The present application provides an asymmetric board, which includes the first master board, the second master board, and the insulating dielectric layer sandwiched between the first master board and the second master board, and the depth control grooves are disposed in the connection position between the units on the asymmetric board, and located on the surface of the second master board and extending a toward the side of the first master board, the depth control grooves provide space for the expansion of the second master board, reduce the stress of the units, and reduce the warping of the second master board. When the number of the depth control grooves in the first direction and/or the second direction is greater than 0, the depths of the depth control grooves increase by X from a center to an edge of the asymmetric board, and the X is greater than or equal to 0.

Electromagnetic shields for electronic devices, and particularly electromagnetic shields with bonding wires for sub-modules of electronic devices are disclosed. Electronic modules are disclosed that include multiple sub-modules arranged on a substrate with an electromagnetic shield arranged on or over the sub-modules. Bonding wires are disclosed that form one or more bonding wire walls along the substrate. The one or more bonding wire walls may be located between sub-modules of a module and about peripheral boundaries of the module. The electromagnetic shield may be electrically coupled to ground by way of the one or more bonding wire walls. Portions of the electromagnetic shield and the one or more bonding wire walls may form divider walls that are configured to reduce electromagnetic interference between the sub-modules or from external sources.

The elastomeric electrode includes: a stretchable substrate 10 having wrinkles formed on one surface thereof, the peaks C and valleys T of the wrinkles being repeated; a wrinkled metal nanoparticle layer 20 including metal nanoparticles 21 and formed by deposition of the metal nanoparticles along the wrinkles of the substrate 10; and a wrinkled monomolecular layer 30 including a monomolecular material having one or more amine groups (—NH.sub.2) and formed by deposition of the monomolecular material onto the metal nanoparticle layer 20. Also disclosed is a method for preparing the elastomeric electrode.

The present invention includes a method of creating high temperature mechanically and thermally stabilized PCB fabrication on a photo-definable glass substrate or photosensitive glass substrate.

A skin care device formed to cover the left side and right side of a human head and applying a micro current to a mask, includes: a wearing portion extending from the left side of the head through the back side to the right side; and an applying portion formed at each of two ends of the wearing portion and applying the micro current to the mask, wherein the applying portion includes: a conductive portion in contact with the mask; a cover portion to which the conductive portion is coupled and which includes a printed circuit board (PCB) generating the current; and a connecting portion electrically connecting the PCB and the conductive portion to each other, the connecting portion being formed of a conductive spring in elastic contact with the conductive portion.

A semiconductor device package includes a carrier and an encapsulant disposed on the carrier. At least one portion of the encapsulant is spaced from the carrier by a space.

A printed circuit board includes: an insulating layer; a first circuit layer disposed on one surface of the insulating layer, and including a first circuit pattern and a first connection pad; and a surface treatment layer disposed on one surface of the first connection pad. The other surface of the first connection pad is covered by the insulating layer, and at least a portion of a side surface of the first connection pad is spaced apart from the insulating layer.

A circuit board includes a circuit substrate, a solder, and a surrounding portion. The circuit substrate includes a connecting pad. The solder is formed on a surface of the connecting pad. The surrounding portion is formed on the surface of the connecting pad and cooperates with the connecting pad to form a groove receiving the solder. The surrounding portion surrounds the solder and is spaced from the solder. A method for manufacturing a circuit board is also provided.

A circuit board includes a circuit substrate, at least one metal pad, and a tin bar corresponding to each of the at least one metal pad. Each of the at least one metal pad is formed on a side of the circuit substrate and is electrically connected to the circuit substrate. A surface of the metal pad facing away from the circuit substrate is recessed toward the circuit substrate to from a recess. The tin bar is received in the recess. A method for manufacturing a circuit board is also provided.

A low temperature co-fired ceramic (LTCC) electronic device includes a template layer, a base layer and a conductor. The template layer and the base layer are ceramic layers. The template layer has an electrode pattern formed by a hollow groove. A depth of the hollow groove is between 10 μm and 120 μm, and a width of the hollow groove is above 80 μm. The base layer is closely overlapped with the template layer. An overlapping area range of the base layer and the template layer at least covers the electrode pattern. The conductor is filled in the hollow groove of the electrode pattern. A filling thickness of the conductor is above 10 μm.