A method of enhancing SAR ADC performance includes employing PVT processor to correct process, voltage and temperature (PVT) variation. The PVT processor senses process, supply voltage and temperature information then maximize the time for SAR binary search process. The PVT processor first applies coarse optimization to correct process and voltage variation then applies fine optimization to correct the temperature variation. The SAR ADC is operated at its optimized PVT condition and its performance is enhanced after PVT optimization.

A sampling device includes a switch capacitor circuit. First ends of two switches are respectively connected to an input signal. Second end of the first switch is connected to an upper plate of a first capacitor. Second end of the second switch is connected to a lower plate of a second capacitor. A connection node connecting a lower plate of the first capacitor to an upper plate of the second capacitor is connected to a power source. The first ends of a third switch and a fourth switch are respectively connected to an input common-mode voltage. A second end of the third switch is connected to the upper plate of the first capacitor. A second end of the fourth switch is connected to the lower plate of the second capacitor. The connection node is connected to the power source. Thus, an output common-mode voltage of the sampling device is adjustable.

A solid-state image sensor includes: an input transistor configured to output, from a drain, a drain voltage according to an input voltage input to a source in a case where the input voltage substantially coincides with a predetermined reference voltage input to a gate; and an output transistor configured to output a signal indicating whether or not a difference between the input voltage input to a source and the drain voltage input to a gate exceeds a predetermined threshold voltage as a comparison result between the input voltage and the reference voltage.

Many electronic circuits rely on the ratio of one component to other components being well defined. Current flow in component can warm the component causing its electrical properties to change, for example the resistance of a resistor may increase due to self-heating as a result of current flow. The present disclosure provides a way to reduce temperature variation between components so as to reduce electrical mismatch between them or the consequences of such mismatch. This is important as even a change of resistance of, for example, 20-50 ppm in a resistor can result in non-linearity exceeding the least significant bit value of a 16 bit digital to analog converter.

A conversion time and an acquisition time of an ADC can be estimated so that a speed of the ADC can be calibrated. An ADC circuit can perform M bit-trials in its conversion phase and continue performing additional bit-trials in a calibration mode. The ADC can count the number of additional bit-trials performed, e.g., X bit-trials, that occur before the next conversion phase, where additional bit-trials can be considered to be the number of available bit-trials during an acquisition time if the ADC continues performing bit-trials instead of sampling an input signal. The ADC can estimate the conversion time and the acquisition time using M and X. Then, the conversion time of the ADC can be calibrated by adjusting one or more of the comparison time, DAC settling delay, and logic propagation delay.

An analog-to-digital converter (ADC) includes a first ADC stage with a first sub-ADC stage configured to output a first digital value corresponding to an analog input voltage. A current steering DAC stage is configured to convert the analog input voltage and the first digital value to respective first and second current signals, determine a residue current signal representing a difference between the first current signal and the second current signal in the current domain, and convert the residue current signal to an analog residual voltage signal. A second ADC stage is coupled to the first ADC stage to receive the analog residual voltage signal, and convert the analog residue voltage signal to a second digital value. An alignment and digital error correction stage is configured to combine the first and the second digital values into a digital output voltage.

A stage, suitable for use in and analog to digital converter or a digital to analog converter, comprises a plurality of slices. The slices can be operated together to form a composite output having reduced thermal noise, while each slice on its own has sufficiently small capacitance to respond quickly to changes in digital codes applied to the slice. This allows a fast conversion to be achieved without loss of noise performance. The slices can be sub-divided to reduce scaling mismatch between the most significant bit and the least significant bit. A shuffling scheme is implemented that allows shuffling to occur between the sub-sections of the slices without needing to implement a massively complex shuffler.

A system and method for regulating transfer characteristics of an integral analog-to-digital converter are provided. The system comprises a cascade N-stage integrator structure having N integrators, the input end of the first integrator is connected to a voltage, the output end of each integrator is connected to the input end of the adjacent integrator, and the output end of the Nth integrator is connected to an output node (VRAMP). Wherein, the N is positive integer greater than or equal to 2. In the cascade multistage integrator structure, the voltage of the output node (VRAMP) is in direct proportion relation with the time to the power of N. By adopting a cascade multistage integrator according to the present disclosure, it is simple to regulate transfer characteristics of the ADC, and the cascade digital signal processing is convenient, which can reduce the ADC conversion time and improve the ADC conversion rate. Compared with the existing polyline mode, the present disclosure has better linearity; and it can be easily extended to cascade multistage integrators.

Processing circuitry comprising: a reference node for connection to a reference voltage source so as to establish a local reference voltage signal at the reference node; a signal processing unit connected to the reference node and operable to process an input signal using the local reference voltage signal, wherein the signal processing unit is configured to draw a current from the reference node at least a portion of which is dependent on the input signal; and a current-compensation unit connected to the reference node and operable to apply a compensation current to the reference node, wherein the current-compensation unit is configured, based on an indicator signal indicative of the input signal and/or of the operation of the signal processing unit, to control the compensation current to at least partly compensate for changes in the current drawn from the reference node by the signal processing unit due to the input signal.

A non-linearity evaluation circuit for use with a signal generator having at least partly non-linear operation, the non-linearity evaluation circuit comprising: a detection unit operable to detect a given amplitude attribute in a target signal generated by the signal generator, the time position of the amplitude attribute in the target signal defining the time location of a snapshot time window relative to the target signal, the part of the target signal occupying the snapshot time window being a corresponding signal snapshot, and the presence of the given amplitude attribute indicating that the signal snapshot includes noise due to the non-linear operation of the signal generator; and a controller operable to analyse the signal snapshot rather than a larger part of the target signal and to evaluate the non-linear characteristics of the operation of the signal generator based on the analysis.