There is provided an optical fiber array that can be easily optically connected to cores of optical waveguides on a connection counterpart substrate without requiring a complicated fabrication process to the connection counterpart substrate and laborious diffusing fusion of the cores. In an array, coating-removed exposed portions of fibers are attached to grooves that are provided on a lower substrate in order to position the optical fibers. Further, the exposed portions are pressed by a lid. Coated portions of the fibers are placed on a flat surface of a concave portion that is provided on the substrate to form a step with the grooves in a state where the exposed portions are attached. Front end parts of the exposed portions of the fibers each have a light collecting portion that collects light beams passing through an inside of the corresponding fiber to reduce an MFD. The light collecting portions are lens-shaped portions that are formed by cutting and are used for optical alignment with the cores of the optical waveguides.

An optical interconnect may provide for optical communications between two IC chips. The optical interconnect may include an array of optoelectronic elements, for example microLEDs and photodetectors, with the array including a plurality of sub-arrays. A fiber bundle of optical fibers may couple the optoelectronic elements, and the fiber bundle may include a plurality of sub-bundles, with for example one sub-bundle for coupling pairs of sub-arrays. Fibers of each sub-bundle may be accurately positioned with respect to one another.

Fiber optic network systems are implemented, at least in part, using very small form factor (VSFF) interconnect components such as VSFF duplex connector; VSFF mechanical transfer ferrule (MT) connector; VSFF duplex uniboot connector; VSFF MT uniboot connector; VSFF duplex adapter; VSFF MT adapter; VSFF duplex pluggable transceiver; VSFF MT pluggable transceiver; VSFF patch cable assembly; VSFF trunk cable; and/or VSFF breakout cable. The VSFF fiber optic network systems can define fiber breakout cabling that connects large trunk cables to many peripheral network locations. The network systems can define branches and sub-branches from a trunk cable. The network systems can define cross-connect sub-networks between sets of transceivers or adapters. The network systems can define a trunk-to-transceiver cabling assembly for connecting a trunk cable to at least 32 transceiver ports.

A ferrule is provided, the fiber is inserted into a through hole axially disposed in the ferrule body, a first end of the fiber is located inside the through hole, a vertical distance between an end face of the first end of the fiber and a plane on which a connection end face of the ferrule body is located is a first preset distance, and the first preset distance is a distance that can leave a gap between a fiber of the ferrule and a fiber of another ferrule after the ferrule abuts the another ferrule.

An optical fiber connector includes an adaptor having an insertion hole and first and second plugs holding, respectively, first and second optical fibers. The adaptor has first and second attracting surfaces having, respectively, one and the other insertion ports of the insertion hole. The first plug has a first attracted surface that receives, from the first attracting surface, an attractive force generated by a magnetic force when the first optical fiber is inserted into the one insertion port. One of the first attracting surface and the first attracted surface is constituted by a permanent magnet, and the other one thereof is constituted by a magnetic body. In a connection state between the first and second optical fibers, at least the outer peripheral edge of the first attracted surface does not continuously contact the outer peripheral edge of the first attracting surface.

An optical fiber connector can terminate a plurality of optical fiber cables, each with a jacket encasing at least one optical fiber and a strength element. A connector housing has a back post. The optical fibers of the plurality of optical fiber cables extend into the connector housing through the back post. A single crimp ring crimps the strength members of the plurality of optical fiber cables onto the back post. In a method of terminating a plurality of optical fiber cables, the cables are inserted through a single crimp ring, optical fibers of each of the cables are terminated in a multifiber ferrule, the cables are loaded into a back body of a connector housing, and strength members of the cables are crimped onto a back post using a single crimp ring.

The present disclosure relates to a matched pair detachable connector for high fiber count applications where the configuration of the connector maintains optical fiber alignment and ferrule alignment during assembly of the connector.

An optical connector holding two or more LC-type optical ferrules is provided. The optical connector includes an outer body, an inner front body accommodating the two or more LC-type optical ferrules, ferrule springs for urging the optical ferrules towards a mating connection, and a back body for supporting the ferrule springs. A removable inner front body for polarity change is disclosed. A multi-purpose rotatable boot assembly for polarity change is disclosed. The multi-purpose boot assembly can be pushed and pulled to insert and remove the micro connector from an adapter receptacle.

A probe comprising a body portion and a tip portion. The body portion comprises: a first mounting portion comprising a plurality of first carriers, each first carrier being arranged to support an elongate first waveguide, the first carriers being disposed in an equiangular arrangement around a longitudinal axis of the body portion; a plurality of first waveguides, each first waveguide being supported in a respective one of the plurality of first carriers; and a body end fitting at which first ends of the first waveguides are supported in the equiangular arrangement around the longitudinal axis of the body portion such that the first waveguides can transmit electromagnetic radiation signals from an energy source to the body end fitting and/or transmit electromagnetic radiation signals from the body end fitting to a receiver. The tip portion comprises: a second mounting portion comprising a plurality of second carriers, each second carrier being arranged to support an elongate second waveguides, the second carriers being disposed in the equiangular arrangement around a longitudinal axis of the tip portion; a plurality of second waveguides, each second waveguides being supported in a respective one of the plurality of second carriers; and a tip end fitting at which first ends of the second waveguides are supported in the equiangular arrangement around the longitudinal axis of the tip portion; and an elongate conduit for piercing human tissue.

In one embodiment, an optical fiber includes an inner core having a core refractive index delta and profile shape parameter α in the range of 1.8 to 2.6, including endpoints, and a cladding layer surrounding the inner core. The cladding layer includes an inner cladding segment having an inner refractive index delta, a trench segment having a trench refractive index delta, and an outer cladding segment having an outer refractive index delta. The optical fiber further includes a coating layer surrounding the cladding layer and having a thickness of less than 30 .Math.m and a modulus greater than or equal to 0.5 GPa.