Abstract: An aspect of the present disclosure includes a node housing for use in a broadband distribution network that includes coupling the amplifier to a lid portion and providing an interface plate in a base portion that allows for RF and power signals to be provided to the RF amplifier within the lid portion. The interface plate disposed within the base portion further preferably provides power pass-through to downstream nodes that remains electrically connected even when the amplifier is decoupled from the lid portion. Thus, the amplifier and/or lid portion may be decoupled from the base portion without disrupting power distribution to the down-stream nodes.

Abstract: The present disclosure is generally directed to a connector assembly that includes an increased outer diameter of the connector member relative to the equivalent G-type connector and an increased inner diameter of the receptable member relative to the equivalent G-type receptacle (also referred to as a seizure nut) to achieve higher current carrying capacity and target frequency rates of up to 3.0 Ghz, for example. In one preferred example, this results in a connector assembly consistent with the present disclosure having a connector member with an outer diameter of at least 10.70 mm, and more preferably 10.76±0.01 mm, rather than the 9.4 mm diameter of existing G-type connectors. Despite this increased diameter, a seizure assembly consistent with the present disclosure can achieve a functional impedance of 75 ohms to maintain nominal signal quality.

Abstract: A coaxial seizure assembly is disclosed that includes an integrated mechanical stop that prevents over-insertion and maintains a nominal/expected impedance value to enable high-frequency switching, e.g., 1.8-3 Ghz or greater. In more detail, the coaxial seizure assembly includes a coaxial receptacle defined by an opening configured to at least partially receive and couple to a coaxial connector. The opening communicates with a seizure cavity defined within the coaxial seizure assembly. A radio frequency (RF) interconnect at least partially extends into the seizure cavity, with the RF interconnect having a first end to electrically couple to an electrical component and a second end that extends a predetermined angle relative to the first end, e.g., substantially 90 degrees. The second end defines a mating surface that aligns within the seizure cavity such that an imaginary line drawn along an insertion path of a coaxial cable conductor pin intersects with the mating surface.

Abstract: A coaxial seizure assembly is disclosed that includes an integrated mechanical stop that prevents over-insertion and maintains a nominal/expected impedance value to enable high-frequency switching, e.g., 1.8-3 Ghz or greater. In more detail, the coaxial seizure assembly includes a coaxial receptacle defined by an opening configured to at least partially receive and couple to a coaxial connector. The opening communicates with a seizure cavity defined within the coaxial seizure assembly. A radio frequency (RF) interconnect at least partially extends into the seizure cavity, with the RF interconnect having a first end to electrically couple to an electrical component and a second end that extends a predetermined angle relative to the first end, e.g., substantially 90 degrees. The second end defines a mating surface that aligns within the seizure cavity such that an imaginary line drawn along an insertion path of a coaxial cable conductor pin intersects with the mating surface.