A method for producing a modularly configurable plug comprises inserting a cable insulator in a pre-shaped outer cable contact, positioning an inner cable contact of a cable in the cable insulator, and bending the pre-shaped outer cable contact to form a cable section. The cable section is adapted to a diameter of the cable and a diameter of the inner cable contact. The method further comprises positioning an inner interface contact in an interface insulator and inserting the interface insulator in an outer interface contact to form an interface section. The interface section is connected to the cable section. The interface section has one of a plurality of different lengths or one of a plurality of different shapes interchangeably connected to the cable section.

A connector assembly includes a connector module having a connector body with side edges and end edges. The connector body has contact channels holding contacts. The connector assembly includes a mounting frame having side walls and an end wall opposite a window between the side walls. The window is open to and provides access to a passage that receives the connector module. The mounting frame includes a connector module support structure for supporting the connector module in the passage that defines a confined space oversized relative to the connector body of the connector module to allow a limited amount of floating movement in the confined space in a lateral direction that is perpendicular to the mating direction.

A vehicular camera assembly includes a front housing portion accommodating a lens, a circuit board having an imager and an electrical connecting element at opposite sides thereof, a rear housing portion and an electrical connector. The rear housing portion includes a rear attachment portion that has an aperture therethrough. The electrical connector electrically connects a wire of the vehicle to the electrical connecting element of the circuit board. The electrical connector includes an electrically conductive element that is electrically conductively connected to an outer ground contact of the connector. The rear housing portion includes a shield element having flexible tabs that protrude through the aperture. As the electrical connector is attached at the rear attachment portion, the shield element tabs engage the electrically conductive element to establish and maintain electrically conductive connection between the shield element and the electrically conductive element and the outer ground contact of the connector.

A vehicular camera assembly includes a front housing portion accommodating a lens, a circuit board having an imager and an electrical connecting element at opposite sides thereof, a rear housing portion and an electrical connector. The rear housing portion includes a rear attachment portion that has an aperture therethrough. The electrical connector electrically connects a wire of the vehicle to the electrical connecting element of the circuit board. The electrical connector includes an electrically conductive element that is electrically conductively connected to an outer ground contact of the connector. The rear housing portion includes a shield element having flexible tabs that protrude through the aperture. As the electrical connector is attached at the rear attachment portion, the shield element tabs engage the electrically conductive element to establish and maintain electrically conductive connection between the shield element and the electrically conductive element and the outer ground contact of the connector.

Receptacles are provided for mating with plugs to establish electrical connections. The receptacles include a shell having a body, and a flange attached to the body. The flange has a projection extending therefrom. The receptacle also has an electrically-insulating insert positioned at least in part within the body; and one or more electrical contacts positioned at least in part within the insert. The receptacle is configured for mounting on a panel. The projection contacts a mounting surface of the panel, to establish a localized contact area that provides bonding between the receptacle and panel.

An ultra-high frequency super thin coaxial RF connector assembly comprising a combination of an ultra-high frequency super thin coaxial RF board side connector and an ultra-high frequency super thin coaxial RF wire side connector, wherein the arrangement of a traditionally conventional board side connector center terminal is omitted for the ultra-high frequency super thin coaxial RF board side connector, for the ultra-high frequency super thin coaxial RF wire side connector to transfer an RF signal to a circuit board directly without using an RF board side center terminal. As such, there is no need to arrange a board side center terminal in the Ultra high frequency super thin coaxial RF board side connector, so that a board side shield terminal in the Ultra high frequency super thin coaxial RF board side connector may provide an electrical shield more effectively, allowing the ultra-high frequency super thin coaxial RF connector assembly of the present invention to be capable of providing an RF signal in an UHF (Ultra High Frequency) millimeter wave band above 30 GHz for transmission.

An ultra-high frequency super thin coaxial RF connector assembly comprising a combination of an ultra-high frequency super thin coaxial RF board side connector and an ultra-high frequency super thin coaxial RF wire side connector, wherein the arrangement of a traditionally conventional board side connector center terminal is omitted for the ultra-high frequency super thin coaxial RF board side connector, for the ultra-high frequency super thin coaxial RF wire side connector to transfer an RF signal to a circuit board directly without using an RF board side center terminal. As such, there is no need to arrange a board side center terminal in the Ultra high frequency super thin coaxial RF board side connector, so that a board side shield terminal in the Ultra high frequency super thin coaxial RF board side connector may provide an electrical shield more effectively, allowing the ultra-high frequency super thin coaxial RF connector assembly of the present invention to be capable of providing an RF signal in an UHF (Ultra High Frequency) millimeter wave band above 30 GHz for transmission.

A jumper cable assembly includes: a plurality of jumper cables, each having a first end terminated in a first connector and a second end terminated in a second connector; and a first mounting structure, the first connectors being mounted in the first mounting structure in a fixed arrangement relative to each other, the arrangement matching an arrangement of connectors of one of an antenna and a piece of cellular equipment to facilitate installation of the jumper cable assembly.

A jumper cable assembly includes: a plurality of jumper cables, each having a first end terminated in a first connector and a second end terminated in a second connector; and a first mounting structure, the first connectors being mounted in the first mounting structure in a fixed arrangement relative to each other, the arrangement matching an arrangement of connectors of one of an antenna and a piece of cellular equipment to facilitate installation of the jumper cable assembly.

Electrical equipment comprising a first portion and a second portion that is electrically insulated from the first portion, the first portion comprising a frontal component, a diode, a photodiode and a processing module, the second portion comprising a first connector connected to the frontal component while being electrically insulated therefrom, a receiving space being arranged to receive a second connector that is able to be connected to the first connector, the processing module being arranged to deliver a supply current to the light-emitting diode so that the latter produces an emitted light signal, in order to acquire a detection electrical signal produced by the photodiode representative of a light signal received by the photodiode, and in order to detect a presence or absence of the second connector in the receiving space depending on the detection electrical signal.