Abstract: A fiber optic terminal includes an enclosure defining an interior space having a plurality module holders and at least one module removably positioned in one of the plurality of module holders. Each removable module may include at least one input adapter and a plurality of output adapters. Each removable module may also include one or more splitters, cable storage components, pass-through components, or parking components. The fiber optic module may also include first and second arms extending from the front side of the body and a handle coupled to the first and second arms. The handle may be rotatable between a closed position and an open position, and may also be removable from the first and second arms when the handle is in the open position.

Abstract: An optical communication cable and related systems and methods are provided. A method for field terminating an optical fiber of a fiber optic distribution cable includes accessing at least one of a plurality of optical fibers of the distribution cable by creating an access location in the distribution cable, inserting a cutting tool through the access location such that the cutting tool extends longitudinally past the access location a predetermined distance, terminating the at least one of the plurality of optical fibers at the predetermined distance, removing at least a portion of the at least one terminated optical fiber through the access location, and inserting the portion of the at least one terminated optical fiber through a furcation tube premounted on a small access closure device.

Abstract: A fiber optic terminal includes an enclosure defining an interior space having a plurality module holders and at least one module removably positioned in one of the plurality of module holders. Each removable module may include at least one input adapter and a plurality of output adapters. Each removable module may also include one or more splitters, cable storage components, pass-through components, or parking components. The fiber optic module may also include first and second arms extending from the front side of the body and a handle coupled to the first and second arms. The handle may be rotatable between a closed position and an open position, and may also be removable from the first and second arms when the handle is in the open position.

Abstract: Optical filter devices for providing a reflective event in an optical network are disclosed. In one embodiment, the optical filter device comprises an optical filter assembly for reflecting one or more preselected wavelengths and a housing. In one embodiment, the housing comprises a plug end and a receptacle end for optical connection into a link or connection node of an optical network. The housing comprises a passageway between the plug end and the receptacle end, and the plug end comprises a shroud with a single fiber connector footprint. At least a portion of the optical filter assembly is disposed within the passageway of the housing. The optical filter devices disclosed allow the network operator the flexibility to choose where to position a reflective location in the optical network along with the ability to move, add or change the reflective location as desired.

Abstract: An optical communication cable and related systems and methods are provided. A method for field terminating an optical fiber of a fiber optic distribution cable includes accessing at least one of a plurality of optical fibers of the distribution cable by creating an access location in the distribution cable, inserting a cutting tool through the access location such that the cutting tool extends longitudinally past the access location a predetermined distance, terminating the at least one of the plurality of optical fibers at the predetermined distance, removing at least a portion of the at least one terminated optical fiber through the access location, and inserting the portion of the at least one terminated optical fiber through a furcation tube premounted on a small access closure device.

Abstract: A fiber optic connection device having a casing with a first end and a second end is disclosed. An optical splitter is positioned in the casing and has an input proximal to the first end of the casing and an output proximal to the second end of the casing. A first optical interface is located adjacent to the first end and is in optical communication with the input of the optical splitter. The first optical interface includes a first optical fiber interconnection point. A second optical interface is located adjacent the second end of the casing and is in optical communication with the output of the optical splitter. The second optical interface includes a second optical fiber interconnection point. In some embodiments, the casing may provide protection from environmental elements.

Abstract: A fiber optic connector assembly having a body connected to first and second tubular enclosures at their first ends is disclosed. The first tubular enclosure extends in a first direction. The second tubular enclosure extends in a second direction. An optical splitter is positioned in the body proximal to the first ends of the first tubular enclosure and the second tubular enclosure. A first waveguide extends from the optical splitter in the first direction through the first tubular enclosure. A second waveguide extends from the optical splitter in the second direction through the second tubular enclosure. A first fiber connector in optical communication with the first waveguide is connected to a second end of the first tubular enclosure. A second fiber connector in optical communication with the second waveguide and is connected to a second end of the second tubular enclosure. In some embodiments, the body may be sealed from environmental elements.

Abstract: An optical fiber distribution system is provided. The system includes a distribution cable having a plurality of cable optical fibers. The system includes a plurality of optical fiber tethers each including a tether optical fiber optically coupled to a cable optical fiber. The tethers provide access to and distribute the optical network at positions along the length of the optical fiber. The system is configured to provide access area organization and/or low profiles, such as through staggered tether lengths, tether webbing and/or access area sleeve arrangements.

Abstract: A fiber optic distribution assembly includes a plurality of fiber optic connectors, each having a plurality of ports arranged in the same predetermined port configuration. The predetermined port configuration has a plurality of port positions. Each of a group of N first optical fibers is optically connected to a first (e.g., input) fiber optic connector at port positions 1 through N of the predetermined port configuration, to support a group of N drop connections. A plurality of M second optical fibers is connected between ports (N+1) through (M+N) of the first fiber optic connector and ports 1 through M of a second (e.g., lateral) fiber optic connector. A plurality of P third optical fibers is connected between ports (M+N+1) through (M+N+P) of the first fiber optic connector and ports 1 through P of a third (e.g., distribution) fiber optic connector.

Abstract: A fiber optic distribution assembly includes a plurality of fiber optic connectors, each having a plurality of ports arranged in the same predetermined port configuration. The predetermined port configuration has a plurality of port positions. Each of a group of N first optical fibers is optically connected to a first (e.g., input) fiber optic connector at port positions 1 through N of the predetermined port configuration, to support a group of N drop connections. A plurality of M second optical fibers is connected between ports (N+1) through (M+N) of the first fiber optic connector and ports 1 through M of a second (e.g., lateral) fiber optic connector. A plurality of P third optical fibers is connected between ports (M+N+1) through (M+N+P) of the first fiber optic connector and ports 1 through P of a third (e.g., distribution) fiber optic connector.

