A piezoelectric optical micro-electro-mechanical systems (POMEMS) device includes a glass layer having a bottom surface and a top surface. The device may also include an upper moisture barrier layer having a top surface and a bottom surface in which the bottom surface of the top moisture barrier layer is substantially coextensive with and interfaces with the top surface of the glass layer. A piezo stack may be attached above the upper moisture barrier layer. The device may also include a lower moisture barrier layer having a bottom surface and a top surface. The top surface of the lower moisture barrier layer is substantially coextensive with and interfaces with the bottom surface of the glass layer. A semiconductor substrate may be attached below the bottom moisture barrier layer.

A microelectromechanical system (MEMS) device may include a MEMS structure above a first substrate. The MEMS structure comprising a central static element, a movable element, and an outer static element. A portion of bonding material between the central static element and the first substrate. A second substrate above the MEMS structure, with a portion of a dielectric layer between the central static element and the second substrate. A supporting post comprises the portion of bonding material, the central static element, and the portion of dielectric material.

A capacitance type transducer has a substrate with an opening on a surface thereof, a back plate arranged to oppose the opening of the substrate, and a vibrating electrode film arranged to oppose the back plate across a gap between the vibrating electrode film and the back plate. The capacitance type transducer converts a displacement of the vibrating electrode film into a change in capacitance between the vibrating electrode film and the back plate. The capacitance type transducer has a pressure releasing flow channel which is an air flow channel formed by a gap between a part of the vibrating electrode film and a protruding portion integrally provided on the back plate.

The application describes MEMS transducers and associated methods of fabrication. The MEMS transducer has a flexible membrane with a vent structure comprising a moveable portion which opens in response to a differential pressure across the membrane to provide a flow path through the membrane. At least one edge of the moveable portion comprises one or more protrusions and/or recesses in the plane of the moveable portion.

A MEMS package has a MEMS chip, a package substrate which the MEMS chip is adhered, a chip cover which wraps the MEMS chip, and a pressure regulation film which is adhered to the front surface of the chip cover. The chip cover has a vent which is formed in a chip outside area, arranged outside than the MEMS chip, the pressure regulation film has a slit. The slit is arranged in the neighborhood of the vent and the vent is covered with the pressure regulation film.

A method for manufacturing a filtering module comprising the steps of: forming a multilayer body comprising a filter layer of semiconductor material and having a thickness of less than 10 μm, a first structural layer coupled to a first side of the filter layer, and a second structural layer coupled to a second side, opposite to the first side, of the filter layer; forming a recess in the first structural layer, which extends throughout its thickness; removing selective portions, exposed through the recess, of the filter layer to form a plurality of openings, which extend throughout the thickness of the filter layer; and completely removing the second structural layer to connect fluidically the first and second sides of the filter layer, thus forming a filtering membrane designed to inhibit passage of contaminating particles.

A device includes a microelectromechanical system (MEMS) sensor die comprising a deformable membrane, a MEMS heating element, and a substrate. The MEMS heating element is integrated within a same layer and a same plane as the deformable membrane. The MEMS heating element surrounds the deformable membrane and is separated from the deformable membrane through a trench. The MEMS heating element is configured to generate heat to heat up the deformable membrane. The substrate is coupled to the deformable membrane.

A device includes a readout circuit coupled between an input node and an output node; a microelectromechanical systems (MEMS) device coupled to the input node; and a first charge controlled clamp circuit coupled between the input node and a first bias node.

Various embodiments of the present disclosure are directed towards a method for forming a microelectromechanical systems (MEMS) device. The method includes forming a filter stack over a carrier substrate. The filter stack comprises a particle filter layer having a particle filter. A support structure layer is formed over the filter stack. The support structure layer is patterned to define a support structure in the support structure layer such that the support structure has one or more segments. The support structure is bonded to a MEMS structure.

A MEMS die includes a substrate having an opening formed therein, and a diaphragm attached around a periphery thereof to the substrate and over the opening, wherein the diaphragm comprises first and second spaced apart layers. A backplate is disposed between the first and second spaced apart layers. One or more columnar supports are disposed through holes disposed through the backplate and connecting the first and second spaced apart layers. At least a partial vacuum exists between at least a portion of the first and second spaced apart layers. The first layer further comprises interior and exterior sub-layers at least proximate to each of the one or more columnar supports, wherein the interior sub-layers include one or more apertures disposed therethrough.