Abstract: Fiber optic cable assemblies and fiber optic terminals supporting port mapping for series connected fiber optic terminals are disclosed. In one embodiment, a fiber optic cable assembly is provided. The fiber optic cable assembly includes a fiber optic cable having a plurality of optical fibers disposed therein between a first end and a second end of the fiber optic cable. The plurality of optical fibers on the first end of the fiber optic cable are provided according to a first mapping. The plurality of optical fibers on the second end of the fiber optic cable are provided according to a second mapping. In this regard, the fiber optic cable assembly provides port mapping of optical fibers to allow multiple fiber optic terminals having the same internal fiber mapping to be connected in series in any order, while providing the same connectivity to each of the terminals in the series.

Abstract: A fiber optic network having a branch cable with a plurality of optical fibers optically coupled to a distribution cable, and first and second optical connection terminals connected in series is disclosed. The first optical connection terminal is adapted to receive a first segment of the branch cable. The first optical connection terminal is configured such that predetermined ones of a first plurality of ports comprise one or more of a first drop port and a first pass-through port. The first drop port is operable for optically coupling a first respective predetermined one of the plurality of optical fibers to a first drop cable. The first pass-through port is operable for optically coupling a second respective predetermined one of the plurality of optical fibers to a second segment of the branch cable extending externally from the first optical connection terminal. The second optical connection terminal is adapted to receive the second segment of the branch cable.

Abstract: A fiber optic network device for optically coupling a fiber optic distribution cable with a fiber optic drop cables is disclosed. Disposed within the fiber optic network device is a plurality of optical fibers optically coupled to the distribution cable. A plurality of ports opens into the fiber optic network device. Predetermined ones of the plurality of ports are operable for optically coupling respective predetermined ones of the plurality of optical fibers each to at least one drop cable external to the fiber optic network device. At least one of the predetermined ones of the plurality of ports is a pass-through port operable for optically coupling at least one of the respective pre-determined ones of the plurality of optical fibers to the at least one drop cable through another fiber optic network device.

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: A fiber optic network having a multi-level architecture is disclosed. A first level of the fiber optic network comprises a first branch. The first branch comprises a plurality of first branch optical fibers optically coupled to a distribution cable and a first branch fiber optic network device. The first branch fiber optic network device is configured to optically couple a first predetermined one of the plurality of first branch optical fibers to a respective first predetermined sub-branch optical fiber, and a second predetermined one of the plurality of first branch optical fibers to a second predetermined sub-branch optical fiber. A second level of the fiber optic network comprises a sub-branch. The sub-branch comprises a first sub-branch fiber optic network device and a second sub-branch fiber optic network device.

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: A method for port mapping a fiber optic network device is disclosed. The method comprises the steps of providing a first fiber optic network device and configuring the first fiber optic network device by disposing therein a first plurality of ports and a plurality of optical fibers optically coupled to a distribution cable. The method also comprises routing predetermined ones of the plurality of optical fibers to respective predetermined ones of the plurality of ports. The first plurality of ports may comprise a first drop port and a first pass-through port. At least one of the predetermined ones of the plurality of optical fibers routes to the first drop port and at least one of the predetermined ones of the plurality of optical fibers routes to the first pass-through port. The method may also comprise providing and configuring a second fiber optic network device optically coupled to the first fiber optic network device through the first pass-through port.

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: Fiber optic cable assemblies and fiber optic terminals supporting port mapping for series connected fiber optic terminals are disclosed. In one embodiment, a fiber optic cable assembly is provided. The fiber optic cable assembly includes a fiber optic cable having a plurality of optical fibers disposed therein between a first end and a second end of the fiber optic cable. The plurality of optical fibers on the first end of the fiber optic cable are provided according to a first mapping. The plurality of optical fibers on the second end of the fiber optic cable are provided according to a second mapping. In this regard, the fiber optic cable assembly provides port mapping of optical fibers to allow multiple fiber optic terminals having the same internal fiber mapping to be connected in series in any order, while providing the same connectivity to each of the terminals in the series.

Abstract: A method for port mapping a fiber optic network device is disclosed. The method comprises the steps of providing a first fiber optic network device and configuring the first fiber optic network device by disposing therein a first plurality of ports and a plurality of optical fibers optically coupled to a distribution cable. The method also comprises routing predetermined ones of the plurality of optical fibers to respective predetermined ones of the plurality of ports. The first plurality of ports may comprise a first drop port and a first pass-through port. At least one of the predetermined ones of the plurality of optical fibers routes to the first drop port and at least one of the predetermined ones of the plurality of optical fibers routes to the first pass-through port. The method may also comprise providing and configuring a second fiber optic network device optically coupled to the first fiber optic network device through the first pass-through port.

