A package for integrated circuits includes a base substrate having a mounting face. A first electronic chip has a top face electrically connected to the mounting face and a bottom face mounted to the mounting face by an adhesive layer. A second electronic chip has a bottom face covered with a thermal interface layer and a top face electrically connected to the mounting face. A heat sink includes a first part embedded in the adhesive layer, a second part having a bottom face in contact with the layer of thermal interface material and a top face, and a connection part between the first part and the second part. A coating encapsulates the first and second electronic chips and the heat sink. The top face of the second part of the heat sink exposed from the encapsulating coating.

Semiconductor devices may include a substrate and a backside-biased semiconductor die supported above the substrate. A backside surface of the backside-biased semiconductor die may be spaced from the substrate. The backside surface may be electrically connected to ground by wire bonds extending to the substrate. Methods of making semiconductor devices may involve supporting a backside-biased semiconductor die supported above a substrate, a backside surface of the backside-biased semiconductor die being spaced from the substrate. The backside surface may be electrically connected to ground by wire bonds extending to the substrate. Systems may include a sensor device, a nontransitory memory device, and at least one semiconductor device operatively connected thereto. The at least one semiconductor device may include a substrate and a backside-biased semiconductor die supported above the substrate. A backside surface of the backside-biased semiconductor die may be electrically connected to ground by wire bonds extending to the substrate.

A method of manufacturing a semiconductor package may include providing a substrate having first and second cutting regions respectively provided along first and second side portions opposite to each other and a mounting region between the first and second cutting regions is provided, disposing at least one semiconductor chip on the mounting region, forming a molding member on the substrate, and removing a dummy curl portion and at least portions of dummy runner portions from the molding member. The molding member may include a sealing portion, the dummy curl portion provided outside the second side portion of the substrate, and the plurality of dummy runner portions on the second cutting region to connect the sealing portion and the dummy curl portion. The substrate may include adhesion reducing pads in the second cutting region, which may contact the dummy runner portions respectively.

A semiconductor device includes a substrate; a semiconductor chip located on the substrate; a sealing resin covering the substrate and the semiconductor chip; and a mottled pattern located at an interface between the sealing resin and at least one of the substrate or the semiconductor chip.

A semiconductor package structure includes a semiconductor chip on a package substrate; a lower connection bump on the package substrate; and an interposer substrate on the lower connection bump on the package substrate and an upper surface of the semiconductor chip. The semiconductor package structure includes an upper connection bump on a lower surface of the interposer substrate; and a support structure on a lower surface of the interposer substrate, spaced apart from the upper connection bump to provide support between the package substrate and the interposer substrate. The upper connection bump and the lower connection bump constitute a connection bump structure, and the support structure includes a metal core ball and a ball cover layer surrounding the metal core ball, wherein the ball cover layer is formed to gradually decrease in thickness in a direction from the interposer substrate to the package substrate cross-section.

A semiconductor package may include a base layer; a first semiconductor chip disposed over and spaced apart from the base layer; a second semiconductor chip stack disposed between the base layer and the first semiconductor chip, the second semiconductor chip stack including a plurality of second semiconductor chips that are stacked in a vertical direction; a bridge die stack disposed between the base layer and the first semiconductor chip and disposed to be spaced apart from the second semiconductor chip stack, the bridge die stack including a plurality of bridge dies that are stacked in the vertical direction and electrically connecting the first semiconductor chip and the base layer to supply power; and a vertical interconnector disposed between the base layer and the first semiconductor chip and disposed to be spaced apart from the second semiconductor chip stack and the bridge die stack, the vertical interconnector electrically connecting the first semiconductor chip and the base layer to transmit a signal.

A method for monitoring an online state of a bonding wire of an Insulated Gate Bipolar Translator (IGBT) module comprises the following steps: Step 1, constructing a full bridge inverter circuit and an online measuring circuit and connecting two input ends of the online measuring circuit to a collecting electrode and an emitting electrode of an IGBT power module of the full bridge inverter circuit to realize a connection of the full bridge inverter circuit and the online measuring circuit; Step 2, establishing a three-dimensional data model of a healthy IGBT; Step 3, establishing a three-dimensional data model of the IGBT with a broken bonding wire; Step 4, optimizing a least squares support vector machine by adopting a genetic algorithm; and Step 5, estimating states of the three-dimensional data models obtained in the Step 2 and the Step 3 by utilizing the optimized least squares support vector machine.

A package substrate includes: a core insulation layer having first and second package regions and a boundary region between the first and second package regions; a first upper conductive pattern in the first package region; a second upper conductive pattern in the second package region; a first insulation pattern on the core insulation layer to partially expose the first and second upper conductive patterns, wherein the first insulation pattern includes a first trench at the boundary region, and first reinforcing portions in the first trench; a first lower conductive pattern in the first package region; a second lower conductive pattern in the second package region; and a second insulation pattern on the core insulation layer to partially expose the first and second lower conductive patterns, wherein the second insulation pattern includes a second trench at the boundary region, and second reinforcing portions in the second trench.

A package substrate includes: a core insulation layer having first and second package regions and a boundary region between the first and second package regions; a first upper conductive pattern in the first package region; a second upper conductive pattern in the second package region; a first insulation pattern on the core insulation layer to partially expose the first and second upper conductive patterns, wherein the first insulation pattern includes a first trench at the boundary region, and first reinforcing portions in the first trench; a first lower conductive pattern in the first package region; a second lower conductive pattern in the second package region; and a second insulation pattern on the core insulation layer to partially expose the first and second lower conductive patterns, wherein the second insulation pattern includes a second trench at the boundary region, and second reinforcing portions in the second trench.

A package structure includes a first circuit board, a second circuit board, at least one electronic component, at least one conductive lead, and a molding compound. The first circuit board includes a first circuit layer and a second circuit layer. The second circuit board includes a third circuit layer and a fourth circuit layer. The electronic component is disposed between the first circuit board and the second circuit board. The conductive lead contacts at least one of the second circuit layer and the third circuit layer. The conductive lead has a vertical height, and the vertical height is greater than a vertical distance between the second circuit layer and the third circuit layer. The molding compound covers the first circuit board, the second circuit board, the electronic component, and the conductive lead. The molding compound exposes the first circuit layer and the fourth circuit layer, and the conductive lead extends outside the molding compound.