplitude-dependent properties of the input circuitry. In some cases, reducing performance requirements on the input circuitry means that the input circuitry can be implemented in the same semiconductor technology as the analog-to-digital converter.

Methods and systems are described for generating a process-voltage-temperature (PVT)-dependent reference voltage at a reference branch circuit based on a reference current obtained via a band gap generator and a common mode voltage input, generating a PVT-dependent output voltage at an output of a static analog calibration circuit responsive to the common mode voltage input and an adjustable current, adjusting the adjustable current through the static analog calibration circuit according to a control signal generated responsive to comparisons of the PVT-dependent output voltage to the PVT-dependent reference voltage, and configuring a clocked data sampler with a PVT-calibrated current by providing the control signal to the clocked data sampler.

A method of operating a redundant successive approximation analog-to-digital converter (ADC) includes: sampling an input signal; and successively approximating the sampled input signal using a digital-to-analog converter (DAC) including DAC reference elements having at least one sub-binary weighted DAC reference element. Successively approximating the sampled input signal includes performing a plurality of successive approximation cycles. Each successive approximation cycle of the plurality of successive approximation cycles including: generating a DAC input word using a successive approximation register (SAR), offsetting the DAC input word to form an offset DAC input word when the successive approximation cycle corresponds to the at least one sub-binary weighted reference element, applying the offset DAC input word to an input of the DAC to produce a first DAC output signal, comparing the first DAC output signal with the sampled input signal using a comparator, and setting a bit of the SAR based on the comparison.

Non-idealities of input circuitry of a receiver signal chain can significantly degrade the overall performance of the receiver signal chain. To meet high performance requirements, the input circuitry is typically implemented with power hungry circuitry in a different semiconductor technology from the analog-to-digital converter that the input circuitry is driving. With suitable optimization techniques, performance requirements on the input circuitry can be reduced while meeting target performance of the receiver signal chain. Specifically, optimization techniques can compensate for input frequency-dependent properties and/or amplitude-dependent properties of the input circuitry. In some cases, reducing performance requirements on the input circuitry means that the input circuitry can be implemented in the same semiconductor technology as the analog-to-digital converter.

Circuits for an analog-to-digital converter and methods of operating an analog-to-digital converter. A resistor digital-to-analog converter (RDAC) has a first reference node coupled to a first current source, a second reference node coupled to a second current source, an input port configured to receive a first voltage, and an output port coupled to a buffer. The RDAC is configured to generate a second voltage including a first voltage shift from the first voltage and to supply the second voltage from the output port of the RDAC to the buffer.

Methods and systems are described for generating a process-voltage-temperature (PVT)-dependent reference voltage at a reference branch circuit based on a reference current obtained via a band gap generator and a common mode voltage input, generating a PVT-dependent output voltage at an output of a static analog calibration circuit responsive to the common mode voltage input and an adjustable current, adjusting the adjustable current through the static analog calibration circuit according to a control signal generated responsive to comparisons of the PVT-dependent output voltage to the PVT-dependent reference voltage, and configuring a clocked data sampler with a PVT-calibrated current by providing the control signal to the clocked data sampler.

An analog-to-digital converter (ADC) includes an input terminal configured to receive an analog input voltage signal. A first ADC stage is coupled to the input terminal and is configured to output a first digital value corresponding to the analog input voltage signal and a first analog residue signal corresponding to a difference between the first digital value and the analog input signal. An inverter based residue amplifier is configured to receive the first analog residue signal, amplify the first analog residue signal, and output an amplified residue signal. The amplified residue signal is converted to a second digital value, and the first and second digital values are combined to create a digital output signal corresponding to the analog input voltage signal.