A substrate includes a heat slug that is disposed in a cavity in the substrate. An engineered filler material is disposed in the cavity over, under, and/or around the heat slug. The engineered filler material is a thermally conductive particle material having a composition that can be adjusted based on a desired coefficient of thermal expansion. An electronic device can be attached to the substrate over the heat slug and the engineered filler material. The heat slug and the engineered filler material provide, or are part of, a heat transfer dissipation path for the electronic device.

A package device and a manufacturing method thereof are provided. The package device includes a substrate, a plurality of conductive pillars, a redistribution layer, at least one bridge chip, at least two active chips, an encapsulant, and an underfill layer. The conductive pillars are disposed on the substrate side by side, the redistribution layer is disposed on the conductive pillars, and the bridge chip is disposed between the substrate and the redistribution layer. The active chips are disposed on the redistribution layer, the bridge chip is coupled between the active chips, and the encapsulant is disposed on the redistribution layer and surrounds the active chips. The underfill layer is disposed between adjacent two of the conductive pillars and between one of the conductive pillars and the bridge chip.

A semiconductor package system includes a substrate, a first and a second semiconductor package, a first thermal conductive layer, a first passive device, and a heat radiation structure. The first and second semiconductor package and first passive device may be mounted on a top surface of the substrate. The first semiconductor package may include a first semiconductor chip that includes a plurality of logic circuits. The first thermal conductive layer may be on the first semiconductor package. The heat radiation structure may be on the first thermal conductive layer, the second semiconductor package, and the first passive device. The heat radiation structure may include a first bottom surface physically contacting the first thermal conductive layer, and a second bottom surface at a higher level than that of the first bottom surface. The second bottom surface may be on the second semiconductor package and/or the first passive device.

A semiconductor package includes a base substrate including a wiring pattern, an interposer substrate including lower and upper redistribution patterns, a semiconductor structure, a heat dissipation structure, a plurality of external connection bumps disposed on a lower surface of the base substrate, a plurality of lower connection bumps disposed between the base substrate and the interposer substrate, and a plurality of upper connection bumps disposed between the interposer substrate and the semiconductor structure.

Each of a plurality of terminals has a first portion and a second portion being a connection target for a semiconductor element. A manufacturing method of a housing includes a first step arranging, for a lower mold provided with a plurality of holes each of which is a target into which the first portion is inserted, a nest having a third portion covering at least one of the holes, a second step arranging, for the lower mold with the nest being arranged therein, the plurality of terminals by inserting the first portion into the hole not covered by the third portion, a third step arranging an upper mold on the lower mold with the nest and the plurality of terminals being arranged therein, and a fourth step, which is executed after the third step, obtaining the housing by performing resin molding using the lower mold and the upper mold.

An integrated device package is disclosed. The integrated device package can include a carrier that has an opening extending at least partially through a thickness of the carrier. The integrated device package can include a microelectronicmechanical systems die that is at least partially disposed in the opening and mechanically and electrically coupled to the carrier. The integrated device package can include a lid that is coupled to the carrier. The lid and the microelectronicmechanical systems die are spaced by a gap defining a back volume.

An integrated device package is disclosed. The integrated device package can include a printed circuit board and a microelectronicmechanical systems die that is at least partially disposed within the printed circuit board and electrically coupled to the printed circuit board. The integrated device package can include a filler material that is at least partially disposed between the microelectronicmechanical systems die and the printed circuit board. The integrated device package can include a lid that is coupled to the printed circuit board. The lid and the microelectronicmechanical systems die are spaced by a gap defining a back volume.

An integrated device package is disclosed. The integrated device package can include a carrier that has a multilayer structure having a first layer and a second layer. The first layer at least partially defines a lower side of the carrier. An electrical resistance of the second layer is greater than an electrical resistance of the first layer. The integrated device package can include a microelectronicmechanical systems die that is mounted on an upper side of the carrier opposite the lower side. The integrated device package can include a lid that is coupled to the carrier. The lid and the microelectronicmechanical systems die are spaced by a gap defining a back volume.

Methods and systems for a semiconductor device package with a die to interposer wafer first bond are disclosed and may include bonding a plurality of semiconductor die comprising electronic devices to an interposer wafer, and applying an underfill material between the die and the interposer wafer. Methods and systems for a semiconductor device package with a die-to-packing substrate first bond are disclosed and may include bonding a first semiconductor die to a packaging substrate, applying an underfill material between the first semiconductor die and the packaging substrate, and bonding one or more additional die to the first semiconductor die. Methods and systems for a semiconductor device package with a die-to-die first bond are disclosed and may include bonding one or more semiconductor die comprising electronic devices to an interposer die.

A device for forming a housing for a power semiconductor module arrangement includes a mold. The mold includes a first cavity including a plurality of first openings and a second opening, the second opening being coupled to a runner system, wherein the runner system is configured to inject a mold material into the first cavity through the second opening. The device further includes a plurality of sleeves or hollow bushings, wherein a first end of each of the plurality of sleeves or hollow bushings is arranged in one of the first openings, and wherein a second end of each of the plurality of sleeves or hollow bushings extends to the outside of the mold, a heating element configured to heat the mold, and a cooling element configured to cool the plurality of sleeves or hollow bushings.