Abstract: A MEMS microphone module includes a MEMS microphone, a modulator connected downstream of the MEMS microphone, and an interference compensation circuit to apply an interference compensation signal to an input of the modulator, the interference compensation signal being opposed to a low-frequency signal interference present at the input of the modulator or a block connected upstream of the input of the modulator.

Abstract: A microphone module includes a first MEMS microphone and a second MEMS microphone, wherein the first MEMS microphone includes a first modulator, and wherein the second MEMS microphone includes a second modulator. For the purpose of noise reduction, a defined offset can be applied to an input of the first modulator or of the second modulator. Alternatively, for the purpose of noise reduction, the first modulator and the second modulator can be operated with different modulation frequencies.

Abstract: A high-ohmic circuit includes a plurality of high-ohmic branches coupled in parallel between a first node and a second node. Each of the plurality of high-ohmic branches includes a first plurality of series connected resistive elements forming a first series path from the first node to the second node, each of the first plurality of series connected resistive elements comprising a first diode-connected transistor. Each of the plurality of high-ohmic branches further includes a second plurality of series connected resistive elements forming a second series path from the first node to the second node, each of the second plurality of series connected resistive elements comprising a second diode-connected transistor. The high-ohmic circuit further includes a plurality of switches, each of the switches being coupled between a corresponding one of the plurality of high-ohmic branches and the second node.

Abstract: A MEMS microphone module includes a MEMS microphone, a modulator connected downstream of the MEMS microphone, and an interference compensation circuit to apply an interference compensation signal to an input of the modulator, the interference compensation signal being opposed to a low-frequency signal interference present at the input of the modulator or a block connected upstream of the input of the modulator.

Abstract: A microphone module includes a first MEMS microphone and a second MEMS microphone, wherein the first MEMS microphone includes a first modulator, and wherein the second MEMS microphone includes a second modulator. For the purpose of noise reduction, a defined offset can be applied to an input of the first modulator or of the second modulator. Alternatively, for the purpose of noise reduction, the first modulator and the second modulator can be operated with different modulation frequencies.

Abstract: In accordance with an embodiment, a digital microphone interface circuit includes a delta-sigma analog-to-digital converter (ADC) having an input configured to be coupled to a microphone, a digital lowpass filter coupled to an output of the delta-sigma ADC, and a digital sigma-delta modulator coupled to an output of the digital lowpass filter. The delta-sigma ADC, the digital lowpass filter, and the digital sigma-delta modulator are configured to operate at different sampling frequencies.

Abstract: In accordance with an embodiment, a digital microphone interface circuit includes a delta-sigma analog-to-digital converter (ADC) having an input configured to be coupled to a microphone, a digital lowpass filter coupled to an output of the delta-sigma ADC, and a digital sigma-delta modulator coupled to an output of the digital lowpass filter. The delta-sigma ADC, the digital lowpass filter, and the digital sigma-delta modulator are configured to operate at different sampling frequencies.

Abstract: In various embodiments, a circuit arrangement includes a calibration filter set up to receive a signal based on a first signal and to provide a calibrated signal, the first signal being a signal which is provided by an analog/digital converter and is based on an analog signal, the analog signal being provided by at least one sensor of a sensor arrangement, a filter arrangement set up to receive a signal based on the first signal and to provide a second signal, and a controller set up to select a sensor-specific control signal dependent on the frequency response of the sensor from a plurality of control signals and to provide the calibration filter with said signal, the calibrated signal being based on the first signal and the sensor-specific control signal and corresponding or substantially corresponding to a predefined spectral mask in a predefined frequency range.

Abstract: A method includes post processing a plurality of temperature sensors grouped into a plurality of sets. For each set of the plurality of sets, a post-processing system coupled to corresponding temperature sensors receives a plurality output signals generated by the corresponding temperature sensors. For each set of the plurality of sets, the post-processing system computes values representing proportional to absolute temperature (PTAT) voltages and values representing internal reference voltages based on output signals generated by the corresponding temperature sensors. For each set of the plurality of sets, the post-processing system computes an average of the values representing the PTAT voltages and relative PTAT voltage variation coefficients. For each set of the plurality of sets, the post-processing system computes values representing corrected PTAT voltages using the relative PTAT voltage variation coefficients.

Abstract: According to an embodiment, a power compensation circuit is configured to be coupled to a power supply. The power compensation circuit includes a measurement circuit and a compensation circuit. The measurement circuit is configured to receive a power supply signal from the power supply, and determine a variation of the power supply signal. The compensation circuit is coupled to the measurement circuit and configured to generate a compensation power consumption based on the variation of the power supply signal, where the compensation power consumption is controlled inversely with the variation of the power supply signal.

