An A/D converter is provided with: an integrator that includes an operational amplifier provided with a first input terminal and an output terminal, and an integration capacitor; a quantizer that outputs a quantization result obtained by quantizing an output signal from the operational amplifier; and a DAC that is connected to the first input terminal and determines DAC voltage. The integrator has a feedback switch between the integration capacitor and the output terminal of the operational amplifier. An analog signal as an input signal is inputted between the integration capacitor and the feedback switch. The integration capacitor samples the analog signal. The quantizer performs the quantization based on the output of the operational amplifier. The DAC sequentially subtracts electric charge accumulated in the integration capacitor to thereby change the analog signal to a digital value.

The present disclosure, in some embodiments, relates to an analog-to-digital converter (ADC). The ADC has a successive approximation register (SAR) configured to receive an input signal and to generate a first digital signal having a plurality of most significant bits and a residue voltage. A voltage-to-time conversion element is configured to generate a time domain representation using the residue voltage. The voltage-to-time conversion element has an amplifier with a input coupled to an output of the SAR, a zero crossing detector coupled to an output of the amplifier, and a current source selectively coupled to the output of the SAR and the input of the amplifier by way of a switching element. A time-based signal processing element is configured to convert the time domain representation to a second digital signal having a plurality of least significant bits.

An analog-to-digital converter (ADC) that uses voltage-based signal processing and time-based signal processing to convert an analog input signal to a digital output signal is disclosed. In some embodiments, the ADC has a voltage-based signal processing element configured to receive an input signal and to generate a first digital signal having a plurality of most significant bits and a residue voltage. A residue offset circuit is configured to provide a residue offset voltage to the residue voltage. A voltage-to-time conversion element is configured to convert a sum of the residue voltage and the residue offset voltage to a time domain representation, and a time-based signal processing element is configured to convert the time domain representation to a second digital signal having a plurality of least significant bits.

A pipeline analog to digital converter includes a k number of stages and an output data register. A first stage of the k number of stages is configured to receive an analog differential input signal and produce a first digital output and a first single ended analog output. A second stage of the k number of stages is configured to receive the first single ended analog output and produce a second digital output. The output data register is configured to generate an output digital value based on the first and second digital outputs.

A pipeline analog to digital converter includes a k number of stages and an output data register. A first stage of the k number of stages is configured to receive an analog differential input signal and produce a first digital output and a first single ended analog output. A second stage of the k number of stages is configured to receive the first single ended analog output and produce a second digital output. The output data register is configured to generate an output digital value based on the first and second digital outputs.

A hybrid analog-to-digital converter (ADC) includes a plurality of analog-to-digital conversion circuits and a combining circuit. The analog-to-digital conversion circuits generate a plurality of partial digital outputs for a same analog input, respectively, wherein the analog-to-digital conversion circuits include a digital slope ADC used to perform signal quantization in a time domain. The combining circuit combines the partial digital outputs generated from the analog-to-digital conversion circuits to generate a final digital output of the analog input.

A hybrid analog-to-digital converter (ADC) includes a plurality of analog-to-digital conversion circuits and a combining circuit. The analog-to-digital conversion circuits generate a plurality of partial digital outputs for a same analog input, respectively, wherein the analog-to-digital conversion circuits include a digital slope ADC used to perform signal quantization in a time domain. The combining circuit combines the partial digital outputs generated from the analog-to-digital conversion circuits to generate a final digital output of the analog input.

The present disclosure relates to an analog-to-digital converter (ADC) that uses voltage-based signal processing and time-based signal processing to convert an analog input signal to a digital output signal. In some embodiments, the ADC has a voltage-based signal processing element configured to receive an input signal and to generate a first digital signal having a plurality of most significant bits and a residue voltage. A residue offset circuit is configured to provide a residue offset voltage to the residue voltage. A voltage-to-time conversion element is configured to convert a sum of the residue voltage and the residue offset voltage to a time domain representation, and a time-based signal processing element is configured to convert the time domain representation to a second digital signal having a plurality of least significant bits.

A method for indirect conversion of a voltage value to a digital word consisting in sampling an input voltage through a parallel connection of a sampling capacitor to a source of the input voltage, and next in mapping a sample value of the input voltage to a time interval, and in assignment of a corresponding value of n-bit output digital word by the use a control module characterized in that the time interval is mapped to a difference of a length of a reference time and a length of a signal time, while the reference time is generated from an instant when the beginning of the time interval is detected by the use the control module, and the signal time is generated from an instant when the end of the time interval is detected by the use the control module, whereas generation of the reference time and the signal time is terminated at the same instant.

A hybrid SAR-ADC that uses a combination of voltage-based signal processing and time-based signal processing to convert an analog input signal to a digital output signal is disclosed. In some embodiments, the hybrid SAR-ADC has a voltage-based signal processing element configured to convert an analog input signal to a first digital signal having a plurality of MSBs and to generate a residue voltage from an input voltage and the first digital signal. A voltage-to-time conversion element is configured to convert the residue voltage to a time domain representation. A time-based signal processing element is configured to convert the time domain representation to a second digital signal comprising a plurality of LSBs. By determining the plurality of MSBs using voltage-based signal processing and determining the plurality of LSBs using time-based signal processing, the hybrid SAR-ADC is able to achieve low power and compact area.