A light assembly and method of forming light assemblies includes a flexible light layer, a thermoplastic housing, and an IMC layer. The flexible light layer has a flexible substrate, a printed circuit, and a plurality of LEDs extending outward from the flexible substrate. The IMC layer is formed opposite the flexible light layer from the thermoplastic housing and covers the LEDs. Forming may include placing the flexible light layer within a mold cavity, injecting the thermoplastic structure on one side of the flexible light layer, and injecting the IMC layer on the opposite side of the flexible light layer from the thermoplastic structure. Injecting the thermoplastic structure into the mold cavity may change the shape of the flexible light layer. Datum features of the flexible light layer may align the thermoplastic structure relative to the datum features.

In an embodiment a carrier includes a base substrate, at least one insulating layer, at least one inner wiring layer, at least one outer wiring layer and at least one through-via in the insulating layer extending through the insulating layer, wherein the base substrate and the insulating layer are formed from different materials, wherein the base substrate is formed for mechanically stabilizing the carrier and supports the insulating layer, wherein the inner wiring layer is arranged in a vertical direction at least in places between the base substrate and the insulating layer, wherein the outer wiring layer is spatially separated from the inner wiring layer at least in places by the insulating layer, and wherein the through-via electrically conductively connects the inner wiring layer to the outer wiring layer and has a lateral cross-section having a maximum lateral extent of at most 100 μm.

An arrangement for exchanging heat between two bodies comprises a circuit board, having at least one first via and at least one second via, wherein at least one heat exchange structure is integrated in the circuit board, wherein the at least one heat exchange structure comprises two heat exchange layers and an intermediate layer arranged between the two heat exchange layers, wherein the two heat exchange layers are thermally joined to each other and electrically separated from each other by the intermediate layer, wherein a first heat exchange layer is associated with the first body and can be brought into thermal contact with it and a second heat exchange layer is associated with the second body and can be brought into thermal contact with it, wherein the at least one first via and the at least one second via are each led through the two heat exchange layers and the intermediate layer arranged between the two heat exchange layers, wherein the at least one first via is in contact only with the first heat exchange layer and is insulated from the second heat exchange layer, and wherein the at least one second via is in contact only with the second heat exchange layer and is insulated from the first heat exchange layer.

A printed circuit board includes a layered substrate having a plurality of layers having an electrical connector footprint configured to receive an electrical connector. The printed circuit board includes pair anti-pads passing through the layered substrate around pairs of signal vias. The printed circuit board includes ground vias passing through the layered substrate. The ground vias are configured to receive ground pins of the electrical connector. The ground vias are located outside of the pair anti-pads. The printed circuit board includes SI vias passing through the layered substrate. The SI vias form an SI fence surrounding the corresponding pair anti-pad.

A circuit module includes a circuit board including an insulating layer, first and second signal conductors, a ground conductor, and a ground conductor layer; and an electronic component including first and second signal terminals and a first ground terminal. The ground conductor includes a first strip portion parallel to the first and second signal conductors. When a portion of the first signal conductor parallel to the second signal conductor and the first signal terminal are set as a first signal wiring line and a portion of the second signal conductor parallel to the first signal conductor and the second signal terminal are set as a second signal wiring line, the circuit board includes a first strip portion connection via conductor that connects the first strip portion and the ground conductor layer in a region where the first and second signal wiring lines are parallel to each other.

A quantum computer includes a refrigeration system under vacuum including a containment vessel, a qubit chip contained within a refrigerated vacuum environment defined by the containment vessel. The quantum computer further includes a plurality of interior electromagnetic waveguides and a plurality of exterior electromagnetic waveguides. The quantum computer further includes a hermetic connector assembly operatively connecting the interior electromagnetic waveguides to the exterior electromagnetic waveguides while maintaining the refrigerated vacuum environment. The hermetic connector assembly includes an exterior multi-waveguide connector, an interior multi-waveguide connector, and a dielectric plate arranged between and hermetically sealed with the exterior multi-waveguide connector and the interior multi-waveguide connector. The dielectric plate permits electromagnetic energy when carried by the interior and exterior pluralities of electromagnetic waveguides to pass therethrough.

Provided is a device for transmitting signals, the device including: a first conductive base and a second conductive base parallel to each other, a waveguide at least partially surrounded by side walls located between the first conductive base and the second conductive base and including at least one electromagnetic band gap (EBG) structure, and at least two directional antennas opposite to or facing each other in a direction in which signals are transmitted, wherein each antenna is on a printed circuit board and includes another EBG structure located on an upper layer and a lower layer of the printed circuit board and at least one matching element, at least a part of each of the antennas is located inside the waveguide to form a wireless channel configured to transmit electromagnetic signals in an area between the antennas, and the at least one matching element is located within a specified distance of the wireless channel and is configured to match the antenna with the wireless channel.

An electronic assembly is provided, including a wiring board, a control element, and a pair of first internal electrical connectors. The wiring board includes a mounting surface, a first patterned conductive layer, a plurality of second patterned conductive layers, a plurality of near conductive holes, a plurality of far conductive holes, and a first conductive path. The first patterned conductive layer is located between the mounting surface and the second patterned conductive layers. The control element is mounted on the mounting surface of the wiring board. The pair of first internal electrical connectors are mounted on the mounting surface of the wiring board, and are adapted for mounting a pair of memory modules. The first conductive path extends from the control element at least through the corresponding second patterned conductive layer and the first patterned conductive layer to the pair of first internal electrical connectors.

Provided is a display device and an electronic apparatus that prevent the occurrence of failure in the connection between a mounting substrate and an electronic component. The display device includes an interconnection layer provided on a support substrate, a plurality of insulating layers provided above the interconnection layer, an opening provided in parts of the insulating layers, and a metal layer electrically connected to the interconnection layer and filling the opening up to a height below a layer surface of the insulating layer.

A coaxial line is provided which includes: a first columnar conductor disposed inside a multilayer substrate such that one end thereof is coupled to a first stripline and that the other end thereof is coupled to a second stripline; and one or more second columnar conductors penetrating the multilayer substrate such that one end thereof is coupled to a ground layer and that the other end thereof is coupled to a ground layer, the first columnar conductor acting as an inner conductor, and the second columnar conductors acting as outer conductors. Each of the first and second striplines is coupled to an open stub acting as resonators and a matching conductor acting as capacitance matching elements.