Abstract:
Various implementations of communications connectors are disclosed. In some implementations, a communications connector, such as a communications plug, may include a plug body and a termination sled positioned at least partially in the plug body. The termination sled may include a printed circuit board (PCB) having a front section, a rear section, and a connecting section connecting the front section and the rear section. In some implementations, a communications cord may include a communications plug having a conductive shell and PCB assembly. The PCB assembly may include a PCB, front and rear load bars, and a shielded divider.
Abstract:
A communication connector has a housing for receiving a communication plug, a printed circuit within the housing, a switch which actuates the printed circuit board, and a translating crossbar which engages the switch. The printed circuit board is moved dependent upon a type of plug inserted. The movement of the circuit board can help to selectively engage one of two sets of circuit traces and groupings of contacts.
Abstract:
Embodiments of the present invention relate to the field of telecommunication, and more specifically, to communication connectors such as, for example, shielded plug and jack connectors. In an embodiment, the present invention is a communication jack that includes a housing and a front sled assembly having a plurality of plug interface contacts (PICs), the front sled assembly being moveable along a horizontal plane of the communication jack between a first position and a second position, the first position being different from the second position.
Abstract:
A communication plug having a plug body and a plurality of contact pairs at least partially within the plug body, the contact pairs including an inherent asymmetric coupling between individual contacts of one of the contact pairs and other individual contacts of another of the contact pairs. Second asymmetric coupling elements are connected between the individual contacts of one of the contact pairs and the other individual contacts of another of the contact pairs. The second asymmetric coupling elements, when combined with the inherent asymmetric coupling, provide a balanced symmetric coupling between the individual contacts of one of the contact pairs and the other individual contacts of another of the contact pairs.
Abstract:
Embodiments of the present invention relate to the field of telecommunication, and more specifically, to communication connectors such as, for example, shielded plug and jack connectors. In an embodiment, the present invention is a communication jack that includes a housing and a front sled assembly having a plurality of plug interface contacts (PICs), the front sled assembly being moveable along a horizontal plane of the communication jack between a first position and a second position, the first position being different from the second position.
Abstract:
Embodiments of the present invention generally relate to the field of electronic communication, and more particularly, to techniques used to compensate for/reduce/or otherwise manipulate crosstalk in communication connectors, and apparatuses and methods which employ such techniques. In an embodiment, the present invention is a communication connector that includes a plurality of signal pairs including at least a first pair and a second pair, a first compensation stage between the first pair and the second pair, and an orthogonal compensation network between the first pair and the second pair. The orthogonal compensation network can be time delayed from the first compensation stage.
Abstract:
A twinax cable is described. The twinax cable has at least one twinax wire pair with a first shield tape wrapped around it and then surrounded by a second shield tape wrapped around the twinax wire pair and the first shield tape. The shield tapes are wrapped such that the metallic sides of the tape face and make contact with each other.
Abstract:
A method of detecting a fault in a power distribution system includes placing a signal on the system at a frequency F1 and then detecting a change in the signal due to a change in the impedence of the system as a result of a fault wherein the change is one of a change in phase, a change in signal tone, or a change in voltage level at the load. In one embodiment, band reject filters can be used to diminish the signal at the load or source. In another embodiment, the power source can be a periodic pulsed power source and the signal can be placed on the system during an idle phase of the periodic pulsed power.
Abstract:
A communications cable has coated conductor wires separated by a wire separator with at least one hole in the cross section to form a twisted pair configured to maintain a distance of approximately 0.375 mm between the conductors and a characteristic impedance of approximately 100 ohms. The coating on the conductors may be an enamel or other appropriately thin insulating material.
Abstract:
A field terminal plug assembly including an RJ45 plug connected to a termination zone. The termination zone includes a wire cap, a rear sled, and an electrical board assembly with attached insulation displacement contacts (IDCs) electrically connected to the twisted wire-pairs of assembly cable. The wire cap is configured to terminate twisted wire-pairs of a communications cable to the IDCs when the wire cap is inserted into the rear sled. The IDCs contain at least a first and a second IDC, the first IDC having a first horizontal length and a first vertical length and the second IDC having a second horizontal length and a second vertical length. The first vertical length does not equal the second vertical length but the first vertical length plus the first horizontal length equals the second vertical length plus the second horizontal length.