A fiber optic ferrule has a main body having a front end, a rear end, and a top surface and a bottom surface joined together by opposing side surfaces and has a longitudinal axis. There are a plurality of optical fiber support structures disposed between the front end and rear end and configured to receive a plurality of optical fibers. The fiber optic ferrule has an end face at the front end of the fiber optic ferrule through which an optical beam passes. There are also a front facing refractive surface and a rear facing refractive surface, the rear facing refractive surface being closer to the end face than the front facing refractive surface, both being at an angle to the front facing refractive surface.

A low-reflection fiber-optic connector. The fiber-optic connector includes a ferrule that includes a fiber passage and an optical fiber traversing the fiber passage. The optical fiber includes a polished fiber end that is substantially flush with a ferrule end face. The ferrule end face, in an area surrounding the polished fiber end, is modified to reduce an optical reflectivity.

An expanded-beam ferrule for an optical interface device has a ferrule body with a fiber support feature that supports an optical fiber. The ferrule body defines a lens having a planar back surface and a convex and aspheric front surface. The lens has a select amount of on-axis spherical aberration that gives rise to an improved coupling efficiency and in particular provided tolerance to misalignments between confronting expanded-beam ferrules used in an expanded-beam optical interface device. The ferrule body can also include multiple lenses and can support multiple optical fibers in operable alignment thereto.

A ferrule mold having a reverse-image of a through-hole array for optical fibers is formed. A non-polymeric ferrule material is deposited in the reverse-image mold, followed by removing the mold to create a multi-fiber connector ferrule having at least two fiber through-holes. An optical fiber is inserted in each through-hole until each fiber endface is positioned approximately even with a connection surface of the ferrule. A fiber recess for each of the optical fibers is formed such that each fiber is recessed from the multi-fiber ferrule connection surface by a distance of at least 0.1 micron. The recess may be formed by differential polishing of the non-polymeric ferrule and endfaces of the optical fibers. Alternatively, a layer of spacer material may be deposited over the multi-fiber ferrule connection surface. An antireflection coating is deposited over the ends of the recessed fibers.

Described are examples of optical blind-mate connector adaptors, optical blind-mate connectors to blind-mate to the adaptors, and optical blind-mate systems. In various implementations, an optical blind-mate connector adapter may include a sleeve, a shutter mounted on a pivot at an opening of the sleeve to move between a closed position and an open position extending into the sleeve, and a cantilever spring anchored to a wall of the sleeve and including a free end extending toward the opening of the sleeve to urge the shutter to the closed position.

An alignment assembly for disposition in an insert for an expanded beam connector, said alignment assembly comprising: (a) at least one cylindrical sleeve having an inner first diameter, and an outer diameter configured to be received in said insert of said connector; (b) a lens disposed in said sleeve, and having a round periphery with a second diameter larger than said first diameter; and (c) a ferrule stub disposed at least partially in said sleeve, and having a round periphery with a third diameter essentially the same as the second diameter, said ferrule stub comprising a fiber stub optically coupled to said lens.

An optical ferrule includes an input surface for receiving and transmitting a central light ray from an optical fiber attached to the optical ferrule. A light redirecting side receives, along a first direction, the central light ray transmitted by the input surface and redirects the received light along a different second direction. The redirected central light ray exits the optical ferrule through an output surface of the optical ferrule. As the central light ray propagates in the optical ferrule from the input surface to the output surface, the central light ray propagates through distinct first and second portions of the optical ferrule having different respective first and second compositions.

An optical waveguide for a magneto-optical current sensor. The optical waveguide includes a first end surface, through which light can be coupled into the optical waveguide, and a second end surface, through which light can be coupled out of the optical waveguide, wherein at least one of the two end surfaces has an anti-reflective coating.

Optical interconnects and related methods are disclosed. An example apparatus described herein includes an optical component carrier including a first tapered surface, a second tapered surface, and an optical component, a waveguide carrier including a third tapered surface engaged with the first tapered surface, and a fourth tapered surface engaged with the second tapered surface, and a waveguide including a second end aligned with the first end.

A ferrule includes a holding part, a first surface and a second surface. The holding part includes a first holding recess including the first surface and a third surface facing the first surface, a first wall, at least one through hole that is open at the third surface and a fourth surface, the fourth surface being located on a side on which the plurality of optical transmission members is inserted, and a plurality of first grooves disposed at the first holding recess along an extending direction of the plurality of optical transmission members, the plurality of optical transmission members inserted to the at least one through hole is respectively disposed at the plurality of first grooves.