A semiconductor device includes a semiconductor die having a main surface, a rear surface, outer edge sides extending between the main and rear surfaces, and a first conductive bond pad disposed on the main surface, an electrically insulating mold compound body formed around the outer edge sides of the semiconductor die with the main surface of the semiconductor die exposed from an upper surface of the mold compound body, a first metallization layer formed on the upper surface of the mold compound body and on the main surface of the semiconductor die, and a first bond pad extension formed in the first metallization layer. The first bond pad extension overlaps with the upper surface of the mold compound body. The first bond pad extension is conductively connected with the first conductive bond pad. The first bond pad extension is an externally accessible point of electrical contact of the device.

A semiconductor device includes a semiconductor die having a main surface, a rear surface, outer edge sides extending between the main and rear surfaces, and a first conductive bond pad disposed on the main surface, an electrically insulating mold compound body formed around the outer edge sides of the semiconductor die with the main surface of the semiconductor die exposed from an upper surface of the mold compound body, a first metallization layer formed on the upper surface of the mold compound body and on the main surface of the semiconductor die, and a first bond pad extension formed in the first metallization layer. The first bond pad extension overlaps with the upper surface of the mold compound body. The first bond pad extension is conductively connected with the first conductive bond pad. The first bond pad extension is an externally accessible point of electrical contact of the device.

The present application relates to a light emitting diode, a light emitting device, and a display device. The light emitting device includes a light emitting diode and a substrate; the substrate is coated with a bonding substance; the light emitting diode is provided with a positive electrode pad and a negative electrode pad; the surface of the positive electrode pad and/or the negative electrode pad is provided with a plurality of protrusions which are embedded in the bonding substance; and the positive electrode pads and the negative electrode pads are fixed to the substrate through the bonding substance. The embodiment of the present application provides projections on the pad of the light emitting diode, avoids the need of increasing the area of the pad, increases the contact area between the pad and the solder with the constant pad area, improves the bonding stability between the light emitting diode and the substrate, and reduces the production cost.

A semiconductor chip package includes a substrate; a semiconductor die mounted on the substrate, wherein the semiconductor die comprises a bond pad disposed on an active surface of the semiconductor die, and a passivation layer covering perimeter of the bond pad, wherein a bond pad opening in the passivation layer exposes a central area of the bond pad; a conductive paste post printed on the exposed central area of the bond pad; and a bonding wire secured to a top surface of the conductive paste post. The conductive paste post comprises copper paste.

A semiconductor chip package includes a substrate; a semiconductor die mounted on the substrate, wherein the semiconductor die comprises a bond pad disposed on an active surface of the semiconductor die, and a passivation layer covering perimeter of the bond pad, wherein a bond pad opening in the passivation layer exposes a central area of the bond pad; a conductive paste post printed on the exposed central area of the bond pad; and a bonding wire secured to a top surface of the conductive paste post. The conductive paste post comprises copper paste.

A method of making a semiconductor device may include providing a carrier comprising a semiconductor die mounting site. A build-up interconnect structure may be formed over the carrier. A first portion of a conductive interconnect may be formed over the build-up interconnect structure in a periphery of the semiconductor die mounting site. An etch stop layer and a second portion of the conductive interconnect may be formed over the first portion of the conductive interconnect. A semiconductor die may be mounted to the build-up interconnect at the semiconductor die mounting site. The conductive interconnect and the semiconductor die may be encapsulated with a mold compound. A first end of the conductive interconnect on the second portion of the conductive interconnect may be exposed. The carrier may be removed to expose the build-up interconnect structure. The first portion of the conductive interconnect may be etched to expose the etch stop layer.

Apparatus(es) and method(s) relate generally to via arrays on a substrate. In one such apparatus, the substrate has a conductive layer. First plated conductors are in a first region extending from a surface of the conductive layer. Second plated conductors are in a second region extending from the surface of the conductive layer. The first plated conductors and the second plated conductors are external to the first substrate. The first region is disposed at least partially within the second region. The first plated conductors are of a first height. The second plated conductors are of a second height greater than the first height. A second substrate is coupled to first ends of the first plated conductors. The second substrate has at least one electronic component coupled thereto. A die is coupled to second ends of the second plated conductors. The die is located over the at least one electronic component.

Apparatus(es) and method(s) relate generally to via arrays on a substrate. In one such apparatus, the substrate has a conductive layer. First plated conductors are in a first region extending from a surface of the conductive layer. Second plated conductors are in a second region extending from the surface of the conductive layer. The first plated conductors and the second plated conductors are external to the first substrate. The first region is disposed at least partially within the second region. The first plated conductors are of a first height. The second plated conductors are of a second height greater than the first height. A second substrate is coupled to first ends of the first plated conductors. The second substrate has at least one electronic component coupled thereto. A die is coupled to second ends of the second plated conductors. The die is located over the at least one electronic component.

A semiconductor device includes an electronic circuit, an interconnection contact such as a solder ball, and a plate configured to concentrate magnetic flux to a predetermined area. The plate is electrically conductive, and it is electrically connected to the electronic circuit.

A semiconductor device includes an electronic circuit, an interconnection contact such as a solder ball, and a plate configured to concentrate magnetic flux to a predetermined area. The plate is electrically conductive, and it is electrically connected to the electronic circuit.