Examples include a device comprising integrated circuit dies molded into a molded panel. The molded panel has three-dimensional features formed therein, where the three-dimensional features are associated with the integrated circuit dies. To form the three-dimensional features, a feature formation material is deposited, the molded panel is formed, and the feature formation material is removed.

The application relates to structures, e.g. substrates for supporting semiconductor die. The substrate defines a frame which lateral surrounds one or more die and is provided in contact with at least one side surface of the die, wherein the frame defines upper and lower surfaces of the substrate.

Certain embodiments of the present disclosure relate to a sensor assembly including a substrate having an outer region, an inner region, and a middle region between the outer region and the inner region. The substrate further includes electrical contact pads on at least the inner region. The sensor assembly further includes a housing coupled to the substrate at the middle region or the outer region to provide a hermetic seal. The sensor assembly further includes a sensor die bonded to the substrate at the inner region. A metal bond bonds electrodes of the sensor die to the electrical contact pads. The metal bond includes platinum, and/or one or more metals selected from tin, indium, copper, aluminum, and/or nickel.

Certain embodiments of the present disclosure relate to a sensor assembly including a housing having a first channel configured to flow a gas in a first direction and a second channel configured to flow the gas in a second direction. The housing is configured to couple to a gas flow assembly. A substrate is disposed within the housing. The substrate has an outer region, an inner region within the first channel, and a middle region between the outer region and the inner region. The substrate further includes electrical contact pads on at least the inner region. A sensor die is coupled to the inner region of the substrate, having an electrical connection to the electrical contact pads. The sensor die is disposed within a gas flow path of the first channel.

Certain embodiments of the present disclosure relate to a sensor assembly including a substrate, a housing, and a sensor die. In certain embodiments, the substrate includes an outer region, an inner region, and a middle region between the outer region and the inner region. In certain embodiments, the substrate includes electrical contact pads on at least the inner region. In certain embodiments, the housing is coupled to the substrate at the middle region or the outer region to provide a hermetic seal. In certain embodiments, the sensor die is coupled to the substrate at the inner region via the electrical contact pads. The sensor die is aligned to the substrate via aligning features that align the sensor die relative to the substrate in at least one of a first plane or a second plane.

An electronic device with stud bumps is disclosed. In an embodiment an electronic device includes a carrier board having an upper surface and an electronic chip mounted on the upper surface, the electronic chip having a mounting side facing the upper surface of the carrier board, a top side facing away from the upper surface, and sidewalls connecting the mounting side to the top side, wherein the electronic chip has equal to or less than 5 stud bumps per square millimeter of a base area of the mounting side, wherein the carrier board has at least one recess in the upper surface, and wherein at least one of the stud bumps reaches into the recess.

A MEMS package includes a MEMS chip, a package substrate which the MEMS chip is adhered and a thin-film filter which is adhered to the package substrate or the MEMS chip. The thin-film filter includes a thin-film part having a film surface and a rear film surface arranged a rear side of the film surface, and a plurality of through holes being formed to penetrate the thin-film part from the film surface to the rear film surface. The through holes are formed in an adhesive region of the thin-film part. The adhesive region is adhered to the package substrate or the MEMS chip.

A MEMS microphone and a manufacturing method thereof are provided. The MEMS microphone comprises a MEMS microphone chip and a housing with an acoustic port. The MEMS microphone chip is mounted in the housing, and a mesh plug is mounted in the acoustic port and made from a mesh material which has a mesh structure that is suitable for passage of sound.

A method for manufacturing a MEMS sensor. The method includes: providing a substrate, applying a support layer onto a back side of the substrate, forming at least one cavity in the substrate in such a way that an access to the back side from the front side is formed, introducing a MEMS structure into the at least one cavity, and fixing the MEMS structure on the support layer.

A micromechanical sensor device and manufacturing method. The micromechanical sensor device is provided with a cap substrate, which has a first front side and a first back side, and which has a through-opening as a media entry region; and with a sensor substrate, which has a second front side and a second back side, and which has, on the second front side, a sensor region that is embedded in an island-like region suspended on the remaining sensor substrate. The island-like region is mechanically decoupled from the remaining sensor substrate by a lateral stress-relief trench and by a cavity situated in the sensor substrate, underneath the island-like region. The first back side is bonded to the second front side so that the through opening is situated above the sensor region. The sensor region is covered by a gel, which fills the through-opening and the stress-relief trench at least partially.