An optical communication subassembly includes one or more optoelectronic devices, one or more optical elements, and a transceiver light coupling unit. Each optical element is configured to change a divergence of the outgoing light relative to a divergence of the incoming light and is spaced apart from and optically aligned with a corresponding optoelectronic device. The transceiver light coupling unit has a mating surface configured for mating with a connector light coupling unit attached to an optical waveguide. A mating direction of the optical light coupling unit forms an angle with the mating surface of the transceiver light coupling unit such that when the connector light coupling unit mates with the transceiver light coupling unit, the angle between the mating direction of the connector light coupling unit and the mating surface of the transceiver light coupling unit causes the optical waveguide to bend.

A fiber optic network architecture for distributing service to local subscribers is disclosed. The architecture includes a plurality of high-fiber count cables connected end-to-end at connectorized coupling locations to form a main cable trunk. The connectorized coupling locations include high-fiber count pass-through connections for optically connecting optical fibers of adjacent ones of the high-fiber count cables end. The connectorized coupling locations also including high-fiber count branch connections for optically connecting optical fibers of the high-fiber count cables to branch locations.

An optical cable subassembly includes one or more optical waveguides, at least light coupling unit comprising a first attachment area permanently attached to the optical waveguides, and at least one cable retainer comprising a second attachment area permanently attached to the optical waveguides and adapted to be installed in a housing. A length of the optical waveguides between the first attachment area and the second attachment area allows a bend in the optical waveguides that provides a predetermined mating spring force at a predetermined angle of the light coupling unit when installed in the housing.

A unitary optical ferrule is molded to include one or more elements for receiving and securing one or more optical waveguides one or more elements for affecting one or more characteristics of light from the optical waveguide while propagating the light within the ferrule. The optical ferrule also includes one or more first alignment features and one or more second alignment features that, when the ferrule is mated with a mating ferrule, each controls alignment of the ferrule with the mating ferrule along three mechanical degrees of freedom. The surface of the optical ferrule can be divided along the thickness axis into a first section and an opposing second section, wherein the first section of the surface includes the receiving and securing elements, the light affecting elements, and the first alignment features and the second section of the surface includes the second alignment features.

An optical connector includes a first attachment area for receiving and permanently attaching to an optical waveguide. A light coupling unit is disposed and configured to move translationally and not rotationally within the housing of the connector. The light coupling unit includes a second attachment area for receiving and permanently attaching to an optical waveguide received and permanently attached at the first attachment area. The light coupling unit also includes light redirecting surface. The light redirecting surface is configured such that when an optical waveguide is received and permanently attached at the first and second attachment areas, the light redirecting surface receives and redirects light from the optical waveguide. The optical waveguide limits, but does not prevent, a movement of the light coupling unit within the housing.

A connector is disclosed that includes a housing and first and second attachment areas located in the housing and spaced apart from each other along the mating direction of the connector. The second, but not the first, attachment area is designed to move relative to the housing. The connector further includes an optical waveguide that is permanently attached to, and under a first bending force between, the first and second attachment areas. The connector also includes a light coupling unit located in the housing for receiving light from the optical waveguide and transmitting the received light to a mating connector along a direction different than the mating direction of the connector. The mating of the connector to the mating connector causes the optical waveguide to be under a greater second bending force between the first and second attachment areas.

An expanded beam connector for use with a fibre optic fibre is described, the expanded beam connector comprising; a body and at least one bore located within said body for accepting a fibre optic ferrule, wherein the perimeter of said bore comprises at least one channel extending from an open end of said bore. Methods of manufacturing an expanded beam connector are also described.

A fiber optic cable connector for connecting the terminal ends of two fiber optic cables having termini of respective ones of multiple optical fibers included within said cables. The connector has a termini with a pin body that includes a flat alignment surface at the rear of the main body. The pin body is received in a bore of an insert body. The forward face of the insert body has a shoulder that partially obstructs the bore and aligns with the flat alignment surfaces of the pin body. The shoulder and flat alignment surface cooperate to ensure that the termini is properly inserted into the bore so that an angled forward contact surface of the termini is properly aligned with the angled forward contact surface of a mating termini of another connector.

A hybrid conduit assembly is disclosed. In one aspect, the hybrid includes an outer jacket with a first side portion housing a first conductor, a second side portion housing a second conductor, and a hollow central conduit portion. The hybrid conduit assembly further includes a first connector assembly defining a central passageway and including first and second electrical connectors that are respectively connected to the first and second conductors. The connector assembly is configured such that it can be connected with other similarly configured connector assemblies such that a hybrid conduit system can be built that has a continuous passageway for the later installation of an optical fiber cable and that has that has interconnected conductors to deliver power from a power source located proximate a first end of the conduit system to an end use device proximate another end of the conduit system.

An example electro-optical connector may comprise an optical ferrule to optically engage with a complementary optical ferrule on a complementary electro-optical connector, a first conductive guide post disposed adjacent to the optical ferrule to electrically engage with a first guide pocket of the complementary electro-optical connector, and a second conductive guide post disposed on an opposite side of the optical ferrule from the first conductive guide post and to electrically engage with a second guide pocket of the complementary electro-optical connector. The first and second conductive guide posts may align the optical ferrule for engagement with the complementary optical ferrule when the guide posts are engaged with the respective guide pockets, and the first and second conductive guide posts may conduct an electrical signal or electrical power from the electro-optical connector to the complementary electro-optical connector.