A method of manufacturing a package structure is provided, including forming a first wiring layer on a carrier board, forming up plurality of first conductors on the first wiring layer, forming a first insulating layer that encapsulates the first wiring layer and the first conductors, forming a second wiring layer on the first insulating layer, forming a plurality of second conductors on the second wiring layer, forming a second insulating layer that encapsulates the second wiring layer and the second conductors, and forming at least an opening on the second insulating layer for at least one electronic component to be disposed therein. Since the first and second insulating layers are formed before the opening, there is no need of stacking or laminating a substrate that already has an opening, and the electronic component will not be laminated and make a displacement. Therefore, the package structure thus manufactured has a high yield rate. The present invention further provides the package structure.

A circuit board includes an insulating layer including first and second insulator films, a first wiring layer embedded in the first insulator film and including pads and first wiring patterns exposed from the first insulator film, and a second wiring layer including second wiring patterns formed on the second insulator film and via wirings penetrating the insulating layer and electrically connecting the second wiring patterns to the first wiring layer. The first insulator film is made of a reinforcement-free resin that includes no reinforcing member. The second insulator film is made of a reinforcing member impregnated with a resin.

A circuit substrate includes a core substrate having a cavity penetrating through the substrate, a combined component accommodated in the cavity of the substrate, a first build-up layer laminated on first surface of the substrate and including an insulating layer such that the insulating layer is covering the cavity, a second build-up layer laminated on second surface of the substrate and including an insulating layer such that the insulating layer is covering the cavity, and a filling resin filling gap formed between the cavity and combined component accommodated in the cavity of the substrate. The combined component includes an electronic component and a metal block, the electronic component has terminal surface on side facing the first surface of the substrate, and the metal block is superposed to surface of the electronic component on the opposite side of the electronic component with respect to the terminal surface.

Embodiments include an inductor that comprises an inductor trace and a magnetic body surrounding the inductor trace. In an embodiment, the magnetic body comprises a first step surface and a second step surface. Additional embodiments include an inductor that includes a barrier layer. In an embodiment, an inductor trace is formed over a first surface of the barrier layer. Embodiments include a first magnetic body over the inductor trace and the first surface of the barrier layer, and a second magnetic body over a second surface of the barrier layer opposite the first surface. In an embodiment, a width of the second magnetic body is greater than a width of the first magnetic body.

A base substrate which prevents burrs generated during the cutting process includes: multiple conductive layers stacked in one direction with respect to the base substrate; at least one insulation layer being alternately stacked with said conductive layers and electrically separating said conductive layers; and a through-hole penetrating said base substrate covering said insulation layer at the contact region where said cut surface and said insulation layer meet during the cutting of said base substrate in accordance with a predetermined region of the chip substrate. A method of manufacturing the base substrate includes alternately stacking conductive layers and insulation layers and forming a through-hole.

Disclosed is an embedded electronic component which can improve reliability of connection with external wiring and efficiency of an embedding process by including: a contact pad provided on at least one surface of a body portion and made of a conductive material; a first insulating layer for covering the at least one surface of the body portion; a first pad in contact with a surface of the contact pad and made of a conductive material; a rearrangement portion provided on a surface of the first insulating layer to be in contact with the first pad; a second pad provided on the surface of the first insulating layer to be in contact with the rearrangement portion; and a second insulating layer having an opening to expose a portion of the second pad while covering the first insulating layer, the first pad, the rearrangement portion, and the second pad.

A display device includes a flexible display panel for displaying an image, and a printed circuit board electrically connected with the flexible display panel through a circuit film. The printed circuit board may include a plurality of boards in a stack, the boards being respectively provided with integrated circuits, driving chips, and circuit wires, and a conducting portion connecting circuit wires of at least two boards among the plurality of boards.

Embedding a discrete electrical device in a printed circuit board (PCB) includes: providing a vertical via as a blind hole from a horizontal surface of the PCB to an electrically conductive structure in a first layer, the first layer being one layer of a first core section of a plurality of core sections vertically arranged above each other, each core section including lower and upper conductive layers, and a non-conductive layer in between; inserting the electrical device into the via, with the device extending within at least two of the core sections; establishing a first electrical connection between a first electrical device contact device and the electrically conductive structure in the first layer; and establishing a second electrical connection between a second electrical device contact and a second layer, the second layer being one of the electrically conductive layers of a second horizontal core section.

Some embodiments include apparatus and methods having a circuit board, a device located on the circuit board, a first Peripheral Component Interconnect Express (PCIe) connector located on the circuit board and coupled to the device, and a second PCIe connector located on the circuit board and coupled to the device. The first PCIe connector is arranged to couple to a first connector of an additional circuit board. The second PCIe connector is arranged to couple to a second connector of the additional circuit board.

A device embedded substrate (20), includes: an insulation layer (12) including an insulation resin material; an electric or electronic device (4) embedded in the insulation layer (12); a terminal (15) serving as an electrode included in the device (4); a conductor pattern (18) formed on the surface of the insulation layer (12); and a conducting via (21) for electrically connecting the conductor pattern (18) and the terminals (15) with each other. The conducting via (21) is made up of a large-diameter section (21a) having a large diameter and a small-diameter section (21b) having a smaller diameter than that of the large-diameter section (21a), in order starting from the conductor pattern (18) toward the terminal (15). A stepped section (17) is formed between the large-diameter section (21a) and the small-diameter section (21b). The large-diameter section (21a) is formed so as to penetrate a sheet-shaped glass cloth (11) disposed in the insulation layer (12).