A busbar assembly according to the present invention includes a first busbar formed by a conductive metal flat plate; a second busbar formed by a conductive metal flat plate, the second busbar disposed in the same plane as the first busbar with a gap being provided between opposing side surfaces of the first and second busbars; and an insulating resin layer filled in the gap so as to mechanically connect the opposing side surfaces of the first and second busbars. Preferably, the opposing side surface of at least one of the first and second busbars is an inclined surface that is closer to the opposing side surface of the other of the first and second busbars from one side toward the other side in the thickness direction.

A package and a corresponding method are described. The method includes: providing a processed first wafer having front and back sides and including power semiconductor dies implemented within the wafer by processing its front side, each die having a first load terminal at the front side and a second load terminal at the back side; providing an unprocessed second wafer made of an electrically insulating material and having first and second opposing sides; forming a plurality of recesses within the second wafer; filling the plurality of recesses with a conductive material; forming a stack by attaching, prior or subsequent to filling the recesses, the second wafer to the front side of the first wafer, the conductive material electrically contacting the first load terminals of the power semiconductor dies; and ensuring that the conductive material provides an electrical connection between the first side and the second side of the second wafer.

A lead frame includes a die pad having a pad top surface and a pad bottom surface opposite to the top pad surface, a plurality of leads, each having a top lead surface and a bottom lead surface opposite to the top lead surface and disposed around the die pad, and a first molding compound disposed between the die pad and each of the leads. The first molding compound exposes the top pad surface of the die pad by covering a portion of the periphery of the top pad surface of the die pad. A method for manufacturing the lead frame is also disclosed.

A semiconductor device comprises at least one semiconductor die electrically coupled to a set of electrically conductive leads, and package molding material molded over the at least one semiconductor die and the electrically conductive leads. At least a portion of the electrically conductive leads is exposed at a rear surface of the package molding material to provide electrically conductive pads. The electrically conductive pads comprise enlarged end portions extending at least partially over the package molding material and configured for coupling to a printed circuit board.

In described examples of an isolation device, an isolation die that has a set of bond pads is mounted on a first lead frame that has a set of leads. A portion of the bond pads are coupled to respective leads. A first mold material encapsulates the isolation device and the first lead frame forming a first package. The first package is mounted on a second lead frame that has a set of leads. A portion of the first lead frame leads is coupled to respective ones of the second lead frame leads. A second mold material encapsulates the first package and the second lead frame.

In some examples, a semiconductor package comprises a lead frame. The lead frame includes a first row of leads; a first pad coupled to the first row of leads; a second row of leads; and a second pad coupled to the second row of leads, the first and second pads separated by a gap. The semiconductor package includes a heat-generating device coupled to the first and second pads and exposed to an exterior of the semiconductor package.

In general aspect, a semiconductor device package can include a substrate and a semiconductor die disposed on and coupled with the substrate. The semiconductor device package can further include a leadframe having an indentation defined therein, at least a portion of the indentation being disposed on and coupled with the semiconductor die via a conductive adhesive.

A semiconductor device comprises at least one semiconductor die electrically coupled to a set of electrically conductive leads, and package molding material molded over the at least one semiconductor die and the electrically conductive leads. At least a portion of the electrically conductive leads is exposed at a rear surface of the package molding material to provide electrically conductive pads. The electrically conductive pads comprise enlarged end portions extending at least partially over the package molding material and configured for coupling to a printed circuit board.

A method of fabricating an electronic device includes depositing a metal layer having external leads on a carrier. A photoresist material layer is patterned on the leads. A dielectric layer is formed over the metal layer such that surfaces of metal pillars from the metal layer are exposed. The photoresist material layer is removed from the leads, and the dielectric layer and the metal layer are removed from the carrier. A die is attached to the first surface of the dielectric layer. The die includes contacts on a surface of the die that contacts the dielectric layer such that the contacts are aligned with and connect to the exposed surfaces of the metal pillars. A mold compound is formed over the die, the dielectric layer, the metal traces, and the metal pillars of the metal layer, but not over the leads of the metal layer.

A method of forming a semiconductor package includes providing a panel, providing one or more metal layers on an upper surface of the panel, forming a die pad and bond pads from the one or more metal layers, the die pad being adjacent to and spaced apart from the bond pads, attaching a die to the die pad, forming electrical connections between the die and the bond pads, encapsulating the die and the electrical connections with an electrically insulating mold compound, removing portions of the panel, and exposing the die pad and the bond pads after encapsulating the die.