Abstract: A plate, a transducer, a method for making a transducer, and a method for operating a transducer are disclosed. An embodiment comprises a plate comprising a first material layer comprising a first stress, a second material layer arranged beneath the first material layer, the second material layer comprising a second stress, an opening arranged in the first material layer and the second material layer, and an extension extending into opening, wherein the extension comprises a portion of the first material layer and a portion of the second material layer, and wherein the extension is curved away from a top surface of the plate based on a difference in the first stress and the second stress.

Abstract: A microphone arrangement includes a housing having a sound hole, a first input audio transducer with a first sensitivity and a second input audio transducer with a second sensitivity. In this microphone arrangement, the first and the second input audio transducers are arranged in the housing, such that the first input audio transducer is directly acoustically coupled with the sound hole and the second input audio transducer is indirectly acoustically coupled with a sound hole via the first input audio transducer.

Abstract: A method for manufacturing a micromechanical sound transducer includes depositing successive layers of first and second membrane support material on a first main surface of a substrate arrangement with a first etching rate and a lower second etching rate, respectively. A layer of membrane material is then deposited. A cavity is created in the substrate arrangement from a side of the substrate arrangement opposite to the membrane support materials and the membrane material at least until the cavity extends to the layer of first membrane support material. The layers of first and second membrane support material are etched by applying an etching agent through the cavity in at least one first region located in an extension of the cavity also in a second region surrounding the first region. The etching creates a tapered surface on the layer of second membrane support material in the second region.

Abstract: A housed loudspeaker array includes a first substrate having a plurality of loudspeaker elements formed therein, a second substrate fixed at a first surface of the first substrate in a flip-chip manner and comprising a plurality of orifices that are aligned with the loudspeaker elements of the plurality of loudspeaker elements of the first substrate, and a cover applied to a second surface of the first substrate opposite to the first surface. A method for manufacturing the housed loudspeaker array is also disclosed.

Abstract: A digital loudspeaker includes a substrate, a first stator fixed with respect to the substrate, a second stator fixed with respect to the substrate and spaced at a distance from the first stator, and a membrane between the first stator and the second stator. The membrane is displaceable between a first position in which the membrane mechanically contacts the first stator and a second position in which the membrane mechanically contacts the second stator. The first stator and the second stator are arranged to electrostatically move the membrane from a rest position spaced apart from the first position and the second position to the first position and the second position, respectively.

Abstract: A sensor module has a carrier substrate having a bottom side and a top side, a sensor chip arranged on the top side of the carrier substrate and having a pressure-sensitive active area, a signal-processing chip arranged on the top side of the carrier substrate next to the sensor chip and being connected to the sensor chip in an electrically conducting manner, a continuous casting material covering the top side of the carrier substrate and the signal-processing chip and being in mechanical contact with both, the casting material having a recess which is arranged such that the casting material does not cover at least a part of the active area of the sensor chip.

Abstract: A sound transducer structure includes a membrane, a counter electrode, and a plurality of elevations. The membrane includes a first main surface, made of a membrane material, in a sound transducing region and an edge region of the membrane. The counter electrode is made of counter electrode material, and includes a second main surface arranged in parallel to the first main surface of the membrane on a side of a free volume opposite the first main surface of the membrane. The plurality of elevations extend in the sound transducing region from the second main surface of the counter electrode into the free volume.

Abstract: A method for producing a microphone module includes arranging a MEMS microphone structure on a first surface of a first substrate, the first substrate further including a second surface, which is opposite to the first surface. Furthermore, a cap is arranging on the first surface of the first substrate such that the cap and the first surface enclose the MEMS microphone structure. A readout device for the MEMS microphone structure is arranged on a first surface of a second substrate which further includes a second surface, which is opposite to the first surface. The second surface of the first substrate is attached to the second surface of the second substrate.

