The present invention relates to microelectromechanical systems (MEMS), and more specifically to an anchor structure for anchoring MEMS components within a MEMS device. The anchor points for rotor and stator components of the device are arranged such that the anchor points are arranged along and overlap a common axis.

In a general aspect, a micromachined gyroscope can include a substrate and a static mass suspended in an x-y plane over the substrate by a plurality of anchors attached to the substrate. The static mass can be attached to the anchors by anchor suspension flexures. The micromachined gyroscope can include a dynamic mass surrounding the static mass and suspended from the static mass by one or more gyroscope suspension flexures.

Embodiments of the disclosure provide an optical sensing system, a method for adjusting a receiving aperture in the optical sensing system, and an adjustable iris in the optical sensing system. The exemplary optical sensing system includes a transmitter configured to emit light beams to an environment. The optical sensing system further includes a receiver configured to receive the light beams returning from the environment. The receiver includes an adjustable iris including a plurality of rotary blades each driven by a MEMS actuator. The plurality of rotary blades collectively form an adjustable receiving aperture for the returned light beams to pass through. The plurality of rotary blades are configured to rotate in order to vary the adjustable receiving aperture during operation of the optical sensing system. The optical sensing system also includes a detector configured to detect the light beams that pass through the adjustable iris.

A micro-electromechanical systems (MEMS) driving arrangement for an electronic device, the micro-electromechanical systems (MEMS) driving arrangement including a driven wheel; a driving actuation assembly for causing rotation of the driven wheel; an indicator assembly including an indicator; and a force absorbing assembly coupled intermediate the indicator assembly and the driven wheel; whereby a force acting upon the indicator assembly is absorbed by the force absorbing assembly so as to inhibit rotation of the driven wheel relative to the driving actuation assembly.

A display device and a display method thereof, and a display equipment are disclosed. The display device includes a display panel and a light transmittance adjusting layer, the display panel includes a plurality of pixel regions, the light transmittance adjusting layer is stacked with the display panel, and the light transmittance adjusting layer is configured to adjust display brightness of the plurality of pixel regions.

The improved scanning MEMS mirror device disclosed herein comprises a mirror body that is rotatable around a rotation axis with respect to a stationary body, wherein a rotation of the mirror body is flexibly restrained with at least one coupling element that biases the mirror body towards a neutral state. The coupling element comprises at least a bridge section and a first leaf spring section and a second leaf spring section. The first leaf spring section extends in an extension direction from a first end thereof at the bridge section towards a second end thereof that is connected to the mirror body. The second leaf spring section extends in an extension direction from a first end thereof at the bridge section towards a second end thereof where it is connected to the stationary body. The extension direction of the first leaf spring section and the extension direction of the second leaf spring section are at least substantially the same as the second planar direction. The leaf spring sections have a thickness defined in a direction orthogonal to the reference plane that is smaller than their width, defined in said first planar direction. The construction of the improved scanning MEMS mirror device results in an increased eigenfrequency of undesirable eigenmodes.

Angular accelerometers are described, as are systems employing such accelerometers. The angular accelerometers may include a proof mass and rotational acceleration detection beams directed toward the center of the proof mass. The angular accelerometers may include sensing capabilities for angular acceleration about three orthogonal axes. The sensing regions for angular acceleration about one of the three axes may be positioned radially closer to the center of the proof mass than the sensing regions for angular acceleration about the other two axes. The proof mass may be connected to the substrate though one or more anchors.

A microelectromechanical system (MEMS) transducer includes a substrate and a pair of electrodes supported by the substrate. The pair of electrodes are configured as a bias electrode-sense electrode couple. A moveable electrode of the pair of electrodes is configured for vibrational movement in a first direction during excitation of the moveable electrode. The pair of electrodes are spaced apart from one another by a gap in a second direction perpendicular to the first direction. The moveable electrode includes a cantilevered end, the cantilevered end being warped to exhibit a resting deflection along the first direction.

Angular accelerometers are described, as are systems employing such accelerometers. The angular accelerometers may include a proof mass and rotational acceleration detection beams directed toward the center of the proof mass. The angular accelerometers may include sensing capabilities for angular acceleration about three orthogonal axes. The sensing regions for angular acceleration about one of the three axes may be positioned radially closer to the center of the proof mass than the sensing regions for angular acceleration about the other two axes. The proof mass may be connected to the substrate though one or more anchors.

Disclosed is a force transfer device that includes a first body that has a first body frame that defines a first chamber and at least one gear element. The gear element has a central gear element region. A first membrane is affixed to a surface of the first body frame, the membrane covering the chamber and having an annular aperture enclosing a central region of the membrane that is affixed to the central gear element region of the gear element. The disclosed force transfer device can be axle or shaft based. Also disclosed in a micro electrostatic motor that includes a motor body having a first and a second face, the motor body defining a chamber and a rotor having a central region. A membrane is disposed over the first face of the motor body, the membrane supporting a pair of spaced electrodes that are electrically isolated by a gap, the membrane having an annular aperture that defines a central region of the membrane that is coupled to the central region of the rotor. The force transfer device can be driven by the electrostatic motor.