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.

A method of converting an analog signal to a digital code, comprising: using a first comparator to receive an input signal and a first comparison signal, and to generate a first output as a function of the input signal and the first comparison signal; using a second comparator to receive the input signal and a second comparison signal, and to generate a second output as a function of the input signal and the second comparison signal; and using an interpolation comparator to receive the first and second outputs, and to generate a third output based on relative timing of the first and second outputs; further including multiplexing to permit a second-level comparator to receive timing signals from the interpolation comparator and only one of two dummy comparators.

A method for providing back-compatibility for rational sampling rate disparities between two circuitries, comprises: a) providing a Phase Locked Loop (PLL) operating at a rate different than that of the Symbols generator, which is coupled to a Digital to Analog Converter (DAC) or an Analog to Digital Converter (ADC); b) providing an interpolation filter coupled to said converter, which filter is adapted to perform sampling rate conversion operations on the samples using zero-stuffing, filtering, and decimation, or the like computation-saving algorithm; and c) obtaining the sampling of the symbols at the required and compatible rate.

A method for operating an electronic device includes detecting, by a touchscreen controller, a touch point on a touchscreen; determining, by the touchscreen controller, coordinates of the touch point; scaling, by the touchscreen controller, up the coordinates of the touch point to obtain scaled up coordinates by overwriting a reserved portion of a touch event protocol with additional information corresponding to the coordinates of the touch point; reporting, by the touchscreen controller, the scaled up coordinates of the touch point to an application processor; and determining, by the application processor, the coordinates of the touch point with an increased resolution by converting the scaled up coordinates into a floating point value.

A method for operating an electronic device includes detecting, by a touchscreen controller, a touch point on a touchscreen; determining, by the touchscreen controller, coordinates of the touch point; scaling, by the touchscreen controller, up the coordinates of the touch point to obtain scaled up coordinates by overwriting a reserved portion of a touch event protocol with additional information corresponding to the coordinates of the touch point; reporting, by the touchscreen controller, the scaled up coordinates of the touch point to an application processor; and determining, by the application processor, the coordinates of the touch point with an increased resolution by converting the scaled up coordinates into a floating point value.

An analog-digital converter includes a first analog-digital conversion unit configured to, during a first analog-digital conversion operation, sequentially charge each of n first differential node pairs, in response to a respective one of a differential sampling signal pair and first to (n−1).sup.th differential signal pairs among n differential signal pairs, in response to each of the n first differential node pairs being sequentially charged, sequentially generate each of n first differential data pairs, and sequentially generate each of n upper differential data pairs to be used as n-bit upper digital data, in response to a respective one of the sequentially-generated n first differential data pairs. The first analog-digital conversion unit is further configured to, during a second analog-digital conversion operation, simultaneously discharge each of the n first differential node pairs, in response to a n.sup.th differential signal pair among the n differential signal pairs.

An analog-digital converter includes a first analog-digital conversion unit configured to, during a first analog-digital conversion operation, sequentially charge each of n first differential node pairs, in response to a respective one of a differential sampling signal pair and first to (n−1).sup.th differential signal pairs among n differential signal pairs, in response to each of the n first differential node pairs being sequentially charged, sequentially generate each of n first differential data pairs, and sequentially generate each of n upper differential data pairs to be used as n-bit upper digital data, in response to a respective one of the sequentially-generated n first differential data pairs. The first analog-digital conversion unit is further configured to, during a second analog-digital conversion operation, simultaneously discharge each of the n first differential node pairs, in response to a n.sup.th differential signal pair among the n differential signal pairs.

There is provided a phase shifter circuit of an optical encoder that receives four signals generated from photodiodes. The phase shifter circuit includes four resistor strings each coupled to two of the four signals having a 90-degrees phase pitch. By taping out different numbers of signals at different tape-out nodes of each of the four resistor strings, the phase shifter circuit is adapted to output signals for different interpolation factors without changing the mask set.

An analog-to-digital converting system and a method with offset correction mechanisms are provided. The method includes steps of: obtaining a direct current offset of an output voltage of a digital analog conversion unit in a system; obtaining first capacitance weights and second capacitance weights sequentially from small to large; subtracting the direct current offset from a digital signal; and multiplying bit values of the digital signal respectively by the corresponding first capacitance weight value or second capacitance weight value to output a decode signal.

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.