A leadframe includes a die pad and a set of electrically conductive leads. A semiconductor die, having a front surface and a back surface opposed to the front surface, is arranged on the die pad with the front surface facing away from the die pad. The semiconductor die is electrically coupled to the electrically conductive leads. A package molding material is molded over the semiconductor die arranged on the die pad. A stress absorbing material contained within a cavity delimited by a peripheral wall on the front surface of the semiconductor die is positioned intermediate at least one selected portion of the front surface of the semiconductor die and the package molding material.

A semiconductor chip package includes a substrate having a top surface and a bottom surface, and a semiconductor device mounted on the top surface of the substrate. A gap is provided between the semiconductor device and the top surface of the substrate. A multi-layer laminate epoxy sheet is disposed on the top surface of the substrate and around a perimeter of the semiconductor device.

A resin molding apparatus including a release film feeder configured to feed a release film is provided. The release film feeder including a feeding roller around which the release film is wound, a gripper configured to grip an end portion of the release film fed from the feeding roller, a support table configured to support the release film fed by a horizontal movement of the gripper in an X direction, the support table configured to horizontally move at least one of in the X direction or in a Y direction perpendicular to the X direction, the X and Y directions defining a surface parallel to a surface of the support table, and a position detecting sensor on the support table and configured to detect position information of the release film may be provided.

A process for conformally coating passive surface mount components soldered to a printed circuit substrate of a lidless flip-chip ball grid array package includes affixing a stiffener ring to the substrate before forming a conformal coating on the passive surface mount components. The stiffener ring is affixed to the substrate so that the plurality of passive surface mount components and the integrated circuit die are contained within an opening formed by the stiffener ring. After affixing the stiffener ring to the substrate, the conformal coating is formed on the passive surface mount components. The conformal coating extends over each of the passive surface mount components, around a periphery of each of the passive surface mount components, and under each of the passive surface mount components. A product made according to the process is also disclosed.

Provided is an electronic device including a substrate, a first metal layer, an electronic component, a cover layer, and an adhesive layer. The first metal layer is formed on the substrate. The electronic component is disposed on the substrate and electrically connected to the first metal layer. The adhesive layer is adhered to the substrate and the cover layer.

Provided is an electronic device including a substrate, a first metal layer, an electronic component, a cover layer, and an adhesive layer. The first metal layer is formed on the substrate. The electronic component is disposed on the substrate and electrically connected to the first metal layer. The adhesive layer is adhered to the substrate and the cover layer.

It is described a interconnect array device (e.g., Ball Grid Array (BGA) device) comprising (a) a substrate having a substrate body and a main surface; (b) an array of solder connection elements formed at the main surface; and (c) a support structure formed at the main surface. The support structure is configured for maintaining, during a soldering process, a predefined spacing between the main surface of the substrate and a further main surface of a component carrier onto which the Ball Grid Array is mounted. The support structure comprises at least one support element. Further described is an electronic package with such a Ball Grid Array device and a method for manufacturing an electronic assembly comprising such an electronic package mounted on a component carrier.

It is described a interconnect array device (e.g., Ball Grid Array (BGA) device) comprising (a) a substrate having a substrate body and a main surface; (b) an array of solder connection elements formed at the main surface; and (c) a support structure formed at the main surface. The support structure is configured for maintaining, during a soldering process, a predefined spacing between the main surface of the substrate and a further main surface of a component carrier onto which the Ball Grid Array is mounted. The support structure comprises at least one support element. Further described is an electronic package with such a Ball Grid Array device and a method for manufacturing an electronic assembly comprising such an electronic package mounted on a component carrier.

A semiconductor device package and a method for packaging the same are provided. A semiconductor device package includes a carrier, an electronic component, a buffer layer, a reinforced structure, and an encapsulant. The electronic component is disposed over the carrier and has an active area. The buffer layer is disposed on the active area of the electronic component. The reinforced structure is disposed on the buffer layer. The encapsulant encapsulates the carrier, the electronic component and the reinforced structure.

A semiconductor package includes a redistribution substrate including a first redistribution layer; a semiconductor chip having a connection pad connected to the first redistribution layer; a vertical connection conductor electrically connected to the connection pad by the first redistribution layer; a core member having a first through-hole accommodating the semiconductor chip and a second through-hole accommodating the vertical connection conductor; an encapsulant filling the first and second through-holes; and a redistribution member including a second redistribution layer. The vertical connection conductor and the core member include a same material. A width of a lower surface of the vertical connection conductor is wider than that of an upper surface thereof, a width of a lower end of the first through-hole is narrower than that of an upper end thereof, and a width of a lower end of the second through-hole is narrower than that of an upper end thereof.