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.

A micromechanical component, whose diaphragm is supported and has support structures on its inner diaphragm side. Each of the support structures includes a first and second edge element structure, and at least one intermediate element structure positioned between the first and second edge element structures. For each of the support structures, a plane of symmetry is definable, with respect to which at least the first edge element structure of the respective support structure and the second edge element structure of the respective support structure are specularly symmetric. In each of support structures, a first maximum dimension of its first edge element structure perpendicular to its plane of symmetry and a second maximum dimension of its second edge element structure perpendicular to its plane of symmetry are greater than the maximum dimension of its intermediate element structure perpendicular to its plane of symmetry.

The present invention relates to a MEMS acoustic sensor for sensing variable capacitance between a flexible diaphragm and a back plate. The MEMS acoustic sensor is composed of a substrate comprising a cavity, a back plate supported on the substrate and comprising a plurality of through holes, an electrode formed on the inner surface of the back plate, at least one anchor protruding from the back plate toward the substrate, a diaphragm supported by the at least one anchor and deformed by a sound wave introduced from the outside through the cavity, and a stress release unit extending from the edge portion of the back plate and in contact with the substrate.

There is provided a MOMS sensor comprising a fiber interface comprising a fiber passthrough for one or more optical fibers, a cavity comprising an element hermetically encapsulated within the cavity, wherein the element is movably anchored by SiN arms, which are movable with respect to walls of the cavity, wherein the SiN arms comprise anchor portions at first ends of the SiN arms, which are connected to the element, and at second ends of the SiN arms, which are connected to the walls of the cavity, and the fiber interface is configured to receive the fibers through the fiber passthrough into positions for communications of light between the element and the fibers. In this way a robust structure that supports sensitivity of the sensor is provided.

A method of fabricating a die for a microelectromechanical systems (MEMS) microphone includes the steps of forming a diaphragm, etching a plurality of slots through the diaphragm to define a plurality of springs, releasing the diaphragm and the plurality of springs, wherein the plurality of springs relieves intrinsic stress of the diaphragm, and sealing the plurality of slots with sealing material, thereby disabling the springs.

A MEMS microphone includes a cavity extending portion that increases the size of the cavity. The cavity extending portion can be sloped or stepped in order to create a desired profile of the extended cavity shape. Thus, the volume of the cavity may be increased in order to decrease the compliance and to increase a Signal to Noise Ratio.

The present disclosure relates to transfer of a selected set of microdevices from a donor substrate to a receiver/system substrate while there can be already microdevices transferred in the system substrate. In particular the invention deals with methods to transfer microdevices to a system substrate that do not damage already transferred microdevices, by using donor substrate heights, cavities and use of sacrificial layers.

A microelectromechanical system (MEMS) structure includes at least first and second metal vias. Each of the first and second metal vias includes a respective planar metal layer having a first thickness and a respective post formed from the planar metal layer. The post has a sidewall, and the sidewall has a second thickness greater than 14% of the first thickness.

A MEMS sensor that comprises a sensing reference plane, at least one anchor coupled to the sensing reference plane, wherein the sensing reference plane is divided by a first and a second axis forming four quadrants on the sensing reference plane, at least one proof mass coupled to the at least one anchor, wherein one of the at least one proof mass moves under an external excitation, and a pattern of sensing elements on the sensing reference plane to detect motion normal of the at least one proof mass relative to the sensing reference plane, wherein the pattern of sensing elements comprises at least three sensing elements in each of the four quadrants.

A system and/or method for utilizing microelectromechanical systems (MEMS) switching technology to operate MEMS sensors. As a non-limiting example, a MEMS switch may be utilized to control DC and/or AC bias applied to MEMS sensor structures. Also for example, one or more MEMS switches may be utilized to provide drive signals to MEMS sensors (e.g., to provide a drive signal to a MEMS gyroscope).