A micro-electro-mechanical system (MEMS) microphone is provided. The MEMS microphone includes a substrate, a diaphragm, a backplate and a first protrusion. The substrate has an opening portion. The diaphragm is disposed on one side of the substrate and extends across the opening portion of the substrate. The backplate includes a plurality of acoustic holes. The backplate is disposed on one side of the diaphragm. An air gap is formed between the backplate and the diaphragm. The first protrusion extends from the backplate towards the air gap.

The present disclosure provides a MEMS device. The MEMS device includes: a substrate; a recess, disposed in the substrate; a movable portion, hollowly supported in the recess; and an isolation joint, inserted into a predetermined position of the movable portion and electrically insulating both sides of the movable portion. A shortest distance between a bottom of the recess and the movable portion is less than a distance between the bottom of the recess and the isolation joint.

The present disclosure relates to an integrated chip structure including a MEMS actuator. The MEMS actuator includes an anchor having a first plurality of branches extending outward from a central region of the anchor. The first plurality of branches respectively include a first plurality of fingers. A proof mass surrounds the anchor and includes a second plurality of branches extending inward from an interior sidewall of the proof mass. The second plurality of branches respectively include a second plurality of fingers interleaved with the first plurality of fingers as viewed in a top-view. One or more curved cantilevers are coupled between the proof mass and a frame wrapping around the proof mass. The one or more curved cantilevers have curved outer surfaces having one or more inflection points as viewed in the top-view.

The present invention relates to a fixed-fixed membrane for a microelectromechanical system (MEMS) microphone. In one embodiment, a MEMS acoustic sensor includes a substrate; a membrane situated parallel to the substrate; and at least one vent formed into the membrane, wherein the at least one vent is a curved opening in the membrane, and wherein the at least one vent is disposed substantially along a length of the membrane.

A micro electro mechanical system (MEMS) includes a circuit substrate comprising electronic circuitry, a support substrate having a recess, a bonding layer disposed between the circuit substrate and the support substrate, through holes passing through the circuit substrate to the recess, a first conductive layer disposed on a front side of the circuit substrate, and a second conductive layer disposed on an inner wall of the recess. The first conductive layer extends into the through holes and the second conductive layer extends into the through holes and coupled to the first conductive layer.

A MEMS sensing device for sensing microparticles in an environment external to the MEMS sensing device is provided. The MEMS sensing device comprises a semiconductor body integrating a sensor and a pump unit, the sensor including a sensor cavity, a membrane suspended over the sensor cavity, and a piezoelectric element over the membrane and configured to cause the membrane to oscillate, about an equilibrium position, at a corresponding resonance frequency when sensing electric signals are applied to the piezoelectric element during a first operative phase of the MEMS sensing device, the resonance frequency depending on an amount of microparticles located on the membrane, the membrane having a plurality of through holes for establishing a fluid communication between the sensor cavity and the environment; the pump is configured to cause air pressure in the sensor cavity to be reduced with respect to the air pressure of the environment during the first operative phase, so that microparticles are caused to adhere onto the membrane by a suction force through the plurality of through holes.

A MEMS transducer for interacting with a volume flow of a fluid includes a substrate including a cavity, and an electromechanical transducer connected to the substrate in the cavity and including an element deformable along a lateral movement direction, wherein a deformation of the deformable element along the lateral movement direction and the volume flow of the fluid are causally related.

A reflector has a reflective surface on first and second directions. Each of torsion beams extends to each opposite side of the reflective surface in the first direction. Each of coupling portions is to each opposite side of the reflector in the first direction and includes a central portion with U-shape having two projection portions and a bottom portion joined to the torsion beam. The projection portions include first concave portions opposing across the torsion beam by being penetrated in thickness direction. Each first concave portion extends in the second direction from an opening to a side surface facing the torsion beam towards an opposite side surface up to a bottom. A distance between the bottoms of the first concave portions across the torsion beam is greater than a distance between the side surfaces each facing the torsion beam of the projection portions.

A sensor includes a weight body, a frame which is located so as to surround the weight body when viewed from above, a beam part which is provided with flexibility and in which a first end is connected to the weight body and a second end is connected to the frame, and a detection part which is provided on the beam part and detects deformation of the beam part as an electric signal. The beam part includes a main part in which a cross-sectional shape in a direction perpendicular to a longitudinal direction connecting the first end and the second end is a rectangular shape, and an extending part which protrudes from at least one of an upper surface or a lower surface of the main part and extends in the longitudinal direction or extends in a width direction perpendicular to the longitudinal direction when viewed from above.

Electric connection flexures for moving stages of microelectromechanical systems (MEMS) devices are disclosed. The disclosed flexures may provide an electrical and mechanical connection between a fixed frame and a moving frame, and are flexible in the moving frame's plane of motion. In implementations, the flexures are formed using a process that embeds the two ends of each flexure in the fixed frame and moving frame, respectively.