A multi-tap device for a cable television (CATV) system includes a tap housing and a first circuit board positioned within and removably connected to the tap housing. A directional coupler is connected to the first circuit board. A faceplate is integral with the tap housing. One or more subscriber tap ports are connected to the faceplate. An access cover is connected to the tap housing. The access cover is configured to be opened to provide access to an interior of the tap housing for a user to disconnect the first circuit board from the tap housing.

A power metering device includes a tap unit including a clamp for engaging a coaxial cable and a probe for electrically coupling to a center conductor of the coaxial cable without damaging the center conductor. A power consumption meter and a power port are electrically connected to the probe. A power transformer is optionally connected between the probe and the power port. A housing surrounds the meter and transformer. The power port supplies power to a customer device, and the meter measures an amount of power passing through the power port. The power consumed by the customer device is reported by the meter to a modem within the housing. The modem may utilize the probe and the center conductor of the coaxial cable to send power consumption data to a service provider, so that an operator of the customer device may be billed and/or the customer device may be controlled to limit its power consumption. Further, the modem may transfer data between the customer device and the service provider.

An apparatus and method for splicing single pair ethernet (SPE) cables. By creating a T shaped intersection, the splicing device allows for sensors and other devices to run perpendicular in relation to the original cable. The splicing device further enables the cable to have multiple drop points along the cable.

Systems and methods are provided for utilizing ideal taps in coaxial networks. An ideal tap may have a plurality of ports that include at least an input port configured for receiving downstream (DS) signals from and transmitting upstream (US) signals to nodes upstream from the tap within the coaxial network; an output port configured for transmitting downstream (DS) signals to and receiving upstream (US) signals from nodes downstream from the tap within the coaxial network; and one or more drop ports for receiving signal from and transmitting signals to customer premise equipment (CPE) in the coaxial network. The ideal tap may further include processing circuits for handling signals received and transmitted via the tap, with the one or more processing circuits being configured to meet particular predefined tap performance criteria, where the particular predefined tap performance criteria comprise one or more of high return loss, high port-to-port isolation, and high port-to-port gain.

To allow a fit-in state between electrical connectors to be firmly maintained, elastic arm-shaped members 23d provided to a conductive shell member 23 so as to elastically displace to a direction orthogonal to a fit-in direction of a mating connector 10 are each provided with an engaging piece 23e having a connector contact surface 23e1 which the mating connector 10 faces from the depth in the fit-in direction and a shell contact surface 23e2 which a part of the conductive shell member 23 faces from the front in the fit-in direction. When an external force is applied to the mating connector 10 in a fit-in state to a removing direction opposite to the fit-in direction, the engaging piece 23e is brought into a state of being interposed between the mating connector 10 and the conductive shell member 23. This avoids a situation in which the engaging piece 23e is removed from the mating connector 10 to cause a lock release.

Superconducting cable connector structures include a terminal body (or other structure) onto which the tapes from the superconducting cable extend. The terminal body (or other structure) has a diameter that is sufficiently larger than the diameter of the former of the superconducting cable, so that the tapes spread out over the outer surface of the terminal body. As a result, gaps are formed between tapes on the terminal body (or other structure). Those gaps are filled with solder (or other suitable flowable conductive material), to provide a current path of relatively high conductivity in the radial direction. Other connector structures omit the terminal body.

A coring tool for a coaxial cable has a tool holder and cutter bit mounted to the tool holder. The cutter bit is constructed from a conductive metal or alloy which is durable for rotatably drilling out and removing a dielectric core surrounding a central conductor of the coaxial cable, as the central conductor is preserved by passing into a central bore formed in the cutter bit. The cutter bit also includes a non-conductive sleeve or coating which prevents the cutter bit from electrically interconnecting, e.g., shorting, the central conductor to an outer conductor of the coaxial cable.

A cable tap structurally configured to provide enhanced protection against radio frequency interference and environmental conditions. The cable tap may include a first housing portion, a second housing portion configured to attach to the first housing portion, and a barrier portion supported on the second housing portion and structurally configured to extend into an interior of the first and second housing portions when the first and second housing portions are in a loose condition to form a physical barrier to inhibit radio frequency interference and block the ingress of rain and debris into the interior to provide enhanced protection against radio frequency interference and environmental conditions when the first and second housing portions are in the loose condition.

There is provided a cable tap (36) comprising an input (38) and an output (40), a first signal path (37) connected between the input (38) and the output (40), and a splitter element (26) providing a plurality of tap ports (24), wherein a second signal path (43) is connected between the splitter element (26) and the first signal path (37) and signal processing element (42) is disposed in the second signal path (43), the signal processing element (42) configured to measure and adjust characteristics of a signal passing between the splitter element (26) and the first signal path (37) so as to ensure each tap port remains at a required signal level. The signal processing element (42) comprises a gain control element (44) acting on at least one level attenuator (46) and at least one equalizer (50).

Housing for attachment to an electrical flat conductor rail with a flat conductor receptacle extending in a first axis, a connecting conductor receptacle extending transversely to the first axis in a second axis, wherein the flat conductor receptacle and the connecting conductor receptacle are formed from a upper housing side and a lower housing side with in each case an inner side and an outer side, which, in the closed state of the housing, receive the flat conductor rail with their inner sides lying opposite one another, characterized in that a shield contact element is arranged on at least one inner side, the shield contact element, in the closed state of the housing, bearing directly against a shield conductor of the flat conductor rail.