A microelectromechanical system (MEMS) microphone includes a cavity to receive an acoustic signal. The acoustic signal causes movement of a diaphragm relative to one or more other surfaces, which in turn results in an electrical signal representative of the received acoustic signal. A light sensor is included within the packaging of the MEMS microphone such that an output of the light sensor is representative of a light signal received with the acoustic signal. The output of the light sensor is used to modify the electrical signal representative of the received acoustic signal in a manner that limits light interference with an acoustical output signal.

An MEMS microphone includes a substrate including a back volume provided inside the substrate and an opening provided at an upper surface of the substrate to communicate the back volume; a sensing device provided at an inner side wall of the back volume; a first cantilever provided inside the back volume and including end portions coupling with the sensing device; a first membrane provided at the opening; a second membrane provided inside the back volume; and second cantilevers, each of which includes a first end mechanically supporting the first cantilever, and a second end connected to the second membrane. By suspending the first cantilever on the second cantilevers, the end portions of the first cantilever always couple with a preset position of the sensing device. Thus, the DC offset of the displacement of the membrane can be prevented.

An MEMS microphone includes a substrate including a back volume provided inside the substrate and an opening provided at an upper surface of the substrate to communicate the back volume; a sensing device provided at an inner side wall of the back volume; a first cantilever provided inside the back volume and including end portions coupling with the sensing device; a first membrane provided at the opening; a second membrane provided inside the back volume; and second cantilevers, each of which includes a first end mechanically supporting the first cantilever, and a second end connected to the second membrane. By suspending the first cantilever on the second cantilevers, the end portions of the first cantilever always couple with a preset position of the sensing device. Thus, the DC offset of the displacement of the membrane can be prevented.

The disclosure relates generally to microphone and vibration sensor assemblies (100) having a transducer (102), like a microelectromechanical systems (MEMS) device, and an electrical circuit (103) disposed in a housing (110) configured for integration with a host device. The electrical circuit includes a transducer bias circuit that applies a bias to the transducer and a bias control circuit (204) that compensates for transducer sensitivity drift caused by variation in an environmental condition of the transducer, and electrical circuits therefor.

The disclosure relates generally to microphone and vibration sensor assemblies (100) having a transducer (102), like a microelectromechanical systems (MEMS) device, and an electrical circuit (103) disposed in a housing (110) configured for integration with a host device. The electrical circuit includes a transducer bias circuit that applies a bias to the transducer and a bias control circuit (204) that compensates for transducer sensitivity drift caused by variation in an environmental condition of the transducer, and electrical circuits therefor.

A MEMS device can include a substrate having a first side and a second side, the substrate including an aperture extending from the first side through the substrate to the second side. The device can include a support structure coupled to the substrate the first side. The device can include a resilient structure coupled to the support structure. The device can include a rigid movable plate coupled to the support structure via the resilient structure and positioned over the aperture. The device can include a proof mass coupled to the movable plate, the proof mass extending into the aperture. The device can include an electrode located on an opposite side of the movable plate from the proof mass.

A vibration sensor module including: a substrate, a first casing, a vibration pickup unit, and a sensor unit. The first casing has an open end on the substrate, the first casing and the substrate are enclosed to form a sealing chamber, and the first casing includes a first top plate opposite to the substrate. The vibration pickup unit is arranged in the sealing chamber, the vibration pickup unit includes a second casing with an open end and an elastic vibration pickup member arranged in the second casing, the open end of the second casing is arranged on the substrate or the first top plate, and the second casing is provided with a vibration transmission through hole. The sensor unit includes a sensor chip arranged on an outer surface of the second casing, and a back cavity of the sensor chip corresponds to the vibration transmission through hole.

To realize a substrate shape capable of ensuring a required substrate thickness while improving acoustic characteristics. A package on which a microphone element is to be mounted, the package including a substrate includes at least one recessed portion in a region corresponding to a mounting portion of the microphone element in the package. A bottom surface of the recessed portion in the substrate is a thin plate portion that is thinner than thicknesses of other regions. The substrate includes a plurality of through holes in the thin plate portion.

To realize a substrate shape capable of ensuring a required substrate thickness while improving acoustic characteristics. A package on which a microphone element is to be mounted, the package including a substrate includes at least one recessed portion in a region corresponding to a mounting portion of the microphone element in the package. A bottom surface of the recessed portion in the substrate is a thin plate portion that is thinner than thicknesses of other regions. The substrate includes a plurality of through holes in the thin plate portion.

According to an embodiment, a digital microphone includes an analog-to-digital converter (ADC) for receiving an analog input signal; a DC blocker component coupled to the ADC; a digital low pass filter coupled to the DC block component; and a nonlinear compensation component coupled to the digital low pass filter for providing a digital output signal.