A semiconductor device package includes a substrate having first and second opposing surfaces. A first surface of a die couples to the second surface of the substrate, and a first surface of an electrically conductive sub-terminal electrically couples with an electrical contact of the die and physically couples to the second surface of the substrate. A mold compound encapsulates the die and a majority of the sub-terminal. In implementations a first surface of the mold compound is coupled to the second surface of the substrate and a second surface of the mold compound opposing the first surface of the mold compound is flush with a second surface of the sub-terminal opposing the first surface of the sub-terminal. In implementations the sub-terminal includes a pillar having a longest length perpendicular to a longest length of the substrate. In implementations an electrically conductive pin couples to the second surface of the sub-terminal.

A semiconductor device package includes a substrate having first and second opposing surfaces. A first surface of a die couples to the second surface of the substrate, and a first surface of an electrically conductive sub-terminal electrically couples with an electrical contact of the die and physically couples to the second surface of the substrate. A mold compound encapsulates the die and a majority of the sub-terminal. In implementations a first surface of the mold compound is coupled to the second surface of the substrate and a second surface of the mold compound opposing the first surface of the mold compound is flush with a second surface of the sub-terminal opposing the first surface of the sub-terminal. In implementations the sub-terminal includes a pillar having a longest length perpendicular to a longest length of the substrate. In implementations an electrically conductive pin couples to the second surface of the sub-terminal.

An integrated power module packaging structure includes a plastic housing having a cavity; a plurality of step-shaped pins embedded in the plastic housing, a first printed circuit board disposed in the cavity, and a second printed circuit board disposed above the first printed circuit board in the cavity. Each of the step-shaped pins includes a first L-shaped bending portion and a second L-shaped bending portion connected to each other. The first printed circuit board is disposed with at least a power device and is electrically connected to at least a part of the first L-shaped bending portions. Two opposite surfaces of the second printed circuit board are respectively disposed with at least an electronic device, and the second printed circuit board is electrically connected to at least a part of the second L-shaped bending portions.

An integrated power module packaging structure includes a plastic housing having a cavity; a plurality of step-shaped pins embedded in the plastic housing, a first printed circuit board disposed in the cavity, and a second printed circuit board disposed above the first printed circuit board in the cavity. Each of the step-shaped pins includes a first L-shaped bending portion and a second L-shaped bending portion connected to each other. The first printed circuit board is disposed with at least a power device and is electrically connected to at least a part of the first L-shaped bending portions. Two opposite surfaces of the second printed circuit board are respectively disposed with at least an electronic device, and the second printed circuit board is electrically connected to at least a part of the second L-shaped bending portions.

A semiconductor power module in which a three-phase AC inverter is incorporated in a package includes first to third circuit patterns on which second, fourth, and sixth switching elements are mounted, respectively, and a fourth circuit pattern on which first, third, and fifth switching elements are mounted; a second main electrode to which all of main electrode wirings of the second, fourth, and sixth switching elements are connected; a second main electrode terminal connected to the second main electrode; a first main electrode electrically connected to the fourth circuit pattern; and a first main electrode terminal connected to the first main electrode, and each of the main electrode wirings of the second, fourth, and sixth switching elements is provided so that a main electrode wiring closer to the second main electrode terminal in a horizontal direction in plan view has a longer length.

A semiconductor power module in which a three-phase AC inverter is incorporated in a package includes first to third circuit patterns on which second, fourth, and sixth switching elements are mounted, respectively, and a fourth circuit pattern on which first, third, and fifth switching elements are mounted; a second main electrode to which all of main electrode wirings of the second, fourth, and sixth switching elements are connected; a second main electrode terminal connected to the second main electrode; a first main electrode electrically connected to the fourth circuit pattern; and a first main electrode terminal connected to the first main electrode, and each of the main electrode wirings of the second, fourth, and sixth switching elements is provided so that a main electrode wiring closer to the second main electrode terminal in a horizontal direction in plan view has a longer length.

A method for manufacturing a power semiconductor module and a power semiconductor module having, in each case, a housing, a switchgear arranged in this housing and having a plurality of connection elements, has the following method steps: A) forming a housing with pre-fixed connection elements; B) arranging the switchgear in the housing and connecting the connection elements to connection surfaces of a substrate of the switchgear; C) arranging a positioning device for fixing the position of the connection elements with respect to one another; D) fixing the connection elements relative to one another and to the housing.

An electronic device includes a first board, a second board, and support pillars. The support pillars hold the first board and the second board mutually separated. The first board has a first surface on which an electronic component is mounted. The first board has a second surface that includes depressed portions into which the support pillars extending from the second board are inserted.

An electronic device includes a first board, a second board, and support pillars. The support pillars hold the first board and the second board mutually separated. The first board has a first surface on which an electronic component is mounted. The first board has a second surface that includes depressed portions into which the support pillars extending from the second board are inserted.

Techniques regarding qubit chip assemblies are provided. For example, one or more embodiments described herein can include an apparatus that can comprise a qubit chip positioned on an interposer chip. The apparatus can also comprise an electrical connector in direct contact with the interposer chip. The electrical connector can establish an electrical communication between a wire and a contact pad of the interposer chip that is coupled to the qubit chip.