According to one embodiment, a switching device includes a first switching element, a second switching element, and a holder. The first switching element includes a plurality of terminals. The second switching element includes a plurality of terminals and is provided apart from the first switching element in a thickness direction of the first switching element. The holder includes a holding member, a connection portion, and a conductor. The holding member is provided with a cavity to contain the first switching element. The cavity includes a bottom portion between the first switching element and the second switching element. The connection portion is provided on the holding member to face the cavity and is electrically connected to the second switching element. The conductor connects the connection portion and the terminals of the first switching element. The first switching element and the second switching element are connected in parallel.

A flexible electronic foil (1, 1, 1) comprising a flexible substrate (2) and at least one electrically conducive portion (3) arranged to the substrate (2). The foil (1, 1, 1) comprises mechanical fastening means (6, 6, 7) for mechanical fastening of the electronic foil (1, 1, 1), the mechanical fastening means being part of the substrate (2) of the electronic foil (1, 1, 1).

A mounting structure of the present disclosure includes a package on whose upper surface an electronic component is mounted, a voltage regulator module, a mother board for mounting the package on an upper surface of the mother board, a driver, a plurality of connectors for electrically connecting a conductor layer of the mother board and a conductor layer of the package to each other, and a heat sink.

Chip-on-board (COB) modular lighting systems and methods of manufacture are described herein. A system includes a COB assembly including a thermally conductive plate and a COB light-emitting diode (LED) device thermally coupled to the thermally conductive plate. The COB LED device includes multiple LED chips disposed on a surface of a substrate. The substrate includes first electrical power contacts exposed from at least the surface. The system further includes an electronics board that has second electrical power contacts. The electronics board is attached to the COB assembly such that the first and second electrical contacts are electrically coupled and the thermally conductive plate is attached to the electronics board.

An electronic component includes: a first substrate; a second substrate that includes a functional element formed on a lower surface of the second substrate, the second substrate being mounted on the first substrate so that the functional element faces an upper surface of the first substrate across an air gap; and an insulating film that is located on the upper surface of the first substrate, overlaps with at least a part of the functional element in plan view, faces the functional element across the air gap, and has a film thickness that is more than half of a distance between a lower surface of the functional element and the upper surface of the first substrate.

A ceramic electronic component includes an electronic component body and portions of first and second metal terminals covered with an outer resin material. The first metal terminal includes, connected in order, a first terminal joint portion, a first extension portion extending in a direction toward a mounting surface, and a first mount portion extending toward a side opposite to the electronic component body. The second metal terminal includes, connected in order, a second terminal joint portion, a second extension portion extending in the direction toward the mounting surface, and a second mount portion extending toward a side opposite to the electronic component body. The first and second mount portions respectively include first and second protrusions protruding toward the mounting surface. The outer resin material includes a protruding portion protruding toward the mounting surface.

An electronic component (E), including at least one circuit carrier (1), which is populated with a number of mechanical and/or electronic component parts (2 to 4) and has at least one contact opening (1.3) for forming a mechanical and/or electrical contact-connection point (KS) to at least one of the component parts (2 to 4), wherein at least one of the component parts (4) is at a distance from the circuit carrier (1), includes at least one electrically conductive housing (4.1) and at least one electrical contact element (4.2) projecting out of the housing (4.1), the contact element being insulated from the housing (4.1) and being connected at least in a materially bonded manner to the contact opening (1.3) of the circuit carrier (1), wherein at least one seal element (5) is arranged in the region of the contact-connection point (KS), in particular between the circuit carrier (1) and the housing (4) of the component part (4).

A printed circuit board composite and a method for producing same. In the method for producing the printed circuit board composite, a first printed circuit board, in particular a sensor carrier printed circuit board, is connected in a form-fitting manner to a second printed circuit board, in particular a supporting printed circuit board. There is also described a printed circuit board composite.

Methods to form a device whereon flexible component elements are attached upon three-dimensional surfaces are described. In some aspects, the present invention includes incorporating flexible semiconductor devices onto three-dimensional surfaces with electrical contacts. In some aspects, the formed device may be incorporated in an ophthalmic device.

The present disclosure provides a bracket for an electronic component. The bracket includes a bearing part configured to bear an electronic component and two side walls. The two side walls are oppositely arranged and disposed at the same side of the bearing part. The two side walls of the bracket are configured to be disposed on a mainboard and define together with the mainboard and the two side walls an accommodating space. The present disclosure further provides an electronic component assembly and a mobile terminal.