Abstract: In various embodiments, a circuit arrangement is provided. The circuit arrangement includes a sensor set up to provide an analogue signal, an analogue/digital converter set up to receive the analogue signal and to provide a first signal, and a first filter set up to receive a signal based on the first signal and to provide a second signal. The first filter is set up in such a manner that the second signal is allowed through without amplification or substantially without amplification in a frequency range of approximately 20 Hz to approximately 10 kHz, and the second signal has a gain of greater than 0 dB at least above a predefined frequency which is greater than approximately 20 kHz.

Abstract: According to an embodiment, a method of operating an acoustic device includes buffering, by a buffer circuit, a first electrical signal from an acoustic transducer to produce a second electrical signal, receiving a feedback signal at a supply circuit, and comparing the feedback signal to a first threshold. The feedback signal is based on the first electrical signal. The method further includes, based on comparing the feedback signal to the first threshold, switching between a first mode and a second mode, supplying a first supply voltage to the buffer circuit during the first mode, and supplying a second supply voltage to the buffer circuit during the second mode. The first supply voltage is different from the second supply voltage.

Abstract: A system and method for a sensor-supported microphone includes an amplifier having an input configured to be coupled to a transducer, and an output coupled to an analog interface to output a transduced electrical signal from the transducer, a data bus configured to be coupled to an environmental sensor, a calibration parameter storage circuit coupled to the data bus, the calibration parameter storage circuit comprising calibration data relating sensitivity of the transducer with environmental measurements provided by the environmental sensor, and a digital interface coupled to the data bus and configured to output the calibration data and the environmental measurements.

Abstract: In some embodiments, a microphone system includes a multi-bit delta-sigma modulator configured to be coupled to a microphone and configured to covert an output of the microphone into a first digital signal with a multi-bit resolution at a first output of the multi-bit delta-sigma modulator. The microphone system also includes a digital noise shaper coupled to the first output of the multi-bit delta-sigma modulator, and configured to convert a multi-bit digital input of the digital noise shaper into a one-bit digital signal.

Abstract: According to an embodiment, a power compensation circuit is configured to be coupled to a power supply. The power compensation circuit includes a measurement circuit and a compensation circuit. The measurement circuit is configured to receive a power supply signal from the power supply, and determine a variation of the power supply signal. The compensation circuit is coupled to the measurement circuit and configured to generate a compensation power consumption based on the variation of the power supply signal, where the compensation power consumption is controlled inversely with the variation of the power supply signal.

Abstract: In various embodiments, a circuit arrangement includes a calibration filter set up to receive a signal based on a first signal and to provide a calibrated signal, the first signal being a signal which is provided by an analog/digital converter and is based on an analog signal, the analog signal being provided by at least one sensor of a sensor arrangement, a filter arrangement set up to receive a signal based on the first signal and to provide a second signal, and a controller set up to select a sensor-specific control signal dependent on the frequency response of the sensor from a plurality of control signals and to provide the calibration filter with said signal, the calibrated signal being based on the first signal and the sensor-specific control signal and corresponding or substantially corresponding to a predefined spectral mask in a predefined frequency range.

Abstract: In some embodiments, a microphone system includes a multi-bit delta-sigma modulator configured to be coupled to a microphone and configured to covert an output of the microphone into a first digital signal with a multi-bit resolution at a first output of the multi-bit delta-sigma modulator. The microphone system also includes a digital noise shaper coupled to the first output of the multi-bit delta-sigma modulator, and configured to convert a multi-bit digital input of the digital noise shaper into a one-bit digital signal.

Abstract: A circuit (290) comprises an RC filter circuit (100), which comprises an ohmic resistor (112) and a capacitor (113). In addition, the circuit (290) comprises a compensation circuit (200), which is designed to provide a compensation current flow (192), which corresponds to a current flow (191) to a load (150).

Abstract: In various embodiments, a circuit arrangement is provided. The circuit arrangement includes a sensor set up to provide an analogue signal, an analogue/digital converter set up to receive the analogue signal and to provide a first signal, and a first filter set up to receive a signal based on the first signal and to provide a second signal. The first filter is set up in such a manner that the second signal is allowed through without amplification or substantially without amplification in a frequency range of approximately 20 Hz to approximately 10 kHz, and the second signal has a gain of greater than 0 dB at least above a predefined frequency which is greater than approximately 20 kHz.

Abstract: A method includes post processing a plurality of temperature sensors grouped into a plurality of sets. For each set of the plurality of sets, a post-processing system coupled to corresponding temperature sensors receives a plurality output signals generated by the corresponding temperature sensors. For each set of the plurality of sets, the post-processing system computes values representing proportional to absolute temperature (PTAT) voltages and values representing internal reference voltages based on output signals generated by the corresponding temperature sensors. For each set of the plurality of sets, the post-processing system computes an average of the values representing the PTAT voltages and relative PTAT voltage variation coefficients. For each set of the plurality of sets, the post-processing system computes values representing corrected PTAT voltages using the relative PTAT voltage variation coefficients.