Abstract: Fiber optic terminals, systems, and methods for providing differentiated network services to subscribers of a fiber optic network are disclosed. In certain embodiments, fiber optic terminals and methods are disclosed for providing more than one network service to subscribers supported by the same fiber optic terminal. In one embodiment, a fiber optic terminal is provided comprising a first optical path connected to a first network-side optical fiber providing a first network service to a first subscriber-side optical fiber. The fiber optic terminal also comprises a second optical path connected to a second network-side optical fiber providing a second network service differentiated from the first network service to a second subscriber-side optical fiber. In this manner, differentiated network services can be provided to subscribers supported by the fiber optic terminal by configuring connections of the subscribers to either the first optical path or second optical path in the fiber optic terminal.

Abstract: Optical receptacles having compliance for facilitating alignment with fiber optic connectors during insertion, and related components, systems and methods are disclosed. In one example, an optical receptacle disposed in a receptacle optical assembly optically connects to a fiber optic component, for example, a ferrule, for facilitating transmission of an optical signal from the optical receptacle to the exemplary ferrule. A support interface between the optical receptacle and receptacle housing contains a compliance feature that permits the optical receptacle to move with respect to the receptacle housing during insertion of the fiber optic connector. An insertion force of the fiber optic connector causes the optical receptacle to be able to move into optical alignment with the connector during insertion of the fiber optic connector, thereby moving ferrule(s) of the fiber optic connector into optical alignment with the ferrule(s) of the optical receptacle.

Abstract: Fiber optic plug connectors having an articulated force structure to inhibit angular ferrule biasing are disclosed. An articulated force structure is provided in the fiber optic plugs to apply a forward force to a ferrule of the fiber optic plug, to dispose the fiber optic plug ferrule in close proximity to an optical interface of the optical receptacle to provide an optical connection therebetween. By the articulating force structure providing an articulating forward force to the fiber optic plug ferrule, the ferrule is able to angularly rotate to inhibit angular biasing applied to the fiber optic plug ferrule as a result of inserting the fiber optic plug into an optical receptacle. The articulating force structure providing an articulating forward force to the fiber optic plug ferrule facilitates alignment of the ferrule with the optical receptacle to preserve optical performance.

Abstract: A collapsible cable reel comprising a frame assembly having with a first end and a second end and at least one cable support is disclosed. A first end assembly releasably connects to the first end of the frame assembly and a second end assembly releasably connects to the second end of the frame assembly. At least one cable support extends from the frame assembly to the first end assembly and is adapted to support a length of cable wound around the collapsible cable reel. The length of the at least one cable support and the frame assembly are shortenable allowing the first end assembly to move closer to the second end assembly and the collapsible cable reel to move from a first position to a second position.

Abstract: Platforms for connecting fiber optic cable assemblies to fiber optic equipment using a universal footprint are disclosed. In one embodiment, a platform for connecting at least one fiber optic cable assembly to fiber optic equipment includes a coupling surface having at least one cable engagement feature, wherein the at least one cable engagement feature is configured to couple the at least one fiber optic cable assembly to the coupling surface, and a plurality of plate engagement features configured to be removably coupled to a plurality of equipment engagement features positioned on the fiber optic equipment. Fiber optic cable assembly coupling systems for coupling fiber optic cable assemblies to fiber optic equipment are also disclosed.

Abstract: An adapter panel support assembly having a frame assembly, a mounting bracket, and a connection assembly is disclosed. The frame assembly may receive and support an adapter panel. The connection assembly connects the frame assembly to the mounting bracket to allow the frame assembly to rotate and releasably lock at more than two positions when force is applied to the frame assembly. The connection assembly has a plurality of detents such that the frame assembly releasably locks at predetermined positions of the detents. The connection assembly has a ball bearing plunger mounted in the frame assembly. The ball bearing plunger retracts when the force is applied to the frame assembly to rotate the frame assembly between the detents and extends into each of the detents at the position of each of the detents to releasably lock the frame assembly at the position of that detent.

Abstract: An optical fiber for use as a stub fiber in an optical fiber connector is disclosed. The optical fiber is configured with a segmented core that includes a single-mode segment with a step-index profile and at least one multimode segment having at least one alpha profile. A connector that employs the stub fiber can connect to both a single mode fiber and a multimode fiber.

Abstract: An optical connector for terminating an optical fiber may include a ferrule, a optical fiber, and an adhesive composition. The ferrule may include a fiber-receiving passage defining an inner surface and the adhesive composition may be disposed within the ferrule and in contact with the inner surface of the ferrule and the optical fiber. The adhesive composition may include a partially cross-linked resin and a thermoset resin. The adhesive composition may include between about 1 to about 85 parts by weight of the thermoset resin per 100 parts by weight of the partially cross-linked resin.

Abstract: A secure cable housing system for use within a secure fiber optic communications network is provided. The secure cable housing system includes a non-secure cable box and a secure equipment box. The secure network equipment box includes a secure interior cavity, and the non-secure cable box is smaller than the secure interior cavity such that the non-secure cable box fits within the secure interior cavity. The secure network equipment box allows the optical cable to be received into the secure interior cavity without disconnecting the fiber optic cable from the non-secure box.

Abstract: A fire resistant optical communication cable is provided. The fire-resistant optical communication cable includes an extruded cable body including an inner surface defining a passage in the cable body and an outer surface. The fire-resistant optical communication cable includes a plurality of elongate optical transmission elements located within the passage of the cable body. The fire-resistant optical communication cable includes a layer of intumescent particles embedded in the material of the cable body forming an intumescent layer within the cable body. The cable may include one or more elements having flame resistant coatings that, upon exposure to heat, form a ceramic layer increasing the combustion time of the coated element.

