An electronic package assembly includes a glass substrate including an upper glass cladding layer, a lower glass cladding layer, a glass core layer coupled to the upper glass cladding layer and the lower glass cladding layer, where the upper glass cladding layer and the lower glass cladding layer have a higher etch rate in an etchant than the glass core layer, a first cavity positioned within one of the upper glass cladding layer or the lower glass cladding layer, and a second cavity positioned within one of the upper glass cladding layer or the lower glass cladding layer, a microprocessor positioned within the first cavity, and a micro-electronic component positioned within the second cavity.

A radio-frequency module includes a multilayer substrate, a first semiconductor device, a second semiconductor device, a first mold layer, and a second mold layer. The multilayer substrate includes a plurality of stacked layers, and has a first major face and a second major face. The first mold layer seals the first semiconductor device. The second mold layer seals the second semiconductor device. The first major face includes a first recess. The first semiconductor device is mounted over a bottom face of the first recess. The second semiconductor device is mounted over the first major face so as to overlie the first recess. The first semiconductor device is connected with a metallic via that extends through a portion of the multilayer substrate from the bottom face of the first recess to the second major face. The first mold layer and the second mold layer are made of different materials.

An embodiment method for forming a semiconductor package includes attaching a first die to a first carrier, depositing a first isolation material around the first die, and after depositing the first isolation material, bonding a second die to the first die. Bonding the second die to the first die includes forming a dielectric-to-dielectric bond. The method further includes removing the first carrier and forming fan-out redistribution layers (RDLs) on an opposing side of the first die as the second die. The fan-out RDLs are electrically connected to the first die and the second die.

A method includes attaching a first-level device die to a dummy die, encapsulating the first-level device die in a first encapsulating material, forming through-vias over and electrically coupled to the first-level device die, attaching a second-level device die over the first-level device die, and encapsulating the through-vias and the second-level device die in a second encapsulating material. Redistribution lines are formed over and electrically coupled to the through-vias and the second-level device die. The dummy die, the first-level device die, the first encapsulating material, the second-level device die, and the second encapsulating material form parts of a composite wafer.

A semiconductor package includes a substrate, a plurality of semiconductor devices stacked on the substrate, an under-fill fillet on side surfaces of the plurality of semiconductor devices, and a molding resin surrounding the plurality of semiconductor devices. An uppermost end of the under-fill fillet includes a planar surface coplanar with an upper surface of a periphery of an uppermost semiconductor device among the plurality of semiconductor devices, and the molding resin completely covers the planar surface.

In accordance with disclosed embodiments, there are provided methods, systems, and apparatuses for implementing reduced height semiconductor packages for mobile electronics. For instance, there is disclosed in accordance with one embodiment a stacked die package having therein a bottom functional silicon die; a recess formed within the bottom functional silicon die by a thinning etch partially reducing a vertical height of the bottom functional silicon die at the recess; and a top component positioned at least partially within the recess formed within the bottom functional silicon die. Other related embodiments are disclosed.

Disclosed is a semiconductor package comprising a package substrate, a first semiconductor chip on the package substrate and including a first region and a second region, a second semiconductor chip on the first region, a heat radiation spacer on the second region, a third semiconductor chip supported by the second semiconductor chip and the heat radiation spacer, and a molding layer covering the first to third semiconductor chips and the heat radiation spacer.

Semiconductor die assemblies having interconnect structures with redundant electrical connectors are disclosed herein. In one embodiment, a semiconductor die assembly includes a first semiconductor die, a second semiconductor die, and an interconnect structure between the first and the second semiconductor dies. The interconnect structure includes a first conductive film coupled to the first semiconductor die and a second conductive film coupled to the second semiconductor die. The interconnect structure further includes a plurality of redundant electrical connectors extending between the first and second conductive films and electrically coupled to one another via the first conductive film.

A semiconductor package includes a first die, a second die, an encapsulant, a first inductor and a second inductor. The second die is stacked on the first die along a first direction. The encapsulant encapsulates the second die over the first die. The first inductor is disposed in the encapsulant and has a first spiral structure, wherein the first spiral structure has a plurality of first coils around a first axis, and the first axis is substantially perpendicular to the first direction. The second inductor is disposed in the encapsulant and having a second spiral structure, wherein the first inductor and the second inductor are disposed at opposite sides of the second die.

A semiconductor package includes a buffer, a chip stack mounted on the buffer, an adhesive layer disposed between the buffer and the chip stack, and a molding material surrounding the chip stack. The buffer includes a plurality of trenches disposed adjacent to a plurality of edges of the buffer. Each of the trenches is shorter than a corresponding adjacent edge of a chip area of the buffer.