Abstract: An optical communication cable and related systems and methods are provided. A method for field terminating an optical fiber of a fiber optic distribution cable includes accessing at least one of a plurality of optical fibers of the distribution cable by creating an access location in the distribution cable, inserting a cutting tool through the access location such that the cutting tool extends longitudinally past the access location a predetermined distance, terminating the at least one of the plurality of optical fibers at the predetermined distance, removing at least a portion of the at least one terminated optical fiber through the access location, and inserting the portion of the at least one terminated optical fiber through a furcation tube premounted on a small access closure device.

Abstract: A fiber optic terminal includes an enclosure defining an interior space having a plurality module holders and at least one module removably positioned in one of the plurality of module holders. Each removable module may include at least one input adapter and a plurality of output adapters. Each removable module may also include one or more splitters, cable storage components, pass-through components, or parking components. The fiber optic module may also include first and second arms extending from the front side of the body and a handle coupled to the first and second arms. The handle may be rotatable between a closed position and an open position, and may also be removable from the first and second arms when the handle is in the open position.

Abstract: A pocket square assembly for a garment enclosure includes a top assembly having a main body portion, a top portion, and a mounting plate internal to the main body portion; and a base assembly adapted to be precisely received within the garment enclosure, the base assembly comprising a slide holder and a mounting slider, wherein the mounting slider cooperates with the slide holder to provide infinite adjustability of the base assembly and defines a cavity for a base mounting component, and wherein the base mounting component detachably mates with the mounting plate of the top assembly such that the top portion extends a predetermined distance out of the garment enclosure.

Abstract: A pocket square assembly for a garment enclosure includes a top assembly having a main body portion, a top portion, and a mounting plate internal to the main body portion; and a base assembly adapted to be precisely received within the garment enclosure, the base assembly comprising a slide holder and a mounting slider, wherein the mounting slider cooperates with the slide holder to provide infinite adjustability of the base assembly and defines a cavity for a base mounting component, and wherein the base mounting component detachably mates with the mounting plate of the top assembly such that the top portion extends a predetermined distance out of the garment enclosure.

Abstract: Design tools and methods of use for designing, ordering, and providing manufacturing and installation instructions for waveguide system networks include a system design tool including a location selection module to determine a selected location, a satellite imagery component to provide an image based on the selected location, an overlay module to overlay a design on the image, and a customization module to customize the design. The system design tool includes one or more design modules to at least one of automatically output and build via user input one or more design options based on the image, and a design customization module to select the design from the one or more design options. The system design tool includes a positioning module to set a pair of connectivity points such that a cable length may be automatically calculated based on a calculated distance between the pair of connectivity points.

Abstract: Connector assemblies and methods are disclosed for providing sealing and strain-relief. In one embodiment, the connector assembly includes a cable assembly having an overmold portion, an inner housing, and a coupling body. The inner housing includes a sealing element for providing sealing from environmental elements and a crank for providing strain-relief for the connector assembly and inhibiting pulling forces on the cable assembly from being transmitted to the connector of the cable assembly.

Abstract: Connector assemblies and methods are disclosed for providing sealing and strain-relief. In one embodiment, the connector assembly includes a cable assembly having an overmold portion, an inner housing, and a coupling body. The inner housing includes a sealing element for providing sealing from environmental elements and a crank for providing strain-relief for the connector assembly and inhibiting pulling forces on the cable assembly from being transmitted to the connector of the cable assembly.

Abstract: A fiber optic network device comprising an input port adapted to receive a multi-fiber cable having active optical fibers designated in a consecutive sequence is disclosed. A first plurality and a second plurality of optical fibers are disposed within the fiber optic network device. The first plurality of optical fibers aligns to a first section of the consecutive sequence and a second plurality of optical fibers aligns to a second section of the consecutive sequence. A plurality of drop ports in the fiber optic network device are adapted to optically couple ones of the first plurality of optical fibers to at least one drop cable. A pass-through port is adapted to optically couple the second plurality of optical fibers to a second fiber optic network device through a multi-fiber adapter in a central alignment at the pass-through port.

Abstract: A fiber optic network device comprising an input port adapted to receive a multi-fiber cable having active optical fibers designated in a consecutive sequence is disclosed. A first plurality and a second plurality of optical fibers are disposed within the fiber optic network device. The first plurality of optical fibers aligns to a first section of the consecutive sequence and a second plurality of optical fibers aligns to a second section of the consecutive sequence. A plurality of drop ports in the fiber optic network device are adapted to optically couple ones of the first plurality of optical fibers to at least one drop cable. A pass-through port is adapted to optically couple the second plurality of optical fibers to a second fiber optic network device through a multi-fiber adapter in a central alignment at the pass-through port.

Abstract: A fiber optic cable assembly includes leg assemblies, a trunk assembly, a splice assembly, and a furcation assembly. Each leg assembly includes a jacket, an optical fiber, strength members, and a connector. The trunk assembly includes a jacket, optical fibers, strength members, and a multi-fiber connector. The splice assembly includes a tube supporting the optical fibers of the leg and trunk assemblies that are spliced together. The furcation assembly is attached to the splice assembly and includes a fan-out structure and first and second locks. The first lock binds the strength members of the leg assemblies to the furcation assembly, and the second lock binds the strength members of the trunk to the furcation assembly. As such, the furcation assembly provides a mechanical linkage between the trunk and leg assemblies to strain relieve the spliced optical fibers in the tube.