A connector assembly for a mobile device includes a bottom plate adapted to be operably coupled with a mobile device and a towel bar being operably coupled with the bottom plate. The towel bar has a quadrilateral cross section that defines at least a first engaging surface and a second engaging surface. The towel bar is adapted to engage an accessory device at at least one of the first engaging surface or the second engaging surface to couple the accessory device with the mobile device.

A telecommunications connector includes a connector body and a shield attached to the connector body, the shield including a main body portion configured for attachment to the connector body and a barrel portion for crimping against a cable to be terminated to the connector. The barrel portion of the shield includes a corrugated side wall made up of a series of bends extending along a direction from the rear end of the barrel toward the front end of the barrel along at least a portion of a length of the barrel, wherein the bends defining the corrugated side wall are provided on the shield at a pre-crimped stage.

A telecommunications connector includes a connector body and a shield attached to the connector body, the shield including a main body portion configured for attachment to the connector body and a barrel portion for crimping against a cable to be terminated to the connector. The barrel portion of the shield includes a corrugated side wall made up of a series of bends extending along a direction from the rear end of the barrel toward the front end of the barrel along at least a portion of a length of the barrel, wherein the bends defining the corrugated side wall are provided on the shield at a pre-crimped stage.

A plug-in connector for a two- or multi-wire cable includes a male and female contact. The male and female contacts are configured to be coupled to first and second wires, respectively, and are elongated in a plug-in direction. A carrier element is configured to position and receive the male and female contacts in first and second receiving spaces, respectively, each at a predefined angle with respect to the plug-in direction, and to electrically insulate the male and female contacts from one another. A shielding element includes first and second channels for receiving the first and second wires, respectively. The channels each penetrate the shielding element from its end located counter to the plug-in direction to its end located in the plug-in direction. The shielding element comprises an electrically conducting material, and is arranged at an end of the carrier element located counter to the plug-in direction.

A connector includes a housing having a fitting part that is inserted and fitted into a counterpart fitting part, a shield shell having a shell flange part disposed opposite a wall surface of a counterpart wall body with an interval therebetween, a first watertight member between the fitting part and the counterpart fitting part, and a second watertight member that is crushed between the shell flange part and a wall surface of the counterpart wall body. The housing has a housing flange part with an outer peripheral surface thereof disposed inside an outer peripheral edge of the shell flange part and outside an inner edge of the shell flange part, and with a contact surface with an annular shape in contact with the wall surface of the counterpart wall body.

A connector includes a housing having a fitting part that is inserted and fitted into a counterpart fitting part, a shield shell having a shell flange part disposed opposite a wall surface of a counterpart wall body with an interval therebetween, a first watertight member between the fitting part and the counterpart fitting part, and a second watertight member that is crushed between the shell flange part and a wall surface of the counterpart wall body. The housing has a housing flange part with an outer peripheral surface thereof disposed inside an outer peripheral edge of the shell flange part and outside an inner edge of the shell flange part, and with a contact surface with an annular shape in contact with the wall surface of the counterpart wall body.

In a connector assembly in which a connector that includes a ground terminal including a plate portion and a mating connector that includes a mating ground terminal including a mating plate portion are fitted to each other, the plate portion and the mating plate portion have plate surfaces that are parallel to each other, the plate portion is composed of a pair of U-shaped portions that are adjacent to each other, the mating plate portion is shaped to have a pair of projection portions forming a concave portion therebetween, the projection portions formed in a pair are respectively positioned in U shapes of the pair of U-shaped portions, each of leg portions of the mutually-adjacent U shapes in the pair of U-shaped portions is positioned in the concave portion, and protrusion portions of the leg portions are respectively in contact with the projection portions.

A receptacle connector assembly includes a receptacle cage including cage walls including a top wall and forming a module channel configured to receive a pluggable module. The top wall includes an opening open to the pluggable module. The receptacle connector assembly includes an EMI gasket coupled to the top wall at the opening. The EMI gasket provides electrical shielding at the opening. The EMI gasket has a base including a mounting surface coupled to the top wall of the receptacle cage. The EMI gasket has a plurality of mating interfaces. The receptacle connector assembly includes a heat sink coupled to the receptacle cage having a heat sink base with a thermal interface located in the module channel and configured to engage the pluggable module to dissipate heat from the pluggable module. The base engages the mating interfaces of the EMI gasket to electrically connect the heat sink to the EMI gasket.

Eyewear devices including a tether and methods for identifying proper installation of the tether are disclosed. An eyewear device includes transmission lines extending through the temples to electrical and electronic components positioned adjacent to edges of a frame. A tether is attached to the temples to enable power and communication flow between the electrical and electronic components rather than through the frame. Proper installation is identified based on communications passing between the electrical and electronic components via the tether.

A harness comprises a connector body, a cable and a cable-holding portion which holds the cable. The connector body comprises a base portion. The cable is connected to the connector body. The cable has an end portion received in the base portion and a main portion extending rearward from the end portion. The cable-holding portion is formed with a recessed portion which opens at least downward in the upper-lower direction (Z-direction). The base portion has an interference portion. The recessed portion and the interference portion are located at opposite sides of the harness, respectively, in the lateral direction (Y-direction). The recessed portion is, at least in part, located at a position same as that of the interference portion in the front-rear direction (X-direction). The recessed portion is, at least in part, located at a position same as that of the interference portion in the upper-lower direction.