Abstract: Optical interface cards, assemblies, and related methods, which may be suited for installation and use in antenna system equipment, are disclosed. In certain embodiments, an optical interface card (OIC) comprising a printed circuit board (PCB) having at least one optical sub-assembly (OSA) mounted to at least one first opening end of the PCB and extending into at least one opening and related methods are disclosed. In other embodiments, optical interface assemblies comprised of two OICs mounted together are disclosed. In other embodiments, a communications equipment enclosure including at least one fan configured to draw in air from a first side of the communications equipment enclosure into a lower plenum and across a plurality of communications components into an upper plenum to provide air cooling are disclosed. In another embodiment, a modular distributed antenna system assembly is disclosed.

Abstract: Communications system housings, assemblies, and related alignment features and methods are disclosed. In certain embodiments, communications cards and related assemblies and methods that include one or more alignment features are disclosed. In certain embodiments, at least one digital connector disposed in the communications card is configured to engage at least one complementary digital connector to align at least one RF connector also disposed in the communications card with at least one complementary RF connector. In other embodiments, printed circuit board (PCB) assemblies are disclosed that include a moveable standoff to provide an alignment feature. In other embodiments, distributed antenna systems and assemblies that include one or more alignment features are disclosed.

Abstract: A connector housing for use with a communication network and management system thereof includes a housing having a plurality of berths each configured to receive an optical connector adapter unit. A housing electrical connector is associated with each berth and faces the front of the housing to engage an adapter unit electrical connector as the adapter unit is inserted into the berth. Guide elements guide and align the housing electrical connectors with the adapter unit connectors as the adapter units are inserted into the berth to allow blind mating of the housing electrical connectors and the adapter unit connectors. Electrical contacts from at least two housing electrical connectors are consolidated into a cable connector positioned adjacent the back of the housing.

Abstract: Multi-port optical connection terminals and mounting platforms and related methods designed to secure optical components inside an enclosure of the multi-port optical connection terminals are disclosed. In one embodiment, a multi-port optical connection terminal includes an enclosure comprising a base and a cover configured to attach to the base to define an interior cavity. A mounting platform defining a mounting surface for mounting at least one optical component comprised from the group consisting of at least one splice tray and at least one optical splitter to the at least one mounting surface is provided. A plurality of mounting tabs of the mounting platform are configured to extend into channels disposed in an interior wall of the base. In this manner, the mounting platform and any optical components secured thereto are secured inside the interior cavity, which may prevent damage to optical fibers and/or splices of the optical components.

Abstract: Embodiments include distribution in optical fiber-based distributed communications systems configured to provide digital data services and radio frequency (RF) communications services, and related components and methods. Embodiments disclosed include units that can be provided in optical fiber-based distributed communications systems that are configured to support RF communication services and digital data services. The units may also be configured to support providing distribution of power.

Abstract: Communications system housings, assemblies, and related alignment features and methods are disclosed. In certain embodiments, communications cards and related assemblies and methods that include one or more alignment features are disclosed. In certain embodiments, at least one digital connector disposed in the communications card is configured to engage at least one complementary digital connector to align at least one RF connector also disposed in the communications card with at least one complementary RF connector. In other embodiments, printed circuit board (PCB) assemblies are disclosed that include a moveable standoff to provide an alignment feature. In other embodiments, distributed antenna systems and assemblies that include one or more alignment features are disclosed.

Abstract: Optical interface cards, assemblies, and related methods, which may be suited for installation and use in antenna system equipment, are disclosed. In certain embodiments, an optical interface card (OIC) comprising a printed circuit board (PCB) having at least one optical sub-assembly (OSA) mounted to at least one first opening end of the PCB and extending into at least one opening and related methods are disclosed. In other embodiments, optical interface assemblies comprised of two OICs mounted together are disclosed. In other embodiments, a communications equipment enclosure including at least one fan configured to draw in air from a first side of the communications equipment enclosure into a lower plenum and across a plurality of communications components into an upper plenum to provide air cooling are disclosed. In another embodiment, a modular distributed antenna system assembly is disclosed.

