Abstract: A triple-membrane MEMS device includes a first membrane, a second membrane and a third membrane spaced apart from one another, wherein the second membrane is between the first membrane and the third membrane, a sealed low pressure chamber between the first membrane and the third membrane, a first stator and a second stator in the sealed low pressure chamber, and a signal processing circuit configured to read-out output signals of the triple-membrane MEMS device.

Abstract: A system includes a first membrane, a second membrane and a third membrane spaced apart from one another, wherein the second membrane is between the first membrane and the third membrane, and the second membrane comprises a plurality of openings, a sealed low pressure chamber between the first membrane and the third membrane, and a plurality of electrodes in the sealed low pressure chamber.

Abstract: An embodiment as described herein includes a microelectromechanical system (MEMS) with a first MEMS transducer element, a second MEMS transducer element, and a semiconductor substrate. The first and second MEMS transducer elements are disposed at a top surface of the semiconductor substrate and the semiconductor substrate includes a shared cavity acoustically coupled to the first and second MEMS transducer elements.

Abstract: A MEMS device includes a first electrode structure and a second electrode structure forming a capacitive sensing arrangement. The MEMS device includes a plurality of anti-stiction bumps arranged between the first electrode structure and the second electrode structure at a corresponding plurality of locations. The plurality of locations being projected into a main surface of the second electrode structure is distributed so as to comprise a first distribution density in a first main surface region of the main surface and so as to comprise second, different distribution density in a second main surface region of the main surface, the second main surface region being delimited from the first main surface region.

Abstract: A MEMS sensor includes a housing with an interior volume, wherein the housing has an access port to the interior volume, a MEMS component in the housing, and a protection structure, which reduces an introduction of electromagnetic disturbance radiation with a wavelength in the range between 10 nm and 20 ?m into the interior volume through the access port and reduces a propagation of the electromagnetic disturbance radiation in the interior volume.

Abstract: A MEMS sensor includes a housing with an interior volume, wherein the housing has an access port to the interior volume, a MEMS component in the housing, and a protection structure, which reduces an introduction of electromagnetic disturbance radiation with a wavelength in the range between 10 nm and 20 ?m into the interior volume through the access port and reduces a propagation of the electromagnetic disturbance radiation in the interior volume.

Abstract: For manufacturing a sound transducer structure, membrane support material is applied on a first main surface of a membrane carrier material and membrane material is applied in a sound transducing region and an edge region on a surface of the membrane support material. In addition, counter electrode support material is applied on a surface of the membrane material and recesses are formed in the sound transducing region of the membrane material. Counter electrode material is applied to the counter electrode support material and membrane carrier material and membrane support material are removed in the sound transducing region to the membrane material.

Abstract: In accordance with one exemplary embodiment, a production method for a double-membrane MEMS component comprises the following steps: providing a layer arrangement on a carrier substrate, wherein the layer arrangement has a first and second membrane structure spaced apart from one another and a counterelectrode structure arranged therebetween, wherein a sacrificial material is arranged in an intermediate region between the counterelectrode structure and the first and second membrane structures respectively spaced apart therefrom, and wherein the first membrane structure has an opening structure to the intermediate region with the sacrificial material and partly removing the sacrificial material from the intermediate region in order to obtain a mechanical connection structure comprising the sacrificial material between the first and second membrane structures, which mechanical connection structure is mechanically coupled between the first and second membrane structures and is mechanically decoupled from the cou

Abstract: A microfabricated structure includes a deflectable membrane, a first clamping layer on a first surface of the deflectable membrane, a second clamping layer on a second surface of the deflectable membrane, a first perforated backplate on the first clamping layer, and a second perforated backplate on the second clamping layer, wherein the first clamping layer comprises a first tapered edge portion having a negative slope between the first perforated backplate and the deflectable membrane.

Abstract: A microfabricated structure includes a deflectable membrane, a first clamping layer on a first surface of the deflectable membrane, a second clamping layer on a second surface of the deflectable membrane, a first perforated backplate on the first clamping layer, and a second perforated backplate on the second clamping layer, wherein the first clamping layer comprises a first tapered edge portion having a negative slope between the first perforated backplate and the deflectable membrane.

Abstract: A microfabricated structure includes a deflectable membrane, a first clamping layer on a first surface of the deflectable membrane, a second clamping layer on a second surface of the deflectable membrane, a first perforated backplate on the first clamping layer, and a second perforated backplate on the second clamping layer, wherein the first clamping layer comprises a first tapered edge portion having a negative slope between the first perforated backplate and the deflectable membrane.

