Embodiments of a connecting element for connecting a first electrical assembly to a second electrical assembly may comprise a rigid, tubular outer housing made of an electrically conductive material and an electrical cable running inside the outer housing along a longitudinal axis of the outer housing. The electrical cable may include at least one inner conductor and a dielectric layer surrounding the at least one inner conductor. At least one segment of the outer housing may be reshaped along the longitudinal axis in such a way as to fix the electrical cable inside the outer housing.

A connector is provided and includes an alignment plate defining major and minor apertures, a capture plate and a pin plate. The capture plate includes an outer body defining an opening, an inner body traversing the opening and first elastic elements extending from the inner body to generate first biases. The capture plate is securable to the alignment plate to position the inner body between the major apertures. The pin plate defines intermediate apertures and includes pins and second elastic elements to generate second biases opposing the first biases. The pin plate is interposable between the alignment and capture plates whereby the intermediate and major apertures align and the pins extend through the minor apertures.

A connector is provided and includes an alignment plate defining major and minor apertures, a capture plate and a pin plate. The capture plate includes an outer body defining an opening, an inner body traversing the opening and first elastic elements extending from the inner body to generate first biases. The capture plate is securable to the alignment plate to position the inner body between the major apertures. The pin plate defines intermediate apertures and includes pins and second elastic elements to generate second biases opposing the first biases. The pin plate is interposable between the alignment and capture plates whereby the intermediate and major apertures align and the pins extend through the minor apertures.

A guarded coaxial cable assembly including at least a pair of conductors, one or more rails, and a jacket covering these parts such as a first rail extending alongside two nearby conductors, the rail and the conductors embedded in an outer electrically insulating jacket, the outer jacket having a pair of generally opposed bearing surfaces for bearing transverse loads, the rail operative to reduce outer jacket deformations resulting from transverse loads applied to the bearing surfaces; and, the orientation of the rail and the conductors within the outer jacket operative to limit conductor or conductor jacket deformations resulting from transverse loads applied to the bearing surfaces.

A guarded coaxial cable assembly including at least a pair of conductors, one or more rails, and a jacket covering these parts such as a first rail extending alongside two nearby conductors, the rail and the conductors embedded in an outer electrically insulating jacket, the outer jacket having a pair of generally opposed bearing surfaces for bearing transverse loads, the rail operative to reduce outer jacket deformations resulting from transverse loads applied to the bearing surfaces; and, the orientation of the rail and the conductors within the outer jacket operative to limit conductor or conductor jacket deformations resulting from transverse loads applied to the bearing surfaces.

Systems and methods of using a multiport assembly and associated components are disclosed. The multiport assembly can include a multiport device that communicatively couples multiple sets or pairs of connectors, such as optical connectors or electrical connectors, together. The multiport assembly can also include an auxiliary port device that couples to the multiport device to expand the capacity of the multiport assembly. Both the multiport and auxiliary port devices can be selectively configured to receive specific types of connectors by selectively coupling to different types of adapters, where the types of adapters correspond to the types of connectors. When coupled to the multiport or auxiliary port devices, the adapters facilitate the formation of the communication between its corresponding set of connectors.

There is provided a coaxial connector device that enables a reduction in deterioration in signal quality and transmission characteristics at high frequencies. A coaxial connector device 1 includes a main connector 10 and a board connector 20. A main connector body 11 has a first fitting part R1 for a coaxial cable connector at one end and a second fitting part R2 at the other end. Inside the main connector body 11, a center contact 13 and a card edge substrate 17 electrically connected to the center contact 13 are included. In a board connector body 21 a slot 23 is formed. When the second fitting part R2 of the main connector 10 is fitted to the board connector 20, the end portion of the card edge substrate 17 is coupled to the slot 23 of the board connector body 21, a plurality of substrate contacts included in the card edge substrate 17 electrically contacts a plurality of inner contacts 25 of the board connector body 21, and the second fitting part R2 of the main connector body 11 electrically contacts an outer conductor contact 27.

There is provided a coaxial connector device that enables a reduction in deterioration in signal quality and transmission characteristics at high frequencies. A coaxial connector device 1 includes a main connector 10 and a board connector 20. A main connector body 11 has a first fitting part R1 for a coaxial cable connector at one end and a second fitting part R2 at the other end. Inside the main connector body 11, a center contact 13 and a card edge substrate 17 electrically connected to the center contact 13 are included. In a board connector body 21 a slot 23 is formed. When the second fitting part R2 of the main connector 10 is fitted to the board connector 20, the end portion of the card edge substrate 17 is coupled to the slot 23 of the board connector body 21, a plurality of substrate contacts included in the card edge substrate 17 electrically contacts a plurality of inner contacts 25 of the board connector body 21, and the second fitting part R2 of the main connector body 11 electrically contacts an outer conductor contact 27.

An electrical connector that comprises an outer conductive shell supporting at least one signal contact therein and that includes a front end for mating with a mating connector and a back end opposite the front end for electrically connecting to a printed circuit board or a coaxial cable. A primary ground connection is located either inside or outside of the outer conductive shell. The primary ground connection is configured to electrically engage the mating connector with the printed circuit board or with the coaxial cable. A secondary ground connection is located either inside or outside of the outer conductive shell. The secondary ground connection is configured to electrically engage the mating connector with the printed circuit board or with the coaxial cable.

An electrical connector that comprises an outer conductive shell supporting at least one signal contact therein and that includes a front end for mating with a mating connector and a back end opposite the front end for electrically connecting to a printed circuit board or a coaxial cable. A primary ground connection is located either inside or outside of the outer conductive shell. The primary ground connection is configured to electrically engage the mating connector with the printed circuit board or with the coaxial cable. A secondary ground connection is located either inside or outside of the outer conductive shell. The secondary ground connection is configured to electrically engage the mating connector with the printed circuit board or with the coaxial cable.