A coaxial connector has a first coaxial connector portion (1) and a second coaxial connector portion (2). The first coaxial connector portion (1) has an external conductor which is designed as a coaxial socket and the distal end of which is designed as a spring cage (3) with individual spring lugs (9.sub.1, 9.sub.2, 9.sub.3, 9.sub.4, 9.sub.5). The second coaxial connector portion (2) has an external conductor (6) which is designed as a coaxial plug. An electrical and mechanical connection exists between the spring lugs (9.sub.1, 9.sub.2, 9.sub.3, 9.sub.4, 9.sub.5) of the first coaxial connector portion (1) and an external shell surface of the external conductor (6) of the second coaxial connector portion (2). In the region of each gap (10.sub.1, 10.sub.2, 10.sub.3, 10.sub.4, 10.sub.5) that is situated between in each case two adjacent spring lugs (9.sub.1, 9.sub.2, 9.sub.3, 9.sub.4, 9.sub.5), there is provided at least one shielding component (11.sub.1, 11.sub.2, 11.sub.3, 11.sub.4, 11.sub.5, 11.sub.1′, 11.sub.2′, 11.sub.3′, 11.sub.4′, 11.sub.5′) which is connected respectively to one of the two adjacent spring lugs (9.sub.1, 9.sub.2, 9.sub.3, 9.sub.4, 9.sub.5). A multiple coaxial connector portion has multiple first coaxial connector portion is arranged in a housing (12).

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.

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.

A self-set home automation and method for handling the self-set home automation and the related devices including cascading intelligent support boxes and plug-in devices to provide simple to install and operate, with less wiring wherein the cascaded devices are optically linked, to include separated low voltage grid and related devices, and a converter for communicating RF, wifi and IR.

A shielding spring shell has a contact tab with a pair of spring sections adjoining a fillet. One of the spring sections is an at least radially resilient radial spring and another of the spring sections is an at least axially resilient axial spring.

A vehicular camera assembly includes a front housing portion accommodating a lens, a circuit board having a connecting element, 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 harness of the vehicle to the connecting element of the circuit board. The electrical connector includes an electrically conductive element that is electrically conductively connected to a coaxial or shielded wire connecting element of the electrical connector. The rear housing portion includes an electrically conductive element that protrudes through the aperture. As the electrical connector is attached at the rear attachment portion, the electrically conductive element of the rear housing portion engages the electrically conductive element of the electrical connector to establish and maintain electrically conductive connection between the electrically conductive elements.

A vehicular camera assembly includes a front housing portion accommodating a lens, a circuit board having a connecting element, 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 harness of the vehicle to the connecting element of the circuit board. The electrical connector includes an electrically conductive element that is electrically conductively connected to a coaxial or shielded wire connecting element of the electrical connector. The rear housing portion includes an electrically conductive element that protrudes through the aperture. As the electrical connector is attached at the rear attachment portion, the electrically conductive element of the rear housing portion engages the electrically conductive element of the electrical connector to establish and maintain electrically conductive connection between the electrically conductive elements.

An anti-noise component is an anti-noise component for a connector including a plug provided on an end portion of a coaxial cable and a jack provided at an opening of a metal housing of an electronic device, the anti-noise component including a cylindrical first conductive member into which the plug is inserted, and a cylindrical second conductive member into which the first conductive member is inserted, wherein a holding portion for the plug is formed on an inner circumferential portion of the first conductive member, an external thread portion is formed on an outer circumferential portion of the first conductive member, an internal thread portion is formed on an inner circumferential portion of the second conductive member, the external thread portion can be screwed into engagement with the internal thread portion, a flange portion is formed at a first end of the second conductive member, and a joining portion to be joined to an outer face of the metal housing is formed on the flange portion.

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 connector assembly includes an outer conductive body having a first end configured to mate with a corresponding electrical connector, and a conductive center contact arranged within the outer conductive body. The center contact comprises a first end configured to mate with the corresponding electrical connector and a second end electrically connecting with a first electrical contact of a circuit board. An outer contact is slidably attached to a second end of the outer conductive body and electrically connects with a second electrical contact of the circuit board. An elastic element is provided for biasing the outer contact in a direction away from the outer conductive body and toward the circuit board.