A packaged pressure sensor, comprising: a MEMS pressure-sensor chip; and an encapsulating layer of elastomeric material, in particular PDMS, which extends over the MEMS pressure-sensor chip and forms a means for transferring a force, applied on a surface thereof, towards the MEMS pressure-sensor chip.

A Micro Electro Mechanical System (MEMS) microphone is provided. The MEMS microphone includes: a substrate including an audio hole and having an oxide layer at a predetermined segment along an upper surface edge; a vibration electrode that is supported by a support layer that is formed along an upper surface edge in a state that is separated to the inside of the center from the oxide layer at an upper portion corresponding to the audio hole; a fixed electrode that is formed at an upper portion of the oxide layer and in which one side of the support layer is bonded to one side of a low surface; and a back plate that is formed at an upper portion of the fixed electrode and in which the other side of the support layer is bonded to one side of a low surface.

Disclosed are a microphone and a manufacturing method thereof. The microphone includes a substrate with a through portion formed in a central portion thereof, a vibration membrane disposed on the substrate and covering the through portion, a fixed membrane installed above the vibration membrane and spaced apart from the vibration membrane with an air layer interposed therebetween, and including a plurality of air inlets perforated in a direction toward the air layer, a support layer supporting the fixed membrane installed above the vibration membrane and spaced apart from the vibration membrane, a back plate formed on the fixed membrane and the support layer and having the air inlet formed to extend in a central portion thereof, and an air outflow part allowing air of the air layer to flow to an outer area of an edge of a sensing area of the fixed membrane on the back plate.

A packaged integrated device includes a package substrate having a first surface and a second surface opposite the first surface, and the package substrate has a hole therethrough. The integrated device package also includes a first lid mounted on the first surface of the package substrate to define a first cavity, and a second lid mounted on the second surface of the package substrate to define a second cavity. A microelectromechanical systems (MEMS) die can be mounted on the first surface of the package substrate inside the first cavity and over the hole. A port can be formed in the first lid or the second lid.

A method of fabricating a micro-electrical-mechanical system (MEMS) transducer comprises the steps of forming a membrane on a substrate, and forming a back-volume in the substrate. The step of forming a back-volume in the substrate comprises the steps of forming a first back-volume portion and a second back-volume portion, the first back-volume portion being separated from the second back-volume portion by a step in a sidewall of the back-volume. The cross-sectional area of the second back-volume portion can be made greater than the cross-sectional area of the membrane, thereby enabling the back-volume to be increased without being constrained by the cross-sectional area of the membrane. The back-volume may comprise a third back-volume portion. The third back-volume portion enables the effective diameter of the membrane to be formed more accurately.

A method of fabricating a micro-electrical-mechanical system (MEMS) transducer comprises the steps of forming a membrane on a substrate, and forming a back-volume in the substrate. The step of forming a back-volume in the substrate comprises the steps of forming a first back-volume portion and a second back-volume portion, the first back-volume portion being separated from the second back-volume portion by a step in a sidewall of the back-volume. The cross-sectional area of the second back-volume portion can be made greater than the cross-sectional area of the membrane, thereby enabling the back-volume to be increased without being constrained by the cross-sectional area of the membrane. The back-volume may comprise a third back-volume portion. The third back-volume portion enables the effective diameter of the membrane to be formed more accurately.

A method for producing at least one cavity within a semiconductor substrate includes dry etching the semiconductor substrate from a surface of the semiconductor substrate at at least one intended cavity location in order to obtain at least one provisional cavity. The method includes depositing a protective material with regard to a subsequent wet-etching process at the surface of the semiconductor substrate and at cavity surfaces of the at least one provisional cavity. Furthermore, the method includes removing the protective material at least at a section of a bottom of the at least one provisional cavity in order to expose the semiconductor substrate. This is followed by electrochemically etching the semiconductor substrate at the exposed section of the bottom of the at least one provisional cavity. A method for producing a micromechanical sensor system in which this type of cavity formation is used and a corresponding MEMS are also disclosed.

Micromechanical devices include actively deflectable elements. The activation is performed by a layer stack which causes the deflection responsive to attractive forces acting upon the layers of the layer stack.

The present invention relates to electrodes for microelectromechanical system (MEMS) microphones. In one embodiment, a MEMS sensor includes a membrane and a backplate situated parallel to the membrane and separated by a gap. The backplate includes a first region that includes a center point of the backplate and has first holes of a first hole pitch, a second region that is positioned outside the first region and has second holes of a second hole pitch that is smaller than the first hole pitch, and a transitional region that is positioned between the first region and the second region and has third holes of a third hole pitch that is between the first hole pitch and the second hole pitch. The first and second regions of the backplate and their respective holes can be of a shape (e.g., hexagonal) that differs from the shape of the backplate.

A MEMS microphone includes a substrate having a back cavity, a vibration diaphragm system, and a housing. The vibration diaphragm system includes at least two sub-vibration diaphragm assemblies, a slit is formed between adjacent two of the at least two sub-vibration diaphragm assemblies, one end, distal from the housing, of each of the at least two sub-vibration diaphragm assemblies is fixed to a cross beam assembly, and first gaps are formed between the at least two sub-vibration diaphragm assemblies and inner sides of the housing, so that the at least two sub-vibration diaphragm assemblies form a cantilever beam structure, which increases compliance of the vibration diaphragm system and further improves sensitivity of microphones.