A mounting wiring board, containing a base, an electrode portion disposed on the base, and a heat generation pattern disposed on the electrode portion and to be heated by a standing wave of a microwave, in which an occupation area of the heat generation pattern is smaller than an area of an upper surface of the electrode portion; an electronic device mounting board using the mounting wiring board; a method of mounting the electronic device; a microwave heating method, which contains heating an object to be heated provided via the heat generation pattern; and a microwave heating apparatus.

A reel-to-reel method to laser-ablate a circuitry pattern on the fly in a reel-to-reel machine as part of a process to fabricate a printed flexible circuit. The laser ablation method includes using an appropriate laser to irradiate a metal sheet thus ablating the edges of an intended circuitry pattern. Slugs can be removed by using an optional sacrificial liner, and the slugs can be optionally ablated into smaller parts first. The laser ablation can also include an optional method of creating tie bars to provide structural support to the web of circuitry patterns.

In a light-emitting device (30), a wiring pattern including conductor wirings (160, 165) and electrodes (170, 180) is formed on a substrate (110), and an Au layer (120) is formed on the wiring pattern.

A power semiconductor substrate comprising an insulating planar base, at least one conductor track and at least one contact area as part of the conductor track, wherein a layer of a metallic material is disposed on the contact area by means of pressure sintering. The associated method comprises the steps of: producing a power semiconductor substrate that includes a planar insulating base, conductor tracks and contact areas; arranging a pasty layer, composed of a metallic material and a solvent, on at least one contact area of the power semiconductor substrate; and applying pressure to the pasty layer.

An electroconductive substrate including a base material and a metal wiring made of at least either of silver and copper, and the electroconductive substrate has an antireflection region formed on part or all of the metal wiring surface. This antireflection region is composed of roughened particles made of at least either of silver and copper and blackened particles finer than the roughened particles and embedded between the roughened particles. The blackened particles are made of silver or a silver compound, copper or a copper compound, or carbon or an organic substance having a carbon content of 25 wt % or more. The antireflection region has a surface with a center line average roughness of 15 nm or more and 70 nm or less. The electroconductive substrate is formed from metal wiring from a metal ink that forms roughened particles, followed by application of a blackening ink containing blackened particles.

The conductive device includes a substrate and an electrically conductive portion. The electrically conductive portion is provided on the substrate. The electrically conductive portion includes an electrically conductive part and a low resistance conductive layer. The electrically conductive part is provided on the substrate and includes an electrically conductive particle and an organic binder. The low resistance conductive layer covers at least part of a surface of the electrically conductive part and has lower resistivity than the electrically conductive part.

A flexible printed circuit board according to an embodiment includes a substrate, a circuit pattern disposed on the substrate and a protective layer disposed on the circuit pattern, and the circuit pattern includes a first circuit pattern and a second circuit pattern, and the first circuit pattern includes a first pad part, a second pad part, and a first wiring part connected to the first pad part and the second pad part, and the first wiring part includes a first pattern extending in contact with the second pad part, and the first pattern includes a first pattern part and a second pattern part disposed under the protective layer, and the first pattern part includes an extension area having a width greater than that of the second pattern part, and a maximum width of the first pattern part is greater than a maximum width of the second pad part.

A reel-to-reel lamination method to laminate a metal foil or circuitry pattern on the fly. The method includes applying a UV laminate or thermoset laminate to the metal foil or the circuitry pattern reel to reel, and then apply a UV radiation or heat to the laminate. There can be an optional enclosure connected to a suction source. The enclosure can have a flexible bladder that physically compresses the laminate.

Electrical connector includes a housing, signal contacts, and ground shields. The signal contacts are coupled to the housing and positioned for mating with mating signal contacts of a mating connector. The ground shields are coupled to the housing and at least partially surround the signal contacts to shield the signal contacts. The ground shields are plated with a ground-material composition along one or more contact segments of the ground shields that come into compression engagement with one or more other conductive members. The ground-material composition includes a tin-nickel (Sn/Ni) alloy plating layer. The signal contacts are plated with a signal-material composition that is different than the ground-material composition.

The present invention is a novel method of preparing copper sheeting for exposure to UV or optical light in the process of manufacturing flexible printed circuit boards. This method seeks to remove the need for the highly complex, costly, and capital-intensive use of collimated UV lights and vacuum chambers in conventional FPCB manufacturing by preparing copper sheeting for non-vacuum non-collimated UV exposure with a relatively trivial method using clear vinyl stickers, conventional toner-adhering decorative foil, and UV reflective glue. This in turn will “democratize” the design, development, fabrication, production, and distribution of advanced electronics that depend upon the use of high-precision FPCBs.