A semiconductor package includes: an electrically insulating core and an electrically conductive first via extending through a periphery region of the core, the core having glass fibres interwoven with epoxy material and one or more regions where the glass fibres are exposed from the epoxy material; a power semiconductor die embedded in an opening in the core and having a first load terminal bond pad which faces a same direction as a first side of the core, a second load terminal bond pad which faces a same direction as a second side of the core, and a control terminal bond pad; a resin that encases the power semiconductor die; a first contact pad plated on the first via at the second side of the core; and a second contact pad plated on the first load terminal bond pad of the power semiconductor die at the first side of the core.

A three-dimensional (3D) integrated circuit (IC) includes a first die. The first die includes a 3D stacked capacitor on a first surface of the first die and coupled to a power distribution network (PDN) of the first die. The 3D IC also includes a second die stacked on the first surface of the first die, proximate the 3D stacked capacitor on the first surface of the first die. The 3D IC further includes active circuitry coupled to the 3D stacked capacitor through the PDN of the first die.

Described is a packaged component having a first surface and an opposite second surface. The packaged component may comprise a first element a second element, and a third element. The first element may have a first surface and an opposite second surface. The second element may have a first surface and an opposite second surface. The third element may electrically connect a portion of the first element to a portion of the second element. The second surface of the first element may be adjacent to the second surface of the packaged component, and the second surface of the second element may be adjacent to the second surface of the packaged component.

Provided are a system on chip (SoC) having a three-dimensional (3D) chiplet structure, and an electronic device including the SoC. The electronic device includes a printed circuit board, the SoC on the printed circuit board, and a memory device on the SoC, wherein the SoC includes an SoC package substrate, a first die arranged on the SoC package substrate, and having a logic circuit thereon, and a second die arranged on the first die, and having a logic circuit thereon.

A method of manufacturing a semiconductor device includes arranging a mask on a support. The mask includes a first area and a second area. A substrate is arranged on the mask. The substrate has a mounting area and a non-mounting area. A solder paste is applied on the mounting area of the substrate. After applying the solder paste, at least one electronic device is arranged on the mounting area. A light soldering process is performed by emitting light on the substrate from a light source above the substrate. The first area of the mask is positioned under the non-mounting area and the second area of the mask is positioned under the mounting area.

A semiconductor device includes an inductance structure and a shielding structure. The shielding structure is arranged to at least partially shield the inductance structure from external electromagnetic fields. The shielding structure includes a shielding structure portion arranged along a side of the inductance structure such that the shielding structure portion is around at least a portion of a perimeter of the inductance structure.

The embodiments herein relate to packages of semiconductor devices having a shielding element and methods of forming the same. An assembly is provided. The assembly includes a semiconductor chip having a passive component and a package within which the semiconductor chip is positioned in. The package includes a shielding element and a package conductive component, and the package conductive component is electrically coupled with the passive component of the semiconductor chip.

An electronic package in which at least one magnetically permeable member is disposed between a carrier and an electronic component, where the electronic component has a first conductive layer, and the carrier has a second conductive layer, such that the magnetically permeable element is located between the first conductive layer and the second conductive layer. Moreover, a plurality of conductive bumps that electrically connect the first conductive layer and the second conductive layer are arranged between the electronic component and the carrier to surround the magnetically permeable member for generating magnetic flux.

One or more chip-embedded integrated voltage regulators (“CEIVR's”) are configured to provide power to a circuit or chip such as a CPU or GPU and meet power delivery specifications. The CEIVR's, circuit or chip, and power delivery pathways can be included within the same package. The CEIVR's can be separate from the circuit or chip.

Improve EM coupling for the wafer-bonding process from a first wafer to a second wafer by a shielding technique. Examples may include building an EM shield implemented by BEOL-stacks/routings, bonding contacts, and TSVs for a closed-loop shielding platform for the integrated device to minimize EM interference from active devices due to eddy currents. The shield may be implemented in the active device layer during a wafer-to-wafer bonding-process that uses two different device layers/wafers, an active device layer/wafer and a passive device layer/wayer. The shield may be designed by the patterned routings for both I/O ports and the GND contacts.