Abstract: Measures are described by which the back volume of a microphone component can be realized regardless of its packaging. Within the framework of a microphone module, a circuit board is used for the 2nd-level mounting of at least one microphone component part, in whose surface at least one connection opening is formed, which terminates in a cavity in the layer structure of the circuit board. In addition, the circuit board surface having the connection opening is configured for a sealing mounting of the microphone component part above the connection opening, so that the microphone component is acoustically connected to the cavity in the circuit board via the connection opening in the circuit board surface, and this cavity functions as backside volume for the microphone component part.

Abstract: Measures are provided for increasing the resistance to compression of a component having a micromechanical microphone pattern. In particular, the robustness of the microphone pattern to highly dynamic pressure fluctuations is to be increased, without the microphone sensitivity, i.e. the microphone performance, being impaired. The microphone pattern of such a component is implemented in a layer construction on a semiconductor substrate and includes at least one acoustically active diaphragm, which spans a sound hole on the substrate backside, and a stationary acoustically penetrable counterelement having through hole openings, which is situated above/below the diaphragm in the layer construction. At least one outflow channel is developed which makes possible a rapid pressure equalization between the two sides of the diaphragm. In addition, at least one controllable closing element is provided, with which the at least one outflow channel is optionally able to be opened or closed.

Abstract: A diaphragm structure of a micromechanical component includes: a diaphragm integrated via at least one spring element into a layered structure, the diaphragm spanning a cavern, so that at least one section of the diaphragm edge extends up to and beyond the edge area of the cavern; and an anchoring structure formed in the overlap area between the diaphragm and the cavern edge area. The anchoring structure includes at least one anchor element structured out of the layered structure above the cavern edge area, and one through opening for the anchor element formed in the edge area of the diaphragm, so that there is a clearance between the anchor element and the through opening which allows for a mechanical stress relaxation of the diaphragm.

Abstract: Measures are described which simplify the functional testing of a component having an MEMS element provided with a pressure-sensitive sensor diaphragm, and which allow a self-calibration of the component even after it is already in place, i.e., following the end of the production process. The component has a housing, in which are situated at least one MEMS element having a pressure-sensitive sensor diaphragm and a switching arrangement for detecting the diaphragm deflections as measuring signals; an arrangement for analyzing the measuring signals; and an arrangement for the defined excitation of the sensor diaphragm. The housing has at least one pressure connection port. The arrangement for exciting the sensor diaphragm includes at least one selectively actuable actuator component for generating defined pressure pulses that act on the sensor diaphragm.

Abstract: Measures are provided for increasing the resistance to compression of a component having a micromechanical microphone pattern. In particular, the robustness of the microphone pattern to highly dynamic pressure fluctuations is to be increased, without the microphone sensitivity, i.e. the microphone performance, being impaired. The microphone pattern of such a component is implemented in a layer construction on a semiconductor substrate and includes at least one acoustically active diaphragm, which spans a sound hole on the substrate backside, and a stationary acoustically penetrable counterelement having through hole openings, which is situated above/below the diaphragm in the layer construction. At least one outflow channel is developed which makes possible a rapid pressure equalization between the two sides of the diaphragm. In addition, at least one controllable closing element is provided, with which the at least one outflow channel is optionally able to be opened or closed.

Abstract: Measures are described by which the back volume of a microphone component can be realized regardless of its packaging. Within the framework of a microphone module, a circuit board is used for the 2nd-level mounting of at least one microphone component part, in whose surface at least one connection opening is formed, which terminates in a cavity in the layer structure of the circuit board. In addition, the circuit board surface having the connection opening is configured for a sealing mounting of the microphone component part above the connection opening, so that the microphone component is acoustically connected to the cavity in the circuit board via the connection opening in the circuit board surface, and this cavity functions as backside volume for the microphone component part.

