Abstract: Indexing modules and tapping modules that can be interconnected in one or more chains to form a network. The indexing modules each include at least one pass-through line that is not dropped or indexed at the indexing module. The tap modules each include a tap line and a pass-through line. Input and pass-through connection interfaces of the indexing and tapping modules are configured so that the tap line of the tap modules is connected only to the pass-through line of the indexing modules.

Abstract: A communication cable is surrounded by a tape with overlapped first and second longitudinal edges. The overlapped portion of the tape extends parallel to the longitudinal length of the communication cable, which is also parallel to the longitudinal central axis of the cable core. An attachment is provided between the overlapped portions of the tape. The attachment may be formed by an adhesive layer between the overlapped portions of the tape or a melting together of the overlapped portions of the tape. In either case, the tape forms a circumferential protective seal around the cable core.

Abstract: The present invention is directed to a splitter or hub that provides plural ports for communicating MoCA signals between devices. More particularly, the present invention relates to a passive splitter to communicate MoCA signals between a gateway/amplifier port and customer devices, or a passive hub to communicate MoCA signals between customer devices. The splitter or hub includes a resistive splitter network and may include a MoCA passing filter and a test port.

Abstract: The present invention is directed to a splitter or hub that provides plural ports for communicating MoCA signals between devices. More particularly, the present invention relates to a passive splitter to communicate MoCA signals between a gateway/amplifier port and customer devices, or a passive hub to communicate MoCA signals between customer devices. The splitter or hub includes a resistive splitter network and may include a MoCA passing filter and a test port.

Abstract: A bi-directional RF signal amplifier includes a housing with an RF input port. A power divider network within the housing terminates to a plurality of active RF output ports. An active communications path connects the RF input port to the power divider network. A passive communications path connects the RF input port to a passive RF output port. A MoCA input/output port is provided on the housing. A MoCA signal path connects the power divider network to the MoCA input/output port, and a MoCA pass filter is located along the MoCA signal path. In another embodiment, a passive splitter includes a housing with an RF input port, a power divider network, and a plurality of CATV/MoCA RF output ports. A CATV communications path connects the RF input port to the power divider network. A MoCA input/output port is provided on the housing. A MoCA signal path connects the power divider network to the MoCA input/output port, and a MoCA pass filter is located along the MoCA signal path.

Abstract: A cable includes a communication carrying medium or a conductive medium. A jacket surrounds the medium along the length of the cable. At least one magnet is embedded within, attached to an outer surface of, or abutting an inner surface of, the jacket. The at least one magnet allows one cable to be attached to another cable, even if only temporarily, so that plural cables can be installed as a single unit. Magnetic attraction may exist as a jacket-to-jacket attraction between first and second cables. Alternatively, magnetic attraction may be used to attach a first cable to an intermediary, such as a spine, and also used to attach a second cable to the same intermediary.

Abstract: The present invention is directed to a bi-directional RF signal amplifier that includes both an active communications path and a passive communications path. The circuitry is simplified and the housing size is reduced by having one port which functions as part of the active communications path when the bi-directional RF signal amplifier is powered, and that functions as part of the passive communications path when the bi-directional RF signal amplifier is unpowered.

Abstract: Common mode noise can exist on an outer conductor of a female F-type port of a RF-device, like a cable modem box or cable TV set-top box. The present invention utilizes a jumper wire attached to an electrically conductive connector, having a shape and size to fit around a base of the F-type female coaxial port. The jumper wire carries the common mode noise away from the outer conductor of the port. In a first embodiment, the jumper wire is connected to a ground line of a household outlet. In a second embodiment, the jumper wire dissipates the noise signal by interacting with one or more ferrites. In a third embodiment, the jumper wire carries the noise signal to a shielding layer of a coaxial cable, which may further carry the noise signal to one or more ferrites or a ground connection.

Abstract: Common mode noise can exist on an outer conductor of a female F-type port of a RF-device, like a cable modem box or cable TV set-top box. The present invention utilizes a jumper wire attached to an electrically conductive connector, having a shape and size to fit around a base of the F-type female coaxial port. The jumper wire carries the common mode noise away from the outer conductor of the port. In a first embodiment, the jumper wire is connected to a ground line of a household outlet. In a second embodiment, the jumper wire dissipates the noise signal by interacting with one or more ferrites. In a third embodiment, the jumper wire carries the noise signal to a shielding layer of a coaxial cable, which may further carry the noise signal to one or more ferrites or a ground connection.

