A power module includes at least two power semiconductor arrangements, each having at least one semiconductor component, in contact with substrate and arranged in a housing. To improve the reliability of the power module, a first power connector and a second power connector are arranged on a first side of the housing and at least one other power connector is arranged on an opposing second side of the housing. Supply lines extending from the power connectors to the power semiconductor arrangements are arranged on the substrate in such a manner that electrical current is provided in a symmetrical manner.

A semiconductor die includes a semiconductor body having first and second active portions. The first active portion includes first source regions. The second active portion includes second source regions. A gate structure extends from a first surface into the semiconductor body and has a longitudinal gate extension along a lateral first direction. A first load pad and the first source regions are electrically connected. A second load pad and the second source regions are electrically connected. A gap laterally separates the first and second load pads. A lateral longitudinal extension of the gap is parallel to the first direction or deviates therefrom by not more than 60 degree. A connection structure electrically connects the first and second load pads. The connection structure is formed in a groove extending from the first surface into the semiconductor body and/or in a wiring layer formed on the first surface.

A semiconductor device includes: an insulating circuit substrate; a semiconductor element including a first main electrode bonded to a first conductor layer of the insulating circuit substrate via a first bonding material, a semiconductor substrate deposited on the first main electrode, and a second main electrode deposited on the semiconductor substrate; and a resistive element including a bottom surface electrode bonded to a second conductor layer of the insulating circuit substrate via a second bonding material, a resistive layer with one end electrically connected to the bottom surface electrode, and a top surface electrode electrically connected to another end of the resistive layer, wherein the first main electrode includes a first bonded layer bonded to the first bonding material, the bottom surface electrode includes a second bonded layer bonded to the second bonding material, and the first bonded layer and the second bonded layer have a common structure.

The present invention relates to a substrate for an optical device, which is configured to connect an optical element substrate and an electrode substrate in a fitting manner, and simultaneously, to form one or more bridge pads which are insulated from the optical element substrate by a horizontal insulating layer, on the optical element substrate. The substrate for an optical device according to a first aspect of the present invention comprises: an optical element substrate which is made of a metal plate and contains a plurality of optical elements therein; a pair of electrode substrates which are made of an insulating material to form a conductive layer on at least a portion of the upper surface thereof, are connected to both side surfaces of the optical element substrate, respectively, and are wire-bonded to the electrodes of the optical elements; and a fitting means which is formed on the side surfaces of the electrode substrate and the optical element substrate to fit the optical element substrate and the electrode substrate. The substrate for an optical device according to a second aspect of the present invention comprises: an optical element substrate which is made of a metal plate and contains a plurality of optical elements therein; a pair of electrode substrates which are made of a metal material to be connected to both side surfaces of the optical element substrate, respectively, and are wire-bonded to the electrodes of the optical elements; a fitting means which is formed on the side surfaces of the electrode substrate and the optical element substrate to fit the optical element substrate and the electrode substrate; and a fitting-type vertical insulating layer which is interposed between the optical element substrate and the electrode substrate so as to be connected to the fitting means.

A semiconductor device includes a case enclosing a region where a semiconductor element as a component of an electric circuit exists. A resin part is fixed to an inside of the case in contact with the region. The resin part is provided with a conductive film, which is a part of the electric circuit. The conductive film is provided in the resin part so that the conductive film comes into contact with the region.

An apparatus includes a package, a wall and a lid. The package may be configured to mount two chips configured to generate one or more signals in a millimeter-wave frequency range. The wall may be formed between the two chips. The wall generally has a plurality of conductive arches that attenuate an electromagnetic coupling between the two chips in the millimeter-wave frequency range. The lid may be configured to enclose the chips to form a cavity.

Semiconductor devices including structures for thermal management, and associated systems and methods, are described herein. In some embodiments, a semiconductor device includes a first die assembly including a semiconductor substrate and a plurality of active circuit elements at a first surface of the semiconductor substrate. The device also includes a second die assembly including a carrier substrate and a redistribution structure on or over a first surface of the carrier substrate. The device further includes a thermal buffer structure between the first and second die assemblies, the thermal buffer structure being coupled to a second surface of the semiconductor substrate and a second surface of the carrier substrate. The device also includes a plurality of interconnections extending through at least the semiconductor substrate, the carrier substrate, and the thermal buffer structure to electrically couple the active circuit elements to the redistribution structure.

According to an aspect, a power module package includes a plurality of power modules including a first power module and a second power module, a plurality of heat sinks including a first heat sink coupled to the first power module and a second heat sink coupled to the second power module, and a module carrier coupled to the plurality of power modules, where the module carrier includes a first region defining a first heat-sink slot and a second region defining a second heat-sink slot. The first heat sink extends at least partially through the first heat-sink slot and the second heat sink extends at least partially through the second heat-sink slot. The power module package includes a housing coupled to the module carrier and a ring member located between the module carrier and the housing.

An inverter for an electric motor or generator having a first device and a second device mounted on an element. The first device includes a first switch, a first contact arranged to be coupled to a first terminal of a power source, and a second contact. The second device includes a second switch, a third contact arranged to be coupled to a second terminal of a power source, and a fourth contact. The first device and the second device are mounted on the element such that a portion of the first contact of the first device that is arranged to be coupled to the first terminal of a power source and a portion of the third contact of the second device that is arranged to be coupled to second terminal of a power source are located adjacent to each other on a first region of the element and the second contact of the first device and the fourth contact of the second device are arranged to be coupled to a coil winding of the electric motor or generator.

A semiconductor packaging structure includes a copper heat-sink with a shim projection which provides a stress release structure. The heat-sink with the shim projection may be used in conjunction with a pedestal in order to further reduce the thermal stress produced from the mismatch of thermal properties between the copper heat-sink metal and the ceramic frame. The copper heat-sink with a shim projection may also be part of the semiconductor package along with a lead frame, the ceramic frame, a semiconductor device, a capacitor, a wire bond and a ceramic lid or an encapsulation. The copper heat-sink, the ceramic frame and the lead frame are all chosen to be cost effective, and chosen such that the packaging process for the semiconductor device is able to achieve a smaller size while maintaining high reliability, low cost, and suitability for volume manufacturing.