A plurality of electrically conductive material layers and a plurality of dielectric layers are alternately stacked on a second substrate. The plurality of electrically conductive material layers comprise first and second patterns. The first pattern comprises at least a first pair of overlaying areas free of the electrically conductive material, and the second pattern comprises at least a second pair of overlaying areas free of the electrically conductive material. The first pair of areas overlay areas of the second pattern having the electrically conductive material and the second pair of areas overlay areas of the first pattern having the electrically conductive material. The plurality of electrically conductive material layers are electrically isolated from one another by the dielectric layers.

A printed circuit board package structure includes a substrate, plural ring-shaped magnetic elements, a support layer, and first conductive layers. The substrate has two opposite first and second surfaces, first ring-shaped recesses, and first grooves. Each of the first ring-shaped recesses is communicated with another first ring-shaped recess through at least one of the first grooves, and at least two of the first ring-shaped recesses are communicated with a side surface of the substrate through the first grooves to form at least two openings. The ring-shaped magnetic elements are respectively located in the first ring-shaped recesses. The support layer is located on the first surface, and covers the first ring-shaped recesses and the first grooves. The support layer and the substrate have through holes. The first conductive layers are respectively located on surfaces of support layer and substrate facing the through holes.

A wiring board with a built-in electronic component includes a substrate having cavity, an insulating layer formed on the substrate such that the insulating layer is covering the cavity, a conductor layer formed on the insulating layer, and an electronic component accommodated in the cavity and including a rectangular cuboid body and terminal electrodes such that each electrode has a metal film form formed on outer surface of the body, and via conductors formed in the insulating layer such that the via conductors are connecting the conductor layer and electrodes. The electrodes are arrayed in a matrix having rows and columns such that adjacent electrodes in row and column directions have the opposite polarities, and the conductor layer includes a line pattern shunting first group of the electrodes in one polarity and a solid pattern shunting second group of the electrodes in the other polarity.

An electronic device embedded substrate and a method of manufacturing the same includes a substrate comprising a cavity formed therein, and an electronic device embedded in the cavity. The substrate and method thereof also include a first support pattern part formed on one surface of the substrate and pressing the electronic device to restrict a movement of the electronic device within the cavity, and a second support pattern part formed on another surface of the core substrate facing opposite to the one surface and extended toward an inside of the cavity to support the electronic device.

A light source module comprising a semiconductor light source mounted directly to a conducting trace of a multilayer printed circuit board having a core comprising a plurality of core layers electrically and thermally coupled by a plurality of buried vias wherein at least one of the core layers comprises a heat sink plane.

A mounting device for mounting electronic components, wherein the mounting device comprises an electrically conductive structure having a first value of thermal expansion in at least one pre-defined spatial direction, an electrically insulating structure having a second value of thermal expansion in the at least one pre-defined spatial direction being different from the first value and being arranged on the electrically conductive structure, and a thermal expansion adjustment structure having a third value of thermal expansion in the at least one pre-defined spatial direction, wherein the third value is selected and the thermal expansion adjustment structure is located so that thermally induced warpage of the mounting device resulting from a difference between the first value and the second value is at least partially compensated by the thermal expansion adjustment structure.

An electronic package is provided, which includes: a substrate, an electronic element disposed on the substrate, and an antenna structure disposed on the substrate. The antenna structure has a base portion and at least a support portion, the base portion including a plurality of openings and a frame separating the openings from one another, and the support portion supporting the base portion over the substrate. Therefore, no additional area is required to be defined on a surface of the substrate, and the miniaturization requirement of the electronic package is thus met.

A method of making a wiring board includes forming a first capacitor carrier layer with a first embedded chip capacitor, a first insulation layer disposed on an upper surface, a second insulation layer disposed on a lower surface, first upper and lower conductive vias in conductive contact with a first electrode, and second upper and lower conductive vias in conductive contact with a second electrode. The method also includes forming a second capacitor carrier layer similar to the first. The method further includes forming a bonded laminate comprising in sequence an upper insulation layer, the first capacitor carrier layer, a center insulation layer, the second capacitor carrier layer, and a lower insulation layer. The method also includes forming a through-hole through the laminate and forming a conductive coating within the through-hole to provide a conductive through-hole. A wiring board also includes the bonded laminate and the embedded capacitors.

A cap chip or high density reroute layer for use in a stacked microelectronic module. A first set of electrically conductive reroute layers are defined on a sacrificial substrate. One or more stud bump columns are defined on an exposed conducive pad on a conductive reroute layer. One or more active or passive electronic elements, or both may be electrically coupled to one or more exposed conductive pads. The layer is encapsulated in an encapsulant and the stud bump columns exposed by removing a portion of the encapsulant. A second set of electrically conductive reroute layers is defined on the layer and electrically coupled to the stud bumps. The sacrificial substrate is removed to provide a cap chip or reroute layer.

A printed circuit board with embedded component includes a double-sided printed circuit board, an electronic component, a plurality of conductive paste blocks, an insulating layer and a wiring layer near the first wiring layer, an insulating layer and a wiring layer near the second wiring layer. The double-sided printed circuit board comprising a first wiring layer, a base, and a second wiring layer. The first wiring layer and the second wiring layer are arranged on opposite sides of the base. The second wiring layer includes a plurality of electrical contact pads. The base defines a number of conductive vias. Each electrical contact pad is aligned with and electrically connected to one corresponding conductive via. The conductive paste blocks are electrically connecting to the conductive vias. The electronic component is electrically connected to the conductive paste blocks. The two insulating layers cover the electronic component and the second wiring layer.