Abstract: A pigtail cable assembly comprising a fiber optic cable having a plurality of optical fibers, a mid-section, a first end section and a second end section is disclosed. The plurality of optical fibers are separated from the fiber optic cable at the first end section. One of the plurality of the optical fibers at the second end section is adapted to be connected to a single fiber splice at a second end when single fiber splicing is intended. A sever site is located on the mid-section. The second end section may be severed from the mid-section at the sever site when mass splicing is intended. When the second end section is separated from the mid-section at the sever site the mid-section of the fiber optic cable is adapted to be connected to a mass splice at the sever site.

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: Dust caps, fiber optic connectors, fiber optic splitter modules and fiber optic connector systems including interlocking aligning features for fiber optic connector parking in fiber distribution hub networks are disclosed. According to one embodiment, a dust cap for mounting upon a ferrule of a fiber optic connector includes a sleeve extending lengthwise between opposed first and second ends. The sleeve defines a lengthwise extending bore that opens through the first end for receiving at least a portion of the ferrule. The dust cap further includes an aligning feature at the second end of the sleeve. The aligning feature includes a neck portion and an interlocking portion such that the interlocking portion has a width that is greater than a width of the neck portion. The aligning feature is configured to slidably engage with a slot of a parking clip.

Abstract: A fiber optic apparatus including a retainer assembly having at least one retainer configured to toollessly, releasably retain a fiber body and or one or more optical fibers is disclosed. An attachment feature may toollessly, removably attach the retainer assembly to a mounting surface. The at least one retainer is configured to releasably retain the fiber body via mounting bosses on the fiber body. A stacking feature may be configured to removably attach a second retainer assembly to the retainer assembly. The at least one retainer may be configured to releasably retain the one or more optical fibers to strain relief the one of more optical fibers. The mounting surface may be fiber optic equipment. The fiber optic equipment may be a shelf mounted to a chassis in a fiber optic equipment rack.

Abstract: Removable strain relief brackets for securing fiber optic cables and/or optical fiber to fiber optic equipment, and related assemblies and methods are disclosed. The removable strain relief brackets may be employed to secure fiber optic cable and/or optical fibers routed to fiber optic equipment. The removable strain relief brackets may also be employed to provide strain relief for fiber optic cable and/or optical fibers routed and secure to fiber optic equipment. Fiber optic cable discussed herein includes optical fiber whether disposed in a common cable jacket or disposed freely of each other outside a cable jacket.

Abstract: A pigtail cable assembly comprising a fiber optic cable having a plurality of optical fibers, a mid-section, a first end section and a second end section is disclosed. The plurality of optical fibers are separated from the fiber optic cable at the first end section. One of the plurality of the optical fibers at the second end section is adapted to be connected to a single fiber splice at a second end when single fiber splicing is intended. A sever site is located on the mid-section. The second end section may be severed from the mid-section at the sever site when mass splicing is intended. When the second end section is separated from the mid-section at the sever site the mid-section of the fiber optic cable is adapted to be connected to a mass splice at the sever site.

Abstract: A fiber optic cassette having a housing having an interior, a component section and a front section is disclosed. A single splice holder, a mass splice holder and a pigtail cable assembly are positioned in the fiber optic component section. The pigtail cable assembly comprises a plurality of optical fibers, and is adapted to provide for at least one of the plurality of optical fibers to connect to one of the fiber optic adapters at a one end of the optical fibers. The pigtail cable assembly is modifiable to provide for the plurality of optical fibers to connect to one of a mass splice held by the mass splice holder and single fiber splices held by the single fiber splice holder at another end.

Abstract: A local convergence point for a fiber optic network is disclosed. The local convergence panel has an enclosure with an interior. An adapter panel separates the interior into a first section and a second section. An interior panel removably mounts in the interior in at least one of the first section and the second section. At least one optical component removably mounts to the interior panel. The optical component may be a splitter module, a splice holder, a routing guide, furcation devices, a ribbon fan-out body, a wave division multiplexer and/or a coarse wave division multiplexer.

Abstract: A variably configurable fiber optic terminal as a local convergence point in a fiber optic network is disclosed. The fiber optic terminal has an enclosure having a base and a cover which define an interior space. A feeder cable having at least one optical fiber and a distribution cable having at least one optical fiber are received into the interior space through a feeder cable port and a distribution cable port, respectively. A movable chassis positions in the interior space and is movable between a first position, a second position and third position. The movable chassis has a splitter holder area, a cassette area and a parking area. A cassette movably positions in the cassette area. A splitter module holder having a splitter module movably positioned therein movably positions in the splitter holder area. The optical fiber of the feeder cable and the optical fiber of the distribution cable are optically connected through the cassette, which also may be through the splitter module.

Abstract: There is provided a fiber optic connector holder adapted to selectively retain two or more fiber optic connectors that include a dust cap on the ferrule. The connector holder comprises a boot retainer to selectively retain a portion of the boot of the connector, and the connector holder comprises a dust cap retainer to selectively retain a portion of the dust cap of the connector. The connector holder is provided in a telecommunications enclosure to provide convenient parking for fiber optic connectors that are not optically connected within a distribution field or the like or that are generally not in service at the time. The connector holders may be selectively installed and/or removed from the telecommunications enclosure to assist in the installation of new fiber optic hardware, such as splitter modules.

Abstract: There is provided a fiber optic connector holder adapted to selectively retain two or more fiber optic connectors that include a dust cap on the ferrule. The connector holder comprises a boot retainer to selectively retain a portion of the boot of the connector, and the connector holder comprises a dust cap retainer to selectively retain a portion of the dust cap of the connector. The connector holder is provided in a telecommunications enclosure to provide convenient parking for fiber optic connectors that are not optically connected within a distribution field or the like or that are generally not in service at the time. The connector holders may be selectively installed and/or removed from the telecommunications enclosure to assist in the installation of new fiber optic hardware, such as splitter modules.