An interconnect structure for insertion loss reduction in signal transmission and a method thereof are disclosed. In an embodiment, an interconnect is formed on a substrate by chemical etching process, and when the interconnect is protected by photoresist in chemical etching process, the etching direction of etching solution is not oriented, so undercut areas are respectively formed on both sides of a bottom of the interconnect at contact of the interconnect and the substrate because of etching solution residue after the etching process. An included angle formed in the undercut area between the interconnect and the substrate is defined as an etch angle, and a length of the portion, exposing in the undercut area, of the substrate is defined as an etch length. Controlling sizes of the etch angle and the etch length can reduce an insertion loss in signal transmission.

Provided herein is a conductive pattern making method and conductive pattern, the method including forming a groove such that its width in an inlet area is bigger than its width in an inner area; filling the groove with a conductive ink composition; and drying the conductive ink composition so that a solvent contained in the conductive ink composition inside the groove is volatilized to reduce the volume of the conductive ink composition.

An electronic device embedded substrate and a method of manufacturing the same includes a substrate comprising a cavity formed therein, and an electronic device embedded in the cavity. The substrate and method thereof also include a first support pattern part formed on one surface of the substrate and pressing the electronic device to restrict a movement of the electronic device within the cavity, and a second support pattern part formed on another surface of the core substrate facing opposite to the one surface and extended toward an inside of the cavity to support the electronic device.

The invention relates to a method for producing a printed circuit board—cooling body structure and such a printed circuit board—cooling body structure, in particular for arrangement in a lighting device of a vehicle, the method comprising at least the following steps: providing a base plate; coating a carrier side of the base plate with an insulation layer and/or with a solder resist; fitting the carrier side with at least one electronic component and applying cooling rib bodies to a cooling side of the base plate opposite the carrier side.

An electronic device according to various embodiments of the present invention may comprise a housing; an inner plate which is built into the housing, at least a portion of which is made of a synthetic resin material, and which comprises a first surface, a second surface facing the opposite direction to the first surface, a first through-hole formed in a cone-shaped cross-section the diameter of which gradually decreases the closer to the second surface from the first surface, and a second through-hole formed in a cone-shaped cross-section, which is disposed adjacent to the first through-hole and the diameter of which gradually decreases the closer to the first surface from the second surface; a first conductive line which is formed on the first surface and is formed to overlap with the first through-hole at least partially when viewed from the first surface, a second conductive line which is formed on the second surface and is formed to overlap with the second through-hole at least partially when viewed from the second surface, a first conductive layer which is deposited conformally on an inner wall of the first through-hole and electrically connected to at least one of the first conductive line and the second conductive line, a second conductive layer which is deposited conformally on an inner wall of the second through-hole and electrically connected to at least one of the first conductive line and the first conductive line, and a wireless communication module which is electrically connected to at least one of the first conductive line and the second conductive line, wherein the first conductive line, the second conductive line, the first conductive layer, and the second conductive layer may comprise the same composition of materials. Such an electronic device may vary according to the embodiment.

An electrical element includes a pair of conducting elements spaced from one another, a recess receiving an electrical component, and a trough extending from a first conducting element of the pair of conducting elements to a second conducting element of the pair of conducting elements. The conducting elements are at least partially exposed in the recess.

A module (101) includes a substrate (1) having a main surface (1a) and a conductor column (4) disposed on the main surface (1a). The conductor column (4) includes a conductor column body (4a) and an overhanging part (4b) overhanging from an outer periphery of the conductor column body (4a) in a middle of a height direction of the conductor column body (4a).

A circuit board including: a first board material layer having a first planar surface and a first sidewall surface perpendicular to the first planar surface; a first conductive layer on the first planar surface; a second board material layer stacked on the first board material layer and having a second planar surface and a second sidewall surface perpendicular to the second planar surface; a second conductive layer on the second planar surface; and a plating on the first sidewall surface and the second sidewall surface and electrically connecting the first conductive layer and the second conductive layer.

A method for producing a camera module having a first part, preferably a housing part, and a second part, preferably a circuit board or a cover part, in which the two parts are connected in positive locking fashion. The positive lock is produced in that a connecting element connected to the first part in the form of a tongue, sleeve or a pin is guided through an opening of the second part, the first part is brought to abut on the second part and subsequently the end of the connecting element protruding beyond the second part is curled in a deforming process so that the curled end abuts on the second part in a pretensioned manner. A camera module is also described.

An electromagnetic wave shielding film includes an insulating protective layer, and a release film covering a surface of the insulating protective layer. The release film has a transmittance of 20-80% at a wavelength of 535 nm, a tight attachment confirmability index Ia of 11 or more, the tight attachment confirmability index Ia being represented by expression 1, and a presence visibility index Iv of 11 or more, the presence visibility index Iv being represented by expression 2.
Ia=(ΔL*.sub.1.sup.2+Δa*.sub.1.sup.2+Δb*.sub.1.sup.2).sup.0.5  (expression 1)
Iv=(ΔL*.sub.2.sup.2+Δa*.sub.2.sup.2+Δb*.sub.2.sup.2).sup.0.5  (expression 2)