An analog-to-digital converter (ADC) having an input operable to receive an input voltage, V.sub.IN, and an output operable to output a digital code representative of V.sub.IN, the ADC including: a voltage-to-delay circuit having an input and an output, the input of the voltage-to-delay circuit coupled to the input of the ADC; a folding circuit having an input and an output, the input of the folding circuit coupled to the output of the voltage-to-delay circuit; and a time delay-based analog-to-digital converter backend having an input and a digital code output coupled to the output of the ADC, the input of the time delay-based analog-to-digital converter backend coupled to the output of the folding circuit.

An analog-to-digital converter (ADC) having an input operable to receive an input voltage, V.sub.IN, and an output operable to output a digital code representative of V.sub.IN, the ADC including: a voltage-to-delay circuit having an input and an output, the input of the voltage-to-delay circuit coupled to the input of the ADC; a folding circuit having an input and an output, the input of the folding circuit coupled to the output of the voltage-to-delay circuit; and a time delay-based analog-to-digital converter backend having an input and a digital code output coupled to the output of the ADC, the input of the time delay-based analog-to-digital converter backend coupled to the output of the folding circuit.

An RF receiver including: a low noise amplifier adapted to be coupled to an antenna and having an output; a bandpass filter coupled to the output of the low noise amplifier and having a voltage signal output, V.sub.IN; a conversion and folding circuit; and an analog-to-digital converter for converting the earlier-arriving or later-arriving delay signals into a digital code representing the voltage signal. The conversion and folding circuit including: a voltage-to-delay converter block, including preamplifiers, for converting the voltage signal into delay signals; and a folding block, including logic gates coupled to the preamplifiers, for selecting earlier-arriving and later-arriving ones of the delay signals.

An RF receiver including: an antenna cable of receiving an RF signal; a low noise amplifier coupled to the antenna and having an output; a bandpass filter coupled to the output of the low noise amplifier and having a voltage signal output, V.sub.IN; a conversion and folding circuit; and an analog-to-digital converter for converting the earlier-arriving or later-arriving delay signals into a digital code representing the voltage signal. The conversion and folding circuit having: a voltage-to-delay converter block, including preamplifiers, for converting the voltage signal into delay signals; and a folding block, including logic gates coupled to the preamplifiers, for selecting earlier-arriving and later-arriving ones of the delay signals; and

A conversion and folding circuit includes a voltage-to-delay converter block, including preamplifiers, for converting a voltage signal into delay signals, and a folding block, including logic gates coupled to the preamplifiers, for selecting earlier-arriving and later-arriving ones of the delay signals. If desired, the logic gates may include odd and even chains for outputting delay signals to first and second analog-to-digital converters. If desired, the conversion and folding circuit may include first and second chains, and a chain selection circuit for selectively outputting a delay signal from a desired one of the first and second chains.

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.

In described examples, an analog to digital converter (ADC), having an input operable to receive an analog signal and an output operable to output a digital representation of the analog signal, includes a voltage to delay (VD) block. The VD block is coupled to the input of the ADC and generates a delay signal responsive to a calibration signal. A backend ADC is coupled to the VD block, and receives the delay signal. The backend ADC having multiple stages including a first stage. A calibration engine is coupled to the multiple stages and the VD block. The calibration engine measures an error count of the first stage and stores a delay value of the first stage for which the error count is minimum.

A circuit including an amplifier array including an amplifier stage with M amplifiers (M2), connected to a resistor interpolator (interpolation order N2) including an input row and at least a second row, each row comprising interpolation resistors connected in series at nodes. The input row including M driven nodes connected to a respective amplifier, and connected in parallel to the second row, with at least some first-row interpolation nodes connected to corresponding second-row interpolation nodes. The resistor interpolator comprising at least one multi-row interpolation cell, with: in the input row, a driven node coupled through first and second interpolation resistors to respective adjacent first and second interpolation nodes; and in the second row, third and fourth interpolation nodes coupled through third and fourth interpolation resistors to an intermediate fifth interpolation node; and with the first and second interpolation nodes connected respectively to the third and fourth interpolation nodes.

An analog-to-digital converter includes a first circuit and a second circuit. The first circuit includes a first quantizer that digitizes an input first analog voltage, has a function of subtracting an analog voltage generated based on the digitalized first value from the first analog voltage, has a function of amplifying a first analog residual voltage which is a result of the subtraction, and a first output drive amplifier that outputs the amplified first analog residual voltage. The second circuit includes a second quantizer that digitizes an input second analog voltage, has a function of subtracting an analog voltage generated based on the digitalized second value from the second analog voltage, has a function of amplifying a second analog-residual voltage which is a result of the subtraction, and a second output drive amplifier that outputs the amplified second analog residual voltage.

A circuit including an amplifier array including an amplifier stage with M amplifiers (M2), connected to a resistor interpolator (interpolation order N2) including an input row and at least a second row, each row comprising interpolation resistors connected in series at nodes. The input row including M driven nodes connected to a respective amplifier, and connected in parallel to the second row, with at least some first-row interpolation nodes connected to corresponding second-row interpolation nodes. The resistor interpolator comprising at least one multi-row interpolation cell, with: in the input row, a driven node coupled through first and second interpolation resistors to respective adjacent first and second interpolation nodes; and in the second row, third and fourth interpolation nodes coupled through third and fourth interpolation resistors to an intermediate fifth interpolation node; and with the first and second interpolation nodes connected respectively to the third and fourth interpolation nodes.