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: A method for producing a membrane for a device, e.g. a microphone, includes providing a substrate is provided on which a counter electrode is disposed. A sacrificial layer is provided on a surface of the counter electrode facing away from the substrate. The surface of the sacrificial layer facing away from the counter electrode is structured to form a plurality of recesses in the surface to define one or several antistick elements and one or several corrugation grooves at the same time. Subsequently, a membrane material is deposited on the structured surface of the sacrificial layer. Then, the sacrificial layer is removed to form the membrane, which has one or several corrugation grooves and one or several antistick elements.

Abstract: A sensor module and semiconductor chip. One embodiment provides a carrier. A semiconductor chip includes a first recess and a second recess and a main surface of the semiconductor chip. The semiconductor chip is mounted to the carrier such that the first recess forms a first cavity with the carrier and the second recess forms a second cavity with the carrier. The first cavity is in fluid connection with the second cavity.

Abstract: A method for producing a membrane for a device, e.g. a microphone, includes providing a substrate is provided on which a counter electrode is disposed. A sacrificial layer is provided on a surface of the counter electrode facing away from the substrate. The surface of the sacrificial layer facing away from the counter electrode is structured to form a plurality of recesses in the surface to define one or several antistick elements and one or several corrugation grooves at the same time. Subsequently, a membrane material is deposited on the structured surface of the sacrificial layer. Then, the sacrificial layer is removed to form the membrane, which has one or several corrugation grooves and one or several antistick elements.

Abstract: In a method for producing a membrane for a device, e.g. a microphone, first, a substrate is provided, whereon a counter electrode is disposed. A sacrificial layer is provided on a surface of the counter electrode facing away from the substrate. The surface of the sacrificial layer facing away from the counter electrode is structured to form a plurality of recesses in the surface to define one or several antistick elements and one or several corrugation grooves at the same time. Subsequently, a membrane material is deposited on the structured surface of the sacrificial layer. Then, the sacrificial layer is removed to form the membrane, which has one or several corrugation grooves and one or several antistick elements.

Abstract: A micromechanical sensor and, in particular, a silicon microphone, includes a movable membrane and a counter element in which perforation openings are formed, opposite to the movable membrane via a cavity. The perforation openings are formed by slots, the width of which maximally corresponds to double the spacing defined by the cavity between the membrane and the counter element.

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: A micromechanical capacitive converter and a method for manufacturing a micromechanical converter comprise a movable membrane and an electrically conductive face element in a carrier layer. The electrically conductive face element is arranged opposite the membrane above a cavity. The electrically conductive face element and the carrier layer are perforated by perforation openings. The opening width of the perforation openings corresponds approximately to the thickness of the carrier layer.

Abstract: A micromechanical capacitive converter and a method for manufacturing a micromechanical converter comprise a movable membrane and an electrically conductive face element in a carrier layer. The electrically conductive face element is arranged opposite the membrane above a cavity. The electrically conductive face element and the carrier layer are perforated by perforation openings. The opening width of the perforation openings corresponds approximately to the thickness of the carrier layer.

Abstract: A sensor module has a carrier substrate having a bottom side and a top side, a sensor chip arranged on the top side of the carrier substrate and having a pressure-sensitive active area, a signal-processing chip arranged on the top side of the carrier substrate next to the sensor chip and being connected to the sensor chip in an electrically conducting manner, a continuous casting material covering the top side of the carrier substrate and the signal-processing chip and being in mechanical contact with both, the casting material having a recess which is arranged such that the casting material does not cover at least a part of the active area of the sensor chip.

Abstract: A micromechanical sensor and, in particular, a silicon microphone, includes a movable membrane and a counter element in which perforation openings are formed, opposite to the movable membrane via a cavity. The perforation openings are formed by slots, the width of which maximally corresponds to double the spacing defined by the cavity between the membrane and the counter element.

Abstract: A micromechanical capacitive converter and a method for manufacturing a micromechanical converter comprise a movable membrane and an electrically conductive face element in a carrier layer. The electrically conductive face element is arranged opposite the membrane above a cavity. The electrically conductive face element and the carrier layer are perforated by perforation openings. The opening width of the perforation openings corresponds approximately to the thickness of the carrier layer.