Plug-in connector (10) having an inner conductor (11), an insulating part (13) and an outer conductor (15), wherein the insulating part (13) is arranged between the inner conductor (11) and the outer conductor (15), wherein the inner conductor (11) and the insulating part (13) are of U-shaped design on account of having a first limb and a second limb as well as a web which connects the limbs, wherein the plug-in connector has a first end (17) and a second end (19) at which the plug-in connector (10) respectively forms a first interface and a second interface on account of the inner conductor (11) and in particular the outer conductor (15) being designed, at the first end (17) and the second end (19), to be connected to conductors (107, 108) of an object (110) for connection.

A cable connector assembly that may include a connector that may comprise a first body and a second body that may be configured to be coupled to the first body, and an adapter comprising a biasing portion. The biasing portion may be configured to be coupled to the second body. The biasing portion may be configured to have a space that is configured to allow the biasing portion to elastically deform radially inwardly. The biasing portion may be configured to exert an axial biasing force axially against the second body. The biasing portion may be configured to exert an outward radial biasing force against the second body. The biasing portion may be configured to provide the axial and radial biasing forces so as to provide a secure ground connection between the connector and the adapter and such that a push/pull connection between the connector and the adapter that is operable by a non-technician user.

A hybrid connector for a data cable, including: a galvanic connector having a plurality of connectors configured to make a galvanic connection with a plurality of connectors in a receptacle wherein a first portion of the plurality connectors are power connections and a second portion of the plurality of connectors are data connections; a plurality of millimeter wave wireless transmitter/receivers (TRx) configured to transmit/receive data from/to the hybrid connector; and a plurality of millimeter wave antennas surrounding the galvanic connector each antenna connected to one of the plurality of millimeter wave TRx's, wherein the plurality of millimeter wave antennas are configured to transmit/receive millimeter wave data signals.

A connection system for a quantum computer that employs constant impedance connectors with attenuation or filtering components or both embedded therein or within an adaptor removably insertable within an adaptor housing for use in a cryogenically cooled quantum computer. The connection system provides a higher density of cables traversing through a hermetic sealed top plate, and which are accessible to chill blocks to reduce the thermal energy from the signal lines. Attenuators or filter circuits are embedded in the constant impedance connector housings, or provided in adaptors that connect on each end to form mating constant impedance connections, in order to reduce signal strength as the signal progresses through the cryogenic environment and to remove extraneous electrical signal noise.

A tap for a cable-television network includes a coupling device configured to receive downstream signals from a distribution line, to provide upstream signals to the distribution line, or both, a plurality of signal conditioning circuits each configured to apply a signal conditioning effect to the downstream signals, the upstream signals, or both, a path-selection device electrically connected to the coupling device and configured to selectably route signals to one or more of the plurality of signal conditioning circuits, and one or more subscriber ports configured to receive at least some of the signals that are selectably routed by the path-selection device, and configured to connect to one or more cables extending to a subscriber premises.

A splitter for use in an in-home network includes an input and a plurality of outputs including at least a first output and a second output. A split point is between the input and the plurality of outputs. A first resistor and a first capacitor are connected in series between the input and the split point. A second resistor and a second capacitor are connected in series between the split point and the first output. A third resistor and a third capacitor are connected in series between the split point and the second output. The input, the first output, and the second output form a resistive Wye-type splitter. A first path exists between the input and the first output. A second path exists between the input and the second output. The first path and the second path have a substantially equal series resistance, series impedance, insertion loss, and isolation.

A connecting device configured to be installed on a first coaxial cable connector to facilitate connection of the first connector to a second connector and to maintain ground continuity across the connectors. In some embodiments, the connecting device includes a grounding element disposed in a gripping member, the grounding element including one or more projections configured to extend beyond an end of the gripping member to conductively engage an outer surface of the second connector.

Embodiments of a method for the manufacture of a connecting element for connecting one electrical assembly to another may comprise the steps of forming a rigid, tubular outer housing of an electrically conductive material, the outer housing having an axis which extends in a longitudinal direction; inserting longitudinally into the outer housing an electrical cable which has at least one inner conductor and a dielectric jacket surrounding the at least one inner conductor; and, reshaping at least one longitudinal segment of the outer housing to fix the electrical cable inside the outer housing. In some embodiments the reshaping may be carried out by rolling and in certain embodiments may be rolled radially at perimeter segments distributed along the perimeter of the longitudinal segment. Such perimeter segments may have a uniform radius and uniform arc length and may be spaced apart from one another such that a compensation segment is formed between the perimeter segments. The compensation segment may be a segment that accepts material displaced from the perimeter segments. In some embodiments the reshaping may comprise stamping the outer housing with stamping jaws. The forming step may comprise a step in which the outer housing is deep-drawn, extruded or turned from a metal blank.

A board to board connector assembly (1) includes a first connector (2) suitable to be arranged on a first printed circuit board (3) and a second connector (4) suitable to be arranged on a second printed circuit board (5). An adapter (6) is arranged in a mounted position between and interconnected to the first and the second connector (2, 4). The adapter (6) includes an adapter inner conductor (7) and an adapter outer conductor (8). The adapter outer conductor (8) is arranged separate from the adapter inner conductor (7) and comprises a bore (18) in which the adapter inner conductor (7) is arranged.

An electrical connector that has a conductive shell supporting at least one signal contact therein and that has a front end for mating with a mating connector and a back end opposite the front end for electrically connecting to a coaxial cable. A ground connection is located inside of the conductive shell. A coupling member is rotatably coupled to the conductive shell and has an engagement feature for mechanically engaging a support panel associated with the mating connector. A sealing member is disposed on the conductive shell that is configured to provide an environmental seal between the conductive shell and the support panel when the conductive shell is mated with the mating connector.