A terminal module disclosed by this specification is provided with a shielded cable including two coated wires, a conductive shield portion for covering outer peripheries of the two coated wires and a sheath portion for covering an outer periphery of the shield portion, inner conductors to be connected to the coated wires, an insulating terminal accommodating member for accommodating end parts of the coated wires together with the inner conductors, and an outer conductor for accommodating the terminal accommodating member. An axis center β of a shield-side pull-out portion for pulling out the coated wires in the shield portion is radially shifted with respect to axis centers α of inner conductor-side pull-out portions for pulling out the coated wires in the inner conductors. A wire insertion path into which linking portions are insertable is formed in a lower wall of the terminal accommodating member.

Disclosed herein is a shield wire grounding device of electric equipment, including: an electric equipment wire electrically connected to the electric equipment, covered by a first sheath, and having an end portion exposed to the outside of the first sheath; a shield wire installed outside the first sheath, and covered by a second sheath; an insulating member covering the exposed portion of the electric equipment; and a grounding member covering the shield wire and the insulating member, electrically connected to the shield wire, and grounded to an electric equipment housing.

Disclosed herein is a shield wire grounding device of electric equipment, including: an electric equipment wire electrically connected to the electric equipment, covered by a first sheath, and having an end portion exposed to the outside of the first sheath; a shield wire installed outside the first sheath, and covered by a second sheath; an insulating member covering the exposed portion of the electric equipment; and a grounding member covering the shield wire and the insulating member, electrically connected to the shield wire, and grounded to an electric equipment housing.

A communication connector has an outer housing with an opening, a shielding wrap at least partially enclosing the outer housing, and a contact carrier assembly configured to be interested into the opening of the outer housing. The contact carrier assembly at least partially encloses at least two contacts each with an insulation displacement contact (IDC). The contact carrier assembly also has an integrated wire cap that utilizes a hinge feature to press cable conductors of a cable into their respective IDCs.

A wire harness includes a cable constituted of a plurality of electric wires bundled together so as to include a plurality of cable ends and a plurality of connectors mounted one-to-one on the plurality of cable ends, wherein each of the plurality of connectors includes a connector terminal connected to an end of the electric wire, a tubular housing body accommodating the connector terminal, and a flange formed to project from an outer circumferential surface of the housing body. On a fitting side for fitting with a mating connector, the flange has a rugged shape that differs between the plurality of connectors.

A wire harness includes a cable constituted of a plurality of electric wires bundled together so as to include a plurality of cable ends and a plurality of connectors mounted one-to-one on the plurality of cable ends, wherein each of the plurality of connectors includes a connector terminal connected to an end of the electric wire, a tubular housing body accommodating the connector terminal, and a flange formed to project from an outer circumferential surface of the housing body. On a fitting side for fitting with a mating connector, the flange has a rugged shape that differs between the plurality of connectors.

A cable assembly comprising a connector with a termination that enables high density and high signal integrity. Shields of cables are terminated to a paddle card via a conductive structure attached to a surface of the paddle card. The signal conductors of the cables are terminated to pads on the paddle card that are exposed within openings of the conductive structure. Such a structure creates a ground structure per cable that provides low insertion loss and low crosstalk, even when multiple cables are aligned side by side and terminated in one or more rows. The cables may be drainless, enabling a large number of cables, such as eight cables, to be packed within the width of a paddle card specified in high density standards such as QSFP-DD or OSFP. The cables may nonetheless have large diameter signal conductors, enabling 2.5 or 3 meter assemblies with less than 17 dB insertion loss.

A cable assembly comprising a connector with a termination that enables high density and high signal integrity. Shields of cables are terminated to a paddle card via a conductive structure attached to a surface of the paddle card. The signal conductors of the cables are terminated to pads on the paddle card that are exposed within openings of the conductive structure. Such a structure creates a ground structure per cable that provides low insertion loss and low crosstalk, even when multiple cables are aligned side by side and terminated in one or more rows. The cables may be drainless, enabling a large number of cables, such as eight cables, to be packed within the width of a paddle card specified in high density standards such as QSFP-DD or OSFP. The cables may nonetheless have large diameter signal conductors, enabling 2.5 or 3 meter assemblies with less than 17 dB insertion loss.

A modular hardware platform utilizes a combination of different types of units that are pluggable into cassette endpoints. The present disclosure enables the construction of an extremely large system, e.g., 500 Tb/s+, as well as small, standalone systems using the same hardware units. This provides flexibility to build different systems with different slot pitches. The hardware platform includes various numbers of stackable units that mate with a cost-effective, hybrid Printed Circuit Board (PCB)/Twinax backplane, that is orthogonally oriented relative to the stackable units. In an embodiment, the hardware platform supports a range of 14.4 Tb/s-800 Tb/s+ in one or more 19″ racks, providing full features Layer 3 to Layer 0 support, i.e., protocol support for both a transit core router and full feature edge router including Layer 2/Layer 3 Virtual Private Networks (VPNs), Dense Wave Division Multiplexed (DWDM) optics, and the like.

A modular hardware platform utilizes a combination of different types of units that are pluggable into cassette endpoints. The present disclosure enables the construction of an extremely large system, e.g., 500 Tb/s+, as well as small, standalone systems using the same hardware units. This provides flexibility to build different systems with different slot pitches. The hardware platform includes various numbers of stackable units that mate with a cost-effective, hybrid Printed Circuit Board (PCB)/Twinax backplane, that is orthogonally oriented relative to the stackable units. In an embodiment, the hardware platform supports a range of 14.4 Tb/s-800 Tb/s+ in one or more 19″ racks, providing full features Layer 3 to Layer 0 support, i.e., protocol support for both a transit core router and full feature edge router including Layer 2/Layer 3 Virtual Private Networks (VPNs), Dense Wave Division Multiplexed (DWDM) optics, and the like.