A semiconductor device may include an embedded device comprising through silicon vias (TSVs) extending from a first surface to a second surface opposite the first surface, wherein the embedded device comprises an active device, a semiconductor die comprising an active surface formed at the first surface, an integrated passive device (IPD), or a passive device. Encapsulant may be disposed over at least five sides of the embedded device. A first electrical interconnect structure may be coupled to a first end of the TSV at the first surface of the embedded device, and a second electrical interconnect structure may be coupled to a second end of the TSV at the second surface of the embedded device. A semiconductor die (e.g. a system on chip (SoC), memory device, microprocessor, graphics processor, or analog device), may be mounted over the first electrical interconnect of the TSV.

Various embodiments of an integrated circuit package and a method of forming such package are disclosed. The package includes a substrate having a core layer disposed between a first dielectric layer and a second dielectric layer, a die disposed in a cavity of the core layer, and an encapsulant disposed in the cavity between the die and a sidewall of the cavity. The package further includes a first patterned conductive layer disposed within the first dielectric layer, a device disposed on an outer surface of the first dielectric layer such that the first patterned conductive layer is between the device and the core layer, a second patterned conductive layer disposed within the second dielectric layer, and a conductive pad disposed on an outer surface of the second dielectric layer such that the second patterned conductive layer is between the conductive pad and the core layer.

A package structure includes a semiconductor die, an insulating encapsulant, a first redistribution layer, a second redistribution layer, antenna elements and a first insulating film. The insulating encapsulant is encapsulating the at least one semiconductor die, the insulating encapsulant has a first surface and a second surface opposite to the first surface. The first redistribution layer is disposed on the first surface of the insulating encapsulant. The second redistribution layer is disposed on the second surface of the insulating encapsulant. The antenna elements are located over the second redistribution layer. The first insulating film is disposed in between the second redistribution layer and the antenna elements, wherein the first insulating film comprises a resin rich region and a filler rich region, the resin rich region is located in between the filler rich region and the second redistribution layer and separating the filler rich region from the second redistribution layer.

A semiconductor packaging structure manufactured in a manner which does not leave the chip damaged or susceptible to damage upon the removal of temporary manufacturing supports includes at least one electrical conductor, at least one conductive layer, a chip, and a colloid. The chip is spaced from the conductive layer, the electrical conductor is disposed between the conductive layer and the chip and electrically connects the conductive layer to the chip. The colloid covers all outer surfaces of the chip. A method of fabricating such a semiconductor packaging structure is also provided.

A package structure and a formation method of a package structure are provided. The method includes forming a conductive structure over a carrier substrate. The conductive structure has a lower portion and an upper portion, and the upper portion is wider than the lower portion. The method also includes disposing a semiconductor die over the carrier substrate. The method further includes forming a protective layer to surround the conductive structure and the semiconductor die. In addition, the method includes forming a conductive bump over the conductive structure. The lower portion of the conductive structure is between the conductive bump and the upper portion of the conductive structure.

A semiconductor package includes a semiconductor chip; a redistribution insulating layer including a first opening; an external connection bump including a first part in the first opening; a lower bump pad including a first surface in physical contact with the first part of the external connection bump and a second surface opposite to the first surface, wherein the first surface and the redistribution insulating layer partially overlap; and a redistribution pattern that electrically connects the lower bump pad to the semiconductor chip.

A patch structure of an integrated circuit package comprises a core having a first side facing downwards and a second side facing upwards. A first solder resist (SR) layer is formed on the first side of the core, wherein the first SR layer comprises a first layer interconnect (FLI) and has a first set of one or more microbumps thereon to bond to one or more logic die. A second solder resist (SR) layer is formed on the second side of the core, wherein the second SR layer has a second set of one or more microbumps thereon to bond with a substrate. One or more bridge dies includes a respective sets of bumps, wherein the one or more bridge dies is disposed flipped over within the core such that the respective sets of bumps face downward and connect to the first set of one or more microbumps in the FLI.

Disclosed are a system-on-chip integrated packaging structure, a manufacturing method therefor and a three-dimensional stacked device. The system-on-chip integrated packaging structure includes: a substrate, a chip, a first electrical connection structure and a second electrical connection structure. A front surface of the substrate is provided with a recess and a via welding pad, and a back surface of the substrate is provided with a conductive via extending to the via welding pad. The chip is embedded in the recess, and a chip welding pad is disposed on a surface of the chip away from a bottom surface of the recess. Different chips may be electrically connected by means of the first electrical connection structure and the second electrical connection structure, which is conducive to form a three-dimensional stacked structure with high-density interconnection, miniaturized packaging and thinning.

The present disclosure relates to a radio frequency (RF) device that includes a mold device die and a multilayer redistribution structure underneath the mold device die. The mold device die includes a device region with a back-end-of-line (BEOL) portion and a front-end-of-line (FEOL) portion over the BEOL portion, and a first mold compound. The FEOL portion includes an active layer, a contact layer, and isolation sections. Herein, the active layer and the isolation sections reside over the contact layer, and the active layer is surrounded by the isolation sections. The first mold compound resides over the active layer without silicon crystal, which has no germanium content, in between. The multilayer redistribution structure includes redistribution interconnections and a number of bump structures that are at bottom of the multilayer redistribution structure and electrically coupled to the mold device die via the redistribution interconnections.

A method includes forming an interconnect component including a plurality of dielectric layers that include an organic dielectric material, and a plurality of redistribution lines extending into the plurality of dielectric layers. The method further includes bonding a first package component and a second package component to the interconnect component, encapsulating the first package component and the second package component in an encapsulant, and precutting the interconnect component using a blade to form a trench. The trench penetrates through the interconnect component, and partially extends into the encapsulant. The method further includes performing a singulation process to separate the first package component and the second package component into a first package and a second package, respectively.