The invention relates to an analog-to-digital converter, ADC, based on single-bit delta-sigma quantization. The ADC includes an integrator, a threshold detector, a feedback block, a range control circuit and an output processing block. The ADC is configured to, based on its own generated digital bitstream, adjust the magnitude of a subtrahend signal in order to achieve autonomous auto-ranging of the ADC during the integration time of a measurement. In particular, the auto-ranging allows for the efficient conversion of an analog input signal with high dynamic range, for example ambient light, to a digital output signal.

A microphone assembly includes a transducer element and a processing circuit. The processing circuit includes an analog-to-digital converter (ADC) configured to receive, sample and quantize a microphone signal generated by the transducer element to generate a corresponding digital microphone signal. The processing circuit includes a feedback path including a digital loop filter configured to receive and filter the digital microphone signal to provide a first digital feedback signal and a digital-to-analog converter (DAC) configured to convert the first digital feedback signal into a corresponding analog feedback signal. The processing circuit additionally includes a summing node at the transducer output configured to combine the microphone signal and the analog feedback signal.

A sigma-delta analog-to-digital converter (ADC) includes a feed-forward circuit, a finite-impulse-response (FIR) digital-to-analog converter (DAC), and a decimation filter. The feed-forward circuit is configured to receive an analog input signal and a feedback signal and generate a set of digital signals. Each feedback element of the FIR DAC includes a flip-flop and a reset circuit. The reset circuit is configured to receive a corresponding reset signal of a set of reset signals and output a reference output signal when the corresponding reset signal is deactivated. The reset signal of each feedback element is deactivated sequentially after each cycle of a clock signal that is received by the flip-flop associated with a corresponding reset circuit of each feedback element. The feedback signal is generated based on the reference output signal. The decimation filter is configured to generate a digital output signal based on the set of digital signals.

In an embodiment, an ADC converter includes a first injection branch and a second injection branch, a first feedback branch and a second feedback branch, an integration node connected to the first and second injection branches and the first and second feedback branches, an integrator connected to the integration node and a comparator connected downstream of the integrator and configured to generate a comparator output signal to control the first and second feedback branches, wherein the first and second injection branches are configured to provide a charge injection dependent on a respective input quantity to the integration node, wherein the input quantity of the first injection branch is selected from a differential voltage signal, a capacitance dependent signal and a current dependent signal, wherein the input quantity of the second injection branch is selected from another one of the differential voltage signal, the capacitance dependent signal and the current dependent signal, and wherein the first and second feedback branches are configured to provide a feedback charge injection dependent on the comparator output signal to the integration node, the first and second feedback branches configured to receive one of a fixed voltage signal or a differential voltage signal.

A microphone assembly includes a transducer element and a processing circuit. The processing circuit includes an analog-to-digital converter (ADC) configured to receive, sample and quantize a microphone signal generated by the transducer element to generate a corresponding digital microphone signal. The processing circuit includes a feedback path including a digital loop filter configured to receive and filter the digital microphone signal to provide a first digital feedback signal and a digital-to-analog converter (DAC) configured to convert the first digital feedback signal into a corresponding analog feedback signal. The processing circuit additionally includes a summing node at the transducer output configured to combine the microphone signal and the analog feedback signal.

An analog to digital converter (ADC) includes voltage and reference input terminals, a buffer circuit, and control logic. The buffer circuit includes input and output terminals and a variable resistor including resistive branches connected in parallel. The control logic is configured to, in a calibration phase, determine a given gain value for which gain error is to be calibrated, determine a set of the resistive branches in the buffer circuit to be used to achieve the given gain value, successively enable a different resistive branch of the variable resistor of the set until all resistive branches of the set have been enabled, determine an output code resulting after enabling all resistive branches of the set, and, from the output code, determine a gain error of the given gain value. The control logic is further configured to take corrective action based upon the gain error of the given gain value.

An analog to digital converter (ADC) circuit includes voltage and reference input terminals, a sample circuit, and control logic. The sample circuit includes input and output terminals, and capacitors connected in parallel and arranged between the input and output terminals. The control logic is configured to, in a calibration phase of operation, cause the multiplexer to route the ADC reference input terminal to the sampling voltage input terminal, determine a given gain value, determine a set of the capacitors to be used to achieve the given gain value, successively enable capacitor subsets to sample voltage of the reference input while disabling a remainder of the capacitors until all capacitors have been enabled, determine a resulting output code, and from the output code, determine a gain error of the given gain value of the ADC circuit.

A method can include, amplifying an analog input signal to generate an amplified analog signal; modulating the amplified analog signal into a digital data stream; filtering the digital data stream with a first digital filter to generate a first filtered data stream, and selectively changing a gain of the amplifier in response to the first filtered data stream. While the digital data stream is filtered with the first digital filter, the digital data stream is filtered with a second digital filter to generate a second filtered data stream. An output digital value corresponding to the analog input signal in response to the second filtered data stream. Corresponding systems and devices are also disclosed.

A digital microphone compresses a large voltage swing signal from a MEMS capacitor to a signal suitable for processing by integrated circuitry. The compression may be performed in an analog domain by selectively coupling adjustment capacitors in parallel to the MEMS capacitor. The digital microphone may decompress the signal in the digital domain using a decompression technique substantially an inverse of the compression performed in the analog domain.

A Sigma-Delta analog to digital converter (ADC) is described. The Sigma-Delta ADC includes a series arrangement of a gain tracker, a first discrete-time integrator stage and a quantizer between an ADC input and an ADC output. The Sigma-Delta ADC includes a digital to analog converter (DAC) having a DAC input and a DAC output connected to the gain tracker. The Sigma-Delta analog to digital converter includes a controller having a control input connected to the quantizer output. The controller provides a digital input to the DAC input and provides a gain control signal to the gain tracker.