A printed circuit board includes a first chip component, a second chip component, and a printed wiring board. The first chip component and the second chip component each has a length L2 in the longitudinal direction. A relationship of 0.894≤L2/L1≤1.120 is satisfied, where L1 represents a length of the first opening in the longitudinal direction. A relationship of 0.894≤L2/4≤1.120 is satisfied, where length L4 represents a length of the second opening in the longitudinal direction. A relationship of 0.183≤L.sub.OA/L.sub.iA≤50.309 is satisfied, where L.sub.iA represents a length of the first land in the longitudinal direction, and L.sub.OA represents a thickness of solder on an end surface of the first electrode. A relationship of 0.183≤L.sub.OB/L.sub.iB≤0.309 is satisfied, where L.sub.iB represents a length of the second land in the longitudinal direction, and L.sub.OB represents a thickness of solder on an end surface of the second electrode.

A housing, for surface-mount technology (SMT), accepts any electronics package that is mounted on a circular substrate. The housing including the assembled electronics package forms an SMT housing assembly. The SMT housing assembly is placed directly onto the surface of a printed circuit board (PCB). The SMT housing assembly is soldered to the PCB using standard soldering techniques, establishing an electrical connection between the electronics package and the PCB.

An electronic component mounting device includes an insulating substrate having a metal pattern formed thereon and a MELF electronic component. The MELF electronic component is fitted into a first receiving portion configured with the metal pattern and the insulating substrate exposed from a lacking portion of the metal pattern. The electronic component mounting device further includes a conductive member formed between the MELF electronic component and the metal pattern, and the conductive member is not formed between the MELF electronic component and the insulating substrate.

A component built-in substrate includes a multilayer body and a substrate including a multilayer ceramic electronic component embedded therein. The multilayer ceramic electronic component includes a first connection portion that protrudes from the first external electrode, and a second connection portion that protrudes from the second external electrode. The substrate includes a core material. The multilayer ceramic electronic component including the first connection portion and the second connection portion includes a surface covered by the core material and embedded in the substrate. The first connection portion protrudes toward a surface of the substrate, and is not exposed at the surface of the substrate. The second connection portion protrudes toward the surface of the substrate, and is not exposed at the surface of the substrate.

Provided are a nano-scale LED assembly and a method for manufacturing the same. First, a nano-scale LED device that is independently manufactured may be aligned and connected to two electrodes different from each other to solve a limitation in which a nano-scale LED device having a nano unit is coupled to two electrodes different from each other in a stand-up state. Also, since the LED device and the electrodes are disposed on the same plane, light extraction efficiency of the LED device may be improved. Furthermore, the number of nano-scale LED devices may be adjusted. Second, since the nano-scale LED device does not stand up to be three-dimensionally coupled to upper and lower electrodes, but lies to be coupled to two electrodes different from each other on the same plane, the light extraction efficiency may be very improved. Also, since a separate layer is formed on a surface of the LED device to prevent the LED device and the electrode from being electrically short-circuited, defects of the LED electrode assembly may be minimized. Also, in preparation for the occurrence of the very rare defects of the LED device, the plurality of LED devices may be connected to the electrode to maintain the original function of the nano-scale LED electrode assembly.

A multilayer ceramic electronic component and a board having the same are provided. The multilayer ceramic electronic component includes a multilayer ceramic capacitor including external electrodes including front portions and band portions extended from the front portions, terminal electrodes respectively surrounding the front portions and portions of lower surfaces of the band portions of the external electrodes and respectively having a ‘’ shaped groove portion formed in lower portions thereof, and conductive adhesive layers connecting the external electrodes and the terminal electrodes to each other.

An electronic component unit and a wire harness include a bus bar plate. The bus bar plate is equipped with a resistor that has a main body and a pair of terminals protruding from the main body, and a substrate main body in which a metallic bus bar is built in a resin material and which has a component mounting section with the resistor mounted thereon. The component mounting section includes a pair of through-holes that penetrates the resin material and the bus bar and allows the terminals to pass, and a recess that is provided between the pair of through-holes, extends in a straight line shape connecting the pair of through-holes, and is capable of supporting the main body of the resistor.

An inductor includes a magnetic core, a first winding, a first electrically conductive standoff, and a second electrically conductive standoff. The magnetic core includes opposing first and second outer surfaces separated from each other in a first direction. The first winding has first and second ends, and the first winding is wound around at least a portion of the magnetic core. The first electrically conductive standoff is connected to the first end of the first winding, and the first electrically conductive standoff extends along the magnetic core in the first direction from the first outer surface to the second outer surface. The second electrically conductive standoff is connected to the second end of the first winding, and the second electrically conductive standoff extends along the magnetic core in the first direction from the first outer surface to the second outer surface.

What is described is a mounting aid for mounting electrical components, in particular electrolytic capacitors or chokes, on a printed circuit board, said mounting aid comprising a body, which has compartments for receiving the electrical components, wherein the compartments have a base with openings for the insertion of connection wires of the electrical components, and metal parts fastened to the body, which metal parts each form at least one contact pin on the underside of the body and each from a busbar for connection to electrical components in a plurality of compartments of the body.

Embodiments include a method of stress testing an electronics package with components that include a visual indicator. In an embodiment, the method comprises populating a plurality of components on an electronics package. In an embodiment, the plurality of components each comprise a visual indicator that is responsive to heat. In an embodiment, the method further comprises stress testing the electronics package and categorizing the plurality of components based on the visual indicators. In an embodiment, the method may further comprise modifying the plurality of components.