A method of fabricating a stretchable and flexible electronic device includes forming each of the functional layers is by: (i) forming on an elastomer substrate a conductive interconnect pattern having islands interconnected by bridges; (ii) applying a conductive paste to the islands; (iii) positioning at least one functional electronic component on each island; and (iv) applying heat to cause the conductive paste to reflow. An elastomer encapsulant is formed over the functional electronic components and the conductive interconnect pattern on each of the functional layers. The elastomer encapsulant has a Young's modulus equal to or less than that of the substrate. The encapsulant includes a pigment to increase absorption of laser light. At least one via is laser ablated, which provides electrical connection to any two functional layers. The via is filled with solder paste to create a bond and electrical connection between the functional layers.

A method for manufacturing a circuit board is disclosed. An inner laminated structure with a conductive wiring layer and an outermost cover layer is provided. The conductive wiring layer includes a connection pad. A mask is disposed on a side of the cover layer away from the conductive wiring layer, and the mask defines a plurality of first openings penetrating the mask. A second opening is formed on the cover layer by laser etching through the mask to expose the connection pad. A surface treatment is applied to the connection pad and an electronic component is electrically connected with the connection pad. A circuit board is also disclosed.

A laser processing method includes providing a unit configured to obtain time t0 from a time when the high-frequency pulse RF output is turned on to a time when the laser is actually output in advance and change a traveling direction of the laser in an optical path of the laser, irradiating the workpiece with all the lasers while the high-frequency pulse RF output is turned on, and removing at least a part of the laser from the workpiece simultaneous with turning off the high-frequency pulse RF output.

A method of fabricating a substrate having a through via includes: providing a carrier board having a release layer thereon; attaching the substrate onto the carrier board via the release layer; applying a light beam to the substrate to form a first blind hole in the substrate, wherein the first blind hole penetrates a first surface and a second surface of the substrate; performing an enlargement process on the first blind hole to form a second blind hole; forming a through via in the second blind hole; and performing a de-bonding process to release the substrate having a through via from the carrier board.

A system and method for making vias in a laminated printed circuit board (PCB). A drill having both a mechanical drill and a laser drill is used to make the via. The mechanical drill is moved over a location in the PCB where a blind via is desired. The mechanical drill drills to a point where a tip of a bit of the mechanical drill is a predetermined distance above a target interconnect layer. Then the drill is moved such that the laser drill is located over the via where the mechanical drill had drilled the via. The laser drill then ablates the resin remaining above the target interconnect layer.

A wiring substrate includes: a wiring layer; an insulating layer that is laminated on the wiring layer; an opening portion that passes through the insulating layer to the wiring layer; and an electric conductor film that is formed at the opening portion of the insulating layer. A surface of the insulating layer includes a smoothed portion that is not covered by the electric conductor film, and a roughened portion that includes an inner wall surface of the opening portion covered by the electric conductor film and that have surface roughness that is greater than surface roughness of the smoothed portion.

A component carrier with a stack including an electrically insulating layer structure and an electrically insulating structure has a tapering blind hole formed in the stack and an electrically conductive plating layer extending along at least part of a horizontal surface of the stack outside of the blind hole and along at least part of a surface of the blind hole. A minimum thickness of the plating layer at a bottom of the blind hole is at least 8 μm. A demarcation surface of the plating layer in the blind hole and facing away from the stack extends laterally outwardly from the bottom of the blind hole towards a lateral indentation and extends laterally inwardly from the indentation up to an outer end of the blind hole. An electrically conductive structure fills at least part of a volume between the plating layer and an exterior of the blind hole.

An apparatus is provided which comprises: a woven fiber layer, a first resin layer on a first surface of the woven fiber layer, a second resin layer on a second surface of the woven fiber layer, the second surface opposite the first surface, and the first and the second resin layers comprising cured resin, a third resin layer on the first resin layer, and a fourth resin layer on the second resin layer, the third and the fourth resin layers comprising an uncured resin, and wherein the fourth resin layer has a thickness greater than a thickness of the third resin layer. Other embodiments are also disclosed and claimed.

A multilayer wiring board that improves the reliability of connection at a via hole connection portion, and a method for producing the multilayer wiring board. In a multilayer wiring board comprising a plurality of metal wiring layers alternately laminated with insulating layers interposed therebetween are electrically connected to each other via a via hole plated layer, wherein a dissimilar metallic layer, made from material different from that of the metal wiring layers, is interposed between each of the metal wiring layers on the bottom surface of the via hole and the via hole plated layer, and the dissimilar metallic layer interposed between the each of the metal wiring layers on the bottom surface of the via hole and the via hole plated layer is arranged in a concave shape on the surface of the concave portion formed in the metal wiring layer on the bottom surface of the via hole.

A resin substrate includes a resin body, an interlayer connection conductor provided in the resin body, and a conductor pattern bonded to the interlayer connection conductor. The resin body includes a gap provided adjacent to or in a vicinity of a bonding portion of the interlayer connection conductor and the conductor pattern, and a contact portion that contacts the interlayer connection conductor.