Abstract: Measures are provided for increasing the resistance to compression of a component having a micromechanical microphone pattern. In particular, the robustness of the microphone pattern to highly dynamic pressure fluctuations is to be increased, without the microphone sensitivity, i.e. the microphone performance, being impaired. The microphone pattern of such a component is implemented in a layer construction on a semiconductor substrate and includes at least one acoustically active diaphragm, which spans a sound hole on the substrate backside, and a stationary acoustically penetrable counterelement having through hole openings, which is situated above/below the diaphragm in the layer construction. At least one outflow channel is developed which makes possible a rapid pressure equalization between the two sides of the diaphragm. In addition, at least one controllable closing element is provided, with which the at least one outflow channel is optionally able to be opened or closed.

Abstract: A microphone structure of an MEMS device has a layer construction including: a base substrate; a deflectable microphone diaphragm at least partly spanning a through-opening in the substrate; a deflectable electrode of a microphone condenser system; a stationary counter-element having ventilation openings situated in the layer construction over the microphone diaphragm and acting as a bearer for a stationary electrode of the microphone condenser system. The diaphragm is bonded into the layer construction on the substrate via a flexible beam. The otherwise free edge region of the diaphragm is curved in a pan shape, so that it extends both vertically and also in some regions laterally beyond the edge region of the through-opening, and the edge region of the through-opening forms a lower stop for the diaphragm movement.

Abstract: A MEMS component for generating pressure pulses is provided, its micromechanical structure including at least three function levels: a first function level in which at least one stationary trench structure is implemented, a second function level, which is implemented above the first function level and includes at least one triggerable displacement element as well as through-openings as pressure outlet openings, the displacement element protruding into the trench structure and being movable in parallel with the function levels, whereby positive and negative pressure pulses are generated, and a third function level, which is implemented above the second function level and includes at least one triggerable cover element for at least one part of the pressure outlet openings in the second function level.

Abstract: A new signal acquisition concept is provided for MEMS components having a pressure-sensitive diaphragm element, which at least partially spans a pressure connection opening. This signal acquisition concept is distinguished by an especially high sensitivity. For this purpose, the MEMS component includes a resonant vibrator device having a vibrating element, which is suspended, capable of vibrating, within a closed cavity and is equipped with at least one drive electrode and at least one sensing electrode. The vibrating element of the resonant vibrator device is coupled mechanically to the diaphragm element, so that the vibrating element is deformed in the case of a diaphragm deflection.

Abstract: A diaphragm structure of a micromechanical component includes: a diaphragm integrated via at least one spring element into a layered structure, the diaphragm spanning a cavern, so that at least one section of the diaphragm edge extends up to and beyond the edge area of the cavern; and an anchoring structure formed in the overlap area between the diaphragm and the cavern edge area. The anchoring structure includes at least one anchor element structured out of the layered structure above the cavern edge area, and one through opening for the anchor element formed in the edge area of the diaphragm, so that there is a clearance between the anchor element and the through opening which allows for a mechanical stress relaxation of the diaphragm.

Abstract: A packaging concept for MEMS components having at least one diaphragm structure formed in the front side of the component is provided, according to which the MEMS component is mounted on a support which at least laterally delimits a cavity adjoining the diaphragm structure. In addition, at least one electrical feedthrough is formed in the support which allows electrical contacting of the MEMS component through the support. To achieve the largest possible rear volume for the diaphragm structure of the MEMS component for a given chip surface area, and also to simplify the processing of the support, according to the invention the electrical feedthroughs are integrated into the wall of the cavity adjoining the diaphragm structure, in that at least one section of such a feedthrough is implemented in the form of an electrically conductive coating of a side wall section of the cavity.

Abstract: A cost-effective and extremely space-saving module approach is provided for at least two micromechanical sensor elements having the same packaging requirements. The sensor module described here includes at least two micromechanical sensor elements whose sensor function is based on the direct or indirect impact of a measuring medium. The at least two sensor elements are situated in a shared housing having at least one access opening for the measuring medium, and the at least two sensor elements are stacked with one component back side on one component front side, so that the upper sensor element at least partially covers the active area of the lower sensor element, while still ensuring the impact of the measuring medium, which is used for the sensor function, on the active area of the lower sensor element.

