A fiber connected body includes: a first multi-core fiber including a first cladding, first cores disposed in the first cladding, and a first marker disposed in the first cladding; and a second multi-core fiber including a second cladding, second cores disposed in the second cladding, and a second marker disposed in the second cladding. One end surface of the second multi-core fiber is connected to one end surface of the first multi-core fiber. Each of the second cores is connected to any one of the first cores, or each of the first cores is connected to any one of the second cores.

A telecommunications device fixation assembly includes a bracket configured to be mounted to a telecommunications fixture, the bracket defining at least one planar wall and a device holder configured to be removably mounted to the bracket, the device holder defining a device holding portion and a fixation portion, wherein the fixation portion defines at least one pocket configured to receive an edge of the planar wall of the bracket, the fixation portion further including an elastically flexible latch configured to snap fit to a portion of the planar wall of the bracket to fix the device holder to the bracket.

A multi-fiber cable assembly includes a pigtail segments spliced to a trunk segment using multiple mass fusion splices. The splices are disposed within an encapsulation at a common axial location. A flexible conduit extends from one end of the encapsulation to protect bare fibers of the trunk segment. A protective sheath extends from the opposite end of the encapsulation to protect the pigtail segments. The conduit and sheath are axially fixed to the encapsulation.

A telecommunications device fixation assembly includes a bracket configured to be mounted to a telecommunications fixture, the bracket defining at least one planar wall and a device holder configured to be removably mounted to the bracket, the device holder defining a device holding portion and a fixation portion, wherein the fixation portion defines at least one pocket configured to receive an edge of the planar wall of the bracket, the fixation portion further including an elastically flexible latch configured to snap fit to a portion of the planar wall of the bracket to fix the device holder to the bracket.

A method of mounting a telecommunications frame (114) to a floor surface includes fixing a floor mounting template (6000) to the floor surface, wherein the template (6000) defines a front end (6020) and a rear end (6022) and first and second sides (6006, 6008) extending therebetween, sliding the telecommunications frame (114) over the floor mounting template (6000) in a direction extending from the front end (6020) to the rear end (6022) of the template, wherein the template (6000) is positioned within a gap (5999) defined by spaced-apart walls (5997) of the telecommunications frame (114), and securing the first side (6006) of the floor mounting template (6000) to a first portion of the telecommunications frame (114) and securing the second side (6008) of the floor mounting template (6000) to a second portion of the telecommunications frame (114).

A system for managing connections for optical fibers that extend from a cable comprises a tray and a tray mount. The tray includes a body having at least one tray mount receiver. The tray mount comprises a base that defines an interface for cooperating with the at least one tray mount receiver, and comprises a clamshell tube configured to receive the optical fibers. The clamshell tube is movable between an open position and a closed position. The tray mount is configured couple the optical fibers to the tray without additional tools.

A telecommunications device fixation assembly includes a bracket configured to be mounted to a telecommunications fixture, the bracket defining at least one planar wall and a device holder configured to be removably mounted to the bracket, the device holder defining a device holding portion and a fixation portion, wherein the fixation portion defines at least one pocket configured to receive an edge of the planar wall of the bracket, the fixation portion further including an elastically flexible latch configured to snap fit to a portion of the planar wall of the bracket to fix the device holder to the bracket.

A termination enclosure includes a chassis configured to hold optical terminations and optical splices. The optical splices are mounted to a removable splice drawer. In certain examples, the splice drawer is removed through a rear of the chassis while the optical terminations remain at the chassis. Optical splices can be made at a workstation remote from the chassis and stored in the splice drawer, which is inserted back into the 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.

An optical fiber interface housing includes a body having a first end and an opposite second end, a port at the first end of the body, an opening at the second end of the body; and a boot coupled with the port. The boot and the port are configured to receive a fiber optic cable containing at least one optical fiber and to permit the at least one optical fiber to pass through the body from the first end to the second end. The opening is configured to receive the at least one optical fiber and to permit the at least one optical fiber to pass through the opening and exit the body.