A semiconductor device A1 includes a substrate 3, a conductive section 5 formed on the substrate 3 and including a conductive material, a lead 1A located on the substrate 3, a semiconductor chip 4A located on the lead 1A, a control chip 4G located on the substrate 3 and electrically connected to the conductive section 5 and the semiconductor chip 4A for controlling an operation of the semiconductor chip 4A, and a resin 7 covering the semiconductor chip 4A, the control chip 4G, at least a part of the substrate 3 and a part of the lead 1A. This configuration contributes to achieving a higher level of integration of the semiconductor device.

A semiconductor device A1 includes a substrate 3, a conductive section 5 formed on the substrate 3 and including a conductive material, a lead 1A located on the substrate 3, a semiconductor chip 4A located on the lead 1A, a control chip 4G located on the substrate 3 and electrically connected to the conductive section 5 and the semiconductor chip 4A for controlling an operation of the semiconductor chip 4A, and a resin 7 covering the semiconductor chip 4A, the control chip 4G, at least a part of the substrate 3 and a part of the lead 1A. This configuration contributes to achieving a higher level of integration of the semiconductor device.

A semiconductor device includes a chip carrier, a first semiconductor chip arranged on the chip carrier, the first semiconductor chip being located in a first electrical potential domain when the semiconductor device is operated, a second semiconductor chip arranged on the chip carrier, the second semiconductor chip being located in a second electrical potential domain different from the first electrical potential domain when the semiconductor device is operated, and an electrically insulating structure arranged between the first semiconductor chip and the second semiconductor chip, which is designed to galvanically isolate the first semiconductor chip and the second semiconductor chip from each other.

A semiconductor module includes a semiconductor device and bus bar. The device includes an insulating substrate, conductive member, switching elements, and first/second input terminals. The substrate has main/back surfaces opposite in a thickness direction, with the conductive member disposed on the main surface. The switching elements are connected to the conductive member. The first input terminal, including a first terminal portion, is connected to the conductive member. The second input terminal, including a second terminal portion overlapping with the first terminal portion in the thickness direction, is connected to the switching elements. The second input terminal is separate from the first input terminal and conductive member in the thickness direction. The bus bar includes first/second terminals. The second terminal, separate from the first terminal in the thickness direction, partially overlaps with the first terminal in the thickness direction. The first/second terminals are connected to the first/second terminal portions, respectively.

A packaged electrical device that includes a cured adhesive layer and a cured layer of die attach material coupled between a semiconductor die and a substrate. The packaged electrical device may also include wire bonds coupled between the substrate and leads of the semiconductor die. In addition, the packaged electrical device may be encapsulated in molding compound. A method for fabricating a packaged electrical device. The method includes printing a layer of die attach material over a semiconductor wafer and applying a layer of 2-in-1 die attach film over the layer of die attach material. The method also includes singulating the semiconductor wafer to create a semiconductor die and placing the semiconductor die onto a substrate. In addition the method includes wire bonding the substrate to leads of the semiconductor die and encapsulating the device in molding compound.

A plastic material substrate has a die mounting location for a semiconductor die. Metallic traces are formed on selected areas of the plastic material substrate, wherein the metallic traces provide electrically-conductive paths for coupling to the semiconductor die. The semiconductor die is attached onto the die mounting location. The semiconductor die attached onto the die mounting location is electrically bonded to selected ones of the metallic traces formed on the plastic material substrate. A package material is molded onto the semiconductor die attached onto the die mounting location.

An integrated circuit package that includes a leadframe and a mold compound encapsulating at least a portion of the leadframe. The mold compound includes a cavity open at a bottom surface of the mold compound that exposes a bottom surface of the leadframe. A thermally conductive and electrically insulating isolation layer is locked within the bottom cavity of the mold compound and contacts the bottom surface of the leadframe.

A semiconductor device includes an insulating substrate, wiring layers, heat dissipation layers, a semiconductor element, and a sealing resin. The wiring layers each have a first obverse face and a first reverse face oriented in opposite directions in a thickness direction of the substrate. The first reverse faces of the wiring layers are connected to the substrate. The heat dissipation layers each have a second obverse face oriented in the same direction as the first obverse face, and a second reverse face oriented opposite to the second obverse face in the thickness direction. The heat dissipation layers are located opposite to the plurality of wiring layers in the thickness direction with respect to the substrate. The second obverse faces of the heat dissipation layers are connected to the substrate. The semiconductor element is connected to one of the first obverse faces of the wiring layers. The sealing resin covers the substrate, the wiring layers, and the semiconductor element. As viewed in the thickness direction, the wiring layers overlap with the heat dissipation layers, respectively.

An electronic module has a first substrate 11; an electronic element 13, 23 provided on one side of the first substrate 11; a sealing part 90 that seals at least the electronic element 13, 23; a connection terminal 110 electrically connected to the electronic element 13, 23 and exposed from a side surface of the sealing part 90; and a stress relaxation terminal 150, which is not electrically connected to the electronic element 13, 23, exposed from the side surface of the sealing part 90.

A packaged semiconductor device includes a substrate having a first surface and a second surface opposite the first surface. At least one semiconductor die is mounted at the first surface of the substrate. Electrically-conductive leads are arranged around the substrate, and electrically-conductive formations couple the at least one semiconductor die to selected leads of the electrically-conductive leads. A package molding material is molded onto the at least one semiconductor die, onto the electrically-conductive leads and onto the electrically-conductive formations. The package molding material leaves the second surface of the substrate uncovered by the package molding material. The substrate is formed by a layer of electrically-insulating material.