A semiconductor device includes a MOSFET including a PN junction diode. A unipolar device is connected in parallel to the MOSFET and has two terminals. A first wire connects the PN junction diode to one of the two terminals of the unipolar device. A second wire connects the one of the two terminals of the unipolar device to an output line, so that the output line is connected to the MOSFET and the unipolar device via the first wire and the second wire. In one embodiment the connection of the first wire to the diode is with its anode, and in another the connection is with the cathode.

A semiconductor device with improved reliability is provided. The semiconductor device is characterized by its embodiments in that sloped portions are formed on connection parts between a pad and a lead-out wiring portion, respectively. This feature suppresses crack formation in a coating area where a part of the pad is covered with a surface protective film.

A semiconductor device with improved reliability is provided. The semiconductor device is characterized by its embodiments in that sloped portions are formed on connection parts between a pad and a lead-out wiring portion, respectively. This feature suppresses crack formation in a coating area where a part of the pad is covered with a surface protective film.

A semiconductor device includes: a first semiconductor chip mounted on a chip mounting portion via a first bonding material; and a second semiconductor chip mounted on the first semiconductor chip. Here, the first semiconductor chip has: a protective film located in an uppermost layer; and a first pad electrode exposed from the protective film at an inside of a first opening portion of the protective film. Also, the second semiconductor chip is mounted on a conductive material, which is arranged on the first pad electrode of the first semiconductor chip, via a second bonding material of an insulative property.

Provided is a semiconductor structure, configured to form a pad, including a substrate, a top-layer conductive line, N layers of secondary-top-layer conductive lines and a plurality of dielectric layers, N being an integer greater than or equal to 2. The top-layer conductive line and the N layers of the secondary-top-layer conductive lines are arranged above the substrate. The N layers of the secondary-top-layer conductive lines are arranged on a side of the top-layer conductive line close to the substrate. Each of the plurality of dielectric layers is located between two respective adjacent layers of the secondary-top-layer conductive lines in a vertical direction. For the N layers of the secondary-top-layer conductive lines, an area in which projections of any two layers of the secondary-top-layer conductive lines on a top surface of the substrate overlap with each other is less than a first threshold.

A semiconductor device includes a predetermined number of leads, a semiconductor element electrically connected to the leads and supported by one of the leads, and a sealing resin that covers the semiconductor element and a part of each lead. Each lead includes some portions exposed from the sealing resin. A surface plating layer is formed on at least one of the exposed portions of the respective leads.

Provided is a semiconductor package including: at least two pads, a first substrate, at least two semiconductor devices, a second substrate, an electrical connection part, and a package housing, wherein the at least two pads are electrically or structurally separated from each other, the first substrate is formed of leads spaced apart from the pads, the at least two semiconductor devices are bonded on each of the pads, the second substrate is formed on and spaced apart from the upper parts of the semiconductor devices, is placed on and electrically connected to the at least one lead of the first substrate, and includes at least one penetrated opening unit on an area facing the at least one semiconductor device, the electrical connection part electrically connects the at least one semiconductor device with the second substrate, and the package housing covers the semiconductor devices and the electrical connection part. Accordingly, the semiconductor package has a multi die structure and is compact. Also, a shielding performance of electromagnetic interference (EMI) and a heat radiation performance are improved in the semiconductor package.

The present disclosure relates to branched proximal connectors for high density neural interfaces and methods of microfabricating the branched proximal connectors. Particularly, aspects of the present disclosure are directed to a branched connector that includes a main body having a base portion of a supporting structure and a plurality of conductive traces formed on the base portion, and a plurality of plugs extending from the main body. Each plug of the plurality of plugs include an end portion of the supporting structure comprised of the one or more layers of dielectric material, and a subset of conductive traces from the plurality of conductive traces. Each trace from the subset of conductive traces terminates at a bond pad exposed on a surface of the end portion of the supporting structure.

A semiconductor device according to the disclosure includes a first semiconductor chip, a second semiconductor chip, a first metal plate provided on an upper surface of the first semiconductor chip, a second metal plate provided on an upper surface of the second semiconductor chip and a sealing resin covering the first semiconductor chip, the second semiconductor chip, the first metal plate and the second metal plate, wherein a groove is formed in the sealing resin, the groove extending downwards from an upper surface of the sealing resin, the first metal plate includes, at an end facing the second metal plate, a first exposed portion exposed from a side face of the sealing resin forming the groove, and the second metal plate includes, at an end facing the first metal plate, a second exposed portion exposed from a side face of the sealing resin forming the groove.

A packaged electrical device that includes a cured adhesive layer and a cured layer of die attach material coupled between a semiconductor die and a substrate. The packaged electrical device may also include wire bonds coupled between the substrate and leads of the semiconductor die. In addition, the packaged electrical device may be encapsulated in molding compound. A method for fabricating a packaged electrical device. The method includes printing a layer of die attach material over a semiconductor wafer and applying a layer of 2-in-1 die attach film over the layer of die attach material. The method also includes singulating the semiconductor wafer to create a semiconductor die and placing the semiconductor die onto a substrate. In addition the method includes wire bonding the substrate to leads of the semiconductor die and encapsulating the device in molding compound.