Abstract: A fiber optic network having a multi-level architecture is disclosed. A first level of the fiber optic network comprises a first branch. The first branch comprises a plurality of first branch optical fibers optically coupled to a distribution cable and a first branch fiber optic network device. The first branch fiber optic network device is configured to optically couple a first predetermined one of the plurality of first branch optical fibers to a respective first predetermined sub-branch optical fiber, and a second predetermined one of the plurality of first branch optical fibers to a second predetermined sub-branch optical fiber. A second level of the fiber optic network comprises a sub-branch. The sub-branch comprises a first sub-branch fiber optic network device and a second sub-branch fiber optic network device.

Abstract: A fiber optic network device for optically coupling a fiber optic distribution cable with a fiber optic drop cables is disclosed. Disposed within the fiber optic network device is a plurality of optical fibers optically coupled to the distribution cable. A plurality of ports opens into the fiber optic network device. Predetermined ones of the plurality of ports are operable for optically coupling respective predetermined ones of the plurality of optical fibers each to at least one drop cable external to the fiber optic network device. At least one of the predetermined ones of the plurality of ports is a pass-through port operable for optically coupling at least one of the respective pre-determined ones of the plurality of optical fibers to the at least one drop cable through another fiber optic network device.

Abstract: A shelf for a fiber optic network device is disclosed. The shelf comprises a platform having a top side and a bottom side. The platform is adapted to removably affix to a base of an optical connection terminal having a port disposed through the base such that the platform positions above the port. The shelf includes an access opening extending through the platform from the top side to the bottom side. The access opening provides access to the port from the top side. A transition area extends from the access opening. The transition area is adapted for routing optical fibers disposed in the optical connection terminal between a space under the platform and the top side. A component area is located on the top side, and adapted for mounting a component. At least one of the optical fibers disposed in the optical connection terminal extends from the component.

Abstract: A fiber optic network having a branch cable with a plurality of optical fibers optically coupled to a distribution cable, and first and second optical connection terminals connected in series is disclosed. The first optical connection terminal is adapted to receive a first segment of the branch cable. The first optical connection terminal is configured such that predetermined ones of a first plurality of ports comprise one or more of a first drop port and a first pass-through port. The first drop port is operable for optically coupling a first respective predetermined one of the plurality of optical fibers to a first drop cable. The first pass-through port is operable for optically coupling a second respective predetermined one of the plurality of optical fibers to a second segment of the branch cable extending externally from the first optical connection terminal. The second optical connection terminal is adapted to receive the second segment of the branch cable.

Abstract: A polarity checking apparatus for multi-fiber connectors includes a body, a diverging lens attached to the body and a screen attached to the body, wherein the apparatus is configured to determine test and/or determine polarity of the multi-fiber connector. The screen may be translucent or may be opaque in part and rotatable for checking whether a signal is being transmitted on an individual optical fiber position of the multi-fiber connector. The invention is also directed to a method for checking the polarity of an optical assembly.

Abstract: An adjustable optical tap for adjusting input power, output power and drop power in a communications network includes an enclosure having a plurality of connector assemblies being configured for interconnecting input and output cables; a cover attachable to the enclosure, the cover including a plurality of drop cable ports; and a tunable splitter disposed in the enclosure in communication with the input cable and the drop cable ports, the tunable splitter being configured for adjustment to affect attenuation in a broad wavelength band.

Abstract: An adjustable optical tap for adjusting input power, output power and drop power in a communications network includes an enclosure having a plurality of connector assemblies being configured for interconnecting input and output cables; a cover attachable to the enclosure, the cover including a plurality of drop cable ports; and a tunable splitter disposed in the enclosure in communication with the input cable and the drop cable ports, the tunable splitter being configured for adjustment to affect attenuation in a broad wavelength band.

Abstract: A polarity checking apparatus for multi-fiber connectors includes a body, a diverging lens attached to the body and a screen attached to the body, wherein the apparatus is configured to determine test and/or determine polarity of the multi-fiber connector. The screen may be translucent or may be opaque in part and rotatable for checking whether a signal is being transmitted on an individual optical fiber position of the multi-fiber connector. The invention is also directed to a method for checking the polarity of an optical assembly.

Abstract: A method for the use of contractile pulling grips for cables in which a portion of the outer jacket of the cable is removed and the contractile grip is applied over one or more cable strength elements.