The coupling loss of optical power on a reception side due to an axis deviation on a transmission side is satisfactorily mitigated. A connector body including a first lens and a second lens is provided. The first lens converges light emitted from a light-emitting body. The second lens shapes and emits the light converged by the first lens. For example, the second lens shapes light emitted from the first lens into collimated light. The focal distance of the second lens can be increased while increase in the distance from the light-emitting body to the second lens is inhibited and the diameter of light from the light-emitting body is restricted so as to be within the diameter of the second lens. The coupling loss of optical power on the reception side due to the axis deviation on the transmission side can be mitigated.

A modular optical connector includes a plurality of coupled optical ferrule support modules. Each optical ferrule support module comprises module connecting features configured to couple each ferrule support module with one or more neighboring ferrule support modules of the plurality of ferrule support modules. One or more optical ferrules are disposed and configured to rotate within the ferrule support module. Each optical ferrule includes a first attachment area configured to attach to one or more optical waveguides. One or more passageways are disposed within the ferrule support module. Each passageway is configured to receive the one or more optical waveguides. The passageway comprises a second attachment area configured to attach to the optical waveguides that are attached to the optical ferrule at the first attachment area. The passageway is dimensioned to constrain the optical waveguides to bend within the housing between the first attachment area and the second attachment area.

Lens-based optical connector assemblies and methods of fabricating the same are disclosed. In one embodiment, a lens-based connector assembly includes a glass-based optical substrate includes at least one optical element within the optical substrate, and at least one alignment feature positioned at an edge of the glass-based optical substrate, wherein the at least one alignment feature is located within 0.4 μm of a predetermined position with respect to the at least one optical element along an x-direction and a y-direction. The lens-based connector assembly further includes a connector element including a recess having an interior surface, The interior surface has at least one connector alignment feature. The glass-based optical substrate is disposed within the recess such that the at least one alignment feature of the glass-based optical substrate engages the at least one connector alignment feature.

A fiber optic connector plug includes a housing. The housing includes a central axis, opposing lateral sides and a top side extending between the opposing lateral sides, and an interior channel, extending through the housing, in a direction parallel to the central axis, from a first end portion of the housing to a second end portion of the housing. The housing also includes a latch, coupled to the housing at the top side. The housing further includes a ferrule, extending from the first end portion of the housing. The housing additionally includes a shutter, coupled to the first end portion of the housing such that the shutter is pivotable and translationally slidable, relative to the first end portion of the housing, between a closed position, in which the shutter covers the ferrule, and an open position, in which the shutter does not cover the ferrule.

An apparatus includes a connector for coupling a cable comprising at least one optical fiber and at least one electrical wire to an optical module at a network communications device, the connector comprising an electrical contact plate for engagement with an electrical contact on the optical module, and a ferrule for receiving the at least one optical fiber. The electrical contact plate is configured for electrically coupling the at least one electrical wire to the electrical contact on the optical module for delivery of power through the optical module.

An optical ferrule includes at least one light affecting element configured to affect one or more characteristics of light from an optical waveguide as the light propagates in the optical ferrule, the light affecting element having an input surface. At least one receiving element receives and secures the optical wave guide to the ferrule so that an output surface of the waveguide is optically coupled to the input surface of the light affecting element. A waveguide stop limits movement of the wave guide toward the input surface of the light affecting element when the optical waveguide is installed in the receiving element. A space between the output surface of the optical waveguide and the input surface of the light affecting element is inaccessible to the optical waveguide when the optical waveguide is installed in the receiving element.

An apparatus includes a base having walls that define a track. The track has input and output ends and defines a coiled path that spirals inward from the input end, reaches an inflection point where a direction of curvature is reversed, and spirals outward towards the output end. The track is configured to receive and maintain a majority of an optical fiber in an at least substantially planar coiled arrangement. The apparatus also includes a first transition arm positioned at the input end and a second transition arm positioned at the output end. Each transition arm is configured to be mechanically coupled to the base and includes a groove configured to receive and maintain a portion of the optical fiber in an at least substantially straight orientation. The walls and transition arms are configured to maintain thermal contact with the optical fiber along its entire length.

A fiber optic connector plug includes a housing. The housing includes a central axis, opposing lateral sides and a top side extending between the opposing lateral sides, and an interior channel, extending through the housing, in a direction parallel to the central axis, from a first end portion of the housing to a second end portion of the housing. The housing also includes a latch, coupled to the housing at the top side. The housing further includes a ferrule, extending from the first end portion of the housing. The housing additionally includes a shutter, coupled to the first end portion of the housing such that the shutter is pivotable and translationally slidable, relative to the first end portion of the housing, between a closed position, in which the shutter covers the ferrule, and an open position, in which the shutter does not cover the ferrule.

A ferrule structure includes a ferrule including a plurality of unit holes, and a plurality of lens units, wherein each lens unit includes a lens part attached to an end part of an optical fiber, and each lens unit is molded from a resin for transmittance an optical signal, and each lens unit is to be inserted in one of the unit holes.

An optical module includes a shell, a circuit board, a light-emitting chip, a lens assembly, an optical fiber ferrule assembly and a fastener. The fastener fixes the optical fiber ferrule assembly to the lens assembly. The fastener includes a fastening body, a first clamping portion and a second clamping portion. The first clamping portion is disposed at one end of the fastening body, and is clamped with the optical fiber ferrule assembly. The second clamping portion is disposed at the other end of the fastening body, and is clamped with the lens assembly.