In examples, a semiconductor device comprises a semiconductor die, an opaque mold compound housing covering the semiconductor die, a conductive terminal extending from the mold compound housing, and an insulative coat covering the mold compound housing and at least a portion of the conductive terminal.

The third side surface includes inclined surfaces inclined in a direction in which a center in an up-down direction of the third side surface is convex. The mold resin further includes a residual section provided in the center of the third side surface and a dowel section provided between the inclined surface and the residual section. The dowel section projects further in a lateral direction than the inclined surface. The residual section further projects in the lateral direction than the dowel section and has a fracture surface perpendicular to the up-down direction.

A semiconductor device according to the present disclosure includes: a lead frame having a plurality of die pad portions electrically independent from each other; a power semiconductor element provided on each of the die pad portions; a wire electrically connecting the power semiconductor element and the lead frame; an epoxy-based resin provided on at least a part of the lead frame; and a sealing resin covering at least each of the die pad portions, the power semiconductor element, the wire, and the epoxy-based resin.

Methods of forming a semiconductor device comprising a lead-frame having a die pad having at least one electrically conductive die pad area and an insulating layer applied onto the electrically conductive die pad area. An electrically conductive layer is applied onto the insulating layer with one or more semiconductor dice coupled, for instance adhesively, to the electrically conductive layer. The electrically conductive die pad area, the electrically conductive layer and the insulating layer sandwiched therebetween form at least one capacitor integrated in the device. The electrically conductive die pad area comprises a sculptured structure with valleys and peaks therein; the electrically conductive layer comprises electrically conductive filling material extending into the valleys in the sculptured structure of the electrically conductive die pad area.

A polyamideimide resin containing a structural unit (Ia) represented by a formula shown below, and a structural unit (IIa) represented by a formula shown below. In the formula (Ia), each X independently represents a hydrogen atom, or at least one substituent selected from the group consisting of halogen atoms, alkyl groups of 1 to 9 carbon, atoms, and alkoxy groups and hydroxyalkyl groups of 1 to 9 carbon atoms. In the formula (IIa), each R independently represents a hydrogen atom, or at least one substituent selected from the group consisting of alkyl groups of 1 to 9 carbon atoms, alkoxy groups of 1 to 9 carbon atoms and halogen atoms, and n represents an integer of 1 to 6.

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In a described example, an apparatus includes: a package substrate having a die pad configured for mounting a semiconductor die, a first lead connected to the die pad, and a second lead spaced from and electrically isolated from the die pad; a spacer dielectric mounted on the die pad; a semiconductor die including a temperature sensor mounted on the spacer dielectric; electrical connections coupling the semiconductor die to the second lead; and mold compound covering the semiconductor die, the die pad, the electrical connections, and a portion of the package substrate, with portions of the first lead and portions of the second lead exposed from the mold compound to form terminals for a packaged temperature sensor device.

Manufacturing a semiconductor device, such as an integrated circuit, comprises: providing a leadframe having a die pad area, attaching onto the die pad area of the leadframe one or more semiconductor die or dice via soft-solder die attach material, and forming a device package by molding package material onto the semiconductor die or dice attached onto the die pad area of the leadframe. An enhancing layer, provided onto the leadframe to counter device package delamination, is selectively removed via laser beam ablation from the die pad area, and the semiconductor die or dice are attached onto the die pad area via soft-solder die attach material provided where the enhancing layer has been removed to promote wettability by the soft-solder material.

A semiconductor device includes at least one semiconductor element having a switching function; a conductive member that forms a path of a current switched by the semiconductor element, and that is made of a first material; and a covering layer that covers at least a portion of the conductive member, and that is made of a second material. The second material satisfies at least one of the following three requirements: (a) having a magnetic permeability higher than the first material; (b) having an electrical resistivity higher than the first material; and (c) having a dielectric loss tangent larger than zero.

A waterproof electronic device includes: an electronic component module having an electronic component including a semiconductor element, a heat dissipating member provided on the electronic component in a thermally conductive manner, and an insulating material that surrounds the electronic component in such a manner that one surface of the heat dissipating member is exposed; and a waterproof film that is formed at least on whole surfaces in regions of the electronic component module that are to be immersed in a coolant.

A lead frame structure of a light emitting diode includes a ceramic bed, a metal layer and a plastic seat. The metal layer has a first metal circuit area, a second metal circuit area, a gap dividing the first metal circuit area and the second metal circuit area, and a metal ring surrounding the first metal circuit area, the second metal circuit area and the gap. The plastic seat has a hollow function area. The first metal circuit area, the second metal circuit area and a part of the metal ring expose the function area to make the metal (circuit) layer of the function area has no gap to avoid excess glue. This can efficiently accomplish to increase intensity, quality and reliability of the packaged products.