The present invention relates generally to electric circuit testing, building, or implementing using a breadboard style PCB. Aspects of the present invention include eliminating the need to use hookup wires when building and testing electric circuits on PCBs. In embodiments, a PCB system having rows and columns of signal tie points connected in a breadboard layout and using an embedded wire and a solder bridge to form partial connections between signal tie points. In embodiments, the embedded wire and solder bridge is capable of connecting a column of signal tie points. In embodiments, the embedded wire and solder bridge is capable of connecting a power rail to a signal tie point. Thus, a circuit can be implemented and tested by applying a small amount of solder to the solder bridge without the need for hookup wires.

A printed circuit board (PCB) comprises a blind via and a discrete component vertically embedded within the blind via.

A printed circuit board (1) comprising an insulating layer (2) and a conducting layer (3) arranged on the insulating layer (2) and structured into a contact surface (4) for an electronic component (11) which is to be populated on the printed circuit board (1) has, in the area of the contact surface (4), at least one channel (8) that passes through the contact surface (4) and the insulating layer (2) and that is filled with a thermally conductive material. The process is characterized by the steps of preparing an insulating layer (2) and a conducting layer (3) connected with the insulating layer (2); producing at least one channel (8) passing through the conducting layer (2) and the insulating layer (3); lining the channel (8) with thermally conductive material; structuring the conducting layer (3) into a contact surface (4) for an electronic component (11) to be populated on the printed circuit board; preparing a solder deposit (9) at least minimally overlapping with the contact surface (4); setting down the electronic component (11); melting the solder, and cooling.

A display device including a film substrate including first and second surfaces, the first surface being opposite to the second surface; a semiconductor chip disposed on the first surface and including an input terminal and a test terminal, which are arranged in a first direction; a first wire extending from the input terminal on the first surface along a second direction, which intersects the first direction; and a second wire including a first extended portion, which extends along the first surface, a second extended portion, which extends along the second surface, and a first via, which penetrates the film substrate and connects the first extended portion and the second extended portion, wherein the first extended portion extends from the test terminal in the second direction and is connected to the first via, and the second extended portion extends from the first via to an edge of the second surface.

A method includes forming one or more vias in a first layer, forming one or more vias in at least a second layer different than the first layer, aligning at least a first via in the first layer with at least a second via in the second layer, and bonding the first layer to the second layer by filling the first via and the second via with solder material using injection molded soldering.

A laminated substrate includes: a first substrate; a second substrate having a through-hole; a third substrate; a first adhesive layer bonding a rear surface of the first substrate and a front surface of the second substrate; a second adhesive layer bonding a rear surface of the second substrate and a front surface of the third substrate; a first post penetrating through the first adhesive layer, electrically connecting the first substrate to the second substrate, and made of an alloy of a high melting point metal and a low melting point metal; a second post penetrating through the second adhesive layer, electrically connecting the second substrate to the third substrate, and made of an alloy of the high melting point metal and the low melting point metal; and an electronic component fixed to the front surface of the third substrate and disposed in the through-hole of the second substrate.

A wiring board assembly (1) includes: a flexible printed wiring board (2) which includes at least an insulating substrate (5) including a through-hole (53), and wiring patterns (61) and (62) provided on the insulating substrate (5) and extending to peripheral edge portions (531n) and (532n) of the through-hole (53); a metal reinforcing plate (3) attached to the flexible printed wiring board (2) and facing the through-hole (53); and a solder connection portion (4) covering an inner wall surface (534) of the through-hole (53) and electrically connecting the wiring patterns (61) and (62) to the metal reinforcing plate (3).

A module component includes a substrate; first, second, third and fourth main electrodes on or in a principal surface of the substrate; a sub-electrode located between two of the four main electrodes and connected to one of the four main electrodes by a solder; a first mount component mounted to the first and second main electrodes; and a second mount component mounted to the third and fourth main electrodes; wherein an area of the sub-electrode is smaller than an area of each of the first, second, third and fourth main electrodes.

Techniques and mechanisms for controlling configurable circuitry including an antifuse. In an embodiment, the antifuse is disposed in or on a substrate, the antifuse configured to form a solder joint to facilitate interconnection of circuit components. Control circuitry to operate with the antifuse is disposed in, or at a side of, the same substrate. The antifuse is activated based on a voltage provided at an input node, where the control circuitry automatically transitions through a pre-determined sequence of states in response to the voltage. The pre-determined sequence of states coordinates activation of one or more fuses and switched coupling one or more circuit components to the antifuse. In another embodiment, multiple antifuses, variously disposed in or on the substrate, are configured each to be activated based on the voltage provided at an input node.

The present invention relates to a circuit board including: a base board having a circuit region and a terminal region; a circuit pattern formed on an upper portion of the base board; and a low-melting-metal layer formed on an upper portion of the circuit pattern. A circuit board capable of reducing manufacturing time and manufacturing costs may be manufactured by omitting a photoresist process.