A component carrier with a stack including a first core layer structure and a second core layer structure, and a recess extending completely through the first core layer structure and extending at least partially into the second core layer structure. Each core layer structure has at least one electrically conductive layer structure and at least one electrically insulating layer structure. The core layer structures are stacked with one on top of the other in a stacking direction.

An opto-electric hybrid board includes: an electric circuit board including an insulation layer and electrical interconnect lines formed on the front surface of the insulation layer; and an optical waveguide provided on the back surface side of the insulation layer of the electric circuit board, with a metal layer therebetween. At least one opening is formed by removing at least part of a region of the metal layer which is overlaid on the contour of an end portion of the optical waveguide. The optical waveguide is formed, with part of the optical waveguide extending into the opening. The opto-electric hybrid board is favorably usable over a prolonged period because the end portion of the optical waveguide provided on the back surface side of the electric circuit board does not peel off the metal layer.

The present invention relates to a light source support of an automotive vehicle. The light source support comprises: a first non-flexible part adapted to be mounted with a plurality of first electronic components; and a second non-flexible part adapted to be mounted with a plurality of second electronic components. The light source support further comprises a flexible arm adapted to join the first non-flexible part and the second non-flexible part to form the light source support, which is twistable and rotatable. The first non-flexible part and the second non-flexible part are joined in a non-axial manner by the flexible arm such that a longitudinal axis of the first non-flexible part is not parallel to a longitudinal axis of the second non-flexible part when the first non-flexible part is joined with the second non-flexible part.

An electronic circuit includes plural individual electronic circuits arranged, in which each of the plural individual electronic circuits has a first conductor column that is connected to a ground of a first layer which is any one of plural conductor layers sequentially stacked in a separated state and extends in a stacking direction, a conductor line that is connected to the conductor column to extend in a band shape in a second layer different from the first layer which is any one of the plural conductor layers, and of which an end portion separated from the conductor column is an open end, and a second conductor column that is connected to the conductor line, is not connected to the ground, and extends in the stacking direction, and each of a first individual electronic circuit and a second individual electronic circuit adjacent to each other among the plural individual electronic circuits has at least a pair of the second conductor columns, which are formed at adjacent positions without interposing any one of the conductor lines of the first individual electronic circuit and the second individual electronic circuit between the pair of the second conductor columns.

The invention provides processes for the manufacture of conductive transparent films and electronic or optoelectronic devices comprising same.

Provided is a circuit board including: a supporting substrate including a first region to which light emitting elements are mounted and a second region extending to be bent from the first region, wherein the second region comprises: a connector mounting portion to which a connector for supplying an electric current to the light emitting elements is mounted; and a non-mounting portion of a connector separated and spaced apart from the connector mounting portion, wherein the connector mounting portion is formed lower than the non-mounting portion of the connector.

A component carrier, wherein the component carrier includes: i) a layer stack with at least one electrically conductive layer structure and/or at least one electrically insulating layer structure, ii) a bendable portion which forms at least a part of the layer stack, and iii) a metal layer which forms at least a part of the bendable portion. Hereby, the metal layer extends over at least 75% of the area of the bendable portion.

A printed circuit board includes a first rigid region and a flexible region, connected to the first rigid region and adjacent thereto in a first direction. The first rigid region has a thickness greater than a thickness of the flexible region, and the flexible region has a plurality of curved portions.

A printed circuit board has a core made of an aluminum material; a bonding member positioned on opposite surfaces of the core; a base layer bonded to the opposite surface of the core through the bonding member; a receiving hole extending through the core, the bonding member, and the base layer; a zinc substitution layer positioned on a surface of the base layer and a portion of the base layer exposed on an inner surface of the receiving hole; and a plating layer positioned on the zinc substitution layer, and having a circuit pattern.

A process for forming a graphene circuit pattern on an object is described. A graphene layer is grown on a metal foil. A bonding layer is formed on a protective film and a surface of the bonding layer is roughened. The graphene layer is transferred onto the roughened surface of the bonding layer. The protective film is removed and the bonding layer is laminated to a first core dielectric substrate. The metal foil is etched away. Thereafter the graphene layer is etched using oxygen plasma etching to form graphene circuits on the first core dielectric substrate. The first core dielectric substrate having graphene circuits thereon is bonded together with a second core dielectric substrate wherein the graphene circuits are on a side facing the second core dielectric substrate wherein an air gap is left therebetween.