An extension of conventional IC fabrication processes to include some of the concepts of flip-chip assemblies while producing a final “non-flip chip” circuit structure suitable for conventional packaging or for direct usage by customers. Multiple IC dies are fabricated on a semiconductor wafer in a conventional fashion, solder bumped, and singulated. The singulated dies are then flip-chip assembled onto a single tile substrate of thin-film material which has been patterned with vias, peripheral connection pads, and one or more ground planes. Once dies are flip-chip mounted to the thin-film tile, all of the dies on the entire tile may be probed using automated testing equipment. Once test probing is complete, the dies and tile are singulated into die/tile assemblies.

An electronic assembly that includes a substrate having an upper surface and a bridge that includes an upper surface. The bridge is within a cavity in the upper surface of the substrate. A first electronic component is attached to the upper surface of the bridge and the upper surface of the substrate and a second electronic component is attached to the upper surface of the bridge and the upper surface of the substrate, wherein the bridge electrically connects the first electronic component to the second electronic component.

A semiconductor device has a substrate. A conductive layer is formed over the substrate and includes a ground plane. A first tab of the conductive layer extends from the ground plane and less than half-way across a saw street of the substrate. A shape of the first tab can include elliptical, triangular, parallelogram, or rectangular portions, or any combination thereof. An encapsulant is deposited over the substrate. The encapsulant and substrate are singulated through the saw street. An electromagnetic interference (EMI) shielding layer is formed over the encapsulant. The EMI shielding layer contacts the first tab of the conductive layer.

In a described example, an apparatus includes: a first mold compound partially covering a thermal pad that extends through a pre-molded package substrate formed of a first mold compound, a portion of the thermal pad exposed on a die side surface of the pre-molded package substrate, the pre-molded package substrate having a recess on the die side surface, with an exposed portion of the thermal pad and a portion of the first mold compound in a die mounting area in the recess; a semiconductor die mounted to the thermal pad and another semiconductor die mounted to the mold compound in the die mounting area; wire bonds coupling bond pads on the semiconductor dies to traces on the pre-molded package substrate; and a second mold compound over the die side surface of the pre-molded package substrate and covering the wire bonds, the semiconductor dies, the recess, and a portion of the traces.

Provided are a wafer level package and a method of manufacturing the same, wherein an underfill sufficiently fills a space between a redistribution substrate and a semiconductor chip, thereby reducing warpage. The wafer level package includes a redistribution substrate including at least one redistribution layer (RDL), a semiconductor chip on the redistribution substrate, and an underfill filling a space between the redistribution substrate and the semiconductor chip. The underfill covers side surfaces of the semiconductor chip. The redistribution substrate includes a trench having a line shape and extending in a first direction along a first side surface of the semiconductor chip.

Implementations of a clip may include a first copper layer directly bonded to a first side of a ceramic layer, a second copper layer directly bonded to a second side of the ceramic layer, the second side of the ceramic layer opposite the first side of the ceramic layer, and a plurality of channels partially etched into a thickness of the second copper layer.

A manufacturing method of a semiconductor package includes locating, on a substrate, a semiconductor device having an external terminal provided on a top surface thereof, forming a resin insulating layer covering the semiconductor device, forming an opening, exposing the external terminal, in the resin insulating layer, performing plasma treatment on a bottom surface of the opening, performing chemical treatment on the bottom surface of the opening after the plasma treatment, and forming a conductive body to be connected with the external terminal exposed in the opening.

A circuit module includes a wiring substrate having a mount surface, a conductor pattern, and an insulating protective layer, the mount surface having first and second areas, the conductor pattern being formed along a boundary between the first and second areas on the mount surface, the insulating protective layer being formed on the mount surface, the insulating protective layer covering the mount surface and the conductor pattern; a plurality of electronic components mounted on the first and second areas; an insulating sealing layer having a trench, the insulating sealing layer covering the plurality of electronic components, the trench having a depth such that the trench penetrates the protective layer to reach a surface of the conductive pattern; and a conductive shield having first and second shield portions, the first shield portion covering an outer surface of the sealing layer, the second shield portion being electrically connected to the conductor pattern.

The present disclosure is related to electronic modules for electronic components and methods for manufacturing the same. In one embodiment, an electronic module is formed using a first substrate having a first component area and a second substrate having a second component area. One or more electronic components may be attached to both the first component area and the second component area. The second substrate is mounted over the first substrate such that the second component area faces the first component area. An overmold covers the first component area and the second component area so as to cover the electronic components on both the first component area and the second component area. In this manner, the number of electronic components within the electronic module that can be mounted on an area of a printed circuit board (PCB) is increased.

A chip package structure includes a substrate, a first chip, a second chip, a bridge, a plurality of first bumps, a plurality of second bumps, a plurality of third bumps and a plurality of solder balls. A first active surface of the first chip and a second active surface of the second chip face a first surface of the substrate. The bridge includes a high-molecular polymer layer and a pad layer located on the high-molecular polymer layer. The first chip is electrically connected to the substrate through the first bumps. The second chip is electrically connected to the substrate through the second bumps. The first chip and the second chip are electrically connected to the pad layer through the third bumps. The first bumps and the second bumps have the same size. The solder balls are disposed on a second surface of the substrate and electrically connected to the substrate.