An angle connector for differential transmission of data signals, having first and second conductor pair ends in a first and second flat angle connector end surface, respectively, wherein the connector end surfaces are tilted spatially relative to one another, wherein, between the angle connector end surfaces, the angle connector has at least one first curved section in which all conductors of the conductor pair(s) are arranged with the respective longitudinal axes parallel to one another and all longitudinal axes follow a curved line, wherein in the first curved section, the longitudinal axes of at least one conductor pair follow differently curved lines, which are curved to varying degrees in such a way that, in the first curved section, two conductors have different geometric lengths relative to one another, wherein the angle connector has at least one second section in which all conductors of the conductor pair(s) are twisted for a predetermined fraction of a lay length in such a way that all conductors of the conductor pair(s) have an identical geometric length.

A wire holder (4) for a modular communications connector includes insertion cavities (21, 22, 25) positioned for receiving a set of twisted conductor pairs so that each conductor pair can be inserted in an insertion cavity and/or two conductor pairs can be inserted in a same insertion cavity, depending on the communications cable type, its constructive features, the type of application, such that it provides a better performance, such as for data communications cables for high data rates. The wire holder (4) distributes the set of insertion cavities (21, 22, 25) in more than two planes, such that a first plane comprises two insertion cavities (21) that each accept one pair of conductors, a second plane comprises an insertion cavity (25) that accepts one pair of conductors and a third plane includes an insertion cavity (22) that accepts more than one pair of conductors.

A wire holder (4) for a modular communications connector includes insertion cavities (21, 22, 25) positioned for receiving a set of twisted conductor pairs so that each conductor pair can be inserted in an insertion cavity and/or two conductor pairs can be inserted in a same insertion cavity, depending on the communications cable type, its constructive features, the type of application, such that it provides a better performance, such as for data communications cables for high data rates. The wire holder (4) distributes the set of insertion cavities (21, 22, 25) in more than two planes, such that a first plane comprises two insertion cavities (21) that each accept one pair of conductors, a second plane comprises an insertion cavity (25) that accepts one pair of conductors and a third plane includes an insertion cavity (22) that accepts more than one pair of conductors.

An electrical connector system includes a connector with a plug. A shroud extends over a portion of the plug and is coupled with the plug. A conductive socket is configured for receiving the plug of the connector. The socket includes a groove formed on an outer surface thereof. The shroud includes spring fingers having a lock portion thereon configured for engaging the groove for securing the connector in the socket. A collar is slidably mounted on the conductive socket and is configured for sliding between a locked position proximate to the socket groove and an unlocked position. The collar is further configured for engaging the spring fingers of the connector shroud in the locked position to hold the finger lock portions engaged with the groove to lock the connector in the socket.

An electrical connector system includes a connector with a plug. A shroud extends over a portion of the plug and is coupled with the plug. A conductive socket is configured for receiving the plug of the connector. The socket includes a groove formed on an outer surface thereof. The shroud includes spring fingers having a lock portion thereon configured for engaging the groove for securing the connector in the socket. A collar is slidably mounted on the conductive socket and is configured for sliding between a locked position proximate to the socket groove and an unlocked position. The collar is further configured for engaging the spring fingers of the connector shroud in the locked position to hold the finger lock portions engaged with the groove to lock the connector in the socket.

Improved wiring arrangements for sensor catheters are provided to reduce wire-to-wire cross-talk wherein wires connecting the sensor of the sensor catheter to a processing unit are divided into a plurality of wire bundles contained within respective sheaths, with the wires in wire bundle twisted together reduce electromagnetic signal interference among the individual wires, or between wire bundles.

Improved wiring arrangements for sensor catheters are provided to reduce wire-to-wire cross-talk wherein wires connecting the sensor of the sensor catheter to a processing unit are divided into a plurality of wire bundles contained within respective sheaths, with the wires in wire bundle twisted together reduce electromagnetic signal interference among the individual wires, or between wire bundles.

A wire containment cap includes a first side having a plurality of retainers for retaining wires, and a second side opposite the first side. Two sidewalls extend between the first side and the second side, and a support rib extends between the two sidewalls. The support rib includes two pair separators for separating wire pairs. In one embodiment, a plurality of sloped pair splitters is located between two of the retainers and includes a sharp point for cutting through insulation material on a pair of bonded wires. A communication jack assembly including a front portion and the wire containment cap is also described.

A system having a plurality of plug-in connectors each with a housing, the shape of the housings differing such that the housings have first housing parts which, at least in terms of the interface connections to second housing parts, are identical to the other components of the particular plug-in connector, and second housing parts having identical connecting means for connecting with the first housing part, and differ slightly in the external shape which serves to form a coding by which the individual positions of the individual plug-in connectors on or in the multiple housing are assigned.

A system having a plurality of plug-in connectors each with a housing, the shape of the housings differing such that the housings have first housing parts which, at least in terms of the interface connections to second housing parts, are identical to the other components of the particular plug-in connector, and second housing parts having identical connecting means for connecting with the first housing part, and differ slightly in the external shape which serves to form a coding by which the individual positions of the individual plug-in connectors on or in the multiple housing are assigned.