Abstract: A MEMS transducer includes a first and a second differential MEMS sensor device. The first differential MEMS sensor device includes a first and a second electrode structure for providing a first differential output signal, and a third electrode structure between the first and second electrode structure. The second differential MEMS sensor device includes a first and second electrode structure for providing a second differential output signal, and a third electrode structure between the first and second electrode structure. A biasing circuit provides the third electrode structure of the first differential MEMS sensor device with a first biasing voltage and provides the third electrode structure of the second differential MEMS sensor device with a second biasing voltage. A read-out circuitry combines the first and second differential output signal in an anti-parallel manner.

Abstract: A MEMS sound transducer element is operable in an audio and an ultrasonic range. The MEMS sound transducer element includes a first electrode structure, wherein a conductive material of the first electrode structure includes a plurality of electrically isolated electrode segments, and a second electrode structure spaced apart from the first electrode structure, wherein the first electrode structure and the second electrode structure are operable as an audio sound transducer. A first subset of the plurality of electrically isolated electrode segments of the first electrode structure is, in conjunction with the second electrode structure, operable as an ultrasonic or audio emitter, and a second subset of the plurality of the electrically isolated electrode segments of the first electrode structure is, in conjunction with the second electrode structure, operable as an ultrasonic or audio receiver.

Abstract: A MEMS assembly includes a housing having an internal volume V, wherein the housing has a sound opening to the internal volume V, a MEMS component in the housing adjacent to the sound opening, and a layer element arranged at least regionally at a surface region of the housing that faces the internal volume V, wherein the layer element includes a layer material having a lower thermal conductivity and a higher heat capacity than the housing material of the housing that adjoins the layer element.

Abstract: A MEMS device includes a first electrode structure and a second electrode structure forming a capacitive sensing arrangement. The MEMS device includes a plurality of anti-stiction bumps arranged between the first electrode structure and the second electrode structure at a corresponding plurality of locations. The plurality of locations being projected into a main surface of the second electrode structure is distributed so as to comprise a first distribution density in a first main surface region of the main surface and so as to comprise second, different distribution density in a second main surface region of the main surface, the second main surface region being delimited from the first main surface region.

Abstract: In accordance with an embodiment, a MEMS sensor includes a MEMS arrangement having a movable electrode and a stator electrode arranged opposite the movable electrode. The MEMS sensor includes a first bias voltage source, which is connected to the stator electrode and which is configured to apply a first bias voltage to the stator electrode. The MEMS sensor further includes a common-mode read-out circuit connected to the stator electrode by a capacitive coupling and comprising a second bias voltage source, which is configured to apply a second bias voltage to a side of the capacitive coupling that faces away from the stator electrode.

Abstract: In accordance with one exemplary embodiment, a production method for a double-membrane MEMS component comprises the following steps: providing a layer arrangement on a carrier substrate, wherein the layer arrangement has a first and second membrane structure spaced apart from one another and a counterelectrode structure arranged therebetween, wherein a sacrificial material is arranged in an intermediate region between the counterelectrode structure and the first and second membrane structures respectively spaced apart therefrom, and wherein the first membrane structure has an opening structure to the intermediate region with the sacrificial material and partly removing the sacrificial material from the intermediate region in order to obtain a mechanical connection structure comprising the sacrificial material between the first and second membrane structures, which mechanical connection structure is mechanically coupled between the first and second membrane structures and is mechanically decoupled from the cou

Abstract: In accordance with one exemplary embodiment, a production method for a double-membrane MEMS component comprises the following steps: providing a layer arrangement on a carrier substrate, wherein the layer arrangement has a first and second membrane structure spaced apart from one another and a counterelectrode structure arranged therebetween, wherein a sacrificial material is arranged in an intermediate region between the counterelectrode structure and the first and second membrane structures respectively spaced apart therefrom, and wherein the first membrane structure has an opening structure to the intermediate region with the sacrificial material and partly removing the sacrificial material from the intermediate region in order to obtain a mechanical connection structure comprising the sacrificial material between the first and second membrane structures, which mechanical connection structure is mechanically coupled between the first and second membrane structures and is mechanically decoupled from the cou

Abstract: For manufacturing a sound transducer structure, membrane support material is applied on a first main surface of a membrane carrier material and membrane material is applied in a sound transducing region and an edge region on a surface of the membrane support material. In addition, counter electrode support material is applied on a surface of the membrane material and recesses are formed in the sound transducing region of the membrane material. Counter electrode material is applied to the counter electrode support material and membrane carrier material and membrane support material are removed in the sound transducing region to the membrane material.

Abstract: An embodiment as described herein includes a microelectromechanical system (MEMS) with a first MEMS transducer element, a second MEMS transducer element, and a semiconductor substrate. The first and second MEMS transducer elements are disposed at a top surface of the semiconductor substrate and the semiconductor substrate includes a shared cavity acoustically coupled to the first and second MEMS transducer elements.