A novel method and apparatus are described that can be used to equalize the latency in fiber optic distribution links within data centers containing multiple pods (clusters of servers) and thereby improve the overall operation and utility of the data center for multiple customers. Specifically, the apparatus serves to add precisely measured latency (signal delays) to data transmission in certain fiber optic cable links so that there are negligible differences in signal transmission times from the central switch (core router) to each of the distributed pods within a data center. While that purposeful addition of latency may, at first, seem counterintuitive to optimizing the performance of a data center, the effect achieved is quite the opposite. That is because all pods will have equal access to received and transmitted data thereby reducing signal congestion and the unbalanced time favoritism of one pod operator over another to the access incoming data.

A communication enclosure is described that includes an enclosure body having a first body portion and a second body portion. An adapter mounting mechanism is disposed in the first body portion, and a connector adapter mounted into the mounting mechanism that is configured to accept an optical fiber connector. The enclosure includes at least one integrated tool for terminating field mountable optical fiber connectors wherein the at least one integrated tool is disposed on one of the first body portion and the second body portion. In an exemplary aspect, the at least one integrated tool is a connector polishing platform.

Devices such as terminals comprising connection ports with associated securing features and methods for making the same are disclosed. In one embodiment, the device comprises a shell, at least one connection port, and at least one securing feature. The at least one connection port is disposed on the terminal with the at least one connection port comprising an optical connector opening extending from an outer surface of the terminal to a cavity of the terminal and defining a connection port passageway. The securing feature is associated with the connection port passageway and is biased by a resilient member having a predetermined pre-load restoring force to the retain position.

A cabinet unit for use in an optical fiber distribution system may include a housing having a cavity, a plurality of extension portions contained within the housing, each extension portion being adapted to support an adapter for receiving cables aligned lengthwise with the extension portion, and a support structure formed on an inner surface of the housing, each extension portion being mounted to the housing by the support structure and extends away from the inner surface of the housing. The plurality of extension portions may be hingedly coupled to the support structure. A clearance between two adjacent extension portions of a given support bar may be configured to be adjusted by rotating the adjacent extension portions along their respective hinged connections.

A telecommunications assembly including a housing and a plurality of modules mounted within the housing. The modules includes a rear face in which is mounted at least one fiber optic connector. Within an interior of the housing are positioned at least one fiber optic adapters. Inserting the module through a front opening of the housing at a mounting location positions the connector of the module for insertion into and mating with the adapter of the housing. The adapters within the interior of the housing are mounted to a removable holder. A method of mounting a telecommunications module within a chassis.

An interconnect system for a building includes a pre-terminated trunk cable assembly that has different groups of optical fibers carried by subunits and terminated by ferrules. The interconnect system also includes trays for managing interconnections with the ferrules. A plurality of adapters are disposed on each tray and arranged in a direction along a longitudinal axis of the tray. The adapters may be oriented at an angle relative to the longitudinal axis to facilitate routing of the optical fibers. At least one tray mount receiver may also be provided on each tray to cooperate with a tray mount that can secure a select subunit to the tray.

A multiport assembly including one or more optical adapters configured to receive an optical connector, a shell having a front face defining one or more connection port insert openings extending from an outer surface of the front face into a cavity of the shell, a connection port insert positioned at least partially within the one of the connection port insert openings of the shell, the connection port insert defining a body including an optical connector opening extending from a front end of the body to a rear end of the body, and a sealing member disposed between the connection port insert and the shell.

An optical distribution and splice frame system includes rack(s), enclosure(s), cable management component(s), and/or cassette(s) that have features to allow for different cable management configurations not yet available in the market. A fiber optic cassette and enclosure are designed to enable flexibility in cable management configurations for the overall system.

An optical cable includes a main body and a termination segment extending from an end of the main body. The main body includes middle portions of optical fibers. The termination segment includes end portions of the optical fibers and multi-fiber connectors attached to the end portions of the optical fibers. The multi-fiber connectors are staggered along a length of the termination segment.

A structured optical fiber cabling system configured to connect first and second layers of switches in a mesh network is disclosed. The system comprises groups of fiber optic ports arranged side-by-side, with each group including a plurality of the fiber optic ports distributed in a vertical direction. A plurality of fiber optic jumper assemblies each include a horizontal segment and a plurality of legs and fiber optic connectors extending from the horizontal segment, with each fiber optic connector configured to connect to a corresponding fiber optic port of the plurality of the fiber optic ports at the same vertical location in each group of the array.