A data processing device includes an internal volume that is electromagnetic interference (EMI) isolated and an optical state detector. The optical state detector obtains electromagnetic radiation from the internal volume while the internal volume is EMI isolated and makes a determination that a device disposed in the internal volume has an optical state associated with the electromagnetic radiation.

A shield structure includes a hollow tubular shield member, a shield shell having a plate-like shell body which is formed with a through hole, and a plate-like bent piece which is extended from an inner edge of the shell body that defines the through hole and which is bent to rise from the shell body, and an annular member which surrounds and fastens the bent piece, wherein at least one bent piece of the shield shell is extended from the inner edge of the shell body, and when the annular member surrounds and fastens the bent piece an outer surface of which is covered with a leading end in the longitudinal direction of the shield member, the leading end is clamped between the annular member and the bent piece.

A Faraday enclosure apparatus and method for manufacturing same are disclosure. The enclosure may comprise one or more sewn seam portions constructed to prevent signal leakage through stitch apertures in the seam. A vestibule section facilitates signal-shielded movement of electronic devices between the ambient environment and the main cavity of the enclosure. A connector filter may be mounted to extend through a wall of the enclosure to manage wired power and signal communications entering and exiting the main cavity of the enclosure. Foldable side walls facilitate the collapsibility of the enclosure for compact transport and storage.

A feed-through provides electromagnetic shielding where one or more signal leads pass through an enclosure. It comprises a frame, having at least one opening, and an assembly comprising two or more joining parts, forming one or more elongated waveguides. The joining parts are divisible along the length of the waveguides, thereby being capable of surrounding a signal lead. The assembly is adapted to be attached to the frame such that one or more signal leads can pass through an opening in the frame and through one of the waveguides. Installation is of the feed-through is made easier by the opening in the frame having a larger maximum extension than the maximum extension of a waveguide.

A cable assembly includes a grommet, a cable, and a ferrule. The grommet has a cylindrical sleeve defining a cable channel therethrough and a flange extending radially outward from the cylindrical sleeve. The cable includes one or more insulated wires, a cable shield surrounding the one or more insulated wires, and an outer jacket surrounding the cable shield. The cable extends through the cable channel of the grommet. The cable shield and the one or more insulated wires protrude from an end of the outer jacket. The cable shield has an overlap portion extending around the end of the outer jacket and surrounding and engaging the cylindrical sleeve of the grommet to electrically connect the cable shield to the grommet. The ferrule surrounds and engages the overlap portion of the cable shield to secure the overlap portion to the cylindrical sleeve of the grommet.

An actuator apparatus is described as having a stator device, a cover device, a contact device and an attenuation device. The stator device and the cover device are joined in such a manner so that a hollow space is formed between the stator device and the cover device. The cover device has an opening, through which the contact device is guided into the hollow space, so that the contact device runs at least partially in the hollow space and at least partially in the cover device. The attenuation device is positioned in the opening in such a manner so that a high-frequency electromagnetic radiation that travels through the opening is more highly attenuated by the attenuation device than the radiation would be attenuated without the presence of the attenuation device.

A device, system and method for protecting electronic systems from failure or damage when such systems are subjected to undesired conducted or radiated energy such as electromagnetic pulse or electromagnetic interference. The invention also reduces the amount of conducted or radiated emissions from an electronic system. A novel, non-conductive signal feedthrough allows a desired signal to be communicated with electrical connectivity. An incoming desired electrical signal is converted to vibrational energy by a piezoelectric transducer, which is communicated into the interior volume of a conductive electrical enclosure housing a system to be protected, where it is converted back to electrical for processing by the system to be protected by a second piezoelectric transducer. The signal feedthrough allows a continuous conductive enclosure to be employed, providing protection from undesired radiated energy. The signal feedthrough allows communication without requiring electrical conduction through the feedthrough, thus protecting against undesired conducted energy.

In a camera, a circuit board converts light having passed through a lens into an electric signal. A connector connects the circuit board to an outside cable. A shielding conductor surrounds the circuit board. An insulating housing houses the circuit board and the shielding conductor. A connector includes inner, intermediate, and outer connectors. The inner connector includes a first outer skin conductor, and is mounted to the circuit board. The intermediate connector includes a second outer skin conductor supporting a shielding conductor, and is connected to the inner connector and the shielding conductor. The outer connector includes a third outer skin conductor, and connects an outside cable to the intermediate connector. The shielding conductor wraps the circuit board from a boundary, as a starting point, between the second outer skin conductor and the shielding conductor. The insulating housing is connected to and supported by the intermediate connector.

An equipment enclosure (1) for electromagnetically isolating an electronic device, the equipment enclosure 1 comprising a conductive housing (3) and a plurality of conductive sheets (5). Each sheet (5) includes an aperture (7). The sheets (5) are stacked in a spaced-apart relationship within the housing (3) thereby defining a plurality of electromagnetically-isolated cavities (9) each within a respective Faraday cage formed by the conductive housing (3) and the conductive sheets (5). The apertures (7) form a channel (11) that extends through the enclosure (1) providing a route for connections between the cavities (9).

The invention relates to a front plate for a housing of a control installation, having a feedthrough for a plug connector. The front plate has at least one compensation element for compensating a tolerance-related offset (V.sub.A, V.sub.R) between the plug connector and the feedthrough (10) is disposed in the feedthrough and/or adjacent to the feedthrough.