Abstract: An MEMS component includes at least one metal-ceramic multilayer stack as a mechanical functional layer in the layered structure of the MEMS component. The metal-ceramic multilayer stack functions as a mechanical functional layer in which at least one component of the micromechanical structure of the MEMS component is configured.

Abstract: A capacitive MEMS microphone structure is provided, which micromechanical microphone structure of component is realized in a layer construction and includes: a diaphragm structure sensitive to sound pressure, which is deflectable in a direction perpendicular to the layer planes of the layer construction; an acoustically penetrable counter-element which has through holes and is formed above or below the diaphragm structure in the layer construction; and a capacitor system for detecting the excursions of the diaphragm structure. The diaphragm structure includes a structural element in the middle area of the diaphragm structure, which structural element projects perpendicularly from the diaphragm plane and which, depending on the degree of excursion of the diaphragm structure, variably extends into a correspondingly formed and positioned through hole in the counter-element.

Abstract: A micromechanical microphone structure configured as a layered structure includes: a semiconductor substrate; a diaphragm structure having an acoustically active diaphragm which at least partially spans a sound opening in the back side of the substrate and is provided with a movable electrode of a microphone capacitor, which diaphragm structure has openings via which pressure compensation occurs between the back side and the front side of the diaphragm; a stationary acoustically permeable counterelement having vents, which counterelement is situated in the layered structure above the diaphragm and which functions as a carrier for a nonmovable electrode of the microphone capacitor; and at least one ridge-like structural element which is situated at the outer edge area of the diaphragm, and which protrudes from the diaphragm plane into corresponding recesses in an adjoining layer.

Abstract: Measures for improving the acoustic properties of a microphone component produced in sacrificial layer technology. The micromechanical microphone structure of such a component is implemented in a layered structure, and includes at least one diaphragm, which is deflectable by sound pressure and which is implemented in a diaphragm layer, and a stationary acoustically permeable counterelement for the diaphragm which is implemented in a thick functional layer above the diaphragm layer and which is provided with through openings for introducing sound. The through openings for introducing sound are situated above the middle region of the diaphragm, while perforation openings which are largely acoustically passive are provided in the counterelement, above the edge region of the diaphragm.

Abstract: A new signal acquisition concept is provided for MEMS components having a pressure-sensitive diaphragm element, which at least partially spans a pressure connection opening. This signal acquisition concept is distinguished by an especially high sensitivity. For this purpose, the MEMS component includes a resonant vibrator device having a vibrating element, which is suspended, capable of vibrating, within a closed cavity and is equipped with at least one drive electrode and at least one sensing electrode. The vibrating element of the resonant vibrator device is coupled mechanically to the diaphragm element, so that the vibrating element is deformed in the case of a diaphragm deflection.

Abstract: A microphone assembly includes two MEMS components each having a micromechanical microphone structure, each microphone structure having: a diaphragm configured to be deflected by sound pressure and provided with at least one diaphragm electrode of a capacitor system; and a stationary acoustically permeable counter-element that acts as bearer for at least one counter-electrode of the capacitor system. The microphone assembly is configured such that under the action of sound the spacing between the diaphragm and the counter-element of the two microphone structures changes in opposite directions.

Abstract: A microphone structure of an MEMS device has a layer construction including: a base substrate; a deflectable microphone diaphragm at least partly spanning a through-opening in the substrate; a deflectable electrode of a microphone condenser system; a stationary counter-element having ventilation openings situated in the layer construction over the microphone diaphragm and acting as a bearer for a stationary electrode of the microphone condenser system. The diaphragm is bonded into the layer construction on the substrate via a flexible beam. The otherwise free edge region of the diaphragm is curved in a pan shape, so that it extends both vertically and also in some regions laterally beyond the edge region of the through-opening, and the edge region of the through-opening forms a lower stop for the diaphragm movement.