A fiber optic system includes a telecommunications chassis defining a front and a rear, a plurality of blades slidably mounted to the chassis, the blades slidable in a direction extending from the front to the rear, and a plurality of fiber optic cassettes removably mounted to each blade. Each fiber optic cassette includes a housing defining a maximum cassette height, the housing formed by a base and a cover mounted thereon. Each cassette defines fiber optic connection locations. The base of each cassette defines a notched area for receiving a portion of the blade on which the cassette is mounted such that the blade does not increase the overall maximum height defined by the housing.

The present invention provides modular trays having cutout features that are configured to engage with a mounting feature of one or more removable rails. The removable rails may be removably secured to a tray body in a plurality of positions to allow a user to install or uninstall rails to support different sized fiber optic modules. For example, a tray may support a twenty-four optical fiber module, two twelve optical fiber modules, or three eight optical fiber modules. Fiber optic enclosures housing the trays can be affixed to the outside of a fiber optic enclosure and allow for easy stacking and unstacking.

A high density fiber enclosure system includes a chassis, cassette trays, an optional unification clip, cassettes, and an optional trunk cable management system. The chassis, cassette trays, and cassettes are configured such that individual cassettes may be installed, removed, and otherwise positioned for easy access by a user. The unification clip allows two adjacent cassette trays to be connected to one other such that cassette trays move as one unit. The trunk cable management system is designed to organize trunk cables and trunk cable furcation legs as well as relieve strain on the trunk cables and trunk cable furcation legs.

A fiber optic telecommunications device includes a frame and a fiber optic module. The fiber optic module includes a main housing portion defining fiber optic connection locations for connecting cables to be routed through the frame and a cable management portion for guiding cables between the main housing portion and the frame. The main housing portion of the fiber optic module is slidably mounted to the frame, the main housing portion slidable between a retracted position and an extended position in a sliding direction. The cable management portion of the fiber optic module includes a radius limiter slidably coupled to both the main housing portion and the frame, wherein movement of the main housing portion with respect to the frame slidably moves the radius limiter with respect to the main housing portion along the sliding direction.

An enclosure for receiving a fiber optic cassette is disclosed comprising a housing having cassette receiving housing portion and a fiber optic cassette receiving rack which fits in the cassette receiving housing portion. The cassette receiving rack comprises a pair of opposed elongate guide members extending parallel to and be spaced apart from one another. A first end of the rack is secured in the cassette receiving space between the top wall and the bottom wall for rotation about an axis between a first position, where the rack is received in at least a portion the cassette receiving housing portion and the at least one door is closed, and a second position wherein a second end of the rack is positioned outside the cassette receiving space and the at least one door is open. The opposed guide members receive each of the at least one fiber optic cassettes therebetween.

A fiber optic telecommunications device includes a frame and a fiber optic module including a rack mount portion, a center portion, and a main housing portion. The rack mount portion is stationarily coupled to the frame, the center portion is slidably coupled to the rack mount portion along a sliding direction, and the main housing portion is slidably coupled to the center portion along the sliding direction. The main housing portion of the fiber optic module includes fiber optic connection locations for connecting cables to be routed through the frame. The center portion of the fiber optic module includes a radius limiter for guiding cables between the main housing portion and the frame, the center portion also including a latch for unlatching the center portion for slidable movement. Slidable movement of the center portion with respect to the rack mount portion moves the main housing portion with respect to the frame along the sliding direction.

An optical cable termination unit includes a case, a first adapter panel that is disposed in the case and includes a plurality of first adapters each configured so that a corresponding one of a plurality of optical connectors is connectable thereto and disconnectable therefrom and a first surface on which the plurality of first adapters are arranged, and a second adapter panel that is disposed in the case and includes a plurality of second adapters each configured so that a corresponding one of a plurality of optical connectors is connectable thereto and disconnectable therefrom and a second surface on which the plurality of second adapters are arranged. The first and second surfaces are separated from each other. The first adapter panel is configured to be movable relative to the second adapter panel so that the first surface and the second surface are capable of becoming parallel to each other.

The present disclosure relates to a fiber optic assembly having a splice tray that increases spatial efficiency within the fiber optic assembly and within the splice tray. The splice tray may be inserted and/or removed from a terminal without utilization of tools. Additionally, the splice tray may be configured to enable one handed insertion or removal, which may be advantageous, such as in small terminals or confined spaces. The splice tray also provides an efficient routing pattern of optical fibers to enable larger diameter optical fibers to be routed within the splice tray and the terminal.

Methods include, for each of a plurality of pluggable optical transceivers that are fiber-coupled to respective inputs of a passive wavelength division multiplexer having a predetermined loss profile defining a path specific loss between each input and a common output, sending an optical output signal along an optical signal path while the other optical transceivers of the plurality are not sending optical output signals and measuring an optical power of the sent optical output signal at an input of a local optical amplifier downstream from an output of the wavelength division multiplexer, wherein the local optical amplifier is configured to transmit the optical output signals to a distant location, and, based on the measured optical powers, determining a loss distribution across the optical output signals at the input of the local optical amplifier by subtracting the predetermined path specific losses of the wavelength division multiplexer, comparing a variation in the loss distribution to a nominal variation to determine a defect in a transceiver fiber path associated with a higher loss component of the distribution where the variation exceeds the nominal variation, comparing an average or maximum loss in the loss distribution to a nominal average or maximum allowable loss to determine a defect in a common fiber path downstream from the multiplexer, and adjusting one or more of the optical powers of the optical output signals produced by the optical transceivers before transmission through the multiplexer, by an optical power offset that produces a predetermined flat optical power spectrum profile at the input of the local optical amplifier and that increases a transmission distance over which the optical output signals decodably propagate.

A network access point enclosure is configured to house a splice tray that is configured to pivot to provide increased access to opposite sides of the splice tray during assembly. The enclosure includes a base, a cover configured to be sealingly coupled with the base to form a housing, and a splice tray configured to be pivotally coupled with the base. The splice tray is configured to be pivoted between a first orientation relative to the base and a second orientation relative to the base. The splice tray is configured to form a larger angle relative to the base in the first orientation than in the second orientation, and the splice tray is configured to provide increased access to a front side of the splice tray and a rear side of the splice tray in the first orientation than in the second orientation.