Disclosed are semiconductor packages and/or methods of fabricating the same. The semiconductor package comprises a package substrate, a first semiconductor chip mounted on the package substrate, a second semiconductor chip mounted on a top surface of the first semiconductor chip, and a first under-fill layer that fills a space between the package substrate and the first semiconductor chip. The package substrate includes a cavity in the package substrate, and a first vent hole that extends from a top surface of the package substrate and is in fluid communication with the cavity. The first under-fill layer extends along the first vent hole to fill the cavity.

The present disclosure relates to a package substrate comprising: a substrate having opposing first surface and second surface; at least one vent hole extending through the first surface and the second surface of the substrate, the vent hole comprising at least a long-strip hole.

In examples, an electronic device comprises a printed circuit board (PCB), an orifice extending through the PCB, and a semiconductor die suspended above the orifice by aluminum bond wires. The semiconductor die is vertically aligned with the orifice and the bond wires coupled to the PCB.

Improving motion sensor robustness utilizing a room-temperature-volcanizing (RTV) material via a solder resist dam is presented herein. A sensor package comprises: a first semiconductor die; a second semiconductor die that is attached to the first semiconductor die to form a monolithic die; and a substrate comprising a top portion and a bottom portion, in which the top portion comprises a plurality of solder resist dams, the monolithic die is attached to the top portion of the substrate via the RTV material being disposed in a defined area of the top portion of the substrate, and the bottom portion of the substrate comprises electrical terminals that facilitate attachment and electrical coupling of signals of the sensor package to a printed circuit board.

Provide is a highly reliable semiconductor device in which stress generated in a semiconductor chip is reduced and an increase in thermal resistance is suppressed. The semiconductor device includes: a semiconductor chip including a first main electrode on one surface thereof and a second main electrode and a gate electrode on the other surface thereof; a first electrode connected to the one surface of the semiconductor chip via a first bonding material; and a second electrode connected to the other surface of the semiconductor chip via a second bonding material. The first electrode is a plate-shaped electrode and has a groove in a region overlapping with the semiconductor chip. The groove penetrates in a thickness direction of the first electrode and reaches an end portion of the first electrode when viewed in a plan view.

Described examples include a sensor device having at least one conductive elongated first pillar positioned on a central pad of a first conductor layer over a semiconductor substrate, the first pillar extending in a first direction normal to a plane of a surface of the first conductor layer. Conductive elongated second pillars are positioned in normal orientation on a second conductor layer over the semiconductor substrate, the conductive elongated second pillars at locations coincident to via openings in the first conductor layer. The second conductor layer is parallel to and spaced from the first conductor layer by at least an insulator layer, the conductive elongated second pillars extending in the first direction through a respective one of the via openings. The at least one conductive elongated first pillar is spaced from surrounding conductive elongated second pillars by gaps.

In an embodiment A package includes a casing having an opening and enclosing a cavity, a die accommodated in the cavity and a membrane attached to the casing, the membrane being air-permeable, covering and sealing the opening, wherein the membrane is configured to allow only a lateral gas flow, and wherein a blocking member is configured to block a vertical gas flow through the membrane into the cavity, the blocking member tightly covering a surface of the membrane at least in an area comprising the opening.

Method and arrangement for assembling one or more microchips (415; 615; 715; 815; 915; 1015) into one or more holes (422; 722), respectively, in a substrate surface (421; 721) of a separate receiving substrate (420; 720; 820; 1020). The holes (422; 722) of the substrate is for microchip insertion out-of-plane in relation to said substrate surface. Each of said microchips is provided with a ferromagnetic layer (213; 613) of ferromagnetic material. The microchips are placed (503) on said substrate surface (421; 721) and it is applied and moved (504) one or more magnetic fields affecting said ferromagnetic layer (213; 613) of each microchip such that the microchips thereby become out-of-plane oriented in relation to said substrate surface (421; 721) and move over the substrate surface (421; 721) until assembled into said holes (422; 722).

Semiconductor assemblies including thermal management configurations for reducing heat transfer between overlapping devices and associated systems and methods are disclosed herein. A semiconductor assembly may comprise a first device and a second device with a thermally conductive layer, a thermal-insulator interposer, or a combination thereof disposed between the first and second devices. The thermally conductive layer and/or the thermal-insulator interposer may be configured to reduce heat transfer between the first and second devices.

Disclosed embodiments include die-edge level passive devices for integrated-circuit device packages that provide a low-loss path to active and passive devices, by minimizing inductive loops.