Abstract: Multi-port optical connection terminals and mounting platforms and related methods designed to secure optical components inside an enclosure of the multi-port optical connection terminals are disclosed. In one embodiment, a multi-port optical connection terminal includes an enclosure comprising a base and a cover configured to attach to the base to define an interior cavity. A mounting platform defining a mounting surface for mounting at least one optical component comprised from the group consisting of at least one splice tray and at least one optical splitter to the at least one mounting surface is provided. A plurality of mounting tabs of the mounting platform are configured to extend into channels disposed in an interior wall of the base. In this manner, the mounting platform and any optical components secured thereto are secured inside the interior cavity, which may prevent damage to optical fibers and/or splices of the optical components.

Abstract: A multi-port optical connection terminal for use as a branch point in a fiber optic communications network at a distance from a mid-span access location provided on a distribution cable having a plurality of optical fibers. The multi-port terminal includes a base and a cover affixed to the base. A stub cable port formed through one of the base and the cover receives a stub cable having at least one optical fiber extending continuously from the multi-port terminal to the mid-span access location. A first end of the optical fiber is optically connected to a respective optical fiber of the distribution cable at the mid-span access location and a fiber optic connector is mounted upon the second end. At least one connector port is provided on the multi-port terminal for receiving the fiber optic connector and a connectorized end of a fiber optic drop cable extending from the multi-port terminal.

Abstract: A connector housing for use with a communication network and management system thereof includes a housing having a plurality of berths each configured to receive an optical connector adapter unit. A housing electrical connector is associated with each berth and faces the front of the housing to engage an adapter unit electrical connector as the adapter unit is inserted into the berth. Guide elements guide and align the housing electrical connectors with the adapter unit connectors as the adapter units are inserted into the berth to allow blind mating of the housing electrical connectors and the adapter unit connectors. Electrical contacts from at least two housing electrical connectors are consolidated into a cable connector positioned adjacent the back of the housing.

Abstract: There is provided a cable attachment for sealing and retaining cables entering an opening of a telecommunications closure. The cable attachment includes an adapter body with an opening through which the cable passes; and a grip device and grommet device are also located within the opening of the adapter body for strain relieving and sealing, respectively, the cable passing through the adapter body. The cable attachment further includes a bolt portion that is selectively moveable relative to the adapter body for applying a force to the grommet device for selectively creating a seal about an outer surface of the cable. Alternative designs for sealing and/or strain relieving cables entering a closure are provided.

Abstract: A multi-port optical connection terminal for use as a branch point in a fiber optic communications network at a distance from a mid-span access location provided on a distribution cable having a plurality of optical fibers. The multi-port terminal includes a base and a cover affixed to the base. A stub cable port formed through one of the base and the cover receives a stub cable having at least one optical fiber extending continuously from the multi-port terminal to the mid-span access location. A first end of the optical fiber is optically connected to a respective optical fiber of the distribution cable at the mid-span access location and a fiber optic connector is mounted upon the second end. At least one connector port is provided on the multi-port terminal for receiving the fiber optic connector and a connectorized end of a fiber optic drop cable extending from the multi-port terminal.

Abstract: A multi-port optical connection terminal for use as a branch point in a fiber optic communications network at a distance from a mid-span access location provided on a distribution cable having a plurality of optical fibers. The multi-port terminal includes a base and a cover affixed to the base. A stub cable port formed through one of the base and the cover receives a stub cable having at least one optical fiber extending continuously from the multi-port terminal to the mid-span access location. A first end of the optical fiber is optically connected to a respective optical fiber of the distribution cable at the mid-span access location and a fiber optic connector is mounted upon the second end. At least one connector port is provided on the multi-port terminal for receiving the fiber optic connector and a connectorized end of a fiber optic drop cable extending from the multi-port terminal.

Abstract: A network access terminal includes an enclosure and a connector panel hinged to the enclosure such that a double-sided connector received within an opening in the panel does not need to be removed to access the rear of the connector. The enclosure has an opening such that telephone cables enter the enclosure and wiring is routed to the underside of the panel. The hinge is located along an edge of the panel adjacent the cable entry for optimum slack management. The network access terminal may also include a mechanical stop for limiting the travel of the panel and for supporting the panel while the technician routes and connects the wiring to the rear of the connector. The front of the panel may incorporate restricted access fasteners such that the underside of the panel can be accessed only by authorized personnel while still permitting access to the front.