Implementations described and claimed herein provide thin film devices and methods of manufacturing and implanting the same. In one implementation, a shaped insulator is formed having an inner surface, an outer surface, and a profile shaped according to a selected dielectric use. A layer of conductive traces is fabricated on the inner surface of the shaped insulator using biocompatible metallization. An insulating layer is applied over the layer of conductive traces. An electrode array and a connection array are fabricated on the outer surface of the shaped insulator and/or the insulating layer, and the electrode array and the connection array are in electrical communication with the layer of conductive traces to form a flexible circuit. The implantable thin film device is formed from the flexible circuit according to the selected dialectic use.

The present disclosure provides a method of manufacturing a conductive pattern and applications thereof, the method including: a step of preparing a laminate including a transparent substrate, a light shielding pattern that is formed on the transparent substrate, and a negative tone photosensitive resin layer that is disposed on the transparent substrate and the light shielding pattern and is in contact with the transparent substrate; a step of irradiating a surface of the transparent substrate opposite to a surface facing the light shielding pattern with light; a step of developing the negative tone photosensitive resin layer to form a resin pattern in a region defined by the transparent substrate and the light shielding pattern; and a step of forming a conductive pattern on the light shielding pattern.

A wiring board includes a wiring layer, an insulating layer, a plurality of opening portions, and a connection terminal. The insulating layer is laminated on the wiring layer and covers a wiring pattern. Each of the plurality of opening portions penetrates through the insulating layer to the wiring pattern. The connection terminal is formed on the respective opening portions and comes into contact with the upper surface of the wiring pattern. The wiring layer includes a first wiring pattern, and a second wiring pattern that is formed of a plurality of laminated metal layers and that is thicker than the first wiring pattern. An upper surface of a metal layer serving as an uppermost layer of the second wiring pattern is a contact surface with the connection terminal and has a same width as an upper surface of a metal layer serving as a layer other than the uppermost layer.

A wiring board includes a wiring layer, an insulating layer, a plurality of opening portions, and a connection terminal. The insulating layer is laminated on the wiring layer and covers a wiring pattern. Each of the plurality of opening portions penetrates through the insulating layer to the wiring pattern. The connection terminal is formed on the respective opening portions and comes into contact with the upper surface of the wiring pattern. The wiring layer includes a first wiring pattern, and a second wiring pattern that is formed of a plurality of laminated metal layers and that is thicker than the first wiring pattern. An upper surface of a metal layer serving as an uppermost layer of the second wiring pattern is a contact surface with the connection terminal and has a same width as an upper surface of a metal layer serving as a layer other than the uppermost layer.

A method for manufacturing a circuit board structure with a waveguide is provided. The method includes: providing a first substrate unit, a second substrate unit, a third substrate unit, and two adhesive layers, the first substrate unit including a first dielectric layer and a first conductive layer, the first conductive layer including a first shielding area and two first artificial magnetic conductor areas disposed on two sides of the first shielding area; the second substrate unit including a second dielectric layer and a second conductive layer, the second conductive layer including a second shielding area; the third substrate unit defining a first slot, and the adhesive layer defining a second slot; stacking the first substrate unit, one of the adhesive layers, the third substrate unit, another one of the adhesive layers, and the second substrate unit in that order; pressing the intermediate body.

In manufacturing a printed circuit board using a semi-additive method, a removal liquid that has been used in removing a nickel-chromium-containing layer (5) is regenerated by contacting the removal liquid with a chelate resin having a functional group represented by a following formula (1) :

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where a plurality of Rs are identical divalent hydrocarbon groups having 1 to 5 carbons, and a portion of hydrogen atoms may be substituted with halogen atoms.

A wiring board includes: a substrate having transparency; a plurality of first wirings which are arranged on an upper surface of the substrate and extend in a first direction and each of which has a back surface in contact with the substrate and a front surface facing an opposite side of the back surface; and has a back surface in contact with the substrate and a front surface facing an opposite side of the back surface. The first wiring has a pair of side surfaces which extend in the first direction and are adjacent to the back surface of the first wiring, and each of the pair of side surfaces of the second wiring is recessed inward. The second wiring has a pair of side surfaces which extend in the second direction and are adjacent to the back surface of the second wiring.

A wiring board includes: a substrate having transparency; a plurality of first wirings which are arranged on an upper surface of the substrate and extend in a first direction and each of which has a back surface in contact with the substrate and a front surface facing an opposite side of the back surface; and has a back surface in contact with the substrate and a front surface facing an opposite side of the back surface. The first wiring has a pair of side surfaces which extend in the first direction and are adjacent to the back surface of the first wiring, and each of the pair of side surfaces of the second wiring is recessed inward. The second wiring has a pair of side surfaces which extend in the second direction and are adjacent to the back surface of the second wiring.

A coil component includes: a coil embedded in a substrate body and having a winding part constituted by a wound conductor; wherein the substrate body has: a first region sandwiched between one end surface of the substrate body and a plane parallel with the one end surface and running through a portion of a first external electrode farthest away from the one end surface; a second region sandwiched between another end of the substrate body and a plane parallel with the another end surface and running through a portion of a second external electrode farthest away from the another end surface; and a third region between the first region and the second region; and the winding part is provided in the third region, and also in the first region where it is wound by one turn or more.

Disclosed herein is an in-mold electronics (IME) structure. The IME structure includes a film, a first plastic resin positioned under the film, and a second plastic resin positioned under the first plastic resin. An electronic circuit is formed on a top or bottom surface of the second plastic resin by a plating method and also electronic elements are mounted thereon. The electronic elements include LED light sources, a plurality of protruding light guides configured to guide lighting through distribution and direction is formed on the top surface of the second plastic resin, and the LED light sources are installed in respective spaces provided by the light guides.