A method for producing a semiconductor package includes providing a lead frame and a bond pad with a space therebetween. The frame is provided with a die bonded thereon and a die pad. The die, the pad, a part of the frame, a part of the bond pad and the space between the frame and the bond pad are encapsulated. Part of the first encapsulation is removed to create a cavity having a bottom surface including an exposed surface of the die, an exposed surface of the pad, an exposed surface of the bond pad and a connecting region between the exposed surface of the pad and the bond pad. The cavity is partly filled with an electrically conductive paste. The electrically conductive paste is cured to obtain an interconnect between the die pad and the bond pad. The interconnect is encapsulated.

A composite substrate includes a submount substrate of an alternating pattern of electrically insulative portions, pieces, layers or segments and electrically conductive portions, pieces, layers or segments, and a shaft, back or plate for supporting the alternating pattern of electrically insulative portions and electrically conductive portions. An active device having a P-N junction can be mounted on the submount substrate. The electrically insulative portions, pieces, layers or segments can be formed from diamond while the electrically conductive portions, pieces, layers or segments can be formed from a metal or metal alloy.

A composite substrate includes a submount substrate of an alternating pattern of electrically insulative portions, pieces, layers or segments and electrically conductive portions, pieces, layers or segments, and a shaft, back or plate for supporting the alternating pattern of electrically insulative portions and electrically conductive portions. An active device having a P-N junction can be mounted on the submount substrate. The electrically insulative portions, pieces, layers or segments can be formed from diamond while the electrically conductive portions, pieces, layers or segments can be formed from a metal or metal alloy.

A method of manufacturing a semiconductor device includes forming an interlayer insulating film over a main surface of a semiconductor substrate, forming a first conductive film pattern for a first pad and a second conductive film pattern for a second pad over the interlayer insulating film, forming an insulating film over the interlayer insulating film such that the insulating film covers the first and the second conductive film patterns, forming a first opening portion for the first pad, the first opening portion exposing a portion of the first conductive film pattern, and a second opening portion for the second pad, the second opening portion exposing a portion of the second conductive film pattern, in the insulating film, and forming a first plated layer by plating over the portion of the first conductive film pattern exposed in the first opening portion, and a second plated layer.

According to one embodiment, a semiconductor device includes a bed portion, a semiconductor element, and a connector. The semiconductor element has a first electrode electrically connected to the bed portion and a second electrode facing away from the bed portion. The connector includes a first connection portion with a first surface electrically connected to the second electrode. The first surface is inclined in a direction from an outer edge portion of the first surface toward a center of the first surface. A lead portion of the connector is electrically connected to the first connection portion and spaced away from the bed portion.

A method of manufacturing a semiconductor device includes forming an interlayer insulating film over a main surface of a semiconductor substrate, forming a first conductive film pattern for a first pad and a second conductive film pattern for a second pad over the interlayer insulating film, forming an insulating film over the interlayer insulating film such that the insulating film covers the first and the second conductive film patterns, forming a first opening portion for the first pad, the first opening portion exposing a portion of the first conductive film pattern, and a second opening portion for the second pad, the second opening portion exposing a portion of the second conductive film pattern, in the insulating film, and forming a first plated layer by plating over the portion of the first conductive film pattern exposed in the first opening portion, and a second plated layer.

A semiconductor module includes a die pad frame; a semiconductor chip disposed in a chip region on an upper surface of the die pad frame, the semiconductor chip having an upper surface on which a first electrode is disposed and a lower surface on which a second electrode is disposed; a conductive connection member for die pad disposed between the second electrode of the semiconductor chip and the upper surface of the die pad frame, the conductive connection member for die pad electrically connecting the second electrode of the semiconductor chip and the upper surface of the die pad frame; and a sealing resin for sealing the semiconductor chip, the die pad frame, and the conductive connection member for die pad.

Provided are a semiconductor device capable of reducing damage on a resin case by heating during manufacture and a method of manufacturing a semiconductor device capable of reducing damage on a resin case by heating during manufacture. A semiconductor device includes a base plate, an insulating substrate, a semiconductor element, and a resin case. The base plate includes first and second regions whose positions differ from each other in a plan view. The insulating substrate is bonded on an upper surface of the second region. The insulating substrate includes a circuit pattern on an upper surface. The semiconductor element is bonded on the circuit pattern. The resin case is bonded on an upper surface of the first region. Thermal resistance between the upper surface and a lower surface of the first region is higher than thermal resistance between the upper surface and a lower surface of the second region.

A semiconductor module includes a die pad frame; a semiconductor chip disposed in a chip region on an upper surface of the die pad frame, the semiconductor chip having an upper surface on which a first electrode is disposed and a lower surface on which a second electrode is disposed; a conductive connection member for die pad disposed between the second electrode of the semiconductor chip and the upper surface of the die pad frame, the conductive connection member for die pad electrically connecting the second electrode of the semiconductor chip and the upper surface of the die pad frame; and a sealing resin for sealing the semiconductor chip, the die pad frame, and the conductive connection member for die pad.

A power module for an electric motor has at least one semiconductor switch half bridge with a high-side semiconductor switch and a low-side semiconductor switch. The semiconductor switches of the semiconductor switch half bridge have contact gap terminals which are each formed by a flat surface region of the semiconductor switch and which each point in the same direction. The high-side semiconductor switch and the low-side semiconductor switch enclose between them a circuit carrier that has at least two electrically conductive layers. A contact gap terminal of the low-side semiconductor switch and a contact gap terminal of the high-side semiconductor switch of the half bridge are electrically connected to each other by the circuit carrier.