A floating connector includes a shell, a plurality of electrodes, two buckle members and a floating member. The shell has an accommodating space and a plurality of openings. The electrodes are disposed in the accommodating space and penetrate the openings to protrude from the openings. The buckle members are respectively disposed on two sides of the accommodating space. Each of the buckle members includes a fixed part, a contacting part, and an elastic part. The floating member includes a body, a plurality of electrode notches, and a bump. The electrode notches are formed on one side of the body that near the electrodes for receiving the electrodes protruding from the openings. The bump is disposed on the body and correspondingly to the notch, and the width of the bump is not greater than that of the notch, so that the bump is restricted in the notches by the guiding structure.

A floating connector includes a shell, a plurality of electrodes, two buckle members and a floating member. The shell has an accommodating space and a plurality of openings. The electrodes are disposed in the accommodating space and penetrate the openings to protrude from the openings. The buckle members are respectively disposed on two sides of the accommodating space. Each of the buckle members includes a fixed part, a contacting part, and an elastic part. The floating member includes a body, a plurality of electrode notches, and a bump. The electrode notches are formed on one side of the body that near the electrodes for receiving the electrodes protruding from the openings. The bump is disposed on the body and correspondingly to the notch, and the width of the bump is not greater than that of the notch, so that the bump is restricted in the notches by the guiding structure.

A cable connector for decreasing signal return loss includes a front cap, a base, and a connecting terminal. A first hole is formed on the front cap, and a second hole is formed on the base. A second front side of the base connects to a first back side of the front cap. The connecting terminal includes an elastic clamping part, a wire connection part, and a lead part. A back side of the clamping part is a free end, and a front side of the clamping part is connected to the wire connection part. The lead part is mounted in front of the wire connection part. The connecting terminal is mounted in the base, and the lead part pierces the front cap covering the connecting terminal through the first hole. The present invention prevents capacitance in the cable connector, and improves electric signal transmission efficiency.

A coaxial connector assembly has a housing with at least one contact receiving cavity which extends from a mating end to a contact assembly receiving end. The contact receiving cavity has a mounting section proximate the contact assembly receiving end. A contact assembly is positioned in the contact receiving cavity. The contact assembly has a front flange proximate a mating portion of the contact assembly. A positioning member is inserted on the mating portion of the contact assembly. The positioning member cooperates with the flange to position the positioning member on the mating portion of the contact assembly. The positioning member cooperates with a wall of the contact receiving cavity to limit the movement of the mating portion of the contact assembly in a direction which is transverse to a longitudinal axis of the contact assembly.

A ground block may include a metal ground plate and a ground wire fixedly coupled with the metal ground plate. The ground wire is configured to be non-detachable from the ground block during normal use of the ground block. The ground block may be formed by soldering, brazing, or clamping the ground wire to the metal ground plate.

An apparatus and a method for optically linking at least two AC and DC low voltage cascading power grids connecting at least two intelligent support boxes (ISB) each powered by two distinct AC standard power grid and separately powered by DC low voltage power grid with each grid is further linked by a cascading segments of optical cable grid, enabling two way control, operate and report electrical activity through plug in wiring devices (PWD) for supporting DC and AC plurality of connected/attached loads.

A ganged connector assembly includes: a plurality of coaxial connectors, each of the coaxial connectors connected with a respective coaxial cable extending rearwardly therefrom, each of the coaxial connectors including an inner contact and an outer body that is electrically separated from the inner contact; a shell having a plurality of cavities; and a plurality of rear bodies, each of the rear bodies encircling a respective outer body, each of the rear bodies mounted in a respective cavity of the shell. Each of the rear bodies includes a first locking feature. A second locking feature is located in each of the cavities and is fixed relative to the shell. The first and second locking features are configured such that rotation of a first of the plurality of rear bodies relative to the shell moves the first rear body between locked and unlocked positions, wherein in the locked position a respective first connector and respective first cable are secured with the shell within a respective cavity, and in the unlocked position the first connector and first cable can be removed from the shell without removing the remaining connectors and cables.

An electromagnetic interference (EMI) shield system is disclosed. The system may include an EMI gasket assembly configured to prevent radio frequency (RF) radiation from escaping through a gap between a RF connector and the enclosure. The gasket assembly may include a gasket including a receiving portion. The receiving portion may be configured to receive a portion of a shaft of the RF connector. The gasket may be formed of a compressible material. The gasket assembly may include a spacer configured to couple to a portion of the shaft of the RF connector. The spacer may be configured to compress the gasket against a portion of the enclosure when the spacer is rotated in a first direction. The spacer may be configured to provide electrical continuity between the radio frequency connector and the gasket by causing the gasket to form an electrical connection with the enclosure when the gasket is compressed.

A modular RF apparatus includes an RF portal and an RF expansion module configured to be coupled with the RF portal. The modular RF apparatus is configured to expand the number of outputs of the RF portal by adding the RF expansion module in a manner that minimizes an increase in the spatial footprint of the modular RF apparatus while allowing easy access to all ports of the modular RF apparatus. The RF portal and the RF expansion module are configured to interlock to create an integrated functional block. The modular RF apparatus are configured to permit upgrading of the RF portal by adding the RF expansion module without disrupting existing connections to the RF portal.

A modular RF apparatus includes an RF portal and an RF expansion module configured to be coupled with the RF portal. The modular RF apparatus is configured to expand the number of outputs of the RF portal by adding the RF expansion module in a manner that minimizes an increase in the spatial footprint of the modular RF apparatus while allowing easy access to all ports of the modular RF apparatus. The RF portal and the RF expansion module are configured to interlock to create an integrated functional block. The modular RF apparatus are configured to permit upgrading of the RF portal by adding the RF expansion module without disrupting existing connections to the RF portal.