The present invention is a system and method for providing a modified Digital-to-Analog converter (DAC) for use in a time-interleaved successive-approximation-register (SAR) analog-to-digital converter (ADC), the DAC including grouping of capacitance electrodes by Bit in a DAC, thereby reducing parasitic capacitances, and substantially improving power efficiency and speed to operate at GHz frequencies.

An A/D conversion device, which operates in one mode including at least one of a ΔΣ mode, a cyclic mode, and a hybrid mode, includes: a first block that processes an analog input signal by a first amplifier; a second block including a second amplifier; a quantization unit that quantizes one of outputs of the first and second blocks; and a control circuit that switches the mode to perform a control corresponding to the mode.

The present disclosure provides an analogue to digital converter (ADC) (100), which includes: a capacitive digital to analogue converter (DAC) (120) configured to sample and hold a received sampling input signal and a latched comparator (140) including a first metal oxide semiconductor field effect transistor (MOSFET) (202); a second MOSFET (204) connected in parallel to the first MOSFET; a third MOSFET (226), wherein a third source terminal of the third MOSFET (226) is coupled with first drain terminal and second drain terminal of the first and second MOSFET (202, 204), wherein a sampling switch (130) is configured to the third source terminal to selectively allow voltage to be supplied to the third MOSFET (226), and wherein the sampling switch is configured to disallow voltage to be supplied to the third MOSFET when the ADC is sampling the input signal.

A delta-sigma modulator generates a bit stream signal from an analog signal by operating according to a modulation period including a sampling period and a filtering period and includes a digital-to-analog converter (DAC) configured to generate a charge signal according to one of a first reference voltage and a second reference voltage according to the bit stream signal during the sampling period and to output a signal generated according to the charge signal and the other of the first reference voltage and the second reference voltage; a loop filter configured to charge a sampling signal corresponding to the analog signal during the sampling period and to filter an output from the DAC and a signal generated according to the sampling signal during the filtering period; and a quantizer configured to generate the bit stream signal according to an output from the loop filter in the modulation period.

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.

An analog-to-digital converter (ADC) device includes an ADC circuitry and a digital slope ADC circuitry. The ADC circuitry is configured to generate first bits and a first voltage according to an input signal. The digital slope ADC circuitry is configured to generate a second voltage at a node according to the first voltage and to gradually adjust the second voltage to generate second bits. After the second bits are generated, the digital slope ADC circuitry is further configured to perform a noise shaping function according to a first residual signal of the node.

A successive approximation (SA) AD converter includes a SA control circuit generating a digital output signal based on an output from a comparator; a first capacitor coupled to an input of the comparator, receiving an analog input signal, and capable of storing electric charges; a second and a third capacitor groups coupling to a reference voltage and storing electric charges previously. The SA control circuit operates for each SA step that the second or the third capacitor group is coupled to a non-inverting input of the comparator and the other is coupled to an inverting input of the comparator based on the output from the comparator. The SA control circuit operates that capacitor terminals of the second and the third capacitor groups coupled to the input of the comparator have the same potential when the reference voltage is stored previously in the second and the third capacitor groups.

In an embodiment a method includes providing an analog signal comprising a first value of a temperature of an object, performing an analog-to-digital conversion of the analog signal using a first analog-to-digital converter (ADC) thereby providing a first digital signal representing an initial digital temperature value, performing an analog-to-digital conversion of the analog signal using a second ADC thereby providing a second digital signal representing a digital reference temperature value, regularly providing the analog signal comprising a successive value of the temperature of the object, performing the analog-to-digital conversion of the analog signal using the second ADC thereby providing the second digital signal representing a successive digital temperature value, calculating a digital delta temperature value according to a difference between the successive digital temperature value and the digital reference temperature value and repeating providing the analog signal, performing the analog-to-digital conversion and calculating the digital delta temperature value as long as the digital delta temperature value lies within a predefined range.

Arrangement for controlling micromechanical actuators, including a digital-to-analog converter and a plurality of micromechanical actuators; wherein the micromechanical actuators are coupled to a connecting structure; wherein the digital-to-analog converter is configured to provide a voltage to be applied to the connecting structure by an adjustable capacitive voltage division that is dependent on a digital input value of the digital-to-analog converter, wherein the digital-to-analog converter is configured to directly include a capacitance of the connecting structure in the capacitive voltage division.