A circuit board structure includes a first dielectric layer, first and second inner circuit layers, a conductive connection layer, a second dielectric layer, two third dielectric layers, third and fourth inner circuit layers, two conductive through vias, first and second annular retaining walls, two fourth dielectric layers, first and second external circuit layers, and third and fourth annular retaining walls. The conductive through vias penetrate the third and second dielectric layers and electrically connect the third and fourth inner circuit layers. The first and second annular retaining walls surround the conductive through vias and electrically connect the third and first and the fourth and second inner circuit layers. The third and fourth annular retaining walls are respectively disposed in the fourth dielectric layers and electrically connect the first external circuit layer and the third inner circuit layer and the second external circuit layer and the fourth inner circuit layer.

A circuit board structure includes a first dielectric layer, first and second inner circuit layers, a conductive connection layer, a second dielectric layer, two third dielectric layers, third and fourth inner circuit layers, two conductive through vias, first and second annular retaining walls, two fourth dielectric layers, first and second external circuit layers, and third and fourth annular retaining walls. The conductive through vias penetrate the third and second dielectric layers and electrically connect the third and fourth inner circuit layers. The first and second annular retaining walls surround the conductive through vias and electrically connect the third and first and the fourth and second inner circuit layers. The third and fourth annular retaining walls are respectively disposed in the fourth dielectric layers and electrically connect the first external circuit layer and the third inner circuit layer and the second external circuit layer and the fourth inner circuit layer.

Provided is a flexible printed wiring board including: a base film which is an insulating layer; a first conductor layer; a second conductor layer; and a through-hole, in which the first conductor layer is provided on one surface of the base film, the second conductor layer is provided on the other surface of the base film, and the through-hole is provided so as to penetrate the base film and electrically connect the first conductor layer and the second conductor layer to each other, and the second conductor layer has a solderable region.

A printed circuit board is provided with multiple electrically conductive layers which are separated from each other by electrically non-conductive layers. At least one electrically conductive outer layer and multiple electrically conductive intermediate layers are provided. At least one electrically conductive through-connection is provided between an electrically conductive outer layer and an electrically conductive intermediate layer. The printed circuit board consists of at least one first multilayer PCB and one second multilayer PCB. The first multilayer PCB is formed from multiple electrically conductive layers and multiple electrically non-conductive layers, and the second multilayer PCB has at least one electrically conductive layer and at least one electrically non-conductive layer. The multilayer PCBs are connected to each other. The electrically conductive through-connection between a first electrically conductive outer layer and a second electrically conductive outer layer is formed from multilayer PCBs.

The present disclosure discloses a multilayer circuit board comprising a plurality of metal layers, a blind via and/or a buried via, the multilayer circuit board is capable of transmitting signal between the different metal layers. The blind via has a pad on a non-opening side of the blind via. An upper or lower layer metal layer on the non-opening side of the blind via adjacent to the blind via has a first hole which is located in a position corresponding to the pad on the non-opening side of the blind via in a depth direction of the blind via; and/or an upper and/or lower layer adjacent to the buried via has a second hole which is located in a position corresponding to the pad of an upper and/or lower orifice of the buried via in a depth direction of the buried via.

A multilayer printed circuit board is provided having a first conductive layer and a first plating resist selectively positioned within the first conductive layer. A second plating resist may be selectively positioned within a second conductive layer. A through hole extends through the first plating resist in the first conductive layer and the second plating resist in the second conductive layer. An interior surface of the through hole is plated with a conductive material except along a length between the first plating resist and the second plating resist. This forms a partitioned plated through hole having a first via segment electrically isolated from a second via segment.

An inductor built-in substrate includes a core substrate having an opening and a first through hole formed therein, a magnetic resin filling the opening and having a second through hole formed therein, a first through-hole conductor including a metal film formed in the first through hole, and a second through-hole conductor including a metal film formed in the second through hole. The core substrate and the magnetic resin are formed such that a surface in the first through hole has a roughness that is larger than a roughness of a surface in the second through hole.

Structures that implement three-dimensional (3D) conductive material (e.g., copper) in printed circuit boards (PCBs) are disclosed. 3D (three-dimensional) conductive material may include trenches and/or buried vias that are filled with conductive material in the PCBs. Trenches may be formed in build-up layers of a PCB by overlapping multiple laser drilled vias. The trenches may be filled with conductive material using electroplating process(es). Buried vias may be formed through the core layers of the PCB by mechanical drilling. The buried via may be filled with solid conductive material using a combination of electroless plating and electrolytic plating of conductive material. Various PCB structures are disclosed that implement combinations of these trenches and/or these buried vias filled with conductive material.

An apparatus is provided which comprises: a plurality of organic dielectric layers forming a substrate, a plurality of first conductive contacts on a top surface of the substrate, a plurality of second conductive contacts on a bottom surface of the substrate, a plurality of third conductive contacts on a side wall surface of the substrate, and one or more discrete capacitor(s) coupled with the third conductive contacts on the side wall surface. Other embodiments are also disclosed and claimed.

Presented herein is a WLCSP intermediate structure and method forming the same, the method comprising forming a first redistribution layer (RDL) on a carrier, the first RDL having mounting pads disposed on the first RDL, and mounting interposer dies on a second side of the first RDL. A second RDL is formed over a second side of the interposer dies, the second RDL having a first side adjacent to the interposer dies, one or more lands disposed on the second RDL, at least one of the one or more lands in electrical contact with at least one of the interposer dies or at least one of the mounting pads. A molding compound is formed around the interposer dies and over a portion of the first RDL prior to the forming the second RDL and the second RDL is formed over at least a portion of the molding compound.