An electronic device including a substrate comprising a hole, and a capacitor capable of being inserted and fixed to the hole of the substrate. The electronic device includes a substrate including a hole, and a capacitor inserted to the hole so as to be mounted on the substrate. The capacitor includes a case provided to accommodate a dielectric therein and forming an exterior of the capacitor, a lead wire connected to the dielectric and extending from an inside of the case to an outside of a first side surface of the case, and a groove recessed on a second side surface of the case opposite to the first side surface and provided to be engaged with a side, which forms a circumference of the hole, of the substrate to allow the case to be inserted and fixed to the hole.

An indicating device includes an enclosure and an indicating lamp. The enclosure includes a base. The base defines a receiving space and an opening communicating with the receiving space. When the indicating lamp is received in the receiving space, the base partially shields the indicating lamp allowing light from the indicating lamp to be transmitted only through the opening.

An electronic contact lens contains electrical components connected by an electrical interconnect. The electrical interconnect has a flat body, with electrical conductors running length-wise along the body. The flat body is oriented perpendicular rather than parallel to the inner and outer surfaces of the contact lens to reduce a visible profile of the interconnect, reducing the amount of light blocked from entering the eye. The body has a curvature shaped to conform to the curvature of the contact lens. As examples, the interconnect may be connected with an electrical component using a tab perpendicular to the flat body of the interconnect, or by forming an edge connection with electrical contacts of the component located along an edge of the component, or through one or more exposed vias formed on the component.

A capacitor module has a module case including a lower case and an upper case. A housing case is fixed to an inner face of the upper case, and a capacitor is housed in the housing case. A circuit board is fixed to an upper face of the lower case. The circuit board has wiring that is electrically connectable to the capacitor, and electronic components and constituting a circuit that controls electric current to the capacitor are mounted on the circuit board.

A connectable assembly is provided and includes a body defining a recess, a male conductive element supportively disposed proximate to the body and a conductive compliant (CC) plug disposed within the recess for establishing a radially compliant, axially free running electrical connection with the male conductive element.

A method is disclosed for manufacturing an electronic component carrier. The method comprises positioning a header of a frame between opposing attachment arms extending outwardly for attaching an electronic component for seating within the frame. Further, latching members of a latching mechanism of the frame are positioned at a distal end of each of the attachment arms for releaseably seating the electronic component. The attachment arms are resiliently flexible such that the latching members bend to a release position and resiliently return to a grasping position for releasing and grasping the electronic component. Handling levers are positioned for removably mating the electronic component to a connector on a circuit board. The handling levers extend upwardly through an outer casing housing the circuit board when in an open position, and the handling levers are substantially parallel with a top surface of the header when in a closed position.

A semiconductor integrated circuit device (101) includes a component built-in board (21) in which at least a first core layer (Co21) on which a first electronic component (C21) is mounted, a second core layer (Co22) on which a second electronic component (C22) is mounted, an adhesive layer (Ad21) arranged between the first core layer (Co21) and the second core layer (Co22), and wiring layers (L21-L28) are stacked; a third electronic component (SoC) mounted in a first core layer (Co21) side of the component built-in board (21) and electrically connected to at least one of the first and second electronic components (C21, C22) through the wiring layers (L21 to L28); and an external connection terminal (BE) formed in a second core layer (Co22) side of the component built-in board (21) and electrically connected to at least one of the first and second electronic components (C21, C22).

Systems, methods, and devices for electrically coupling an integrated circuit to a set of coaxial lines via a printed circuit board assembly are described. A device sample holder includes a printed circuit board that is operable to edge-couple to an integrated circuit. A surface of the printed circuit board that carries a set of coaxial connectors is orthogonal to another surface of the printed circuit board that exposes a set of conductive traces. The set of conductive traces are operable to electrically couple to a set of conductive paths of an integrated circuit to provide a communicative path between the integrated circuit and components of an input/output system in a refrigerated environment.

A multilayer ceramic capacitor includes a capacitor main body including a multilayer body including dielectric layers and internal electrode layers alternately laminated, and external electrodes each at end surfaces of the multilayer body and connected to the internal electrode layers, and two interposers on a surface in a lamination direction of the capacitor main body, and spaced apart from each other in a length direction connecting the two end surfaces and intersecting the lamination direction. The external electrodes each include a bulge portion protruding in the lamination direction on the surface of the capacitor main body. The interposers each include a recess portion on each of the end surfaces, and in a cross section extending in the lamination direction and the length direction and passing through a center in a width direction. The bulge portion is closer to the end surface in the length direction than the recess portion.

A support structure located at a bottom of a ball grid array (BGA) is provided. The support structure includes a printed circuit board (PCB) having first positioning pin holes, an interface plate having second positioning pin holes which correspond to the first positioning pin holes arranged on the PCB, a support film arranged on the PCB and having support portions, and positioning components penetrating the first positioning pin holes and the second positioning pin holes corresponding to the first positioning pin holes to assemble the support film on the PCB and the interface plate.