A printed wiring board includes a resin insulating layer, pads formed on the resin insulating layer, an uppermost resin insulating layer formed on the resin insulating layer such that the uppermost resin insulating layer is covering the pads and has openings exposing the pads, respectively, via conductors formed in the uppermost resin insulating layer such that the via conductors are formed on the pads exposed from the openings in the uppermost resin insulating layer, respectively, and metal posts formed on the via conductors such that each of the metal posts has a portion on a surface of the uppermost resin insulating layer around the via conductors and a side surface having a flared bottom extending toward the uppermost resin insulating layer.

A wiring substrate includes a first insulating layer, a conductor layer formed on the first insulating layer, a second insulating layer formed on the first insulating layer such that the second insulating layer is covering the conductor layer, and a coating film formed on a surface of the conductor layer such that the coating film is adhering the conductor layer and the second insulating layer. The conductor layer includes a conductor pad and a wiring pattern, and the conductor pad of the conductor layer has a mounting surface including a first region and a component mounting region formed such that the second insulating layer has a through hole exposing the component mounting region and that the first region is covered by the second insulating layer and roughened to have a surface roughness higher than a first surface roughness of a surface of the wiring pattern facing the second insulating layer.

A solder member mounting method includes providing a substrate having bonding pads formed thereon, detecting a pattern interval of the bonding pads, selecting one of solder member attachers having different pattern intervals from each other, such that the one selected solder member attacher of the solder member attachers has a pattern interval corresponding to the detected pattern interval of the bonding pads, and attaching solder members on the bonding pads of the substrate, respectively, using the one selected solder member attacher.

A connector includes mounting tabs that are extended relative to traditional mounting tabs. On a back side of the printed circuit board (PCB), the mounting tabs connect to a back plate. The mounting tabs extend through the PCB and connect with the back plate, which provides improved structural integrity. Depending on the connector, the use of the mounting tabs can use existing mounting holes for the connector and remove the need for additional mounting holes.

Vias may be established in printed circuit boards or similar structures and filled with a monolithic metal body to promote heat transfer. Metal nanoparticle paste compositions may provide a ready avenue for filling the vias and consolidating the metal nanoparticles under mild conditions to form each monolithic metal body. The monolithic metal body within each via can be placed in thermal contact with one or more heat sinks to promote heat transfer.

A manufacturing method of a multilayered board, includes: a dot pattern forming process that forms a dot pattern comprising at least one hemispherical micro-lens shape by repeating a process of forming one hemispherical micro-lens shape by jetting one droplet for forming the dot pattern in an inkjet manner; and a stack pattern forming process that forms a stack pattern having a thickness less than that of the micro-lens by jetting a droplet for forming the stack pattern on a predetermined area around the dot pattern in the inkjet manner.

A method for manufacturing a circuit board with narrow conductive traces and narrow spaces between traces includes a base layer and two first wiring layers disposed on opposite surfaces of the base layer. Each first wiring layer includes a first bottom wiring and a first electroplated copper wiring. The first bottom wiring is formed on the base layer. The first bottom wiring includes a first end facing the base layer, a second end opposite to the first end, and a first sidewall connecting the first end and the second end. The first electroplated copper wiring covers the second end and the first sidewall of the first bottom wiring.

A thin film board according to the present invention has a structure in which a land, which is a connection portion with a transmission line of a printed circuit board, is used as a back wiring and extends from the end to the inside of the thin film board, and the back wiring and the front wiring are connected by a through hole. In the structure of this thin film board, the land does not become a stub and does not affect the high frequency characteristics of the circuit element. That is, there is no trade-off between the connectivity between the printed circuit board and the thin film board and the high frequency characteristics of the circuit element. Therefore, the thin film board and the circuit element in which the thin film board is mounted on the printed circuit board can support high frequency electric signals up to 60 GHz.

A transparent antenna includes a substrate, an antenna grid layer, and a ground grid layer. The substrate has an electrically conductive hole extending from two opposite surfaced of the substrate. The antenna grid layer is formed on a surface of the substrate. The antenna grid layer includes a feeding portion and a transmission portion. The ground grid layer is formed on another surface of the substrate. The ground grid layer is coupled to the feeding portion of the antenna grid layer via the electrically conductive hole. An offset distance between a projection of a gridline of the antenna grid layer on the first surface and a projection of a gridline of the ground grid layer on the first surface is smaller than or equal to half of a difference between a line width of the antenna grid layer and a line width of the ground grid layer.

An assembly (110) for dissipating heat generated by a heat generating electrical component (16) which is surface mounted on a circuit board (11) in a surface mounting process. The assembly comprises a heat buffer (120) made of a thermally and electrically conducing material, and being surface mounted on the circuit board (11) so as to be soldered to a thermal flag (18) of the heat generating electrical component (16). The assembly further comprises a heat sink (12) in thermal contact with the heat buffer, and a galvanic separation (13) between the heat buffer and heat sink. The heat capacitance of the heat buffer can absorb short term increases in heat dissipation from the electrical component, before the heat is further dissipated to the galvanically separated heat sink. This may drastically improve performance of the surface mounted component.