According to a first aspect of the present disclosure, a semiconductor device is provided. The semiconductor device includes a first transistor, a second transistor, at least one source terminal, at least one gate terminal, at least one drain terminal, a source wire, a gate wire, a drain wire and a support part. The support part includes two first support-part edges and two second support-part edges. Each of the two first support-part edges is parallel to a first direction, and the two first support-part edges are spaced apart from each other in a second direction that is perpendicular to the first direction. Each of the two second support-part edges is physically connected to the two first support-part edges. The source wire, the gate wire and the drain wire cross at least one of the two second support-part edges in plan view.

A power module includes a mount layer, a control layer, and a drive layer that are formed on an electrically insulative substrate and multiple power semiconductor elements mounted on the mount layer in one direction and each including a first drive electrode connected to the mount layer, a second drive electrode connected to the drive layer, and a control electrode connected to the control layer. A control terminal is connected to the control layer and a detection terminal is connected to the drive layer. At least one of the control layer and the drive layer includes a detour portion that detours to reduce a difference between the power semiconductor elements in a sum of a length of a first conductive path between the control electrode and the control terminal and a length of a second conductive path between the second drive electrode and the detection terminal.

A semiconductor arrangement includes a substrate, a semiconductor element connected to the substrate and including on a side remote from the substrate a contact surface which is connected to the substrate via a first bond connecting means such that as to form on the contact surface a stitch contact arranged between a first loop and a second loop of the first bond connecting means. The first loop has a first maximum and the second loop has a second maximum. A second bond connecting means has a first transverse arranged to run above the first stitch contact and, viewed running parallel to the contact surface, between the first maximum of the first loop and the second maximum of the second loop. The first transverse loop of the second bond connecting means is arranged to run below the first maximum of the first loop and/or the second maximum of the second loop.

A semiconductor device includes an insulating substrate, wiring layers, heat dissipation layers, a semiconductor element, and a sealing resin. The wiring layers each have a first obverse face and a first reverse face oriented in opposite directions in a thickness direction of the substrate. The first reverse faces of the wiring layers are connected to the substrate. The heat dissipation layers each have a second obverse face oriented in the same direction as the first obverse face, and a second reverse face oriented opposite to the second obverse face in the thickness direction. The heat dissipation layers are located opposite to the plurality of wiring layers in the thickness direction with respect to the substrate. The second obverse faces of the heat dissipation layers are connected to the substrate. The semiconductor element is connected to one of the first obverse faces of the wiring layers. The sealing resin covers the substrate, the wiring layers, and the semiconductor element. As viewed in the thickness direction, the wiring layers overlap with the heat dissipation layers, respectively.

A semiconductor device provided according to an aspect of the present disclosure includes a semiconductor element, a bonding target, a first wire, a wire strip and a second wire. The bonding target is electrically connected to the semiconductor element. The first wire is made of a first metal. The first wire includes a first bonding portion bonded to the bonding target and a first line portion extending from the first bonding portion. The wire strip is made of the first metal. The wire strip is bonded to the bonding target. The second wire is made of a second metal different from the first metal. The second wire includes a second bonding portion bonded to the bonding target via the wire strip and a second line portion extending from the second bonding portion.

It is an object of the present invention to provide a semiconductor device which allows an increase in the number of semiconductor elements mounted in parallel and prevents a shape of an insulating substrate onto which the semiconductor elements are mounted, from being laterally long, and provide a semiconductor module including such semiconductor device. A semiconductor device according to the present invention includes an insulating substrate, a metal pattern which is a continuous piece and is bonded to one main surface of the insulating substrate, and a plurality of switching elements which are bonded to a surface opposite to the insulating substrate on the metal pattern, and the plurality of switching elements are arranged in a matrix of two or more rows and two or more columns on the metal pattern.

A bidirectional switch module includes a plurality of bidirectional switches and a mount board. Each of the plurality of bidirectional switches includes a first source electrode, a first gate electrode, a second gate electrode, and a second source electrode. On the mount board, the plurality of bidirectional switches are mounted. In the bidirectional switch module, the plurality of bidirectional switches are connected in parallel.

Methods of manufacturing semiconductor packages. Implementations may include: providing a substrate with a first side, a second side, and a thickness; forming a plurality of pads on the first side of the substrate; and applying die attach material to the plurality of pads. The method may include bonding a wafer including a plurality of semiconductor die to the substrate at one or more die pads included in each die. The method may also include singulating the plurality of semiconductor die, overmolding the plurality of semiconductor die and the first side of the substrate with an overmold material, and removing the substrate to expose the plurality of pads and to form a plurality of semiconductor packages coupled together through the overmold material. The method also may include singulating the plurality of semiconductor packages to separate them.

A method for bonding a hermetic module to an electrode array including the steps of: providing the electrode array having a flexible substrate with a top surface and a bottom surface and including a plurality of pads in the top surface of the substrate; attaching the hermetic module to the bottom surface of the electrode array, the hermetic module having a plurality of bond-pads wherein each bond-pad is adjacent to the bottom surface of the electrode array and aligns with a respective pad; drill holes through each pad to the corresponding bond-pad; filling each hole with biocompatible conductive ink; forming a rivet on the biocompatible conductive ink over each pad; and overmolding the electrode array with a moisture barrier material.

Various embodiments of an integrated circuit module and a method of forming such module are disclosed. The module includes a first die having an active substrate, an integrated circuit disposed on a first major surface of the active substrate, and a cavity disposed in a second major surface of the active substrate. The module also includes a second die having a first major surface, a second major surface, and a conductive pad disposed on the second major surface. The second die is disposed at least partially within the cavity of the first die such that the first major surface of the second die faces the cavity of the first die.