A method for manufacturing a micromechanical inertial sensor, including: forming a movable MEMS structure in a MEMS wafer; connecting a cap wafer to the MEMS wafer; forming an access opening into the cavity, the access opening to the cavity being formed from two opposing sides; a defined narrow first access opening being formed from one side of the movable MEMS structure and a defined wide second access opening being formed from a surface of the MEMS wafer, the second access opening being formed to be wider in a defined manner than the first access opening; and closing the first access opening while enclosing a defined internal pressure in the cavity.

The present invention relates to a vibration sensor comprising a carrier substrate comprising a first surface and a second surface, a suspension member and a moveable mass secured thereto, wherein the moveable mass and/or at least part of the suspension member is/are adapted to vibrate when the vibration sensor is exposed to external vibrations, a read-out arrangement for detecting vibrations of the moveable mass and/or at least part of the suspension member, and a signal processor for at least processing an electric signal from the read-out arrangement, wherein the read-out arrangement comprises a capacitor formed by a first capacitor electrode and a second capacitor electrode separated by an air gap, and wherein the first capacitor electrode and/or the second capacitor electrode comprises one or more air venting channels in order to reduce squeeze film damping effects between the first and second capacitor electrodes. The present invention further relates to a hearing device comprising such a vibration sensor and use of the vibration sensor for voice recognition in a hearing device.

A micromechanical component is provided, the micromechanical component enclosing a cavity, the micromechanical component including a sensor element situated in the cavity, and the micromechanical component including a getter situated in the cavity. The micromechanical component includes a structure, situated between the sensor element and the getter, which is designed in such a way that a particle that is desorbed by the getter is sorbed onto and/or into an area of the micromechanical component that is spaced apart from the sensor element.

An electronic device includes a substrate, a lid which is bonded to the substrate, and a functional element which is provided between the substrate and the lid, in which the lid includes a penetration hole which penetrates a portion between an inner surface and an outer surface, the penetration hole includes a first hole portion and a second hole portion, a flat area of the second hole portion is set to be smaller than a flat area of the first hole portion, at least a part of an inner wall surface of the second hole portion substantially forms a right angle with respect to a bottom surface of the first hole portion, and the penetration hole is sealed with a sealing member.