A method for manufacturing a printed wiring board includes forming a conductor layer including first and second pads on an insulating layer, forming a dry film resist layer on the insulating and conductor layers, forming first and second openings exposing the first and second pads, applying first metal plating to form first and second base plating layers on the first and second pads, applying second metal plating to form a first top plating layer of a first post and portion of a second top plating layer of a second bump post, applying the second metal plating further to form second portion of the second top layer of the second post, removing the dry film resist layer, forming a solder resist layer to cover the first and second posts, and thinning the solder resist layer over entire surface to position the first and second top layers outside the solder resist layer.

A circuit board having a high reflectivity includes a wiring board, a first solder resist layer, and a second solder resist layer. The wiring board includes a wiring layer on an outer side, the wiring layer including wiring and a bond pad spaced from the wiring. The first solder resist layer, with opening and groove, covers the wiring layer, the bond pad is exposed from the opening but spaced from the first solder resist layer. The second solder resist layer infills the groove and covers the first solder resist layer but does not make contact with the mounting surface of the bond pad. A method for manufacturing such circuit board is also disclosed.

The object of the present invention is to provide a printed circuit board that improves the heat radiating effect as the entire printed circuit board and a manufacturing method for such a printed circuit board. A printed circuit board includes a base member having two main surfaces, at least one heat-radiating conductor layer formed on at least one of the main surfaces of the two main surfaces of the base member and a solder resist layer formed on a surface of the heat-radiating conductor layer, and in this printed circuit board, the heat-radiating conductor layer has two main surfaces and at least one side face, the heat-radiating conductor layer has its one main surface of the two main surfaces made in planar contact with the main surface of the base member, the solder resist layer further has an etching liquid resistance, and is formed on the other main surface of the two main surfaces of the heat-radiating conductor layer, with the side face of the heat-radiating conductor layer being exposed, and the heat-radiating conductor layer and the solder resist layer are allowed to form a laminate 24 having a substantially convex shape with an appropriate height.

A system for effectively curing dry film ink throughout its thickness on circuit boards being made applies an exposure system, a circuit board, and a method for making the circuit board. The exposure system includes a plurality of mixed light sources with different wavelengths within a range of 365 nm to 440 nm, the mixed light sources can output at least three different wavelengths of light each of substantially a single wavelength and a fourth source of light able to output light of a spectrum of wavelengths, the ranges of light being between 365 nm and 440 nm.

A vehicular electronic device has a semiconductor package and a multilayer wiring board. An electrode pad of the multilayer wiring board, to which a signal terminal of the semiconductor package is soldered, has a wiring pattern in an inner layer of the multilayer wiring board. A solder resist is applied and spaced from a periphery of the electrode pad to the exterior. The signal terminal is soldered to the electrode pad to cover an upper surface and an upper end of a side surface of the electrode pad. As a result, a crack is less likely to occur in solder connected to the signal terminal. Therefore, the signal terminal can be electrically connected with high reliability even when the signal terminal is provided in the semiconductor package with a small number.

Some embodiments provide a novel surface-mount technology (SMT) printed circuit board (PCB) assembly. The SMT PCB assembly includes at least a pair of adjacent conductive pads with a small gap between them. During the development phase of the SMT PCB assembly, the small gap between the adjacent conductive pads, as well as some of the adjacent portions of the conductive pads, are covered with solder mask. An SMT component (e.g., a zero-ohm resistor) may then be mounted to the SMT PCB assembly through the exposed portions of the conductive pads. During the production phase, however, the solder mask is revised to cover the far sides of the conductive pads, which results in the adjacent portions of the conductive pads being exposed. As such, a solder jumper can easily be created during the production phase by connecting the two conductive pads using solder paste.

A method includes applying solder pastes separately to first and second portions of the first member; bringing the solder paste applied to the first portion of the first member and a first portion of the second member into contact with each other, and bringing the solder paste applied to the second portion of the first member and a second portion of the second member into contact with other; and causing the solder paste brought into contact with the first portion of the second member and the solder paste brought into contact with the second portion of the second member to melt. In the melting, molten solder formed by melting the solder paste brought into contact with the first portion of the second member and molten solder formed by melting the solder paste brought into contact with the second portion of the second member are joined to each other.

A method of forming an electronic assembly. The method includes covering a patterned conductive layer that is on a dielectric layer with a solder resist; depositing a metal layer on to the solder resist; depositing a photo resist onto the metal layer; patterning the photo resist; etching the metal layer that is exposed from the photo resist to form a metal mask; removing the photo resist; and plasma etching the solder resist that is exposed from the metal mask. An electronic assembly for securing for an electronic card. The electronic assembly includes a patterned conductive layer that is on a dielectric layer; and a solder resist covering the patterned conductive layer and the dielectric layer, wherein the solder resist includes openings that expose the patterned conductive layer, wherein the openings in the solder resist only have organic material on side walls of the respective openings.

A wiring board includes a substrate, pads formed on an electronic-component mounting surface of the substrate, and a resin insulation layer covering the electronic-component mounting surface and having opening portions such that the opening portions are exposing the pads, respectively. The pads include a non-solder mask defined pad having a wiring portion and a non-solder mask defined pad having no wiring portion, and the opening portions are formed such that the non-solder mask defined pads have exposed conductor areas which have substantially same areas inside the opening portions.

A method for applying ink to a printed circuit board to form a pattern, the method may include flooding the printed circuit board with ink, such that the ink advances within edges of the pattern; freezing the ink before the ink exceeds the edges of the pattern; and vibrating the printed circuit board during a vibration period that at least partially overlaps at least one of the flooding and the freezing.