Abstract: Gradient index (GRIN) lens assemblies employing lens alignment channels, as well as fiber optic connectors and fiber optic cable assemblies employing such GRIN lens assemblies, are disclosed. In one embodiment, a GRIN lens assembly includes a lens holder body having a mating face, a surface extending from the mating face, and a lens alignment channel. The lens alignment channel is defined by a narrow portion extending from the surface to a first depth and at least partially along a length of the surface, and a wide portion extending from the narrow portion to a second depth. A lens opening defined by the wide portion of the lens alignment channel at the mating face is disposed in the mating face. The wide portion of the lens alignment channel is configured to support a GRIN lens disposed in the lens alignment channel.

Abstract: A fiber inspection device is configured to be removably attached to a portable camera, such as a smartphone or other mobile computing device. The device may be arranged to have a slim form factor that complements the form factor of the smartphone or other device. The device may be configured to inspect a polish and/or cleave of the optical fiber. By leveraging the built in camera, computing power and user interface of a smartphone or other mobile computing device, a fiber inspection device can be inexpensively produced for inspecting a polish of an optical fiber endface using mass market camera hardware and software, without the need to develop dedicated electronics hardware or embedded software.

Abstract: A fiber inspection device is configured to inspect a cleave of an optical fiber endface. The device may also be configured to inspect a polish of the optical fiber using the same imaging hardware and/or software. Just as it is important to attain a smooth uniform polish of the optical fiber endface, it is equally important that the initial cleave generate a flat and uniform surface. If an adequate cleave is not attained, signal attenuation may occur, even if the polish of the endface is of otherwise high quality. Thus, by enabling cleave inspection both in the field and lab settings, overall quality control can be increased.

Abstract: High-connection density and bandwidth fiber optic apparatuses and related equipment and methods are disclosed. In certain embodiments, fiber optic apparatuses are provided and comprise a chassis defining one or more U space fiber optic equipment units. At least one of the one or more U space fiber optic equipment units may be configured to support particular fiber optic connection densities and bandwidths in a given 1-U space. The fiber optic connection densities and bandwidths may be supported by one or more fiber optic components, including but not limited to fiber optic adapters and fiber optic connectors, including but not limited to simplex, duplex, and other multi-fiber fiber optic components. The fiber optic components may also be disposed in fiber optic modules, fiber optic patch panels, or other types of fiber optic equipment.

Abstract: A plug for connecting to an electronic device includes a housing having an aperture, a magnetic element positioned in the aperture and having a second aperture, at least one contact within the aperture and the second aperture, a cord connected to the housing, and a mechanism configured to reduce a moment arm on the housing when a force is applied to the cord. The plug may be used as part of a connection that further includes a receptacle having a magnetic element with a recess, wherein the recess comprises an aperture, and at least one contact extending through the third aperture and into the recess.

Abstract: Indexable optical fiber connectors, optical connector arrays, and optical connector systems are disclosed. According to one embodiment, an optical fiber connector includes a connector body comprising an optical coupling face and a connector housing that surrounds the connector body. The connector housing includes a first interconnecting surface having an indentation arraying feature, and a second interconnecting surface having a protrusion arraying feature. The first interconnecting surface and the second interconnecting surface are orthogonal to the optical coupling face. The indentation arraying feature is configured to mate with a corresponding protrusion arraying feature of a first adjacent interconnecting optical fiber connector by a non-locking engagement relationship. Similarly, the protrusion arraying feature is configured to mate with a corresponding indentation arraying feature of a second adjacent optical fiber connector by a non-locking engagement relationship.

Abstract: Attachment mechanisms configured to be employed to attach a rear housing section to a fiber optic housing, and related assemblies and methods are disclosed. The rear housing section and the fiber optic housing may be part of fiber optic equipment configured to support fiber optic connections of a fiber optic network. The attachment mechanism is configured to be attached and extend from the rear housing section of the fiber optic housing while maintaining the same installed U space of the housing. The attachment mechanism may include a spring plunger which may releasably maintain the rear housing section in a position to allow fasteners to removably attach the rear housing section to the fiber optic housing. In this manner, the rear housing section may be attached to and removed from the fiber optic housing in an efficient manner to minimize downtime for the fiber optic network.

Abstract: Disclosed is a passive illumination apparatus for improving the visibility of an optical fiber by projecting reflected light to passively illuminate an optical fiber for allowing the user improved visibility for inserting the optical fiber into an orifice. One embodiment of the concept uses a passive illumination apparatus having a pattern of one or more colors for reflectively transmitting chromatic light along with an optional contrast surface such as a gray or black stripe for providing a highly contrasting background for the user to view the optical fiber against. The ambient light is transmitted or directed from a reflective surface such as a concave curved region for passively illuminating the optical fiber. The passive illumination apparatus may be used on any suitable device such as a connector installation tool, a splicer, a stripper for an optical fiber coating or a cleaver as desired.

Abstract: An optical connector for terminating an optical fiber includes a ferrule, an optical fiber, and an adhesive composition disposed within a fiber-receiving passage of the ferrule. The adhesive composition, which is in contact with the inner surface of the ferrule and the optical fiber, includes a partially cross-linked resin that is a polymer and a coupling agent that chemically bonds the partially cross-linked resin to an inorganic surface of at least one of the optical fiber and the ferrule.

Abstract: A fiber optic assembly includes a connector and a cover bonded to an end face of the connector. The connector includes a ferrule, where an optical fiber extends through the ferrule and to the end face of the connector. An end of the optical fiber is polished proximate to the end face. The cover is bonded directly to the end face of the connector, and overlays the polished end of the optical fiber such that the cover protects the optical fiber, limits access of dust to the end face of the connector, and draws loose particulates from the end face upon removal of the cover.