An electromagnetic shielding element and, transmission line assembly and electronic structure package using the same are provided. The electromagnetic shielding element is applied to the transmission line assembly and the electronic structure package to shield electromagnetic noise. The electromagnetic shielding element includes a quantum well structure, and the quantum well structure includes at least two barrier layers and at least one carrier confined layer located between the two barrier layers. Each barrier layer has a thickness between 0.1 nm and 500 nm, and the thickness of the carrier confined layer is between 0.1 nm and 500 nm. The electromagnetic shielding element absorbs electromagnetic wave noise to suppress electromagnetic interference.

Example embodiments described in this disclosure are generally directed to a plastic enclosure that provides EMI shielding and heat sinking to an electronic assembly. In one embodiment, the enclosure includes a housing portion formed of a base material that includes a polymer containing graphene nanostructures and carbon nanostructures. The graphene nanostructures provide a thermal conductivity characteristic to the base material. A set of standoff elements made of the base material is provided inside the housing for mounting the electronic assembly. Heat generated by the electronic assembly is conducted out of the enclosure by the standoff elements due to the graphene nanostructures. The carbon nanostructures provide an electrical conductivity characteristic to the base material. A lid formed of the base material may be attached to the housing portion. The carbon nanostructures in the housing portion and the lid provide EMI shielding to the electronic assembly inside the enclosure.

A housing (121) having an electromagnetic shielding property includes a resin molded body (101), which is a cured product of a thermosetting resin composition, and a plating layer (103) provided on a surface of the resin molded body (101) (cured product), in which the plating layer (103) includes a Cu layer (first plating layer (105)), and a thickness of the Cu layer (first plating layer (105)) is 2 μm or more and 30 μm or less.

A display assembly for an imaging device including a display panel, a display, a first control unit, a second control unit and a thermally insulating layer, and a housing. The thermally insulating layer divides the housing in at least a first cavity including the first control unit and a second cavity including the second control unit. The thermally insulating layer preventing heat generated in the first cavity or the second cavity from reaching the other cavity and including an electrically conductive material to at least partially shield electromagnetic radiation generated in the first or the second cavity from reaching the other cavity.

An electronic device includes an electromagnetic interference shield having a layer of conductive material covering at least a portion of the electronic device and having a skin depth of less than 2 μm for electromagnetic signals having frequencies in a kilohertz range.

Disclosed herein is an electromagnetic shielding housing including a housing body, and a fan unit coupled to the housing body, wherein an electromagnetic shielding layer is provided on an inner surface of the housing body, and the fan unit includes a fan configured to generate an air flow into an internal space of the housing body, and a Peltier element configured to cool air flowing into the internal space of the housing body.

In a described example, a structure includes a substrate having a surface with multiple sides. A sensor is positioned within the substrate and a seed layer is over at least four sides of the surface of the substrate. A magnetic shield layer is over the seed layer for the at least four sides of the surface of the substrate.

A circuit module 2 comprises: a wiring structure 4; at least one electronic component 6a, 6b arranged on the upper surface of the wiring structure 4; an insulating resin layer 8 which is provided on the upper surface of the wiring structure 4 and in which at least one electronic component 6a, 6b is embedded; and a metal layer 10 provided on the upper surface of the insulating resin layer 8. The surface roughness of the portion S1 directly above each electronic component on the upper surface of the insulating resin layer 8 is expressed as R1. The surface roughness of the portion S2 other than the portion directly above all the electronic components on the upper surface of the insulating resin layer 8 is expressed as R2. At least one R1 satisfies the condition: R1>R2.

Example embodiments described in this disclosure are generally directed to a plastic enclosure that provides EMI shielding and heat sinking to an electronic assembly. In one embodiment, the enclosure includes a housing portion formed of a base material that includes a polymer containing graphene nanostructures and carbon nanostructures. The graphene nanostructures provide a thermal conductivity characteristic to the base material. A set of standoff elements made of the base material is provided inside the housing for mounting the electronic assembly. Heat generated by the electronic assembly is conducted out of the enclosure by the standoff elements due to the graphene nanostructures. The carbon nanostructures provide an electrical conductivity characteristic to the base material. A lid formed of the base material may be attached to the housing portion. The carbon nanostructures in the housing portion and the lid provide EMI shielding to the electronic assembly inside the enclosure.

To provide an electronic control device capable of securing electromagnetic compatibility and mechanical strength. An electronic control device includes a base portion formed in a bottomed cylindrical shape; an electronic control board provided in the base portion; and connectors provided on an opening side of the base portion and electrically connected to the electronic control board, in which the base portion includes a first layer formed of a conductive member and a second layer formed of a member different from that of the first layer.