A power module (PM) includes: an insulating substrate; a semiconductor device disposed on the insulating substrate, the semiconductor device including electrodes on a front surface side and a back surface side thereof; and a graphite plate having an anisotropic thermal conductivity, the graphite plate of which one end is connected to the front surface side of the semiconductor device and the other end is connected to the insulating substrate, wherein heat of the front surface side of the semiconductor device is transferred to the insulating substrate through the graphite plate. There is provide an inexpensive power module capable of reducing a stress and capable of exhibiting cooling performance not inferior to that of the double-sided cooling structures.

A semiconductor device includes a substrate, a semiconductor die, and an antistatic die attach material between the substrate and the semiconductor die. The antistatic die attach material includes a mixture of a nonconductive adhesive material and carbon black or graphite. In one example, the antistatic die attach material has a resistivity between 10.sup.1 Ω.Math.cm and 10.sup.10 Ω.Math.cm.

A soldering jig for double-faced cooling power modules is provided. The soldering jig prevents thermal deformation of a substrate during a soldering process. The soldering jig is used to fix the position of an upper substrate and a lower substrate when a semiconductor chip is disposed and soldered between the upper and lower substrates. The soldering jig includes a lower jig plate that is disposed under the lower substrate and fixes the position of lower substrate, an upper jig plate that is disposed over the upper substrate and compresses the upper substrate toward the lower substrate. Additionally, a connector which couples the lower jig plate and the upper jig plate, and an insert is installed on the connector and is disposed between the upper substrate and the lower substrate to maintain a constant distance between the upper substrate and the lower substrate during a soldering process.

A structure including a photonic integrated circuit die, an electric integrated circuit die, a semiconductor dam, and an insulating encapsulant is provided. The photonic integrated circuit die includes an optical input/output portion and a groove located in proximity of the optical input/output portion, wherein the groove is adapted for lateral insertion of at least one optical fiber. The electric integrated circuit die is disposed over and electrically connected to the photonic integrated circuit die. The semiconductor dam is disposed over the photonic integrated circuit die. The insulating encapsulant is disposed over the photonic integrated circuit die and laterally encapsulates the electric integrated circuit die and the semiconductor dam.

A semiconductor device configures one arm of an upper-lower arm circuit, and includes: a semiconductor element that includes a first main electrode and a second main electrode, wherein a main current between the first main electrode and the second main electrode; and multiple main terminals that include a first main terminal connected to the first main electrode and a second main terminal connected to the second main electrode. The first main terminal and the second main terminal are placed adjacent to each other; A lateral surface of the first main terminal and a lateral surface of the second main terminal face each other in one direction orthogonal to a thickness direction of the semiconductor element.

The semiconductor device includes at least three semiconductor elements disposed directly or indirectly on a planar member and constituting an upper arm and a lower arm which perform ON and OFF action at mutually differential times; an upper-surface voltage applied region of each semiconductor element is configured to be narrower than an area of the aforementioned whole semiconductor element in planar view; and each semiconductor element is disposed so that the shortest distance between the semiconductor elements constituting the upper arm is formed so as to be longer than the shortest distance between the semiconductor element constituting the upper arm and the semiconductor element constituting the lower arm.

A semiconductor device includes a semiconductor chip, a metal member, and a terminal. The semiconductor chip has an electrode. The metal member is electrically connected to the electrode. The terminal extends from the metal member to be connected to an external connection member. The terminal has a width-increased portion in a predetermined area beginning from a first end of the terminal that connects to the metal member.

A display device is disclosed. The display device includes a substrate having a plurality of pixels, wherein each of the plurality of pixels includes at least one light emitting chip, and a structure on one side of at least one of the plurality of pixels. A base material of the light emitting chip is the same as a base material of the structure.

A printed circuit board assembly of an implantable medical device comprises a printed circuit board and a sensor device that is arranged at the printed circuit board and joined to the printed circuit board by way of an adhesive layer. It is provided in the process that the adhesive layer is formed of an adhesive compound in which glass spheres are embedded. In this way, a printed circuit board assembly is provided which, in a simple, inexpensive manner, allows a sensor device to be joined to a printed circuit board for installation in a medical device, with advantageous mechanical decoupling and improved process reliability.

A package structure is provided. The package structure includes a die, a lead frame, and a conductive glue. The lead frame includes a die pad and a retaining wall structure. The die pad is configured to support the die, and the retaining wall structure surrounds the die. The conductive glue is disposed between the die and the lead frame.