An interface for mitigating electromagnetic interference (EMI) on a printed circuit board (PCB) is disclosed. The PCB can contain circuit components and includes one or more signal planes sandwiched between corresponding ground planes. The PCB has a first and second side and an interface region separating the first and second sides that includes a partition wall projecting outward from the interface region, configured for EMI shielding between the first side and second sides, one or more pairs of input and output pads straddling the interface region on respective first and second sides and configured to accommodate an EMI line filter, and a ground barrier within the printed circuit board under the interface region. A method of mitigating EMI using the interface is also disclosed.

Disclosed is an electronic apparatus including a printed board, a plurality of connectors mounted on the printed board, a plurality of communication control circuits that is mounted on the printed board and that controls communication through corresponding ones of the plurality of connectors, and a shield member disposed to face the printed board, in which an annular ground pattern surrounding, without interruption, a shield area including the plurality of communication control circuits is formed on a front surface of the printed board, the plurality of connectors is all disposed outside the ground pattern surrounding the shield area, and the shield member covers the shield area and is fixed to the printed board such that a portion facing the ground pattern is electrically connected to the ground pattern.

An electronic module that comprises a housing; a cover that is disposed over the housing to define an interior; and one or more electronic components positioned within the interior is provided. At least a portion of the housing, cover, or both contain a polymer composition that exhibits an in-plane thermal conductivity of about 1 W/m-K or more as determined in accordance with ASTM E 1461-13 and an electromagnetic shielding effectiveness of about 20 dB or more as determined at a frequency of 1 GHz in accordance with EM 2107A.

Wireless electronic devices include one or more wireless antennas to provide for wireless communications. The antenna cables are routed internally within the device and typically noise from components located on a circuit board may couple to the antenna cables and cause a degradation in wireless performance, impact antenna sensitivity and cause packet loss. Utilizing raised pathways in a heat sink utilized for thermal transfer of heat to a housing enables tunnels to be formed between the housing and the heat sink. Routing the antenna cables through the tunnels improves noise isolation for the antenna cables while still maintaining the heat transfer. The raised pathways are configured to not interfere with components on the circuit board or components included in the housing. The wireless antennas may be mounted within the housing instead of on the board so no portion of the antenna cables are located on the circuit board.

An electromagnetic pulse (EMP) resistant telecommunications system includes core components mounted within and shielded by a Faraday cage. The components include a data source or storage device. An ethernet switch selectively connects the data source or storage device to a primary satellite router and a post-EMP satellite router. Telecommunications signals are output from and input to the core components via low noise blocks (LNBs) and block upconverters (BUCs). A method of resisting EMP interference for a telecommunications system includes the steps of enclosing and shielding core components in a Faraday cage and providing output via LNBs and BUCs to an antenna subsystem.

Methods and systems capable of launching signal-carrying transverse electromagnetic waves onto a transmission line in the higher voltage region of the transmission distribution network. Such methods and systems may include a surface wave launcher located in the higher voltage region, a network unit located in a lower voltage region, and an arrester separating the surface wave launcher and the network unit, the arrester preventing voltage from arcing over from the higher voltage region to the lower voltage region where the arrester provides the signal to the surface wave launcher.

A network communication device includes communication circuitry configured to communicate signals over a network cable, and a connector configured to connect to the network cable. The connector includes one or more signal terminals, an inner shield connection and an outer shield connection. The one or more signal terminals are configured to connect to one or more signal conductors of the network cable for communicating the signals. The inner shield connection surrounds the one or more signal terminals and is connected to a circuit ground of the communication circuitry. The outer shield connection surrounds the inner shield connection and is connected to an additional ground of the network communication device, the additional ground being different from the circuit ground.

An information handling system to wirelessly transmit and receive data may include a base chassis including a metal C-cover and metal D-cover to house a processor, a memory, and a wireless adapter, the metal C-cover to house a speaker grill, the speaker grill covering a speaker to emit audio waves; the speaker grill formed within the C-cover to emit a target radio frequency (RF) including a slot formed around a portion of the speaker grill forming a peninsula on the speaker grill that is physically separated from the C-cover; an antenna element placed behind the speaker grill and operatively coupled to the wireless adapter; an electromagnetic interference (EMI) shield forming a cavity enclosing the speaker and the antenna element, including a plurality of metallic shielding walls extending from the C-cover to a D-cover of the information handling system; and a conductive rubber gasket placed between the plurality of conductive walls and the D-cover to shield the cavity from EMI sources.

The present disclosure relates to an enclosure comprising a body, a lid, a locking member, and a resilient element arranged between the body and the lid. The resilient member is arranged to exert a resistive force on the lid when pressed between the body and the lid to seal the enclosure in a sealed position. The body includes at least a first recess and the lid includes at least a second recess, where each pair of a first recess and second recess is arranged to align in the sealed position, and to form a corresponding channel when aligned against the resistive force such that the enclosure is in the sealed position, and to then receive a corresponding locking member in the channel.

An endoscope connector includes: a plug including an electric contact configured to be electrically connected to an external medical apparatus, the plug being provided with a first substrate; a first frame electrically connected to the plug; a second frame electrically connected to the first frame, the second frame being made of metal; a first electric connection member electrically connected to the first substrate; a second electric connection member connected to the first electric connection member; a substrate unit including a second substrate and an electromagnetic shield member covering the second substrate, the electromagnetic shield member being made of metal; and an urging member configured to urge the substrate unit in a direction of the second frame, and to put the electromagnetic shield member into an electric conduction state by causing the electromagnetic shield member to abut on the second frame.