A semiconductor package comprises a first die thermally coupled to a first thermally conductive device. The first thermally conductive device has a first surface exposed to an exterior of the semiconductor package. The package comprises a second die thermally coupled to a second thermally conductive device, the second thermally conductive device having a second surface exposed to an exterior of the semiconductor package. The first and second dies are positioned in different horizontal planes.

A trench capacitor includes a plurality of trenches in a semiconductor substrate. A first polysilicon layer is located within the plurality of trenches and over a top surface of the substrate. The first polysilicon layer is continuous between the plurality of trenches. The trench capacitor further includes a plurality of second polysilicon layers. Each of the second polysilicon layers fills a corresponding trench of the plurality of trenches. The second polysilicon layers each extend to a top surface of the first polysilicon layer.

Power amplifier electronics for controlling application of radio frequency (RF) energy generated using solid state electronic components may further be configured to control application of RF energy in cycles between high and low powers. The power amplifier electronics may include a semiconductor die on which one or more RF power transistors are fabricated, an output matching network configured to provide impedance matching between the semiconductor die and external components operably coupled to an output tab, and bonding ribbon bonded at terminal ends thereof to operably couple the one or more RF power transistors of the semiconductor die to the output matching network. The bonding ribbon may have a width of greater than about five times a thickness of the bonding ribbon.

A packaged semiconductor system, including: at least one electronic device on a device mounting surface of a substrate having terminals for attaching bond wires; at least one discrete component adjacent to the at least one electronic device, a second electrode of the at least one discrete component parallel to and spaced from a first electrode by a component body; the first electrode a metal foil having a protrusion extending laterally from the body and having a surface facing towards the second electrode; bonding wires interconnecting respective terminals of the at least one electronic device, the first electrode and the second electrode, and bonded to the surface of the second electrode and to the protrusion that extend away from the respective surfaces in a same direction; and packaging compound covering portions of the at least one electronic device, the at least one discrete component, and the bonding wires.

A trench capacitor includes a plurality of trenches in a doped semiconductor surface layer of a substrate. At least one dielectric layer lines a surface of the plurality of trenches. A second polysilicon layer that is doped is on a first polysilicon layer that is on the dielectric layer which fills the plurality of trenches. The second polysilicon layer has a higher doping level as compared to the first polysilicon layer.

A package structure of a power device includes a substrate having a first circuit, a first power device, a second power device, an insulation film having a second circuit, at least one electronic component, and a package. The first power device, the second power device, and the insulation film are disposed on the substrate. The first power device and the second power device are directly electrically connected to each other via the first circuit of the substrate. The electronic component is disposed on the insulation film. The package encapsulates the substrate, the first power device, the second power device, and the electronic component.

A trench capacitor includes a plurality of trenches in a doped semiconductor surface layer of a substrate. At least one dielectric layer lines a surface of the plurality of trenches. A second polysilicon layer that is doped is on a first polysilicon layer that is on the dielectric layer which fills the plurality of trenches. The second polysilicon layer has a higher doping level as compared to the first polysilicon layer.

It is an object of the present invention to provide a semiconductor module in which a bonded portion has high reliability, and that has a small area. A semiconductor module includes a plurality of metal plates extending in a horizontal direction and stacked in a vertical direction, at least one switching element, and at least one circuit element. The at least one switching element is bonded between two of the plurality of metal plates, facing each other in a vertical direction. The at least one circuit element is bonded between two of the plurality of metal plates, facing each other in a vertical direction. Disposed between the plurality of metal plates is an insulating material. At least one of the plurality of metal plates is bonded to the at least one switching element and the at least one circuit element.

A packaged semiconductor system, including: at least one electronic device on a device mounting surface of a substrate having terminals for attaching bond wires; at least one discrete component adjacent to the at least one electronic device, a second electrode of the at least one discrete component parallel to and spaced from a first electrode by a component body; the first electrode a metal foil having a protrusion extending laterally from the body and having a surface facing towards the second electrode; bonding wires interconnecting respective terminals of the at least one electronic device, the first electrode and the second electrode, and bonded to the surface of the second electrode and to the protrusion that extend away from the respective surfaces in a same direction; and packaging compound covering portions of the at least one electronic device, the at least one discrete component, and the bonding wires.

A semiconductor chip includes a semiconductor body having a lower side with a lower chip metallization applied thereto. A first contact metallization layer is produced on the lower chip metallization. A second contact metallization layer is produced on a metal surface of a substrate. The semiconductor chip and the substrate are pressed onto one another for a pressing time so that the first and second contact metallization layers bear directly and extensively on one another. During the pressing time, the first contact metallization layer is kept continuously at temperatures which are lower than the melting temperature of the first contact metallization layer. The second contact metallization layer is kept continuously at temperatures which are lower than the melting temperature of the second contact metallization layer during the pressing time. After the pressing together, the first and second contact metallization layers have a total thickness less than 1000 nm.