Embodiments disclosed herein include electronic packages and methods of assembling an electronic package. In an embodiment, an electronic package comprises a package substrate with a stepped top surface, and a first die on a first plateau of the stepped top surface. In an embodiment, a second die is on a second plateau of the stepped top surface, where the second die extends over the first die, In an embodiment, a third die is on a third plateau of the stepped top surface, where the third die extends over the second die.

Various embodiments disclosed relate to methods of making omni-directional semiconductor interconnect bridges. The present disclosure includes semiconductor assemblies including a mold layer having mold material, a first filler material dispersed in the mold material, and a second filler material dispersed in the mold material, wherein the second filler material is heterogeneously dispersed.

A semiconductor device has a first conductive layer and a semiconductor die disposed adjacent to the first conductive layer. An encapsulant is deposited over the first conductive layer and semiconductor die. An insulating layer is formed over the encapsulant, semiconductor die, and first conductive layer. A second conductive layer is formed over the insulating layer. A first portion of the first conductive layer is electrically connected to V.sub.SS and forms a ground plane. A second portion of the first conductive layer is electrically connected to V.sub.DD and forms a power plane. The first conductive layer, insulating layer, and second conductive layer constitute a decoupling capacitor. A microstrip line including a trace of the second conductive layer is formed over the insulating layer and first conductive layer. The first conductive layer is provided on an embedded dummy die, interconnect unit, or modular PCB unit.

An apparatus is described. The apparatus includes I/O structures having pads and solder balls to couple with a semiconductor chip, wherein, a first subset of pads and/or solder balls of the pads and solder balls that approach the semiconductor chip during coupling of the semiconductor chip to the I/O structures are thinner than a second subset of pads and/or solder balls of the pads and solder balls that move away from the semiconductor chip during the coupling of the semiconductor chip to the I/O structures.

The disclosure concerns methods of forming a semiconductor device with a repairable redistribution layer (RDL) design, comprising: preparing an original repairable RDL design; forming first conductive segments of the repairable RDL design; inspecting the first conductive segments of the repairable RDL design to detect manufacturing defects; detecting at least one defect in the first conductive segments; and forming second conductive segments of the repairable RDL design according to a new custom RDL design to mitigate the negative effects of the at least one defect among the first conductive segments. The disclosure also concerns semiconductor devices with a repairable RDL design.

A device is provided. The device includes a bridge layer over a first substrate. A first connector electrically connecting the bridge layer to the first substrate. A first die is coupled to the bridge layer and the first substrate, and a second die is coupled to the bridge layer.

A routing structure between dies is provided, including a trace layer, disposed on a substrate, wherein a plurality of routing paths is embedded in the trace layer. In addition, a first die and a second die are disposed on the trace layer and connected by the routing paths. A spacing gap between the first die and the second die is along a first direction and interfacing edges of the first die and the second die are extending along a second direction perpendicular to the first direction. Each of the routing paths includes a first straight portion in parallel to connect to the interfacing edges. The first straight portion has a slant angle with respect to the first direction other than 0° and 90°.

There is provided a semiconductor device including: a lead frame including a first opening portion; a resin filled in the first opening portion; and a semiconductor element electrically connected to the lead frame, wherein a side wall surface of the lead frame in the first opening portion has a larger average surface roughness than an upper surface of the lead frame.

An interconnect structure includes a first conductor, a second conductor, a dielectric block, a substrate, and a pair of conductive lines. The first conductor and the second conductor form a differential pair design. The dielectric block surrounds the first conductor and the second conductor. The first conductor is separated from the second conductor by the dielectric block. The substrate surrounds the dielectric block and is spaced apart from the first conductor and the second conductor. The pair of conductive lines is connected to the first conductor and the second conductor, respectively, and extends along a top surface of the dielectric block and a top surface of the substrate.

A structure may include a first material, a second material joined to the first material at a junction between the first and second materials, and one or more media extending across the junction to form a continuous interconnect between the first and second materials, wherein the first and second materials are heterogeneous. The structure may further include a transition at the junction between the first and second materials. The one or more media may include a functional material which may be electrically conductive. The structure may further include a third material joined to the second material at a second junction between the second and third materials, the media may extend across the second junction to form a continuous interconnect between the first, second, and third materials, and the second and third materials may be heterogeneous.