A joint connector includes high and low potential wire terminals (10H, 10L), a plurality of sub-housings (20A, . . . ) corresponding to the respective twisted pair cables and configured to hold the high and low potential wire terminals (10H, 10L), a main housing (30) configured to accommodate the sub-housings (20A, . . . ) in a stacked state, high and low potential connection conductors (40H, 40L) configured to connect the high potential wire terminals (10H) to each other and connect the low potential wire terminals (10L) to each other, and a holding member (50) including housing restraining portions (54) and to be mounted into the main housing (30) such that the housing restraining portions cross the sub-housings (20A, . . . ). The housing restraining portions (54) restrain restrained portions of the sub-housings (20A, . . . ) to impede the withdrawal of the sub-housings (20A, . . . ) in a direction opposite to a housing insertion direction.

Disclosed is a high-density split cable for use in a network incorporating high-density connections for increased efficiency, network operation and management. The high-density connections are incorporated into the patch panel, network switch, and cables that connects them, as well as into cable analyzers and printed circuit boards (PCBs) which allow for a complete network within a single computer running virtualization software.

Disclosed is a high-density split cable for use in a network incorporating high-density connections for increased efficiency, network operation and management. The high-density connections are incorporated into the patch panel, network switch, and cables that connects them, as well as into cable analyzers and printed circuit boards (PCBs) which allow for a complete network within a single computer running virtualization software.

A connector structure enables the replacement of an STP cable (10B) and a UTP cable (10A) without making a large structural change. UTP connection terminals (21A) to be connected to respective wires (11) of the UTP cable (10A) are arranged to be proximate in a width direction by being accommodated into accommodating portions (26) of a UTP dielectric (22A) proximate in the width direction. STP connection terminals (21B) to be connected to respective wires (11) of the STP cable (10B) are farther apart in the width direction than the UTP connection terminals (21A) by being accommodated in accommodating portions (26) of an STP dielectric (22B) spaced apart in the width direction. The UTP connection terminals and the STP connection terminals are set such that protrusions (34) projecting out from box portions (27) in a common direction when accommodated in the accommodating portions (26).

A connector structure enables the replacement of an STP cable (10B) and a UTP cable (10A) without making a large structural change. UTP connection terminals (21A) to be connected to respective wires (11) of the UTP cable (10A) are arranged to be proximate in a width direction by being accommodated into accommodating portions (26) of a UTP dielectric (22A) proximate in the width direction. STP connection terminals (21B) to be connected to respective wires (11) of the STP cable (10B) are farther apart in the width direction than the UTP connection terminals (21A) by being accommodated in accommodating portions (26) of an STP dielectric (22B) spaced apart in the width direction. The UTP connection terminals and the STP connection terminals are set such that protrusions (34) projecting out from box portions (27) in a common direction when accommodated in the accommodating portions (26).

Disclosed is a high-density switch for up to 40 high-density jacks for use in a network incorporating high-density connections for increased efficiency, network operation and management. The high-density connections are incorporated into the patch panel, network switch, and cables that connects them, as well as into cable analyzers and printed circuit boards (PCBs) which allow for a complete network within a single computer running virtualization software.

Disclosed is a high-density switch for up to 40 high-density jacks for use in a network incorporating high-density connections for increased efficiency, network operation and management. The high-density connections are incorporated into the patch panel, network switch, and cables that connects them, as well as into cable analyzers and printed circuit boards (PCBs) which allow for a complete network within a single computer running virtualization software.

Disclosed is a high-density non split cable for use in a network incorporating high-density connections for increased efficiency, network operation and management. The high-density connections are incorporated into the patch panel, network switch, and cables that connects them, as well as into cable analyzers and printed circuit boards (PCBs) which allow for a complete network within a single computer running virtualization software.

Disclosed is a high-density non split cable for use in a network incorporating high-density connections for increased efficiency, network operation and management. The high-density connections are incorporated into the patch panel, network switch, and cables that connects them, as well as into cable analyzers and printed circuit boards (PCBs) which allow for a complete network within a single computer running virtualization software.

Disclosed is a high-density port converter for use in a network incorporating high-density connections for increased efficiency, network operation and management. The high-density connections are incorporated into the patch panel, network switch, and cables that connects them, as well as into cable analyzers and printed circuit boards (PCBs) which allow for a complete network within a single computer running virtualization software.