A microelectromechanical motion sensor device is described, provided with: a base substrate having a front surface with extension in a horizontal plane; and a sensing structure arranged above the base substrate, for sensing components of a motion quantity along respective sensing axes. The sensing structure is provided with: a housing element integrally coupled above the front surface of the base substrate and internally defining a cavity; a single mobile mass arranged inside the cavity; an elastic supporting arrangement arranged above the mobile mass, with main extension in a plane overlying the mobile mass to elastically support the mobile mass inside the cavity, so that it is suspended above the front surface of the base substrate and performs, due to inertial effect, a respective sensing movement in response to each of the components of the motion quantity; and a sensing electrode arrangement, capacitively coupled to the mobile mass for sensing the components of the motion quantity.

A micromirror device includes a mirror portion, a pair of first support portions, a pair of movable frames, a pair of second support portions, a fixed frame, a pair of first connecting portions, and a pair of second connecting portions. The movable frame is line-symmetrical with respect to the first axis and has a reinforcing structure that is not in contact with the boundary portion between the movable frame and the first support portion, and the first connecting portion and the second connecting portion each have a line-symmetrical shape with respect to the first axis and support the first actuator and the second actuator to be swingable around the first axis.

A steerable laser transmitter pairs a MEMS MMA with an optical amplifier to provide a high-power steered laser beam over a wide FOR. A single MEMS MMA may be positioned downstream of the optical amplifier. In a two-stage architecture, a MEMS MMA provides continuous fine steer upstream of the optical amplifier and a beam steerer, another MEMS MMA or a QWP and stack of switchable PGs, provides discrete coarse steering downstream. In the two-stage architecture, the upstream MEMS MMA is configured to limit its steering range to the acceptance angle of the optical amplifier, at most 22. The MEMS MMA may include piston capability to shape the wavefront of the beam.

A microelectromechanical accelerometer is provided that includes one or more proof masses. The accelerometer also includes four sets of stator combs that form a set of four measurement capacitors together with rotor combs. Some rotor combs have a positive offset in a direction in the device plane in relation to stator, while others have a negative offset. Some rotor combs have a negative offset in a direction perpendicular to the device plane in relation to stator combs. Moreover, some stator combs have a negative offset in the direction perpendicular to the device plane in relation to rotor combs.

A microelectromechanical-mirror device has a fixed structure defining an external frame delimiting a cavity, an internal frame arranged above the cavity and defining a window, and a tiltable structure with a reflective surface and arranged in the window. Elastically coupled to the internal frame by first and second coupling elastic elements. An actuation structure is coupled to the internal frame to cause the rotation of the tiltable structure around first and second axes. The actuation structure has a first pair of driving arms, elastically coupled to the internal frame and carrying piezoelectric material regions to cause rotation of the tiltable structure around the first axis, and a further pair of driving arms carrying piezoelectric material regions to cause rotation of the tiltable structure around the second axis and interposed between the fixed structure and the internal frame, to which they are elastically coupled by first and second suspension elastic elements.

A mirror device manufacturing method includes a forming step of forming a structure by forming a base portion, a movable portion, and a coupling portion coupling the base portion and the movable portion to each other such that the movable portion is able to swing with respect to the base portion through processing of a wafer, and forming a mirror layer in the movable portion; and a collecting step of performing collection of foreign substances from the structure using a collection member after the forming step. A mirror unit manufacturing method includes a sealing step of sealing the mirror device after the collecting step.

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 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.

A microelectromechanical system (MEMS) device includes: a hinge layer; a second layer; and an elongated via coupled between the hinge layer and the second layer.

A microelectromechanical device has a first tiltable mirror structure extending in a horizontal plane defined by first and second horizontal axes and includes a fixed structure defining a frame delimiting a cavity, a tiltable element carrying a reflecting region, elastically suspended above the cavity having first and second median axes of symmetry, elastically coupled to the frame by first and second coupling structures on opposite sides of the second horizontal axis. The first tiltable mirror structure has a driving structure coupled to the tiltable element to cause rotation around the first horizontal axis. The first tiltable mirror structure is asymmetrical with respect to the second horizontal axis and has, along the first horizontal axis, a first extension on a first side of the second horizontal axis, and a second extension greater than the first extension, on a second side of the second horizontal axis opposite to the first side.