Various embodiments may relate to a lighting module, including a first printed circuit board, on which at least one light source is arranged, a covering element, which at least partially covers the first printed circuit board, and a second printed circuit board, on which at least one electronic component is arranged, wherein the second printed circuit board is fastened to the covering element and is electrically connected to the first printed circuit board.

An electronic device including a housing; a printed circuit board (PCB) in the housing, wherein the PCB includes a plurality of layers with one or more conductive and insulation layers; a first electrical component formed as at least a part of or in the housing; a second electrical component above or near the PCB in the housing, wherein the first and second electrical components are separated; and at least one electrical path extending from the first electrical component to the second electrical component, wherein at least a portion of the electrical path runs on or inside the PCB, wherein the PCB includes a region including a pattern of conductive vias, wherein each of the vias extends through at least part of the plurality of layers to contact at least one of the one or more conductive layers, and wherein the electrical path runs through the region without contacting the vias.

A conductive element such as an antenna, for use in electronic devices, including mobile devices such as cellular phones, smartphones, personal digital assistants (PDAs), laptops, and wireless tablets, and methods of, and apparatus for, forming the same. In one exemplary aspect, the present disclosure relates to a conductive antenna formed using deposition of conductive fluids as well as the method and equipment for forming the same. In one embodiment, a complex (3D) conductive trace is formed using two or more different print technologies via creation of different domains within the conductive trace pattern.

A package, able to encapsulate at least one component, forming a closed cavity of Faraday cage type having side walls resting on a base and that are surmounted by a cover, wherein at least one of the side walls includes exterior electrical connection elements linked electrically to the interior of the cavity, the exterior connection elements able to interconnect with an exterior circuit such that the side wall faces the exterior circuit when the exterior connection elements are interconnected with the circuit.

Tamper-proof electronic packages and fabrication methods are provided which include a glass substrate. The glass substrate is stressed glass with a compressively-stressed surface layer. Further, one or more electronic components are secured to the glass substrate within a secure volume of the tamper-proof electronic package. In operation, the glass substrate is configured to fragment with an attempted intrusion event into the electronic package, and the fragmenting of the glass substrate also fragments the electronic component(s) secured to the glass substrate, thereby destroying the electronic component(s). In certain implementations, the glass substrate has undergone ion-exchange processing to provide the stressed glass. Further, the electronic package may include an enclosure, and the glass substrate may be located within the secure volume separate from the enclosure, or alternatively, the enclosure may be a stressed glass enclosure, an inner surface of which is the glass substrate for the electronic component(s).

A wearable electronic device includes a ring-shaped main body, plural receiving parts, plural circuit boards and a wiring board. The plural receiving parts are disposed within the ring-shaped main body. The plural circuit boards are disposed within the corresponding receiving parts. One of the plural circuit boards corresponds to one receiving part. The wiring board is 111 within the ring-shaped main body and electrically connected with the plural circuit boards. Consequently, the circuit boards are electrically connected with each other through the wiring board.

A method of manufacturing an assembly with a housing part and at least two conductors of shape sheet metal parts may include providing at least one first conductor formed from at least one sheet metal part and at least one second conductor formed from at least one sheet metal part. The method may then include arranging the first and second conductors in an injection mould in such a way that the first conductor may come into mechanical contact with the second conductor in a common contact zone to produce an electrical connection. The method may then include at least partially overmoulding the first and second conductors with a plastic to form a joint housing part. The method may further include bonding the first and second conductors in a region of the common contact zone after at least partially overmoulding the first and second conductors.

In a composite component having a laminate body, a conductive layer and a connector can be joined to one another using an intermediate flexible circuit. Among other things, this flexible circuit places the conductive layer and the connector in electrical communication with one another. Furthermore, during the forming process and because of its thinness, the flexible circuit integrates well with the layers of the laminate body and can accommodates some spatial displacement of the connector and conductive material relative to one another.

An electronic device may include a mechanical structure that mechanically supports the electronic device. One or more traces may be formed on one or more surfaces of the mechanical structure. Other electrical components may also be mounted on the surface of the mechanical structure and may or may not be connected to one or more of the traces. Additionally, one or more passivation layers may be formed on one or more of the surfaces, traces, and/or other electrical components and one or more traces and/or other electrical components may be intermixed with such passivation layers. In this way, the mechanical structure may be operable to function as an electrical component of the electronic device.

A physical quantity detector includes a housing, a circuit board, a cover, a resin member, a conductor, and a conductive member. The circuit board includes a board surface. The cover faces the board surface and defines, together with the hosing, a passage through which the target fluid flows. The conductor includes a passage side portion and a connecting portion. The conductive member electrically connects the connecting portion to the circuit board. The conductive member includes a first end in the thickness direction facing a contact target that is either one of the connecting portion or the board surface. The first end includes a contact portion in contact with the contact target and a contactless portion away from the contact target in the thickness direction.