An extremely thin copper foil is provided that enables formation of highly fine different wiring patterns with a line/space (L/S) of 10 μm or less/10 μm or less on two sides of the copper foil and is thus usable as an inexpensive and readily processable substitution for silicon and glass interposers. The extremely thin copper foil includes, in sequence, a first extremely thin copper layer, an etching stopper layer, and the second extremely thin copper layer. Two sides of the extremely thin copper foil each have an arithmetic average roughness Ra of 20 nm or less.

A substrate for contacting an electrical pin arranged in a housing includes a base having a recess receiving the electrical pin, a metal leadframe having a contacting region electrically and/or thermally contacting the electrical pin, and a contact pin extending along a mating direction in a plane parallel to the metal leadframe and configured to electrically contact a mating contact pin of a mating connector. The metal leadframe is rigidly fixed to the base to prevent a relative movement between the metal leadframe and the substrate. The substrate is movable with respect to the housing along a locking direction from an unlocked position where the substrate is not locked to the housing to a locked position in which the substrate is locked to the housing. A movement of the contacting region with respect to the electrical pin is prevented in the locked position.

A camera module and its molded circuit board assembly and manufacturing method are disclosed, wherein the molded circuit board assembly includes a circuit board and a molded base integrally formed with the circuit board through a molding process. The molded base forms a light window disposed corresponding to a photosensitive element of the camera module, wherein the light window is configured to have a trapezoidal or to multi-stair trapezoidal shape cross section which has diameters increasing from bottom to top to facilitate demoulding, so as to prevent damage to the molded base, and to avoid stray light.

Disclosed are special component carriers made of MID-capable plastic in order to make the geometric arrangement of electrical components, such as microprocessors, LEDs, sensors, antennas and the like, on a circuit board more flexible. Said component carriers can have a standardized footprint for connecting to the circuit board and can be adapted to the terminals and the geometric arrangement of the components using individually applied conducting tracks, in particular in an LDS process. Furthermore, the specially shaped component carriers allow the electrical components to be geometrically oriented, in particular at a right angle to the circuit board and parallel to the circuit board, which is especially highly advantageous for antennas and acceleration sensors. Furthermore, SMT soldering is made possible in the pre-mounted state even for temperature-sensitive components.

Disclosure provides an adapter board and a method for making the adapter board, which includes providing a mold in which a plurality of first fixing plates and second fixing plates are provided, providing a plurality of wires sequentially passed through the plurality of first fixing plates and the second fixing plate, injecting a non-conductive material into the cavity to form a body, and cutting the body along both sides of the first fixing plates and the second fixing plates to obtain a plurality of board bodies. The first fixing plates are provided with a plurality of first fixing holes, and the second fixing plates are provided with a plurality of second fixing holes. The board body includes a first surface and a second surface. A plurality of first connection pads are formed on the first surface, and a plurality of second connection pads are formed on the second surface.

A printed circuit board according to an embodiment includes an insulating layer; a first pad disposed on an upper surface of the insulating layer; a second pad disposed on a lower surface of the insulating layer; a first device mounted on the first pad; a second device mounted on the second pad; a first molding layer disposed on the insulating layer and molding the first device; and a second molding layer disposed on the lower surface of the insulating layer and molding the second device, wherein a lower surface of the second molding layer is positioned on the same plane as a lower surface of the second device.

An electronic module includes: a mount table including a first electrode mounting surface on which an electronic component is mounted; a plurality of electrode mount parts that are formed in the mount table and at which lands corresponding to a plurality of respective electrodes of the electronic component are formed on the first electrode mounting surface; a step part located between the plurality of electrode mount parts and including a predetermined step relative to the first electrode mounting surface of the mount table; and a solder withdrawing part at which an end part of a corresponding one of the lands is extended to the step part or a side surface of the mount table.

Provided is a molded circuit component 300 in which a metal layer 200 is formed with high adhesion by giving a degree of freedom to a base material 100. In the molded circuit component 300 in which the metal layer 200 is formed in a processing region 110 in the base material 100, a plurality of recesses 120 each having a plurality of holes 130 are continuously formed in the processing region 110, the processing region 110 has a ratio of a width to a maximum depth with respect to a surface of the base material 100 of 10:1 to 6:1, the processing region 110 is formed to have a width in a range of 20 μm to 200 μm, and formed to have a maximum depth with respect to the surface of the base material 100 in a range of 2 μm to 30 μm, the metal layer 200 can be formed in the processing region 110 by laminating using a plating method, and a catalyst that reacts with a metal that forms the metal layer 200 at the time of the lamination is attached to the holes 130 and the recesses 120.

An illumination assembly includes a polymeric substrate, an electrical circuit including two conductors supported by the polymeric substrate, an LED electrically coupled to the two conductors, and a heat spreader thermally coupled to the LED. The two conductors can be printed on the polymeric substrate, embedded within the polymeric substrate, or lie atop the polymeric substrate. The illumination assembly may be fabricated in three-dimensional form factors.

A plated molded article 1 is characterized in that a partial region R in a surface 21 of a base material 2 is provided with a plurality of non-penetrating holes 4 of substantially corresponding shapes and substantially corresponding sizes that are formed in a scattered pattern in such a manner as to be separated from each other at a substantially averaged hole density, and a plated part 3 is formed while filling the non-penetrating holes 4 and is provided continuously over the partial region R in such a manner as to extend across the non-penetrating holes 4. It is possible to obtain a plated molded article capable of forming a required plated part in a short time on a surface of a base material and capable of improving smoothness of an outer surface of the plated part and adhesion property of the plated part.