A printed wiring board includes a first insulating layer, a first conductor layer formed on first surface of the first insulating layer, a second conductor layer formed on second surface of the first insulating layer, a first via structure formed in the first insulating layer such that the first via structure is connecting the first and second conductor layers, a second insulating layer formed on the second surface of the first insulating layer such that the second conductor layer is embedded into the second insulating layer, a third conductor layer formed on the second insulating layer, and a second via structure formed in the second insulating layer such that the second via structure is connecting the second and third conductor layers. The second conductor layer includes a dedicated wiring layer which transmits data between two electronic components to be mounted to the first surface of the first insulating layer.

A printed circuit board includes: a first insulating layer; a first circuit layer disposed on one surface of the first insulating layer and including a connection pad; a second insulating layer disposed on the one surface of the first insulating layer and embedding the first circuit layer; a via penetrating through the second insulating layer and connected to the first circuit layer; a metal post disposed on one surface of the second insulating layer and connected to the via; and a hole penetrating through the second insulating layer and exposing at least a portion of the connection pad of the first circuit layer. The metal post is spaced apart from the hole, and protrudes from the second insulating layer.

A component built-in board comprises a multi-layer structure comprising a plurality of unit boards stacked therein a plurality of electronic components built in thereto in a stacking direction. The plurality of unit boards include: a first board having a first insulating layer and comprising an opening in which the electronic component is housed; and an intermediate board adjacent to the first board and comprising a first adhesive layer provided on at least a side of the first board of a second insulating layer. The intermediate board includes a first wiring layer formed at a position overlapping in the stacking direction a gap between an inner periphery of the opening and an outer periphery of the electronic component of the first board on a surface on the first board side of the second insulating layer.

A resin multilayer substrate includes a multilayer body including resin layers and adhesive layers that are laminated, via conductors in the resin layers, and bonding portions in the adhesive layers. The bonding portion is connected to the via conductor. One of the resin layer and the adhesive layer is a gas high-permeable layer having a higher gas permeability than the other one. The bonding portion includes an organic substance, or has a higher void content rate per unit plane sectional area than the via conductor. At least a portion of each of the bonding portions contacts the gas high-permeable layers.

A wiring board includes electronic components, a multilayer core substrate including insulating layers and conductive layers such that the insulating layers include a central insulating layer in the center position of the core in the thickness direction, a first build-up layer including an insulating layer and a conductive layer such that the insulating layer has resin composition different from that of the insulating layers in the core, and a second build-up layer including an insulating layer and a conductive layer such that the insulating layer has resin composition different from that of the insulating layers in the core. The core has cavities accommodating the electronic components, respectively, and including a first cavity and a second cavity such that the first and second cavities have different lengths in the thickness direction and are penetrating through the central layer at centers of the first and second cavities in the thickness direction.

A build-up process for fabricating a multi-layer PCB is provided during which a mezzanine redistribution, or routing, structure is formed within one of the PCB dielectric material layers that allows additional electrical interconnections (i.e., traces and crossovers) to be made within that layer, thereby obviating the need to add an additional PCB layer in order to make those interconnections. The mezzanine redistribution structure also can be interconnected with the metal layers that are above and below it to further increase routing complexity and flexibility. The mezzanine redistribution structure can be formed without increasing the total thickness of the PCB and without substantially increasing costs.

A transmission circuit board includes a bendable area, a first transmission areas, and a second transmission areas. The first and second transmission areas are connected to the bendable area. The inner circuit substrate board further includes a substrate layer and an inner circuit layer formed on the substrate layer and including a first signal circuit. The transmission circuit board further includes a first dielectric layer formed on the inner circuit layer, a first outer circuit layer formed on the first dielectric layer, a first protecting layer formed on the first outer circuit layer, and a first shielding layer formed on the first protecting layer. The first dielectric layer lies the first and second transmission areas. Two ends of the first signal circuit are connected to the first outer circuit layer. The first shielding layer is connected to the first outer circuit layer and lies the bendable area.

A resin multilayer board includes an insulating substrate including a first main surface and mounting electrodes only on the first main surface. The insulating substrate includes first and second resin layers that are laminated. The Young's modulus of the second resin layers is higher than that of the first resin layers. The first and second resin layers are arranged in a distributed manner along a lamination direction of the first and second resin layers. The insulating substrate includes a first and second portions that are two equally divided portions of the insulating substrate in the lamination direction and are respectively positioned closer to the first main surface and farther from the first main surface, and a volume ratio of the second resin layers in the first portion is higher than a volume ratio of the second resin layers in the second portion.

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 film stack made from compacted green films and capable of being sintered to form a ceramic component with monolithic multi-layer structure is disclosed. The film stack includes a functional layer comprising a green film comprising a functional ceramic and a tension layer comprising a green film comprising a dielectric material. The tension layer is directly adjacent to the functional layer in the multi-layer structure. The multilayer structure also includes a first metallization plane and second metallization plane. The functional layer is between the first metallization plane and the second metallization plane.