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.

In an illustrative example, an apparatus includes a passive-on-glass (POG) device integrated within a glass substrate. The apparatus further includes a semiconductor die integrated within the glass substrate.

A printed wiring board includes a core substrate, a first build-up layer, and a second build-up layer. Each build-up layer includes a first insulating layer including reinforcing material, a second resin insulating layer not containing reinforcing material, a first via conductor through the first insulating layer, and a second via conductor through the second insulating layer such that the top diameter of the first via conductor is substantially equal to the top diameter of the second via conductor and that the bottom diameter of the first via conductor is smaller than the bottom diameter of the second via conductor. The conductor layer on the first insulating layer includes a metal foil, a seed layer and an electrolytic plating film. The conductor layer on the second insulating-layer includes a seed layer and an electrolytic plating film and has thickness substantially equal to thickness of the conductor layer on the first insulating-layer.

Systems and methods for providing a PWB. The methods comprise: forming a Core Substrate (CS) a First Via (FV) formed therethrough; disposing a First Trace (FT) on an exposed surface of CS that is in electrical contact with FV; laminating a first HDI substrate to CS such that FT electrically connects FV via with a Second Via (SV) formed through the first HDI substrate; disposing a Second Trace (ST) on an exposed surface of the first HDI substrate that is in electrical contact with SV; and laminating a second HDI substrate to the first HDI substrate such that ST electrically connects SV to a Third Via (TV) formed through the second HDI substrate. SV comprises a buried via with a central axis spatially offset from central axis of FV and SV. FV and SV have diameters which are smaller than TV's diameter.

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.

A circuit structure includes an annular conductor, a conductive via and at least one extension conductor. The annular conductor extends along a direction. The conductive via is disposed in the annular conductor and extending along the direction. The at least one extension conductor is electrically connected to at least one end of the annular conductor and extending toward the conductive via.

A method of making printed circuit board vias using a double drilling and plating method is disclosed. A first hole is drilled in a core, the first hole having a first diameter. The first hole is filled and/or plated with an electrically conductive material. A circuit pattern may be formed on one or two conductive layers of the core. A multilayer structure may then be formed including a plurality of cores that also include pre-drilled and plated via holes, wherein at least some of the pre-drilled and plated via holes are aligned with the first hole. A second hole is then drilled within the first hole and the aligned pre-drilled and plated holes, the second hole having a second diameter where the second diameter is smaller than the first diameter. A conductive material is then plated to an inner surface of the second hole.

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 multi layer 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.

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.

A printed circuit board according to an embodiment of the present invention includes, alternately, at least one insulating layer containing a synthetic resin as a main component; and a plurality of conductive layers including circuit patterns, wherein the plurality of circuit patterns of the plurality of conductive layers form a spiral pattern in plan view, and the plurality of circuit patterns are connected together via a plurality of through-holes so as to form a single closed loop in which a current flows counterclockwise or clockwise in an entirety of the spiral pattern. The conductive layers are preferably formed on both surfaces of the at least one insulating layer so as to form a pair. The spiral pattern includes a plurality of multi-row circuits arranged to form multi-rows, and a bridging circuit that connects an end portion of one multi-row circuit of one of the conductive layers to an end portion of another multi-row circuit of the other conductive layer, the other multi-row circuit being adjacent to the one multi-row circuit.