A component package includes a printed circuit board; a first electronic component disposed in a first region on the printed circuit board; a second electronic component disposed in a second region on the printed circuit board; and a metal wall disposed on the printed circuit board and spatially partitioning the first region and the second region on a plane. The metal wall is directly connected to the printed circuit board.

A manufacturing method of an embedded component package structure includes the following steps: providing a carrier and forming a semi-cured first dielectric layer on the carrier, the semi-cured first dielectric layer having a first surface; providing a component on the semi-cured first dielectric layer, and respectively providing heat energies from a top and a bottom of the component to cure the semi-cured first dielectric layer; forming a second dielectric layer on the first dielectric layer to cover the component; and forming a patterned circuit layer on the second dielectric layer, the patterned circuit layer being electrically connected to the component.

A component carrier includes a stack with at least one electrically conductive layer structure and at least one electrically insulating layer structure, a component embedded in the stack, and a via formed in the at least one electrically insulating layer structure along a horizontal path having a length being larger than a horizontal width.

Electromagnetic shields for electronic devices, and particularly electromagnetic shields with bonding wires for sub-modules of electronic devices are disclosed. Electronic modules are disclosed that include multiple sub-modules arranged on a substrate with an electromagnetic shield arranged on or over the sub-modules. Bonding wires are disclosed that form one or more bonding wire walls along the substrate. The one or more bonding wire walls may be located between sub-modules of a module and about peripheral boundaries of the module. The electromagnetic shield may be electrically coupled to ground by way of the one or more bonding wire walls. Portions of the electromagnetic shield and the one or more bonding wire walls may form divider walls that are configured to reduce electromagnetic interference between the sub-modules or from external sources.

A component built-in substrate includes a multilayer body and a substrate including a multilayer ceramic electronic component embedded therein. The multilayer ceramic electronic component includes a first connection portion that protrudes from the first external electrode, and a second connection portion that protrudes from the second external electrode. The substrate includes a core material. The multilayer ceramic electronic component including the first connection portion and the second connection portion includes a surface covered by the core material and embedded in the substrate. The first connection portion protrudes toward a surface of the substrate, and is not exposed at the surface of the substrate. The second connection portion protrudes toward the surface of the substrate, and is not exposed at the surface of the substrate.

The present invention relates to the field of integrating electronic systems that operate at mm-wave and THz frequencies. A monolithic multichip package, a carrier structure for such a package as well as manufacturing methods for manufacturing such a package and such a carrier structure are proposed to obtain a package that fully shields different functions of the mm-wave/THz system. The package is poured into place by polymerizing photo sensitive monomers. It gradually grows around and above the MMICs (Monolithically Microwave Integrated Circuit) making connection to the MMICs but recessing the high frequency areas of the chip. The proposed approach leads to functional blocks that are electromagnetically completely shielded. These units can be combined and cascaded according to system needs.

A circuit board with embedded components and a method of fabricating the same are provided. The method includes coating an adhesive layer over a substrate, and disposing electronic components on the adhesive layer. Subsequently, after disposing a dielectric layer over the electronic components and the adhesive layer, the substrate and the adhesive layer are removed to form an embedded layer. Then, a wiring layer is formed on the electronic components, and conductive connecting components are formed within the dielectric layer. A cover layer is laminated over the dielectric layer and the wiring layer. Therefore, the electronic components are embedded within the dielectric layer, and the wiring layer electrically connecting to the electronic components are precisely located on a surface of the embedded layer.

An inductor component includes a core base material, a magnetic body in the core, a first conductor pattern formed on primary surface of the core, a second conductor pattern formed on secondary surface of the core, and through-hole conductors formed in through holes through the core such that the conductors are connecting the first and second patterns. The first pattern, second pattern and conductors are positioned to form an inductor such that the magnetic body is positioned on inner side of the inductor, each conductor has a diameter k1, each pattern has conductor thickness in range of 50 μm to 200 μm and has line patterns each having width w1 and separated by line separation distance w2, and a ratio of cross-sectional area of each line pattern to cross-sectional area of each conductor along the diameter k1 in direction of the width w1 is in range of 0.8 to 2.0.

One or more stud bumps may form a conductive column to a component having back side metallization. In an embodiment, the column of stud bumps may be about 130 um vertically (Z-direction). Providing a microelectronics package with a column of stud bumps electrically connected to a component having back side metallization may provide a cost effective electrical interconnect and may enable the incorporation of components of different thicknesses, including that the component thicknesses are independent of each other, in a single fanout package, while providing a thin package profile and back side surface finish integration.

In a component-embedded substrate, a component and wiring block units are embedded in a component-embedded layer; conductive layers are located on all surfaces of the wiring block units; the component and the wiring block units are arranged such that lower surface side conductive layers of the wiring block units and electrodes of the component contact lower surface side wiring layers; via-hole conductors are located in respective upper positions relative to upper surface side conductive layers of the wiring block units and the electrodes of the component; and upper surface side wiring layers of the component-embedded layer are thus electrically connected to upper surface side conductive layers of the wiring block units, and the electrodes of the component by the via-hole conductors.