A semiconductor device includes: a single die pad made of a metal or metal alloy and having a first surface, a second surface that is an opposite side of the first surface, and a pair of ground leads protruding from an end edge in plan view; a signal lead arranged between the ground leads; a plurality of leads arranged around the die pad in plan view; a semiconductor chip mounted on the second surface; bonding wires connecting a signal pad of the chip and the signal lead and connecting a ground pad of the chip and the ground leads; and a mold resin covering the die pad, the signal lead, the plurality of leads, the chip, and the bonding wires; wherein an interval between the signal lead and each of the ground leads is narrower than an interval between the plurality of leads.

There is provided a lead frame. The lead frame includes: a die pad; a lead terminal that is separated from the die pad and disposed around the die pad; and a resin layer that is formed between the die pad and the lead terminal so as to fix the die pad and the lead terminal. The resin layer has an opening portion that exposes at least a lower surface of the lead terminal.

Provided are a semiconductor module capable of further increasing an effect of canceling out a parasitic inductance by a current and a power converter including the semiconductor module. The semiconductor module includes a first leadframe, a second leadframe, a third leadframe, an insulating material, a first semiconductor element, and a second semiconductor element. The first leadframe is a plate-shaped wiring path to which a first potential is applied. The second leadframe is a plate-shaped wiring path including an output terminal. The third leadframe is a plate-shaped wiring path to which a second potential is applied. The first semiconductor element is directly joined to the first leadframe with a joint material therebetween, and the second semiconductor element is directly joined to the second leadframe with a joint material therebetween. The first leadframe and the second leadframe face each other with the insulating material therebetween.

Provided are a semiconductor module capable of further increasing an effect of canceling out a parasitic inductance by a current and a power converter including the semiconductor module. The semiconductor module includes a first leadframe, a second leadframe, a third leadframe, an insulating material, a first semiconductor element, and a second semiconductor element. The first leadframe is a plate-shaped wiring path to which a first potential is applied. The second leadframe is a plate-shaped wiring path including an output terminal. The third leadframe is a plate-shaped wiring path to which a second potential is applied. The first semiconductor element is directly joined to the first leadframe with a joint material therebetween, and the second semiconductor element is directly joined to the second leadframe with a joint material therebetween. The first leadframe and the second leadframe face each other with the insulating material therebetween.

An electronic component includes a carrier and an electronic chip mounted with compressive strain on the carrier. At least a part of a material of the carrier fulfils at least two of the following three criteria: an offset yield point in a range between 100 C. and 300 C. is at least 300 N/mm.sup.2; a yield strength in a range between 100 C. and 300 C. is at least 250 N/mm.sup.2; an electrical conductivity at 20 C. is at least 65% of the International Annealed Copper Standard (IACS).

A packaged semiconductor device includes a routable molded lead frame structure with a surface finish layer. In one embodiment, the routable molded lead frame structure includes a first laminated layer including the surface finish layer, vias connected to the surface finish layer, and a first resin layer covering the vias leaving the top surface of the surface finish layer exposed. A second laminated layer includes second conductive patterns connected to the vias, bump pads connected to the second conductive patterns, and a second resin layer covering one side of the first resin layer, the second conductive patterns and the bump pads. A semiconductor die is electrically connected to the surface finish layer and an encapsulant covers the semiconductor die and another side of the first resin layer. The surface finish layer provides a customizable and improved bonding structure for connecting the semiconductor die to the routable molded lead frame structure.

Embodiments of the present invention are directed to a method of manufacturing a semiconductor package with an internal routing circuit. The internal routing circuit is formed from multiple molding routing layers in a leadframe land grid array semiconductor package by using a laser to blast away un-designed conductive areas to create conductive paths on each molding compound layer of the semiconductor package.

A semiconductor device includes a substrate and a chip. The substrate has a first conduction layer, a second conduction layer, and an isolation layer disposed between the first conduction layer and the second conduction layer. The first conductive layer has a first portion and a second portion spaced apart from the first portion, and each of the first portion and the second portion includes a main part and a plurality of extension parts extending from the main part. The chip is disposed on the extension parts of the first portion and the second portion of the first conductive layer.

A package structure includes a first conduction layer, a second conduction layer, and an isolation layer. The first conduction layer includes a plurality of first portions, and the second conduction layer includes a plurality of portions. The isolation layer is disposed between the first conduction layer and the second conduction layer, and the isolation layer is composed of one of nitride and oxide mixed with at least one of epoxy and polymer.

A lead frame includes a plurality of leads formed from a metal plate having a front side and a back side, a first resin member, and a second resin member. The leads have side faces thereof fixed with the first resin member. Faces serving as internal connectors of the leads are uncovered on the side of the front-side surface of the first resin member, and faces serving as external connectors of the leads are uncovered on the side of the back-side surface of the first resin member. The second resin member is formed on the front-side surface of the first resin member to be at a level higher than the faces serving as the internal connectors, and has openings for leaving the faces serving as the internal connectors uncovered.