An object of the present invention is to suppress electrical contact between an outer peripheral portion of an intermediate electrode and a front surface electrode of a semiconductor chip without increasing the area of the semiconductor chip. A facing surface of the first intermediate electrode facing a first main electrode is smaller than a facing surface of the first main electrode facing the first intermediate electrode, and has an outer peripheral protective region and a connection region surrounded by the protective region. A pressure-contact semiconductor device includes a plurality of first conductor films partially formed in the connection region, and a first insulating film formed in regions in the connection region where no first conductor films are formed and in the protective region.

A multiphase inverter apparatus includes an insulating substrate, a plurality of half bridge circuits and a phase output lead for each half bridge circuit. The substrate includes a conductive redistribution structure on a first surface and having at least one low voltage bus and at least one high voltage bus. Each half-bridge circuit is electrically coupled between a low voltage bus and a high voltage bus and includes: a packaged low side switch; a packaged high side switch; and a phase output electrically coupled with the respective phase output lead. The packaged low side and high side switches are arranged on the first surface of the substrate. The phase output lead is arranged on and electrically coupled to the packaged low side and high side switches such that the low side and high side switches are arranged vertically between the phase output lead and the first surface of the substrate.

There is provided a semiconductor device including a first electrode including a first plate portion, the first plate portion including a first surface and a second surface facing the first surface, a plurality of semiconductor chips provided above the second surface, and a second electrode including a second plate portion provided above the semiconductor chips, the second plate portion including a third surface facing the second surface and a fourth surface facing the third surface, the second plate portion including a plurality of protrusion portions provided between the semiconductor chips and the third surface, the protrusion portions being connected to the third surface, each of the protrusion portions including a top surface including the same shape as a shape of each of the semiconductor chips in a plane parallel to the second surface, the second plate portion including a second outer diameter larger than a first diameter of a smallest circle circumscribing the protrusion portions provided on an outermost side among the protrusion portions in a plane parallel to the third surface, and a third plate portion including a fifth surface connected to the fourth surface and a sixth surface facing the fifth surface, the third plate portion including a third outer diameter equal to or smaller than the first diameter.

A package structure includes a first circuit board, a second circuit board, at least one electronic component, at least one conductive lead, and a molding compound. The first circuit board includes a first circuit layer and a second circuit layer. The second circuit board includes a third circuit layer and a fourth circuit layer. The electronic component is disposed between the first circuit board and the second circuit board. The conductive lead contacts at least one of the second circuit layer and the third circuit layer. The conductive lead has a vertical height, and the vertical height is greater than a vertical distance between the second circuit layer and the third circuit layer. The molding compound covers the first circuit board, the second circuit board, the electronic component, and the conductive lead. The molding compound exposes the first circuit layer and the fourth circuit layer, and the conductive lead extends outside the molding compound.

A power module includes a spacer block, a thermally conductive substrate coupled to one side of the spacer block, and a semiconductor device die coupled to an opposite side of the spacer block. The spacer block includes a solid spacer block and an adjacent flexible spacer block. An inner portion of the device die is coupled to the solid spacer block, and an outer portion of the semiconductor device die is coupled to the adjacent flexible spacer block.

A semiconductor package includes a first substrate, a first layer structure, a second layer structure, a first antenna layer and an electronic component. The first antenna layer is formed on at least one of the first layer structure and the second layer structure, wherein the first antenna layer has an upper surface flush with a layer upper surface of the first layer structure or the second layer structure. The electronic component is disposed on a substrate lower surface of the first substrate and exposed from the first substrate. The first layer structure is formed between the first substrate and the second layer structure.

A circuit, comprising a diode, a conductive upper support disposed on top of the diode and electrically coupled to the diode, a conductive lower support disposed underneath the diode and electrically coupled to the diode, a mechanical support disposed adjacent to the diode, the conductive upper support and the conductive lower support, an insulator disposed underneath the mechanical support, an upper terminal coupled to the mechanical support and electrically coupled to the conductive upper support and a lower terminal coupled to the insulator and electrically coupled to the conductive lower support.

A power module includes a power semiconductor device, a first power lead electrically connected to a first power terminal of the power semiconductor device, a second power lead disposed in parallel to the first power lead near the first power lead and electrically connected to a second power terminal of the power semiconductor device, and a conductive plate disposed to be spaced apart from the first power lead or the second power lead by a predetermined distance such that a region overlapping with the first power lead or the second power lead is formed.

A semiconductor device package and manufacturing method thereof are provided. The semiconductor device package includes a first conductive structure, a second conductive structure, a connection element, a conductive member, an encapsulant and a binding layer. The first conductive structure includes a first circuit layer. The second conductive structure is disposed over the first conductive structure. The connection element is disposed on and electrically connected to the first circuit layer. The conductive member protrudes from the second conductive structure. The encapsulant is disposed between the first conductive structure and the second conductive structure. The binding layer is disposed between the second conductive structure and the encapsulant.

Provided is a method of manufacturing a semiconductor having a double-sided substrate including preparing a first substrate on which a specific pattern is formed to enable electrical connection, preparing at least one semiconductor chip bonded to a metal post, bonding the at least one semiconductor chip to the first substrate, bonding a second substrate to the metal post, forming a package housing by packaging the first substrate and the second substrate to expose a lead frame, and forming terminal leads toward the outside of the package housing. Accordingly, the semiconductor chip and the metal post are previously joined to each other and are respectively bonded to the first substrate and the second substrate so that damage generated while bonding the semiconductor chip may be minimized and electrical properties and reliability of the semiconductor chip may be improved.