A field installable fiber optical connector formed using a mechanical splice assembly secured within an opening of a plug frame. A fiber optical cable is secured to a distal end of a rear body that is secured to a distal end of the plug frame.

An optical fiber connection system (600) configured to interconnect a plurality of first and second optical fibers (54, 54) is described. The connection system comprises a first bare fiber holder (620) that includes a clamping plate (540) having an interconnection portion (544) with a generally planar surface, wherein bare ends of the plurality of first optical fibers (54) are disposed adjacent to interconnection portion (544) and wherein the plurality of first optical fibers (54) are secured in the first bare fiber holder (620) at a first distance from the bare ends of the plurality of first optical fibers (54) and a second bare fiber holder (620) that includes a splicing plate (580) having a plurality of alignment channels (585), wherein a bare end of each of the second optical fibers (54) extend at least partially into one of the plurality of alignment channels (585) and wherein the plurality of second optical fibers (54) are held at a second distance from the bare ends of the plurality of second optical fibers (54).

Optical connectors that substantially preserve alignment and are easy to manufacture. The alignment system using the optical connectors disclosed herein include a first housing, a second housing and an alignment component, the said alignment component configured to provide optical alignment between the optical components.

Example embodiments provide a device that includes a rigid block body with a reservoir with two angled walls, a channel dug into a center axis of a bottom of the two angled walls, a stop wall at one end of the channel and an open end at a second end of the channel, a hole at a bottom portion of the stop wall, and a cut-out funnel shaped area on an opposite side of the stop wall from the channel, and the cut-out funnel shaped area funnels into the hole.

Hardened fiber optic connectors having a splice connector assembly are disclosed. The splice connector assembly is attached to an optical fiber of a fiber optic cable by way of a stub optical fiber, thereby connectorizing the hardened connector. In one embodiment, the hardened connector includes an inner housing having a first shell and a second shell for securing a tensile element of the cable and securing the splice connector assembly. Further assembly of the hardened connector has a portion of the inner housing fitting into a shroud of the hardened connector. The first shell comprises first and second alignment fingers that allow the mating the hardened connector with a complimentary device. The first shell can have any suitable alignment portion for mating with a complementary device. The hardened connector may also include features for fiber buckling, sealing, cable strain relief or a pre-assembly of components for ease of installation.

An epoxy-free, high-durability and low-cost plastic optical fiber splice design and fabrication process which meets commercial airplane environmental requirements. The splice design: (1) does not require the use of epoxy to join the end faces of two plastic optical fibers together; (2) incorporates double-crimp rings to provide highly durable pull force for the plastic optical fibers that are joined together; (3) resolves any vibration problem at the plastic optical fiber end faces using a miniature stop inside a splice alignment sleeve; and (4) incorporates a splice alignment sleeve that can be mass produced using precision molding or three-dimensional printing processes.

Optical connectors that substantially preserve alignment and are easy to manufacture. The alignment system using the optical connectors disclosed herein include a first housing, a second housing and an alignment component, the said alignment component configured to provide optical alignment between the optical components.

An object of the present invention is to provide a core position recognition method, a connection method, and a connection apparatus that can simplify connection operations, and reduce rotational displacement and positional displacement. The connection apparatus according to the present invention includes a function capable of acquiring the rotation amount of an MCF during the bonding/fixing step. Specifically, the connection apparatus of the present invention uses an MCF with lines drawn on a side surface thereof, thereby recognizing the rotation amount of the MCF from the side surface, and calculating the absolute positions of the cores. The connection apparatus according to the present invention can recognize the absolute position s of the cores from a side image of an MCF in a state in which the MCF has been rotated. By forming a waveguide on a glass substrate serving as a connection destination so as to match the absolute positions of the cores, the rotational and positional displacements of the MCF can be eliminated, thus making it possible to reduce the connection loss.

An epoxy-free, high-durability and low-cost plastic optical fiber splice design and fabrication process which meets commercial airplane environmental requirements. The splice design: (1) does not require the use of epoxy to join the end faces of two plastic optical fibers together; (2) incorporates double-crimp rings to provide highly durable pull force for the plastic optical fibers that are joined together; (3) resolves any vibration problem at the plastic optical fiber end faces using a miniature stop inside a splice alignment sleeve; and (4) incorporates a splice alignment sleeve that can be mass produced using precision molding or three-dimensional printing processes.

Provided is an optical fiber holder comprising a holder body and a cover. The holder body has an accommodation section capable of accommodating a plurality of optical fibers. The holder body or the cover has at least one ridge which can be disposed within the accommodation section. When the cover is closed over the holder body, a plurality of sections which can parallelly accommodate the plurality of optical fibers are parallelly formed by the inner surface of the accommodation section, the lower surface of the cover, and the ridge.