A MEMS pressure sensor is provided having a membrane made with one of plurality of metal layers. A lid is positioned above the membrane and connected to a plurality of cavity walls at distal ends of the membrane. The lid includes an array of holes positioned on a region of the lid. A fixed metal electrode is positioned below the lid.

A micro-electronic non-landing mirror system includes a substrate, at least two supporting assemblies, at least two driving electrodes, a rotating mirror, and a driving circuit. The rotating mirror is elastically supported on the supporting assemblies through elastic reset assemblies. When the driving circuit applies a driving voltage, the rotating mirror moves closer to the driving electrode to which the driving voltage is applied within a range of movement that does not land on the substrate. When the driving circuit removes the driving voltage, the rotating mirror gets back to move away from the driving electrode under elastic restoring force of the elastic reset assemblies. Each elastic reset assembly includes at least two elastic reset units connected to different corners of the rotating mirror by a corresponding one supporting assembly. Each elastic reset unit is configured for providing the rotating mirror with at least two rotational degrees of freedom.

A MEMS device includes a movable mass having a central region overlying a sense electrode and an opening in which a suspension structure and spring system are located. The suspension structure includes an anchor coupled to a substrate and rigid links extending from opposing sides of the anchor. The spring system includes a first and second spring heads coupled to each of the rigid links. A first drive spring is coupled to the first spring head and to the movable mass, and a second drive spring is coupled to the second spring head and to the movable mass. The movable mass is resiliently suspended above the surface of the substrate via the suspension structure and the spring system. The spring system enables drive motion of the movable mass in the drive direction and sense motion of the movable mass in a sense direction perpendicular to the surface of the substrate.

A microelectromechanical device is provided that includes a mobile rotor and a fixed stator in a device plane. Moreover, a fixed wall defines a wall plane that is adjacent to the device plane and a motion limiter is provided to prevent the rotor from coming into direct physical contact with the fixed wall. The motion limiter includes a shock absorber that extends from the rotor to the stator and a fixed stopper structure that protrudes from the fixed wall toward the shock absorber.

A camera system incorporating a MEMS actuator to achieve focus adjustments to compensate for the thermal expansion of the lens assembly is disclosed. The camera comprises a lens barrel, lens holder, infra-red (IR) filter, board circuit, MEMS actuator, housing package for the actuator, and an image sensor. The image sensor is directly wire bonded to pads on the circuit board such that these pads are movable at the image sensor end and fixed at the circuit board end. When the camera is exposed to temperature variations, the MEMS actuator moves the sensor along the optical axis to maintain the image in focus.

An optical system including a dual-layer microelectromechanical systems (MEMS) device, and methods of fabricating and operating the same are disclosed. Generally, the MEMS device includes a substrate having an upper surface; a top modulating layer including a number of light modulating micro-ribbons, each micro-ribbon supported above and separated from the upper surface of the substrate by spring structures in at least one lower actuating layer; and a mechanism for moving one or more of the micro-ribbons relative to the upper surface and/or each other. The spring structures are operable to enable the light modulating micro-ribbons to move continuously and vertically relative to the upper surface of the substrate while maintaining the micro-ribbons substantially parallel to one another and the upper surface of the substrate. The micro-ribbons can be reflective, transmissive, partially reflective/transmissive, and the device is operable to modulate a phase and/or amplitude of light incident thereon.

A frame (110) is rotatably coupled to a substrate (200) by way of a torsion spring element (100), wherein the frame (110) can be both twisted in relation to the substrate (200) and moved linearly in relation to said substrate (200). The torsion spring element (100) is made of a single piece and suitable for use in micro-electromechanical devices.

Various embodiments of the present disclosure are directed towards a semiconductor device. The semiconductor device comprises a substrate. A cavity is disposed in the substrate. A microelectromechanical system (MEMS) layer is disposed over the substrate. The MEMS layer comprises a movable diaphragm disposed over the cavity. The movable diaphragm comprises a central region and a peripheral region. The movable diaphragm is flat in the central region of the movable diaphragm. The movable diaphragm is corrugated in the peripheral region of the movable diaphragm.

A micromechanical device includes a semiconductor body, a first mobile structure, an elastic assembly, coupled to the first mobile structure and to the semiconductor body and adapted to undergo deformation in a direction, and at least one abutment element. The elastic assembly is configured to enable an oscillation of the first mobile structure as a function of a force applied thereto. The first mobile structure, the abutment element and the elastic assembly are arranged with respect to one another in such a way that: when the force is lower than a force threshold, the elastic assembly operates with a first elastic constant; and when the force is greater than the threshold force, then the first mobile structure is in contact with the abutment element, and a deformation of the elastic assembly is generated, which operates with a second elastic constant different from the first elastic constant.

An MEMS device includes a substrate with a substrate plane, a mass element having a rest position and configured to perform a deflection from the rest position parallel to the substrate plane and in a fluid surrounding the mass element. Further, the MEMS device includes a spring arrangement that is coupled between the substrate and the mass element and configured to deform based on the deflection. An actuator structure is provided that is coupled to the mass element by means of a coupling and configured to apply a force to the mass element by means of the coupling to cause the deflection and a movement of the fluid.