A printed circuit board with an embedded bridge includes: a first connection structure including a first insulating film; a bridge disposed on the first connection structure and having one surface, in contact with the first insulating film; and a second connection structure disposed on the first connection structure, and including a second insulating film. The second insulating film covers at least a portion of the other surface of the bridge.

A method includes providing a layer of non-conductive material having a conductive electroplating seed layer formed on a surface thereof; applying a photoresist layer over the surface of the conductive electroplating seed layer; and defining wiring channels in the photoresist resist layer. The method includes electroplating a conductive material in the defined wiring channels; adhering a non-conductive layer over the photoresist layer and the plated conductive material in the wiring channels; and removing the layer of non-conductive material and the conductive electroplating seed layer.

A wiring substrate includes a first conductor layer including wirings, an interlayer insulating layer formed on the first conductor layer and covering the first conductor layer, a second conductor layer formed on the interlayer insulating layer and including wirings, a via conductor formed in the interlayer insulating layer such that the via conductor is penetrating through the interlayer insulating layer and connecting the first conductor layer and the second conductor layer, and a wiring part formed in the interlayer insulating layer and including an embedded wiring layer filling one or more grooves formed in the interlayer insulating layer. The interlayer insulating layer includes a first insulating layer and a second insulating layer laminated on the first insulating layer, and the embedded wiring layer is formed in the first insulating layer on a side facing the second insulating layer and filling the groove or grooves formed in the first insulating layer.

A method of fabricating a wiring board with an embedded interposer substrate includes preparing a main substrate, forming a recess on the main substrate, placing an interposer substrate into the recess, electrically connecting a second pad of the interposer substrate and the first pad of the main substrate, and filling a gap between the interposer substrate and the main substrate with an underfill. The recess exposes a first pad of the main substrate. A second pad of interposer substrate and the first pad of the main substrate are made of the same metal and formed in different outer surface profiles. The underfill entirely touches side surfaces and a bottom surface of the interposer substrate.

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 high density region for a low density circuit. At least a first liquid dielectric layer is deposited on the first surface of a first circuitry layer. The dielectric layer is imaged to create plurality of first recesses. Surfaces of the first recesses are plated electro-lessly with a conductive material to form first conductive structures electrically coupled to, and extending generally perpendicular to, the first circuitry layer. A plating resist is applied. A conductive material is electro-plated to the first conductive structure to substantially fill the first recesses, and the plating resist is removed.

A multi-layer substrate structure to achieve multiple arrangements of power/ground domains is disclosed. The multi-layer substrate structure comprises a first layer for disposing an integrated circuit thereon and a second layer coupled to the first layer, wherein a connection structure is electrically connected to a plurality of power/ground domains on the second layer. With different combinations of the sawing lines and keep-out regions on the multi-layer substrate structure for cutting off some portions of the connection structure, the invention can achieve multiple arrangements of power/ground domains without impacting the customer's PCB or system board design so as to cut short the cycle time for engineering development phase.

Disclosed is an apparatus and methods for making same. The apparatus includes a first insulating layer, a first metal layer disposed on a surface of the first insulating layer, and a metallization structure embedded in the first insulating layer. The metallization structure occupies only a portion of a volume of the first insulating layer. The metallization structure has a line density greater than a line density of the first metal layer.

A method for producing a printed circuit board (13, 15, 16) with multilayer subareas in sections, characterized by the following steps: a) providing at least one conducting foil (1, 1′) and application of a dielectric insulating foil (3, 3′) to at least one subarea of the conducting foil; b) applying a structure of conducting paths (4, 4′) to the insulating layer (3, 3′); c) providing one further printed circuit board structure; d) joining of the further printed circuit board structure with the conducting foil (1, 1′) plus insulating layer (3, 3′) and conducting paths (4, 4′) by interposing a prepreg layer (5, 85; 18, 18′), and e) laminating the parts joined in step d) under pressing pressure and heat; and a printed circuit board produced according to this method.

A multilayer board includes a layered body including insulating base material layers that are laminated, and first and second signal lines, a first ground conductor including a first opening, a second ground conductor, a third ground conductor, and an interlayer connecting conductor. The first signal line overlaps the first opening when seen in a layering direction. The second signal line is provided on a layer different from a layer including the first signal line and includes a portion extending side by side with the first signal line when seen in the Z-axis direction. The first, second, and third ground conductors are connected by the interlayer connecting conductor. The third ground conductor is disposed on a layer including the first signal line or a layer positioned between the first signal line and the second signal line.