A method of manufacturing a circuit board having waveguides including forming a waveguiding structure by injection molding. The waveguiding structure includes a plurality of waveguides arranged at intervals and at least one connecting portion connecting two adjacent waveguides. Each waveguide includes a waveguiding substrate and at least one protrusion on the waveguiding substrate. The connecting portion is removed to obtain at least two waveguides. A metal layer is formed to wrap the whole outer surface of each waveguide. A plurality of receiving grooves is formed to penetrate a wiring board. Each waveguide wrapped by the metal layer is embedded in one of the receiving grooves. The waveguides and the wiring board are fixed. A portion of the metal layer on a surface of each protrusion facing away from the waveguiding substrate is removed. A circuit board is also provided.

An electronic device may have layers of glass for forming components such as a display. A display cover glass layer may overlap an array of pixels. A touch sensor may be formed under the display cover glass layer. Conductive structures such as transparent conductive electrodes or other conductive layers of material may be formed on the outer surface of the display cover glass layer. The electrodes on the outer surface of the display cover glass layer may be coupled to metal contacts and other circuitry on the inner surface of the display cover glass layer using conductive vias. Vias may be provided with barrier layers, opaque coatings, tapers, and other structures and may be formed using techniques that enhance compatibility with chemical strengthening processes.

Disclosed herein are a method of fabricating a stretchable electrical circuit and an apparatus for fabricating a stretchable electrical circuit, wherein the method of fabricating a stretchable electrical circuit includes stretching a stretchable substrate, forming a plurality of alignment marks on a surface of the stretchable substrate, forming a first axis extending from a line connecting two alignment marks among the plurality of alignment marks, and a second axis perpendicular to the first axis, marking one point of the surface of the stretched stretchable substrate with coordinates made by the first axis and the second axis, and disposing electrical components using the coordinates.

A manufacturing method of an electronic device including following steps is provided. A first substrate is provided. A thermal release adhesive layer is provided on the first substrate. A thinning process is performed on the first substrate to form a first thinned substrate. A cutting process is performed on the first thinned substrate to form a first sub-substrate. The thermal release adhesive layer is separated from the first thinned substrate or the first sub-substrate. In the manufacturing method of the electronic device provided in one or more embodiments of the disclosure, the manufacturing process of the electronic device may be simplified, and/or defects of the resultant electronic device may be reduced.

A system and method for providing and using wickless capillary driven constrained vapor bubble heat pipes for application in electronic devices with various system platforms are disclosed. An example embodiment includes: a substrate; and a plurality of wickless capillary driven constrained vapor bubble heat pipes embedded in the substrate, each wickless capillary driven constrained vapor bubble heat pipe including a body having a capillary therein with generally square corners and a high energy interior surface, and a highly wettable liquid partially filling the capillary to dissipate heat between an evaporator region and a condenser region.

A substrate with an electronic component embedded therein includes: a core structure having a cavity; a metal layer disposed on a bottom surface of the cavity of the core structure; and an electronic component disposed on the metal layer in the cavity of the core structure. The substrate with the electronic component embedded therein has an excellent heat dissipation effect.

A printed circuit board according to the embodiment includes an insulating layer; a first pad on a top surface of the insulating layer; a second pad on a bottom surface of the insulating layer; and a via formed in the insulating layer and having one surface connected to the first pad and an opposite surface connected to the second pad, wherein the via includes a plurality of via parts which are at least partially overlapped with each other.

Embodiments disclosed include a multilayer substrate for semiconductor packaging. The substrate may include a first layer with a first side with an xy-plane and individual locations on the first side have a first side distance below the first side xy-plane, and a second side with a second side xy-plane and individual locations on the second side may have a second side distance below the second side xy-plane; and a second layer with a first side coupled to the second side of the first layer and a second side opposite the first side of the second layer, wherein a thickness of the second layer at the individual locations on the second layer may be comprised of the first side distance plus the second side distance. Other embodiments may be described and/or claimed.

For a carrier plate, it is proposed to brace a first ceramic functional layer over a connecting layer (VS) with a ceramic stressing layer (SPS) in order to reduce the lateral sintering shrinkage. The functional layer (FS) and the stressing layer (SPS) are glass-free or have only a small glass content of less than 5 wt %, whereas the connecting layer (VS) comprises a glass component or is a glass layer.

A printed board includes: a depression formed in at least one surface of a board; an open hole formed in the board so as to penetrate the board from a bottom portion of the depression; and a conductor formed over an edge of an opening portion of the open hole and an inner surface of the open hole.