The present application relates to a package substrate and a package structure. The package substrate includes: a first conductive layer, located on the top of a base and comprising power lines configured to supply power to chips and signal lines configured to provide signals to the chips; and, a second conductive layer, located on the bottom of the base and comprising first pads and local interconnection lines, the first pads being electrically connected to the signal lines, the plurality of associated first pads being electrically connected by the local interconnection lines.

A dual-sided MOS IC includes an isolation layer and a MOS transistor. The isolation layer separates the MOS IC into a MOS IC frontside and a MOS IC backside. The MOS transistor is on both the MOS IC frontside and the MOS IC backside. The MOS transistor includes MOS gates, a first source connection in a first subsection of the MOS IC frontside, and a second source connection in a second subsection of the MOS IC backside. The first and second source connections are electrically coupled together through a first front-to-backside connection extending through the isolation layer. The MOS transistor further includes a first drain connection in the first subsection of the MOS IC backside, and a second drain connection in the second subsection of the MOS IC frontside. The first and second drain connections are electrically coupled together through a second front-to-backside connection extending through the isolation layer.

A radio frequency (“RF”) transistor amplifier die includes a semiconductor layer structure having a plurality of transistor cells, and an insulating layer on a surface of the semiconductor layer structure. Conductive pillar structures protrude from the insulating layer opposite the surface of the semiconductor layer structure, and are configured to provide input signal, output signal, or ground connections to the transistor cells. The ground connections are arranged between the input and/or output signal connections to the transistor cells. Related devices and packages are also discussed.

A semiconductor device is proposed. The semiconductor device includes a semiconductor body including a first main surface. A plurality of trench electrode structures extend in parallel along a first lateral direction. A first one of the plurality of trench electrode structures includes a gate electrode. A gate contact is electrically connected to the gate electrode in a gate contact area. The gate contact area is arranged in a first section along the first lateral direction. An isolation structure is arranged between the gate contact and the semiconductor body in the gate contact area. A bottom side of the isolation structure is arranged between a bottom side of the first one of the plurality of trench electrode structures and the first main surface along a vertical direction. The gate contact extends up to or below the first main surface along the vertical direction.

The present invention provides a packaging method and a packaging structure for a cascode power electronic device, in which a hetero-multiple chip scale package is used to replace the traditional die bonding and wire bonding packaging method. The cascode power electronic device can reduce the inductance resistance and thermal resistance of the connecting wires and reduce the size of the package; and increase the switching frequency of power density. The chip scale package of the present invention uses more than one gallium nitride semiconductor die, more than one diode, and more than one metal oxide semiconductor transistor. The package structure can use TO-220, quad flat package or other shapes and sizes; the encapsulation process of the traditional epoxy molding compounds can be used in low-power applications; and the encapsulation process of ceramic material can be used in high-power applications.

A semiconductor component includes at least two functional units which are identical to one another and are wired to one another, the identical functional units each include at least one gate finger, at least one source finger and at least one drain finger; the wiring comprising conductor tracks. A first track connects the gate fingers respectively, a second track connects the source fingers respectively, and a third track connects the drain fingers of the at least two same functional units, respectively.

A transistor device includes a substrate, a gate contact pad on the substrate, and a transistor die on the substrate adjacent the gate contact pad. The transistor die includes an active region and a gate bond pad adjacent the active region, and the gate bond pad has a side edge adjacent the active region that extends in a first direction. The transistor device includes a bonding wire bonded to the gate contact pad at a first end of the bonding wire and to the gate bond pad at a second end of the bonding wire. The bonding wire extends in a second direction that is oblique to the first direction such that the bonding wire forms an angle relative to the first direction that is less than 90 degrees.

Power semiconductor devices comprise a silicon carbide based semiconductor layer structure including an active region defined therein and a gate bond pad that is on the semiconductor layer structure and vertically overlaps the active region.

The disclosure concerns an electronic device provided with two high electron mobility transistors stacked on each other and having in common their source, drain, and gate electrodes. For example, each of these electrodes extends perpendicularly to the two transistors. For example, the source and drain electrodes electrically contact the conduction channels of each of the transistors so that said channels are electrically connected in parallel.

In a described example, an apparatus includes: a package substrate having a die pad configured for receiving a semiconductor die, and having conductive leads spaced from the die pad; a semiconductor die mounted on the die pad, the semiconductor die having bond pads on an active surface configured for making electrical connections; electrical connections coupling the bond pads of the semiconductor die to the conductive leads; mold compound covering a portion of the package substrate, the semiconductor die, and the electrical connections, with the leads extending through the mold compound and having end portions exposed from the mold compound; and the leads having a first portion with a first width and extending with the first width from the mold compound to a second portion having a second width that greater than the first width.