One aspect relates to a method of manufacture of an electronic assembly comprising at least these steps: providing a substrate having at least a first contact area; positioning a spot of a UV curable substance on the substrate; positioning an electrically conductive item on the substrate wherein the electrically conductive item is superimposed on the first contact area and on the spot of curable substance; exposing the UV curable substance to UV irradiation, wherein a mechanical connection between the electrically conductive item and substrate is formed; and optionally connecting the first contact area with the electrically conductive item. One aspect relates to an electronic assembly comprising a substrate with a contact area, a spot of a cured substance on the substrate and an electrically conductive item that is in electrically conductive connection with the first contact area and mechanically connected through the spot of cured substance to the substrate.

A system includes a substrate; a bond pad; a wire spanning above the substrate, having a first end bonded to the bond pad and a second end extending from the bond pad to terminate in a second end thereof; and a support structure disposed on the substrate, the support structure comprising at least a side wall and extending from the substrate to terminate in an end portion spaced from the substrate to support the wire.

A semiconductor device includes a shielding wire formed across a semiconductor die and an auxiliary wire supporting the shielding wire, thereby reducing the size of a package while shielding the electromagnetic interference generated from the semiconductor die. In one embodiment, the semiconductor device includes a substrate having at least one circuit device mounted thereon, a semiconductor die spaced apart from the circuit device and mounted on the substrate, a shielding wire spaced apart from the semiconductor die and formed across the semiconductor die, and an auxiliary wire supporting the shielding wire under the shielding wire and formed to be perpendicular to the shielding wire. In another embodiment, a bump structure is used to support the shielding wire. In a further embodiment, an auxiliary wire includes a bump structure portion and wire portion and both the bump structure portion and the wire portion are used to support the shielding wire.

A semiconductor device includes a shielding wire formed across a semiconductor die and an auxiliary wire supporting the shielding wire, thereby reducing the size of a package while shielding the electromagnetic interference generated from the semiconductor die. In one embodiment, the semiconductor device includes a substrate having at least one circuit device mounted thereon, a semiconductor die spaced apart from the circuit device and mounted on the substrate, a shielding wire spaced apart from the semiconductor die and formed across the semiconductor die, and an auxiliary wire supporting the shielding wire under the shielding wire and formed to be perpendicular to the shielding wire. In another embodiment, a bump structure is used to support the shielding wire. In a further embodiment, an auxiliary wire includes a bump structure portion and wire portion and both the bump structure portion and the wire portion are used to support the shielding wire.

The invention relates to the electrically conductive bond between at least two electrical components and/or devices at a carrier mounted with electronic and/or electrical devices, said bond being formed by a bond wire. The bond wire is bonded in a force fitting, shape matching manner and/or with material continuity to the electrical components and/or devices and is shaped in an arcuate manner between the electrical components and/or devices at a spacing from the surface of the carrier and from electronic and/or electrical devices arranged there. The respective bond wire is bent a multiple of times with changing directions between the electrical components and/or devices such that tips or regions of individual arcs are arranged at different spacings from the surface of the carrier. At least one element formed from or by an electrically conductive material can, however, also be arranged between the surface of the carrier and the arcuate bond wire and the electrically conductive material is arranged at a spacing from the respective bond wire.

A signal block and a double-faced cooling power module that uses the signal block is provided. The signal block includes a plurality of signal clips that are formed in a ribbon shape to connect a first signal pad formed on a semiconductor chip and a second signal pad formed on a signal lead frame. An insulator fixes the position of the plurality of signal clips while spacing the signal clips apart from each other.