A power semiconductor module includes: a substrate including first, second, and third metal patterns separated from each other, a semiconductor element located on the substrate, a lead frame located on the substrate and including first, second, third, and fourth bodies; a first terminal connected to the first body, a second terminal connected to the second body, and a third common terminal that connects the third body and the fourth body, wherein a length of the third common terminal is longer than that of the first and second terminals.

A semiconductor device according to the present invention includes: a semiconductor element; a first metal body having a die pad to which the semiconductor element is mounted, the semiconductor element being mounted on a die bond surface of the die pad; a second metal body which has a wire bond pad connected to a signal electrode of the semiconductor element via a wire, and is provided on the same side as the die bond surface such that the second metal body is separated from the first metal body and covered by the first metal body, the second metal body forming a transmission line together with the first metal body; and a molding resin holding the first metal body and the second metal body such that a surface of the first metal body opposite to the die bond surface is exposed.

A power field-effect transistor package is fabricated. A leadframe including a flat plate and a coplanar flat strip spaced from the plate is provided. The plate has a first thickness and the strip has a second thickness smaller than the first thickness. A field-effect power transistor chip having a third thickness is provided. A first and second contact pad on one chip side and a third contact pad on the opposite chip side are created. The first pad is attached to the plate and the second pad to the strip. Terminals are concurrently attached to the plate and the strip so that the terminals are coplanar with the third contact pad. The thickness difference between plate and strip and spaces between chip and terminals is filled with an encapsulation compound having a surface coplanar with the plate and the opposite surface coplanar with the third pad and terminals. The chip, leadframe and terminals are integrated into a package having a thickness equal to the sum of the first and third thicknesses.

A chip package structure can include: a lead frame having a carrier substrate and a first lead around the carrier substrate; a first conductive post arranged on the first lead and electrically coupled with the first lead; a first chip having an active face and an inactive face opposite to the active face and attached to the carrier substrate, and electrode pads on the active face are provided with a first electrical connector; a first plastic package configured to fully encapsulate the first chip, and to partly encapsulate the lead frame, where the first plastic package includes a first surface and a second surface opposite to the first surface, where the first conductive post and the first electrical connector are exposed on the first surface, and where the first lead is exposed on the second surface, and a second lead being arranged on the first surface.

Provided is a coupled semiconductor package including at least two substrate pads; at least one semiconductor chip installed on each of the substrate pads; at least one terminal each of which is electrically connected to each substrate pad and each semiconductor chip; and a package housing covering a part of the at least one semiconductor chip and the at least one terminal, wherein lower surfaces of one or more substrate pads are formed to be electrically connected and lower surfaces of another one or more substrate pads are formed to be electrically insulated. Accordingly, partial insulation may be economically realized without applying an insulating material to a heat sink, when the package is joined to the heat sink.

The semiconductor device improves heat dissipation by loading a diode and a MOSFET or IGBT in a single package. A drain electrode disposed on a rear surface of a MOSFET chip is soldered to an upper surface of a first lead frame, and a cathode electrode disposed on a rear surface of a diode chip is soldered to an upper surface of a second lead frame. Rear surfaces of the first lead frame and second lead frame to which neither the diode chip nor the MOSFET chip is connected are disposed so as to be exposed from a sealing resin.

A semiconductor device that includes a first die pad, an adhesive, and a second die pad fixed to the top surface of the first die pad via the adhesive. The second die pad includes a body portion and a protrusion portion provided on a side surface of the body portion. A semiconductor chip is fixed to a top surface of the second die pad, and a lead is electrically connected to the semiconductor chip. The semiconductor device further includes a package material that covers the first die pad, the second die pad, the semiconductor chip, and the lead. The first die pad is substantially as thick as the lead.

A semiconductor device may be provided with: a semiconductor chip; an encapsulant encapsulating the semiconductor chip therein; and a conductor member joined to the semiconductor chip via a solder layer within the encapsulant. The conductor member may comprise a joint surface in contact with the solder layer and a side surface extending from a peripheral edge of the joint surface. The side surface may comprise an unroughened area and a roughened area that is greater in surface roughness than the unroughened area. The unroughened area may be located adjacent to the peripheral edge of the joint surface.

A multichip package and a method for manufacturing the same are provided. A multichip package includes: a plurality of semiconductor chips each mounted on corresponding lead frame pads; lead frames connected to the semiconductor chips by a bonding wire; and fixed frames integrally formed with at least one of the lead frame pads and configured to support the lead frame pads on a package-forming substrate.

A semiconductor module forming a semiconductor device includes lead frames in which switching elements are mounted on the side of upper surfaces and heat radiation surfaces are formed on the side of lower surfaces, and bus bars disposed on the lead frames and connecting between plural switching elements. The heat radiation surfaces of the lead frames are arranged on one plane and upper surfaces of flat surface portions of the bus bars are arranged on one plane, therefore, a layout property on the heat radiation surfaces or the upper surfaces the flat surface portions is good, which facilitates creation of a heat radiation structure and so on.