An optical scanning system includes one or more Micro-Electro-Mechanical System (MEMS) Micro-Mirror Arrays (MMAs) used to scan a field-of-view (FOV) over a field-of-regard (FOR). The MEMS MMA is configured such that optical radiation from each point in the FOV does not land on or originate from out-of-phase mirror segments and a diffraction limited resolution of the optical system is limited by the size of the entrance pupil and not by the size of individual mirrors.

Disclosed are an electrostatically driven comb structure of an MEMS (Micro Electro Mechanical System), a micro-mirror using the same, and a preparation method therefor. The surface of a comb of the electrostatically driven comb structure of the MEMS has an insulating layer, and the insulating layers on the surfaces of adjacent combs are the same type of insulating layers or different insulating layers; the micro-mirror with the electrostatically driven comb structure of the MEMS successively includes a substrate, an isolating layer and a device layer from bottom to top; the method for manufacturing the micro-mirror prepares the insulating layers by high temperature oxidization, plasma enhanced chemical vapor deposition, low pressure chemical vapor deposition, atmospheric pressure chemical vapor deposition, physical deposition, atomic layer deposition or stepwise heterogeneous deposition; same or different insulating layers are obtained on the surfaces of the driving comb and the ground comb; when the driving comb and the ground comb adsorb each other, the insulating layers on the surfaces of the two contact without forming a short circuit, so that a good insulating effect is achieved. The electrostatically driven MEMS micro-mirror capable of preventing adsorptive damage provided by the present invention features compact structure and simple process.

A thermal metamaterial device comprises at least one MEMS thermal switch, including a substrate layer including a first material having a first thermal conductivity, and a thermal bus over a first portion of the substrate layer. The thermal bus includes a second material having a second thermal conductivity higher than the first thermal conductivity. An insulator layer is over a second portion of the substrate layer and includes a third material that is different from the first and second materials. A thermal pad is supported by a first portion of the insulator layer, the thermal pad including the second material and having an overhang portion located over a portion of the thermal bus. When a voltage is applied to the thermal pad, an electrostatic interaction occurs to cause a deflection of the overhang portion toward the thermal bus, thereby providing thermal conductivity between the thermal pad and the thermal bus.

A micromechanical device capable of providing out-of-plane motion and force generation in response to an in-plane strain applied to the device is provided. Embodiments of the present invention comprise one or more islands that are operatively coupled with one or more hinges. The hinges are operative for inducing rotation of the islands when a lateral strain is applied to the structure. In some embodiments, the hinges are also electrically conductive such that they enable electrical communication between the one or more islands and devices external to the structure. Some embodiments of the present invention are particularly well suited for use in biological applications. Some devices in accordance with the present invention are fabricated using conventional planar processes, such as flex-circuit fabrication techniques.

This disclosure relates to devices for two-dimensional deflection of a laser beam, which include a substrate having a substrate opening, a spring membrane provided on the substrate having spring arms extending over the substrate opening, and a middle section arranged in the substrate opening and supported by the spring arms. The middle section is mounted so it is two-dimensionally tiltable and is axially displaceable in both directions of the spring membrane middle axis. The device includes a mirror fastened on the middle section of the spring membrane and a magnetic or electrostatic drive for tilting the mirror against the restoring force of the spring arms. One or more of a component coupled to the mirror and an end stop unit are configured to limit axial deflection of the middle section to a distance that is within a range of axial deflection of the middle section during the drive-related tilting of the mirror.

A micromechanical constituent includes an actuator designed to impart to a displaceable element a first displacement motion around a first rotation axis and a second displacement motion around a second rotation axis oriented tiltedly with respect to the first rotation axis, the actuator including a permanent magnet on a first spring element and a one second permanent magnet on a second spring element, where the first permanent magnet is excitable to perform a first translational motion tiltedly with respect to the first rotation axis and tiltedly with respect to the second rotation axis, and the second permanent magnet is excitable to perform a second translational motion directed oppositely to the first translational motion, causing the second displacement motion of the displaceable element around the second rotation axis.

The invention relates to a micro-electromechanical device used as a force sensor, comprising a mobile mass connected to at least one securing zone by means of springs or deformable elements, and means for detecting the movement of the mobile mass, the mobile mass having an outer frame and an inner body, the outer frame and the inner body being connected by at least two flexible portions forming integral decoupling springs on two separate sides of the outer frame.

An optical reflective device includes: a movable part configured to be rotated about a rotation axis; a reflection surface located on the movable part; a frame part connected to the movable part at two positions symmetrical about the rotation axis; torsion part extending along the rotation axis; a connection part connecting one end of the torsion part to the frame part; a drive part connected to another end of the torsion part and configured to rotate the torsion part about the rotation axis; and a fixation part supporting the drive part, the connection part has higher rigidity than the torsion part, at least one pair of joint surfaces are formed at a boundary between the torsion part and the connection part, and the one pair of joint surfaces are symmetrical about the rotation axis and each have an acute angle on the torsion part side with the rotation axis.

A movable device includes a movable portion including a reflecting surface; a pair of drive beams to support the movable portion rotatably around a predetermined rotation axis with the movable portion disposed between the pair of drive beams; and a support portion configured to support the pair of drive beams. The support portion has a light passing portion on each of both sides of the movable portion in a direction intersecting with the rotation axis in a plane along the reflecting surface in a state in which the movable portion is not rotated, the light passing portion allowing light reflected by the reflecting surface to pass through the light passing portion.

Provided is an acceleration sensor, including a base; a first anchor point fixed to a middle part of the base; an inner side mass unit surrounding an outer side of the first anchor point, an outer side mass unit surrounding an outer side of the inner side mass unit, a first seesaw unit and a second seesaw unit arranged opposite to each other to define an annular structure surrounding an outer side of the outer side mass unit, a first acceleration detection unit and a second acceleration detection unit. Part of the first acceleration detection unit is arranged at the annular structure to detect acceleration in an out-of-plane Z-axis direction, the second acceleration detection unit is arranged at the outer side mass unit to detect acceleration in an in-plane X-axis direction and in an in-plane Y-axis direction. A design thereof is reasonable and the sensitivity is high.