A modular multipurpose telecommunications enclosure has a plurality of walls, to which are removably affixed a plurality of mounting bulkheads. Each mounting bulkhead has a plurality of mounting holes arranged into a specified hole pattern that is configured to receive and mount cameras or other electronics units from various different equipment manufacturers which employ different hole patterns in their mounting kits. The enclosure is made of a high thermal conductivity material such as aluminum to promote convection cooling and employs one or more airflow vents to keep any internal electronics from reaching undesirably high temperatures during operation. The enclosure also features antenna mounting holes to accommodate various wireless communication antennas, as well as a mounting bracket to allow easy installation of the enclosure in a desired location. The enclosure is rugged and durable against the elements to facilitate purposes such as video monitoring of an outdoor area.

An electronic component module includes: a substrate including a conductive pattern; an electronic component provided to the substrate; a sealing portion covering the electronic component and substrate, and having an upper surface and a side surface that form an edge portion; a contact portion configured to be electrically connected with the conductive pattern, the contact portion exposed on a vertical surface continuous with the side surface of the sealing portion; a removal portion formed by removing the predetermined edge portion formed by the upper surface and the side surface of the sealing portion; and a shielding film covering the upper surface, the side surface and the contact portion of the sealing portion. The removal portion is a region allowing a conductive material to pass therethrough so that the contact portion is covered with the shielding film, the conductive material being scattered in vacuum atmosphere lower than atmospheric pressure.

An EMI/energy dissipating filter for an active implantable medical device (AIMD) is described. The filter comprises a first gold braze hermetically sealing the insulator to a ferrule that is configured to be mounted in an opening in a housing for the AIMD. A lead wire is hermetically sealed in a passageway through the insulator by a second gold braze. A circuit board substrate is disposed adjacent the insulator. A two-terminal chip capacitor disposed adjacent to the circuit board has an active end metallization that is electrically connected to the active electrode plates and a ground end metallization that is electrically connected to the at least one ground electrode plates of the chip capacitor. There is a ground path electrically extending between the ground end metallization of the chip capacitor and the ferrule. The ground path comprises at least a first electrical connection material connected directly to the first gold braze, and at least an internal ground plate disposed within the circuit board substrate with the internal ground plate being electrically connected to both the first electrical connection material and the ground end metallization of the chip capacitor. An active path electrically extends between the active end metallization of the chip capacitor and the lead wire.

An example implantable connector for connecting an electronics package and a neural interface is made by way of a compressible contacts (e.g., a spring) that physical contacts a corresponding exposed bond pad. The compressible contact is held in compression with the exposed bond pad using a mechanical coupler. The compressible contact is physically separated and electrically isolated from other contacts by way of a compressible gasket. The compressible gasket is also held in compression using the mechanical coupler.

A mobile terminal includes a display unit; a front window arranged in front of the display unit; a frame arranged behind the display unit; and a waterproof member arranged between an edge of the front window and an edge of the frame forming a closed loop and forming a sealed space between the front window and the frame by forming a looped curve, wherein the water proof member comprises a start portion, an end portion and the looped curve between the start portion and the end portion, the start portion and the end portion are bent toward the inside of the looped curve.

There are provided an electronic component housing package and the like which have high efficiency of heating by infrared rays. An electronic component housing package includes an insulating substrate including a plurality of insulating layers stacked on top of each other, an upper surface of the insulating substrate being provided with an electronic component mounting section. The plurality of insulating layers each contain a first material as a major constituent. The electronic component housing package comprises one or more infrared-ray absorbing layers disposed between the plurality of insulating layers and/or disposed on an upper surface of uppermost one of the plurality of insulating layers. The one or more absorbing layers contain a second material which is higher in infrared absorptivity than the first material.

An apparatus includes an upper housing, a gasket, and a lower housing. The upper housing generally comprises a plurality of tabs and a plurality of threaded sockets. The lower housing generally comprises a plurality of openings configured to engage the tabs of the upper housing and a plurality of holes configured to align with the plurality of threaded sockets when assembled to the upper housing.

An example implantable connector for connecting an electronics package and a neural interface is made by way of a set of compressible contacts (e.g., springs) that physical contact a set of corresponding exposed bond pads. The compressible contacts are held in compression with the exposed bond pads using a mechanical coupler. The compressible contacts are physically separated and electrically isolated from each other by way of a compressible gasket. The compressible gasket is also held in compression using the mechanical coupler.

A glass wafer has an internal surface and an opposing external surface separated by a wafer thickness. A hermetic, electrically conductive feedthrough extends through the wafer from the internal surface to the opposing external surface. The feedthrough includes a feedthrough member having an inner face exposed along the internal surface for electrically coupling to an electrical circuit. The feedthrough member extends from the inner face partially through the wafer thickness to an exteriorly-facing outer face hermetically embedded within the wafer.

A housing or enclosure for an electronic device is formed from a shell and chassis may positioned along an interior of the shell. The shell may be formed from a hard or cosmetic material and the chassis may be formed from a machinable material. The chassis may define one or more machined surfaces that are configured to receive or mount a component of the electronic device.