Abstract: A CATV & MoCA splitter has an input and at least one output that is “CATV & MoCA” and at least one output that is “MoCA only.” The splitter functions as a building block to provide a customizable installation that supplies the needed number of “CATV & MoCA” outputs and the needed number of “MoCA only” outputs. The splitter includes a housing with first, second and third coaxial ports attached to the housing. In one embodiment, the second coaxial port is connected to the first coaxial port via a power divider so that all frequencies presented to the first coaxial port can pass to the second coaxial port, and vice versa. A high pass filter, which passes only MoCA signals, connects the power divider and third coaxial port.

Abstract: The present invention is directed to a bi-directional RF signal amplifier that includes both an active communications path and a passive communications path. The circuitry is simplified and the housing size is reduced by having one port which functions as part of the active communications path when the bi-directional RF signal amplifier is powered, and that functions as part of the passive communications path when the bi-directional RF signal amplifier is unpowered.

Abstract: The present invention is directed to a splitter or hub that provides plural ports for communicating MoCA signals between devices. More particularly, the present invention relates to a passive splitter to communicate MoCA signals between a gateway/amplifier port and customer devices, or a passive hub to communicate MoCA signals between customer devices. The splitter or hub includes a resistive splitter network and may include a MoCA passing filter and a test port.

Abstract: A bi-directional RF signal amplifier includes a housing with an RF input port. A power divider network within the housing terminates to a plurality of active RF output ports. An active communications path connects the RF input port to the power divider network. A passive communications path connects the RF input port to a passive RF output port. A MoCA input/output port is provided on the housing. A MoCA signal path connects the power divider network to the MoCA input/output port, and a MoCA pass filter is located along the MoCA signal path. In another embodiment, a passive splitter includes a housing with an RF input port, a power divider network, and a plurality of CATV/MoCA RF output ports. A CATV communications path connects the RF input port to the power divider network. A MoCA input/output port is provided on the housing. A MoCA signal path connects the power divider network to the MoCA input/output port, and a MoCA pass filter is located along the MoCA signal path.

Abstract: A CATV & MoCA splitter has an input and at least one output that is “CATV & MoCA” and at least one output that is “MoCA only.” The splitter functions as a building block to provide a customizable installation that supplies the needed number of “CATV & MoCA” outputs and the needed number of “MoCA only” outputs. The splitter includes a housing with first, second and third coaxial ports attached to the housing. In one embodiment, the second coaxial port is connected to the first coaxial port via a power divider so that all frequencies presented to the first coaxial port can pass to the second coaxial port, and vice versa. A high pass filter, which passes only MoCA signals, connects the power divider and third coaxial port.

Abstract: Assemblies include a micronode having an optical connector, a coaxial connector port and a housing that includes a plurality of mounting bores. The assembly further includes a filter having a housing that underlies the micronode housing, the filter housing including a plurality of mounting bores, the mounting bores of the filter housing aligning with the mounting bores of the micronode housing. The filter further includes a first optical connector configured to receive an optical drop cable, a second optical connector configured to receive an optical cable and an optical pigtail cord that is connected to the optical connector of the micronode.

Abstract: Methods of reducing optical beat interference in a fiber optic network are provided. The optical fiber network may have a plurality of optical network units that communicate with a shared receiver. The optical signals that are transmitted from the optical network units to the receiver may have polarization states that are selected to reduce optical beat interference at the receiver.

Abstract: Methods of reducing optical beat interference in a fiber optic network are provided. The optical fiber network may have a plurality of optical network units that communicate with a shared receiver. The optical signals that are transmitted from the optical network units to the receiver may have polarization states that are selected to reduce optical beat interference at the receiver.

Abstract: Assemblies include a micronode having an optical connector, a coaxial connector port and a housing that includes a plurality of mounting bores. The assembly further includes a filter having a housing that underlies the micronode housing, the filter housing including a plurality of mounting bores, the mounting bores of the filter housing aligning with the mounting bores of the micronode housing. The filter further includes a first optical connector configured to receive an optical drop cable, a second optical connector configured to receive an optical cable and an optical pigtail cord that is connected to the optical connector of the micronode.

Abstract: Methods of reducing optical beat interference are disclosed in which an output of a first temperature control system that establishes an operating temperature of a first laser that is included in a first optical network unit is controlled so that the operating temperature of the first laser varies according to a first continuous function that has a first amplitude and a first frequency and an output of a second temperature control system that establishes an operating temperature of a second laser that is included in a second optical network unit is controlled so that the operating temperature of the second laser varies according to a second continuous function that has a second amplitude and a second frequency, where the first continuous function is different than the second continuous function, the first amplitude is different than the second amplitude, and/or the first frequency is different than the second frequency.

Abstract: Methods of reducing optical beat interference in a fiber optic network are provided. The optical fiber network may have a plurality of optical network units that communicate with a shared receiver. The optical signals that are transmitted from the optical network units to the receiver may have polarization states that are selected to reduce optical beat interference at the receiver.