Techniques for shielding wearable surface electromyography (sEMG) devices are described. According to some aspects, an sEMG device may comprise amplification circuitry comprising at least a first differential amplifier and at least two sEMG electrodes electrically connected to the amplification circuitry. The device may further comprise at least one auxiliary conductor not electrically connected to the amplification circuitry, wherein the at least one auxiliary conductor is configured to be electrically coupled to a wearer of the wearable device, and an electromagnetic shield surrounding the wearable device at least in part and electrically connected to the at least one auxiliary conductor.

A junction box used for making electrical connections to a photovoltaic panel. The junction box has two chambers including a first chamber and a second chamber and a wall common to and separating both chambers. The wall may be adapted to have an electrical connection therethrough. The two lids are adapted to seal respectively the two chambers. The two lids are on opposite sides of the junction box relative to the photovoltaic panel. The two lids may be attachable using different sealing processes to a different level of hermeticity. The first chamber may be adapted to receive a circuit board for electrical power conversion. The junction box may include supports for mounting a printed circuit board in the first chamber. The second chamber is configured for electrical connection to the photovoltaic panel. A metal heat sink may be bonded inside the first chamber.

A shielding member includes a frame body and an outer cover. Two sides of a first end of the frame body respectively include a first shaft portion. Two sides of the frame body respectively include a first side plate. The frame body is covered by the outer cover. Two sides of a first end of the outer cover respectively include a second shaft portion, and each of the second shaft portions is pivotally connected to the corresponding first shaft portion. Two sides of the outer cover respectively include a second side plate, and each of the second side plates covers an outer side of the corresponding first side plate. Accordingly, the frame body and the outer cover are assembled to form a one-piece metallic shielding member. The structure of the shielding member is simple, the manufacturing for the shielding member is easy, and the cost for manufacturing the shielding member is reduced.

In accordance with some embodiments, an apparatus that seals the audio path of an enclosed device is provided. The apparatus includes a first housing portion and a second housing portion, when mated, are arranged to enclose a device, where a surface of the second housing portion is arranged to impart pressure on the device toward the first housing portion. The apparatus further includes a first supporting portion disposed along one side of the first housing portion and arranged to support the device. The apparatus also includes a first liner disposed in the first housing portion and arranged to form a first cavity, where the first cavity is adjacent to the first supporting portion. The apparatus further includes a noise generator operable to provide noise signal stream and a first audio output device coupled to the noise generator operable to output first masking signals to the first cavity.

A circuit board assembly for association with an aircraft includes a circuit board and an electromagnetic interference component connected to the circuit board. The circuit board assembly may further include an enclosure having an electromagnetic signal permissive layer and an electromagnetic signal blocking layer. The electromagnetic signal permissive layer may include a housing that define a volume. The housing may enclose the electromagnetic interference component on the circuit board. The electromagnetic signal blocking layer defines a conductive barrier about the electromagnetic interference component.

An enclosure includes a power flow control device to attach to a high voltage transmission line, a plurality of panels formed of metal, a shorting connection provided between each pair of panels, an electrical connection from at least one panel of the plurality of panels to the high voltage transmission line, a receiving region provided on each panel for each shorting connection, and an equipotential surface for reducing electromagnetic interference from the high voltage transmission line to internal components of the power flow control device, and from the internal components of the power flow control device to the high voltage transmission line.

The electronic device includes: a substrate having an electronic circuit formed therein; a housing for housing the substrate; and a connector disposed on the substrate and serving as an interface between outside and inside of the housing. The substrate has a main circuit pattern portion that forms a main circuit and a frame ground pattern portion that forms a frame ground. The main circuit pattern portion and the frame ground pattern portion are disposed so as not to overlap each other on the substrate and in the substrate. A terminal of the connector is disposed in the frame ground pattern portion.

An apparatus includes a ear piece case housing, a receptacle within the ear piece case housing and configured to hold an earpiece, an earpiece connector at the receptacle and configured to electrically connect with the earpiece, and electromagnetic shielding materials integrated into the ear piece case housing to electromagnetically isolate the earpiece while the earpiece is contained within the case housing. The ear piece case housing may include a charger and a removable slide cover adapted for sliding over the charger.

A laminated electronic component includes a multilayer body including multiple insulator layers that are laminated and including a bottom surface, a top surface, and multiple side surfaces. The laminated electronic component includes a shield film provided on at least one side surface of the multilayer body. In the laminated electronic component, at least one step difference is provided along a ridge at which the bottom surface and a corresponding one of the side surfaces of the multilayer body are connected to each other, and the shield film includes an edge portion disposed within the at least one step difference.

A method for reducing a volume of air within an electrical distribution system. The method includes providing at least one cable, surrounding the at least one cable with an isolating unit, placing a first shielding body on a top surface of the isolating unit, placing a second shielding body on a bottom surface of the isolating unit, wherein placing the first shielding body and the second shielding body creates a gap X1 between the first shielding body or the second shielding body and the isolating unit, and crimping the first shielding body to the second shielding body to create a shield housing, so that a gap X2 is created between the first shielding body or the second shielding body and the isolating unit, wherein X2 is less than X1. The at least a portion of the first shielding body may overlap with the second shielding body, and the first shielding body or the second shielding body may include at least one flared portion. The overlap may occur at a location corresponding to the flared portion, with the flared portion having a length N, wherein N may be equal to about 2(X1−X2). Gaps X1 and X2 may be air gaps.