Certain types of fiber termination enclosures include an enclosure and at least one of a plurality of plate module mounting assemblies. Example plate module mounting assemblies include a termination panel plate assembly; a splice tray plate assembly; a cable spool plate assembly; and a drop-in plate assembly. Example cable spool plate assemblies include a cable spool arrangement rotationally coupled to a mounting plate, which fixedly mounts within the enclosure housing. A stand-off mount element may be disposed on the front of the cable spool arrangement to rotate in unison with the cable spool arrangement. The stand-off mount element may include one or more termination adapters.

Fiber optic connectors and connectorized fiber optic cables include connector housings having locking portions defined on the connector housing that allow the connector housing to be selectively coupled to a corresponding push-button securing member of a multiport assembly. Methods for selectively connecting a fiber optic connector to, and disconnecting the fiber optic connector from the multiport assemblies allow for connector housings to be forcibly and nondestructively removed from the multiport assembly.

The present disclosure relates to a fiber optic cable breakout assembly that includes a transition body made from a moldable material having an inlet end and an opposite outlet end. The moldable transition body includes a centering element positioned therein and an internal splice positioned within the centering element to splice a plurality of breakout fibers to at least one cable. The centering element is configured to center the splice, the at least one cable and the plurality of breakout fibers prior to molding the transition body. The transition body is adapted to protect the splice and fibers such that no other external protection is needed.

An optical fiber includes a glass portion, a primary coating layer, and a secondary coating layer. In the optical fiber, a value of microbend loss characteristic factor F.sub.μBL_GΔβ is 6.1 ([GPa.sup.−1.Math.μm.sup.−2.5/rad.sup.8].Math.10.sup.−12) or less when represented by
F.sub.μBL_GΔβ=F.sub.μBL_G×F.sub.μBL_Δβ,
where F.sub.μBL_G is geometry microbend loss characteristic and F.sub.μBL_Δβ is optical microbend loss characteristic.

In one embodiment, a method of preparing a round fiber optic cable includes applying a cable orientation guide to a portion of the fiber optic cable. The fiber optic cable includes a jacket, a first strength member, a second strength member, and an optical fiber. The strength members and the optical fiber are disposed within the jacket along a strength axis. Applying the cable orientation guide rotates the fiber optic cable such that the strength axis is positioned along a preferential axis. The method further includes forming a punched area in the jacket. The method also include removing a portion of the jacket forward of the punched area to provide a flat end face defined by the punched area for attaching the cable to a retention body of a fiber optic connector.

In one embodiment, a method of preparing a round fiber optic cable includes applying a cable orientation guide to a portion of the fiber optic cable. The fiber optic cable includes a jacket, a first strength member, a second strength member, and an optical fiber. The strength members and the optical fiber are disposed within the jacket along a strength axis. Applying the cable orientation guide rotates the fiber optic cable such that the strength axis is positioned along a preferential axis. The method further includes forming a punched area in the jacket. The method also include removing a portion of the jacket forward of the punched area to provide a flat end face defined by the punched area for attaching the cable to a retention body of a fiber optic connector.

An optical fan-out assembly includes: a fiber optic cable comprising a plurality of optical fibers and a surrounding jacket; a housing comprising first and second mating halves that mate to form a cavity, each of the first and second halves having opposite first and second ends and first and second lips adjacent respective first and second ends; the second half having a window, wherein the first lips create a seal with the cable jacket; a disk with a plurality of holes, a plurality of slots, and having a periphery, wherein a respective one of the plurality of slots extends between each hole and the periphery, the disk adjacent to and forming a seal with the second lips of the first and second halves; and a plurality of furcation tubes, each of the furcation tubes being inserted into a respective hole; wherein the optical fibers extend through the cavity, and each optical fiber is received in a respective furcation tube.

Fiber optic connectors, cable assemblies and methods for making the same are disclosed. In one embodiment, the optical connector comprises a housing and a ferrule. The housing comprises a longitudinal passageway between a rear end and a front end, and, a part of the rear portion of the housing comprises a round cross-section and a part of the front portion of the housing comprises a non-round cross-section with a transition region disposed between the rear portion and the front portion.

Multiports having connection ports with associated securing features and methods for making the same are disclosed. In one embodiment comprises a multiport for providing an optical connection comprising a shell, a connection port insert, and at least one securing feature. The shell comprises a first end having a first opening leading to a cavity. The connection port insert comprises a body having a front face and at least one connection port comprising an optical connector opening extending from the front face into the connection port insert with a connection port passageway extending through part of the connection port insert to a rear portion, where the connection port insert is sized so that at least a portion of the connection port insert fits into the first opening and the cavity of the shell. The at least one securing feature is associated with the at least one connection port.

Multiports comprising a connection port insert having at least one optical port along with methods for making are disclosed. One embodiment is directed to a multiport for providing an optical connection comprising a shell and a connection port insert. The shell comprises a first end having a first opening leading to a cavity. The connection port insert comprises a body having a front face and at least one connection port comprising an optical connector opening extending from the front face into the connection port insert with a connection port passageway extending through part of the connection port insert to a rear portion, where the connection port insert is sized so that at least a portion of the connection port insert fits into the first opening and the cavity of the shell.