The present disclosure relates to various types of optical fibers that are spliced together with a splice protector provided to house the spliced optical fibers. The splice protector has dimensions that enable improved mechanical properties of the spliced optical fiber.

An optical connector for terminating a cable containing one or more multicore fibers. The connector has a plug housing, a ferrule disposed inside the housing, a rotatable frame, and a multicore fiber (MCF) stub having a length of a first MCF a portion of which is fixed inside the ferrule so that a first endface of the fiber is exposed at the front end of the ferrule. An opposite endface of the first MCF is cleaved for fusion splicing to a second MCF in the cable to be terminated. The ferrule also has a flange, and the frame is formed to engage the flange for rotation so that cores in the first MCF can be aligned and positioned in a prescribed orientation relative to the plug housing, and cores in the second MCF can be aligned with corresponding cores in the first MCF when the first and the second MCFs are fusion spliced to one another.

A fiber optic fanout assembly includes: a fiber optic trunk cable comprising a plurality of optical fibers within a surrounding jacket; a fanout housing with an internal bore and rear and front end portions, the fanout housing receiving the optical fibers from the trunk cable within the internal bore though the rear end portion; a plurality of furcation tubes, each containing one or more of the optical fibers; a first sealing structure that creates a first seal between the fanout housing and the jacket of the fiber optic cable; a first disk having a plurality of holes, the first disk mounted to the front end portion of the fanout housing, wherein the furcation tubes and optical fibers residing therein are inserted into the holes in the first disk; and a plurality of second sealing structures, each of which provides a second seal between the furcation tubes and the first disk.

The present disclosure relates to an optical splice package for splicing together first and second optical fibers or first and second sets of optical fibers. The optical fibers have elastic bending characteristics. The splice package includes a splice housing including a mechanical alignment feature for co-axially aligning ends of the first and second optical fibers or sets of optical fibers within the splice housing. The splice housing contains adhesive for securing the ends of the first and second optical fibers or sets of optical fibers within the splice housing. The optical package has a weight less than a spring force corresponding to the elastic bending characteristics of the first and second optical fibers or sets of optical fibers.

A sealed terminal has a housing, a splice tray, and a faceplate. The housing has an interior compartment and a first perimeter flange defining an opening into the interior compartment. The splice tray is positioned in the interior compartment and is configured to support a module or a cartridge. The faceplate has a plurality of ports and a second perimeter flange extending at a perimeter edge of the faceplate. The sealed terminal also has at least one connection bracket and a gasket for connecting the housing and the faceplate to each other. The connection bracket has a slot receiving the first perimeter flange and the second flange in an abutting position. The gasket is positioned between the first perimeter flange and the second perimeter flange and configured to seal any gap therebetween.

A break-out assembly includes an enclosure defining a first port at the first end to receive an optical cable and a second port at the second end to receive a plurality of break-out cables. Each port leads to the interior of the enclosure. A cable retention region defined within the enclosure at the second end is configured to enable the break-out cables to each secure to the enclosure at one of a plurality of axial locations. Certain types of break-out assemblies include other cable retention regions to axially and/or rotationally secure the optical cable to the enclosure. A splice retention region is disposed within the enclosure between the first port and the second cable retention region. The splice retention region receives optical splices at which optical fibers of the optical cable are spliced to optical fibers of the break-out cables.

The present disclosure describes fusion spliced cable assemblies. An assembly may include a first and a second fiber optic cable, where an end of at least a first optical fiber from the first fiber optic cable is fusion spliced together with an end of at least a second optical fiber from the second fiber optic cable, the first optical fiber having a first length of prepared fiber extending from the spliced end of the first optical fiber to a transition point of the first optical fiber, the second optical fiber having a second length of prepared fiber extending from the spliced end of the second optical fiber to a transition point of the second optical fiber, where the transition point of the first optical fiber is a distance from the transition point of the second optical fiber, and where a total length of prepared fiber is the sum of the first length of prepared fiber for the first optical fiber and the second length of prepared fiber for the second optical fiber; a support configured to engage at least a portion of the total length of prepared fiber such that the distance between the transition points of each optical fiber is less than the total length of prepared fiber of the first and second optical fibers; and a transition housing coupled to the first and second fiber optic cables and surrounding the support. Fusion spliced cable assembly breakout kits are also provided.

As described herein, a mode field adapter (MFA) comprises a first fiber including a core associated with a fundamental mode field diameter and a cladding with a diameter that decreases toward a waist. The MFA comprises a second fiber including a core associated with a fundamental mode field diameter that matches the fundamental mode field of the first fiber at the waist and a cladding with a diameter that matches the diameter of the cladding of the first fiber at the waist and increases from the waist of the second fiber. The cladding of the first fiber may be adiabatically etched such that a core-to-cladding ratio of the first fiber changes over a length of the first fiber, and the core and the cladding of the second fiber may be adiabatically tapered such that a core-to-cladding ratio of the second fiber is constant over a length of the second fiber.

Disclosed is an optical fiber-based divergence-limiting device for limiting divergence from a first maximum divergence of input light to a second maximum divergence of output light, in which the second maximum divergence is less than the first maximum divergence.

The present invention relates to a low-profile splice protection system for protecting multi-fibre fusion splice sites. The splice protection system comprises coating material to package the splice site and may comprise a protective housing.