In some exemplary embodiments, a MEMS accelerometer includes a device wafer having a proof mass and a plurality of tracking anchor points attached to a substrate. Each tracking anchor is configured to deflect in response to asymmetrical deformation in the substrate, and transfer mechanical forces generated in response to the deflection to tilt the proof mass in a direction of the deformation.

An microelectromechanical switch uses electrostatic attraction to draw a beam toward a contact and electromagnetic repulsion to disengage and repel the beam from the contact. The electrostatic attraction is generated by a gate electrode. The electromagnetic repulsion is generated between the beam and a magnetic coil positioned on the same side of the beam as the contact. The magnetic coil produces a magnetic field, which induces a current in the beam that repels the magnetic coil. The gate electrode and the magnetic coil may be co-planar or in different planes. A circuit may also operate a coil-shaped structure act as the gate electrode and the magnetic coil, depending on the configuration.

The invention relates to an acceleration sensor (100) having a sensor material (120) which is mounted by means of spring elements (130) so as to be movable along a movement axis (x) over a substrate (110), first trim electrodes (140) which are connected to the sensor material (120), and second trim electrodes (150) which are connected to the substrate (110) and are associated with the first trim electrodes (140). When the sensor material is deflected along the movement axis, a spring force acting on the sensor material (120) is generated by the spring elements (130), and when the sensor material (120) is deflected, an electrostatic force acting on the sensor material (120), which counteracts the spring force, is generated by application of an electrical trim voltage between the first trim electrodes (140) and the second trim elements (150).

A device includes a carrier having a plurality of cavities, a micro-electro-mechanical system (MEMS) substrate bonded on the carrier, wherein the MEMS substrate comprises a first side bonded on the carrier, a moving element over a bottom electrode, wherein the bottom electrode is formed of polysilicon and a second side having a plurality of bonding pads and a semiconductor substrate bonded on the MEMS substrate, wherein the semiconductor substrate comprises a top electrode and the first moving element is between the top electrode and the bottom electrode.

Various embodiments of the present disclosure are directed towards a semiconductor structure comprising a spring structure. A first substrate underlies a second substrate. The first and second substrates at least partially define a cavity. A microelectromechanical systems (MEMS) component is arranged in the cavity. The spring structure is disposed between a region of the second substrate and the MEMS component. The spring structure comprises a first layer and a second layer. The first layer continuously extends along a first vertical surface of the second layer.

Apparatuses, systems, and methods associated with placement of magnets within a microelectromechanical system device are disclosed herein. In embodiments, a method of affixing at least one magnet in a microelectromechanical system, may include affixing an electromagnetic actuator to a base structure of the microelectromechanical system, the affixing including affixing the electromagnetic actuator within a recess formed in the base structure. The method may further include placing a magnet within the recess, wherein the recess includes at least a portion of a spring, the spring affixed to the base structure and extending into the recess, the placing including placing the magnet on a side of the electromagnetic actuator, between the spring and the side of the electromagnetic actuator, the spring pressing the magnet against the side of the electromagnetic actuator and maintaining a position of the magnet in response to the placing the magnet within the recess.

A micro-electro-mechanical systems (MEMS) terminal structure of board-to-board electrical connector and manufacturing method thereof are provided. The terminal of the terminal structure includes a side arm, a bent portion, and a flexible arm integrally formed as one component. The flexible arm includes a first portion and a second portion. The first portion and the side arm form an insertion space. The second portion and the side arm form a locking space. The second portion of the flexible arm has a contact portion. The insertion space is greater than the locking space. The terminal has curved and locking features to extend the moment arm of the terminal for improving the terminal flexibility. The terminal contacts a mating terminal through multiple points, thereby improving the contact stability and providing the locking function. Furthermore, by using the MEMS techniques for semiconductor industries, the terminal of micro board-to-board electrical connector can be manufactured.

A check-valve comprises: a thin sheet and a thick sheet; flow paths for flowing fluid which are formed by penetrating the thin sheet and the thick sheet; a flow-in chamber and a flow-out chamber which are connected to the flow paths; a partition sheet which is bonded to the thin sheet and the thick sheet while being sandwiched therebetween, and has a flexible inner flange which projects in cavities of the flow-in chamber and the flow-out chamber and does not close the flow-out valve chamber by flexing toward the flow-out valve chamber in a normal flow, and closes the flow-in valve chamber by flexing toward the flow-in valve chamber in a reverse flow; and a through-pass hole which is opened at the partition sheet and connects the both valve chambers.

A system and method for precisely positioning a moveable structure in a micro-electromechanical system (MEMS). The system includes a substrate and a moveable device structure supported on the substrate. The device structure is moveable from an initial position to a deployment position at a predetermined offset angle to the substrate. A moveable anchor structure is supported on the substrate in proximity to the device structure. The anchor structure is locked to the device structure when the device structure is moved to the deployment position.

An MEMS sound transducer comprises a first and a second backplate, as well as a diaphragm, which is arranged between the first and the second backplate and is held by an edge fastening between the first and the second backplate. The MEMS sound transducer comprises a clamping structure, which is configured to provide fixing for the diaphragm when an electrostatic force acting in an operating state is applied between the first and the second backplate and at a distance from the edge fastening, and to release the fixing in absence of the electrostatic force.