A semiconductor device package includes a carrier; a sensor element disposed on or within the carrier; a cover disposed above the carrier and comprising a top surface, a bottom surface and an inner sidewall, the inner sidewall defining a penetrating hole extending from the top surface to the bottom surface; and a light transmissive element covering the penetrating hole, wherein the sensor element senses or detects light passing through the light transmissive element.

Lighting module for a projector of a motor vehicle, the lighting module including a light source and a matrix of micromirrors, characterized in that it includes a mask disposed between the light source and the matrix of micromirrors, the mask including an opening allowing light rays coming from the light source to pass and oriented towards the matrix of micromirrors, and the mask including an opaque part blocking light rays coming from the light source and not oriented toward the matrix of micromirrors.

A hermetic capsule including a semiconductor/metal base with sensitive semiconductor/polymer electrical and optical components formed thereon and a semiconductor/metal lid. The semiconductor/metal lid sealed to the semiconductor/metal base by metallization so as to form a chamber including all of the sensitive semiconductor/polymer electrical and optical components and hermetically sealing the chamber and all sensitive components from the ambient. External access to the sensitive semiconductor/polymer electrical and optical components is provided through a metallization.

A method includes, before attaching a window assembly to a semiconductor wafer, the semiconductor wafer including a plurality of integrated circuits and each integrated circuit including an electrical connection pad, adhering the window assembly to a carrier fixture. The method further includes, before attaching the window assembly to the semiconductor wafer, removing portions of the window assembly to create removal areas. The method then includes attaching the window assembly to the semiconductor wafer such that the electrical connection pad of each of the plurality of integrated circuits is within a removal area and removing the carrier fixture leaving the window assembly adhered to the semiconductor wafer with the electrical connection pad exposed of each of the plurality of integrated circuits.

A method for manufacturing a protective wafer including a frame wafer and an optical window, and to a method for manufacturing a micromechanical device including such a protective wafer having an inclined optical window. Also described are a protective wafer including a frame wafer and an optical window, and a micromechanical device including a MEMS wafer and such a protective wafer, which delimit a cavity, the protective wafer including an inclined optical window.

A microelectromechanical systems (MEMS) package assembly and a method of manufacturing the same is provided. The MEMS package assembly includes a substrate, a housing coupled to the substrate to form a cavity, wherein the housing includes a transparent plate disposed above and parallel to the substrate and is configured to permit a transmission of light therethrough, and a MEMS chip disposed within the cavity and including a first main surface proximal to the transparent plate and a second main surface opposite to the first main surface and coupled to the substrate. The MEMS chip is oriented such that the first main surface is tilted at a tilt angle with respect to the transparent plate.

A hermetic capsule including a semiconductor/metal base with sensitive semiconductor/polymer electrical and optical components formed thereon and a semiconductor/metal lid. The semiconductor/metal lid sealed to the semiconductor/metal base by metallization so as to form a chamber including all of the sensitive semiconductor/polymer electrical and optical components and hermetically sealing the chamber and all sensitive components from the ambient. External access to the sensitive semiconductor/polymer electrical and optical components is provided through a metallization.

Provided is a position detection method including splitting detection light into first and second light, the first light being incident on a returning optical path, a portion of the first light being transmitted through a beam splitter and a remaining portion of the first light being reflected by the beam splitter to reach the beam splitter through a movable mirror every time the first light reaches the beam splitter through the movable mirror, combining the first light transmitted though the beam splitter and the second light to generate multiple interference light, extracting a second interference light signal having a wavelength of 1/p (p is a natural number) of a wavelength of detection light from a first interference light signal of the multiple interference light, and calculating a position of the movable portion in a predetermined direction based on the second interference light signal.

A semiconductor device package includes: (1) a carrier; (2) a sensor element disposed on or within the carrier; and (3) a cover including a top surface, a bottom surface and an inner sidewall, the inner sidewall defining a penetrating hole extending from the top surface to the bottom surface, and the penetrating hole exposing the sensor element. The semiconductor device package is characterized such that (i) the inner sidewall is divided into an upper portion and a lower portion, the upper portion is substantially perpendicular to the top surface, and the lower portion is tilted; or (ii) the entire inner sidewall is tilted. The lower portion of the inner sidewall or the entire inner sidewall is tilted at an angle of between about 10 to less than about 90, relative to the top surface.

A die-wrapped packaged device includes at least one flexible substrate having a top side and a bottom side that has lead terminals, where the top side has outer positioned die bonding features coupled by traces to through-vias that couple through a thickness of the flexible substrate to the lead terminals. At least one die includes a substrate having a back side and a topside semiconductor surface including circuitry thereon having nodes coupled to bond pads. One of the sides of the die is mounted on the top side of the flexible circuit, and the flexible substrate has a sufficient length relative to the die so that the flexible substrate wraps to extend over at least two sidewalls of the die onto the top side of the flexible substrate so that the die bonding features contact the bond pads.