Disclosed herein is a multi-die device, and an integrated chip package assembly having the multi-die device. The multi-die device includes a first IC die and a second IC die disposed at a same tier; a first conductive pillar coupled with the first IC die; a second conductive pillar coupled with the second IC die; and an interconnecting die disposed between the first conductive pillar and the second conductive pillar and configured to couple with the first IC die and the second IC die. The multi-die device further includes a first interconnecting interface disposed on the first IC die; a second interconnecting interface disposed on the second IC die, the first interconnecting interface and the second interconnecting interface being separated by a molding material.

A semiconductor device has a substrate. A semiconductor die is disposed over the substrate. A first encapsulant is deposited over the semiconductor die. A ferromagnetic film is disposed over the first encapsulant. A second encapsulant is deposited over the ferromagnetic film. A shielding layer is optionally formed over the substrate, first encapsulant, and second encapsulant.

A semiconductor device has a first RDL substrate with first conductive pillars formed over a first surface of the first RDL substrate. A first electrical component is disposed over the first surface of the first RDL substrate. A hybrid substrate is bonded to the first RDL substrate. An encapsulant is deposited around the hybrid substrate and first RDL substrate with the first conductive pillars and first electrical component embedded within the encapsulant. A second RDL substrate with second conductive pillars formed over the second RDL substrate and second electrical component disposed over the second RDL substrate can be bonded to the hybrid substrate. A second RDL can be formed over a second surface of the first RDL substrate. A third electrical component is disposed over a second surface of the first RDL substrate. A shielding frame is disposed over the third electrical component.

A microelectronic device is formed to include an embedded die substrate on an interposer; where the embedded die substrate is formed with no more than a single layer of transverse routing traces. In the device, all additional routing may be allocated to the interposer to which the embedded die substrate is attached. The embedded die substrate may be formed with a planarized dielectric formed over an initial metallization layer supporting the embedded die.

A method for fabricating a semiconductor wafer may etch a surface of a silicon substrate to form a first cavity and a second cavity. The method may apply a first dielectric layer to the surface of the silicon substrate, the first cavity, and the second cavity. The method may affix a first die into the first cavity of the silicon substrate. The method may affix a second die into the second cavity of the silicon substrate. The method may apply a second dielectric layer to the surface of the silicon substrate, an exposed surface of the first die, and an exposed surface of the second die. The method may form a redistribution layer over the second dielectric layer, where the redistribution layer is configured to electrically couple the first die to the second die.

A package structure is provided. The package structure includes a redistribution structure, and the redistribution structure has multiple insulating layers and multiple conductive features. The package structure also includes a semiconductor die and a device element over opposite surfaces of the redistribution structure. The package structure further includes a first protective layer at least partially surrounding the semiconductor die. In addition, the package structure includes a second protective layer at least partially surrounding the device element. The second protective layer is thicker than the first protective layer, and the second protective layer and the first protective layer have different coefficients of thermal expansion.

Semiconductor devices and methods of forming the semiconductor devices are described herein that are directed towards the formation of a system on integrated substrate (SoIS) package. The SoIS package includes an integrated fan out structure and a device redistribution structure for external connection to a plurality of semiconductor devices. The integrated fan out structure includes a plurality of local interconnect devices that electrically couple two of the semiconductor devices together. In some cases, the local interconnect device may be a silicon bus, a local silicon interconnect, an integrated passive device, an integrated voltage regulator, or the like. The integrated fan out structure may be fabricated in wafer or panel form and then singulated into multiple integrated fan out structures. The SoIS package may also include an interposer connected to the integrated fan out structure for external connection to the SoIS package.

A semiconductor device package comprises a semiconductor device, a first encapsulant surrounding the semiconductor device, a second encapsulant covering the semiconductor device and the first encapsulant, and a redistribution layer extending through the second encapsulant and electrically connected to the semiconductor device.

A semiconductor assembly includes a device carrier that includes a dielectric core region and a plurality of contact pads disposed on an upper surface, a semiconductor device package having a plurality of lower surface terminals, a discrete passive element comprising a main body and a pair of leads, and a region of gap filler material, wherein the semiconductor device package is mounted on the device carrier with the lower surface terminals facing and electrically connected to a group of the contact pads, wherein the discrete passive element is mounted on the device carrier with the pair of leads electrically connecting with contact surfaces on the device carrier, and wherein the region of gap filler material is arranged between a lower surface of the main body and the upper surface of the semiconductor device package and thermally couples the semiconductor device package to the discrete passive element.

This application discloses a chip packaging structure, an electronic device, and a preparation method. The packaging structure includes: a first redistribution layer, chip wafers, a second redistribution layer, and a packaging layer. The first redistribution layer and the second redistribution layer are electrically connected to each other. The packaging layer is sandwiched between the first redistribution layer and the second redistribution layer. At least two stacked chip wafers are embedded in the packaging layer. Any two adjacent chip wafers are electrically connected to each other, and any of the chip wafers is electrically connected to at least one of the first redistribution layer and the second redistribution layer.