A mirror unit includes a light scanning device and a package. The package has a main body portion provided with a light incident opening that opens on one side in a predetermined direction, a protrusion provided on a top surface of the main body portion, and a flat plate-shaped window member disposed on the top surface on an inward side of the protrusion and covering the light incident opening. An end surface of the protrusion on the one side is positioned more to the one side than the window member. A thickness of the protrusion is smaller than a height of the protrusion from the top surface. When viewed in any direction perpendicular to the predetermined direction, a length of a part covered by the protrusion in the window member is longer than a length of a part exposed from the protrusion in the window member.

The invention relates to a MEMS mirror assembly for detecting a large angular range up to 180°, preferably up to 160°, and to a method for producing a MEMS mirror assembly. The mirror assembly comprises a carrier substrate (1), on which a mirror (2) vibrating about at least one axis is mounted, a transparent cover (4), which is connected in a hermetically sealed manner to the carrier substrate (1) and which comprises an ellipsoidal dome (6) having a substantially round base area, and a compensation optical system (8), which is arranged in a predefined beam path for an incident beam outside the dome (6). The middle of the mirror (2) lies in the centre point of the dome, and the compensation optical system (8) collimates the incident beam in such a way that a divergence or convergence of the beam caused by the boundary surfaces of the dome once said beam has exited from the dome (6) is substantially compensated. The MEMS mirror assemblies are produced by joining a cover wafer and a mirror wafer, which each comprise a plurality of hemispherical domes and mirrors mounted on the carrier substrate. The mirror assemblies are then separated from the joined wafers. The domes of the cover wafer are produced by a glass flow process.

A transmitting device, preferably containing at least two laser diodes and a scanning mirror, which is deflectable about its center (MP) and is arranged in a housing with a transparent cover element. The cover element is formed, at least in a coupling-out region, by a section of a monocentric hemispherical shell (HK) with a center of curvature (K) and is arranged to cover the scanning mirror in such a way that the center of curvature (K) of the hemispherical shell (HK) and the center (MP) of the scanning mirror coincide, and is formed in a coupling-in region by an optical block, comprising a toroidal entrance surface, in the special form of a cylindrical surface, at least one toroidal exit surface and at least two first mirror surfaces arranged between them, for deflecting and pre-collimating the laser beams.

A method for producing a micromechanical device having inclined optical windows, and a corresponding micromechanical device are described. The production method includes: providing a first substrate having a front side and a rear side; forming a plurality of spaced-apart through holes in the first substrate which are arranged along a plurality of spaced-apart rows in the first substrate; forming a respective continuous beveled groove along each of the rows, the grooves defining a seat for the inclined optical windows; and inserting the optical windows into the grooves above the through holes.

The present disclosure concerns an emitter package for a photoacoustic sensor, the emitter package comprising a MEMS infrared radiation source for emitting pulsed infrared radiation in a first wavelength range. The MEMS infrared radiation source may be arranged on a substrate. The emitter package may further comprise a rigid wall structure being arranged on the substrate and laterally surrounding a periphery of the MEMS infrared radiation source. The emitter package may further comprise a lid structure being attached to the rigid wall structure, the lid structure comprising a filter structure for filtering the infrared radiation emitted from the MEMS infrared radiation source and for providing a filtered infrared radiation in a reduced second wavelength range.

A production method for a micromechanical device having inclined optical windows. First and second substrates are provided. A plurality of through-holes is produced in the first and second substrate such that for each through-hole in the first substrate a congruent through-hole is produced in the second substrate, which overlap when the first substrate is placed over the second substrate. A slanted edge region is produced around a respective through-hole in the first and second substrate, the edge region being inclined at a window angle, two slanted edge regions situated on top of each other being congruent in a top view and being inclined at the same window angle. A window foil is provided having a structured window region, which covers the through-hole in a top view of the window foil in each case, the window foil forming an optical window slanted at the window angle above the respective through-hole.

A cover for an infrared detector and a method of fabricating the cover are disclosed. The cover comprises a wafer comprising a material such as silicon that transmits infrared radiation. The wafer has a first surface and a second surface opposite the first surface. An antireflective region is formed in the wafer to enhance transmission of infrared radiation through the cover. The antireflective region comprises a first plurality of antireflective elements such as moth-eyes formed in the first surface. The first plurality of antireflective elements are sized and shaped and arranged relative to one another to form a region of graded refractive index at the first surface so as to reduce the amount of infrared radiation reflected by the cover at the antireflective region. The cover comprises a wall extending from the first surface and surrounding the antireflective region. The wall comprises a plurality of layers of material deposited on the wafer so that, when the cover is bonded to a sensor substrate via the wall, a cavity is formed that encapsulates a sensor region of the sensor substrate. The depth of the cavity may be adjusted by depositing the plurality of layers of material with a combined thickness equivalent to the desired depth of the cavity. A second plurality of antireflective elements may be formed in the second surface to enhance the antireflective properties of the antireflective region.

The present disclosure relates to an optical scanner package comprising a scanner element, a lower substrate having an inner space, and a semi-spherical transmissive window. The semi-spherical transmissive window has different inclinations in an incident position thereof and in an emission position thereof, and interference caused by sub-reflection can thus be reduced. Since the incident angle α and the maximum emission angle β are small, anti-reflection coating design is easy, and light loss can be reduced. There is an advantage in that, even when the optical scanning angle (OSA) γ of a laser is large, the maximum emission angle β is small, and emitted laser light thus has a small change in characteristics. In addition, since there are curvatures on both sides of two axes, there is little restriction regarding the incident direction even in the case of two-axis driving.

An interposer substrate, a MEMS device and a corresponding manufacturing method. The interposer substrate is equipped with a front side and a rear side, a cavity starting from the rear side, which extends up to a first depth, a through-opening and a sunken area situated between the cavity and the through-opening, which is sunken from the rear side up to a second depth in relation to the rear side, the first depth being greater than the second depth.

A MEMS chip package is provided with a removable cover to allow non-destructive testing. The MEMS package has a container (with walls and a bottom) and a cover. The cover has a glass pane, and is secured to the MEMS package with an elastomeric gasket mounted between the walls of the MEMS package and the cover. A number of attachment mechanisms secure the cover to the MEMS package.