Abstract: A microelectromechanical systems (MEMS) device includes a MEMS die and an electrical circuit electrically connected to the MEMS die. The electrical circuit includes a first capacitor that produces a first output signal based on a signal received from the MEMS die, and a second capacitor that produces a second output signal based on a signal received from the MEMS die. The electrical circuit is configured to determine a nominal capacitance of the MEMS die based on a ratio of the first output signal to the second output signal and a ratio of the capacitances of the first and second capacitors.

Abstract: A microelectromechanical systems (MEMS) device includes a MEMS die and an electrical circuit electrically connected to the MEMS die. The electrical circuit includes a first capacitor that produces a first output signal based on a signal received from the MEMS die, and a second capacitor that produces a second output signal based on a signal received from the MEMS die. The electrical circuit is configured to determine a nominal capacitance of the MEMS die based on a ratio of the first output signal to the second output signal and a ratio of the capacitances of the first and second capacitors.

Abstract: A circuit in an analog-to-digital converter (ADC) includes an amplifier configured to receive an output of a backend DAC; a harmonic distortion correction circuit (HDC) coupled to the amplifier and configured to correct distortion components due to the residue amplifier present in a digital signal from the backend ADC, the HDC circuit providing an output to an adder, the adder receiving a coarse digital output from a coarse ADC; and a DAC noise cancellation circuit (DNC) configured to provide an output to the adder, wherein the DNC circuit is configured to correct distortion components due to the DAC present in the digital signal from the backend ADC; wherein the output of the adder is an ADC digital output and wherein the ADC digital output forms an input to the HDC and the DNC.

Abstract: An input circuit for an analog-to-digital converter (ADC) includes at least one bootstrap circuit, including at least one first switch for connecting electrical power to a first terminal of at least one capacitor; at least one second switch for connecting a second terminal of the at least one capacitor to a signal to be sampled; at least one third switch for connecting the first terminal of the at least one capacitor to the control gate of at least one sampling network input switch; at least one fourth switch for connecting the at least one sampling network input switch to a substrate; and at least one fifth switch for connecting the second terminal of the at least one capacitor to the substrate.

Abstract: A system including a sample-and-hold circuit for receiving a plurality of analog input signals; an analog-to-digital converter for converting each of the analog inputs to a digital signal; and a processor configured for implementing fractional delay recovery for the analog-to-digital converter. In some embodiments, the fractional delay recovery includes converting each of the plurality of analog input signals to a digital version in the predetermined order; upsampling each digital version in the predetermined order; digitally filtering each upsampled value in the predetermined order; and downsampling each filtered value in the predetermined order.

Abstract: A pipeline ADC is provided in which a DEM function and summation of sequences occur within a flash ADC. According to various aspects of the present disclosure, embedding the processing functions needed for DAC and amplifier error correction with the circuitry of a coarse ADC and rearranging the digital calibration blocks HDC and DNC ensures accurate estimation of the errors.

Abstract: A circuit in an analog-to-digital converter (ADC) includes an amplifier configured to receive an output of a backend DAC; a harmonic distortion correction circuit (HDC) coupled to the amplifier and configured to correct distortion components due to the residue amplifier present in a digital signal from the backend ADC, the HDC circuit providing an output to an adder, the adder receiving a coarse digital output from a coarse ADC; and a DAC noise cancellation circuit (DNC) configured to provide an output to the adder, wherein the DNC circuit is configured to correct distortion components due to the DAC present in the digital signal from the backend ADC; wherein the output of the adder is an ADC digital output and wherein the ADC digital output forms an input to the HDC and the DNC.

Abstract: An input circuit for an analog-to-digital converter (ADC) includes at least one bootstrap circuit, including at least one first switch for connecting electrical power to a first terminal of at least one capacitor; at least one second switch for connecting a second terminal of the at least one capacitor to a signal to be sampled; at least one third switch for connecting the first terminal of the at least one capacitor to the control gate of at least one sampling network input switch; at least one fourth switch for connecting the at least one sampling network input switch to a substrate; and at least one fifth switch for connecting the second terminal of the at least one capacitor to the substrate.

Abstract: A system including a sample-and-hold circuit for receiving a plurality of analog input signals; an analog-to-digital converter for converting each of the analog inputs to a digital signal; and a processor configured for implementing fractional delay recovery for the analog-to-digital converter. In some embodiments, the fractional delay recovery includes converting each of the plurality of analog input signals to a digital version in the predetermined order; upsampling each digital version in the predetermined order; digitally filtering each upsampled value in the predetermined order; and downsampling each filtered value in the predetermined order.

Abstract: A pipeline ADC is provided in which a DEM function and summation of sequences occur within a flash ADC. According to various aspects of the present disclosure, embedding the processing functions needed for DAC and amplifier error correction with the circuitry of a coarse ADC and rearranging the digital calibration blocks HDC and DNC ensures accurate estimation of the errors.

Abstract: A method and apparatus is disclosed for improving high frequency performance of an amplifier, such as for example, a current mirror. In one embodiment, a delay element is introduced in a current mirror signal path to account for signal propagation delay that may exist in one or more alternative signal paths. The delay element maintains desired phase alignment at a cascade node of the current mirror thereby establishing, in one embodiment, the cascode node (Vc) in an AC ground state. To extend current mirror high frequency capability an embodiment is disclosed having cross-coupled capacitors, active elements, or one or more other devices configured to provide positive feedback to one or more current mirror inputs. The positive feedback may be selectively configured to increase the operational bandwidth of the current mirror.