A method and apparatus for adjusting a bandwidth of a sigma delta converter by adjusting a reference voltage provided to the sigma delta converter. The apparatus includes a switched capacitor digital-to-analog converter in the feedback loop of the sigma delta modulator. The sigma delta modulator determines the bandwidth mode of the converter and adjusts the reference voltage to deliver high performance functionality. In one embodiment, a multi-bit digital signal is received by the digital-to-analog converter. The reference voltage is provided to multiple capacitive circuits of the digital-to-analog converter and the capacitive circuits are activated and deactivated based on the multi-bit digital signal. The digital-to-analog converter, thus, provides a feedback analog signal using dynamic element matching.

Embodiments of the invention include an oversampling Analog to Digital Converter that uses uneven non-overlapping clock phases to reduce switched capacitor circuit power consumption. A return-to-zero sub phase of one of the clock phases may also be used for feedback reference capacitors. A delay lock loop may be combined with the non-overlapping clock phase generator to control accurate timing.

A sigma-delta modulator comprising a plurality of filter stages in series with each other, wherein at least one of the plurality of filter stages is configured to provide a filter-output-signal; and a plurality of gain stages, each gain stage configured to provide a gain-output-signal. The sigma-delta modulator also includes a filter-output-switching-element configured to selectively couple the filter-output-signal to an input terminal of one of the plurality of gain stages; and a plurality of filter-input-switching-elements. Each of the plurality of filter-input-switching-elements is associated with one of the plurality of filter stages, wherein the plurality of filter-input-switching-elements are configured to selectively couple one of the gain-stage-output-signals to an input terminal of its associated one of the plurality of filter stages.

In accordance with embodiments of the present disclosure, a method of neutralizing voltage kickback associated with a reference buffer of a switched capacitor based data converter having a first switched capacitor coupled to an output node of the reference buffer wherein the first switched capacitor comprises at least one first capacitor and at least one first switch may be provided. The method may include coupling a passive network to the output node of the reference buffer in response to a presence of a condition for encountering the voltage kickback in order to create an approximately equal and opposite voltage kickforward by the passive network to at least partially neutralize the voltage kickback.

Provided are apparatuses and methods, in which a disturbed measurement variable is converted to a digital signal. The digital signal is then averaged over a number of sampling values which corresponds to a period of the disturbances.

A method and apparatus for adjusting a bandwidth of a sigma delta converter by adjusting a reference voltage provided to the sigma delta converter. The apparatus includes a switched capacitor digital-to-analog converter in the feedback loop of the sigma delta modulator. The sigma delta modulator determines the bandwidth mode of the converter and adjusts the reference voltage to deliver high performance functionality. In one embodiment, a multi-bit digital signal is received by the digital-to-analog converter. The reference voltage is provided to multiple capacitive circuits of the digital-to-analog converter and the capacitive circuits are activated and deactivated based on the multi-bit digital signal. The digital-to-analog converter, thus, provides a feedback analog signal using dynamic element matching.

A single plate capacitance sensor includes a sensor capacitor and a reference capacitor that share common plate. A capacitance-to-digital sigma delta modulator provides separate sensor excitation and reference excitation signals to the sensor capacitor and the reference capacitor to provide high resolution detection. Programmable ratio-metric excitation voltages and adaptive excitation voltage sources can be used to enhance modulator performance.

Embodiments of the invention include an oversampling Analog to Digital Converter that uses uneven non-overlapping clock phases to reduce switched capacitor circuit power consumption. A return-to-zero sub phase of one of the clock phases may also be used for feedback reference capacitors. A delay lock loop may be combined with the non-overlapping clock phase generator to control accurate timing.

A device and method for sigma-delta modulation may include an input signal and a plurality of integrators. The output of the integrators and a data input may be input to an adder, the sum output to be input to a quantizer to generate a quantized output signal. A reset input to the first integrator may be asserted during a first sample of the quantized output signal to reduce the signal discontinuity at the input of the first integrator, which improves the stability of the sigma-delta modulator.

A sigma-delta modulator comprising a plurality of filter stages in series with each other, wherein at least one of the plurality of filter stages is configured to provide a filter-output-signal; and a plurality of gain stages, each gain stage configured to provide a gain-output-signal. The sigma-delta modulator also includes a filter-output-switching-element configured to selectively couple the filter-output-signal to an input terminal of one of the plurality of gain stages; and a plurality of filter-input-switching-elements. Each of the plurality of filter-input-switching-elements is associated with one of the plurality of filter stages, wherein the plurality of filter-input-switching-elements are configured to selectively couple one of the gain-stage-output-signals to an input terminal of its associated one of the plurality of filter stages.