Abstract: Disclosed are optical connectors having lenses along with methods for making the same. In one embodiment, the optical connector includes a fiber body having a front portion with a plurality of fiber guides, and a connector body having a plurality of connector body fiber guides that lead to a plurality of lenses at a front portion of the connector body. The fiber body attaches to the connector body and may align a plurality of optical fibers to the lenses at the front portion of the connector body. One embodiment has the fiber body configured as a crimp body with a barrel at a rear portion for attaching a fiber optic cable.

Abstract: A molded waveguide side-facet coupler to facilitate an optical connection between optical side-facets and a fiber optic connector is disclosed. Instead of molding the side-facet coupler with the external mounting surface disposed on an external surface of the mold, the mold for the side-facet coupler is provided such that the mounting surface of the side-facet coupler is provided as a molded internal recess surface. The moldable material for the side-facet coupler is disposed around a recess core that is part of the mold, thereby forming a unitary component having at least one internal recess surface for providing an external mounting surface for the side-facet coupler. As the molded material cures around the core structure, the external surfaces of the unitary component pull away from internal surfaces of the mold, and shrink around the core structure. Thus, the internal recess surface of the unitary component is formed within narrower, repeatable tolerances.

Abstract: A traceable cable assembly includes a traceable cable having at least one data transmission element, a jacket at least partially surrounding the at least one data transmission element, and a tracing optical fiber incorporated with and extending along at least a portion of a length of the traceable cable. The traceable cable assembly also includes a connector provided at each end of the traceable cable. Each connector has a connector housing having opposed first and second ends, the second end being coupled to the traceable cable, and a diffuser supported by the connector housing. The connector housing is configured to receive tracer light from the tracing optical fiber and allow the tracer light to leave the connector housing. The diffuser is also configured to diffuse the tracer light leaving the connector housing.

Abstract: Field-installable mechanical splice connectors for making optical and/or electrical connections in the field are disclosed. One embodiment is a hybrid mechanical splice connector having an electrical portion and an optical portion that includes at least one electrical contact, a shell, and at least one body for receiving at least one field optical fiber and securing the electrical contact. The connector includes a mechanical retention component for securing at least one optical field fiber to the at least one body. Another embodiment is directed to a mechanical splice connector having at least one body for receiving at least one field optical fiber, a mechanical retention component for securing at least one optical field fiber to the at least one body, and at least one lens attached to the at least one body.

Abstract: Disclosed are optical connectors and methods for making the same. In one embodiment, the optical connector comprises an optical body, one or more first magnetic materials attached to the optical body, a housing, and one or more second magnetic materials attached to the housing. The first magnetic material(s) provide alignment with an optical element of a complimentary receptacle and the optical body may include one or more openings for receiving the first magnetic materials. The second magnetic material(s) attached to the housing provide retention of the optical connector with the complimentary receptacle when mated together. Consequently, the optical connector allows for quick and easy assembly along with a robust structure for a large number of mating/unmating cycles. In other embodiments, the optical devices disclosed may further include one or more electrical contacts for making a hybrid connection or have a TIR surface integrated into a portion of a housing.

Abstract: Field-installable mechanical splice connectors for making optical and/or electrical connections in the field are disclosed. One embodiment is a mechanical splice connector having an optical portion that includes at least one lens. The connector also includes a mechanical retention component for securing at least one optical field fiber to the at least one body.

Abstract: Gradient index (GRIN) lens holders employing groove alignment feature(s) and a recessed cover, as well as optical connectors and methods employing such GRIN lens holders, are disclosed. In one embodiment, the GRIN lens holder contains one or more internal groove alignment features configured to secure one or more GRIN lenses in the GRIN lens holder. The groove alignment features are also configured to accurately align the end faces of the GRIN lenses. The GRIN lens holder also contains a recessed cover having a front face that is negatively offset with respect to a mating surface of the GRIN lens holder. The GRIN lens holders disclosed herein can be provided as part of an optical fiber ferrule and/or a fiber optic component or connector for making optical connections.

Abstract: Disclosed are optical connectors having lenses along with methods for making the same. In one embodiment, the optical connector includes a fiber body having a front portion with a plurality of fiber guides, and a connector body having a plurality of connector body fiber guides that lead to a plurality of lenses at a front portion of the connector body. The fiber body attaches to the connector body and may align a plurality of optical fibers to the lenses at the front portion of the connector body. One embodiment has the fiber body configured as a crimp body with a barrel at a rear portion for attaching a fiber optic cable.

Abstract: A molded waveguide side-facet coupler to facilitate an optical connection between optical side-facets and a fiber optic connector is disclosed. Instead of molding the side-facet coupler with the external mounting surface disposed on an external surface of the mold, the mold for the side-facet coupler is provided such that the mounting surface of the side-facet coupler is provided as a molded internal recess surface. The moldable material for the side-facet coupler is disposed around a recess core that is part of the mold, thereby forming a unitary component having at least one internal recess surface for providing an external mounting surface for the side-facet coupler. As the molded material cures around the core structure, the external surfaces of the unitary component pull away from internal surfaces of the mold, and shrink around the core structure. Thus, the internal recess surface of the unitary component is formed within narrower, repeatable tolerances.

Abstract: Gradient index (GRIN) lens holders employing groove alignment feature(s) in recessed cover and single piece components, connectors, and methods are disclosed. In one embodiment, the GRIN lens holder contains one or more internal groove alignment features configured to secure one or more GRIN lenses in the GRIN lens holder. The groove alignment features are also configured to accurately align the end faces of the GRIN lenses. The GRIN lens holders disclosed herein can be provided as part of an optical fiber ferrule and/or a fiber optic component or connector for making optical connections. A fiber optic connector containing the GRIN lens holders disclosed herein may be optically connected to one or more optical fibers in another fiber optic connector or to an optical device, such as a laser-emitting diode (LED), laser diode, or opto-electronic device for light transfer.

Abstract: Disclosed are optical ports and devices using the optical ports. The optical port includes a mounting body having a first pocket and at least one mounting surface for securing the optical port, one or more optical elements, and a first alignment feature disposed in the pocket, wherein the alignment feature includes a piston that is translatable during mating. The one or more optical elements may be an integral portion of the mounting body or a discrete lens. In other embodiments, the mounting body may include a plurality of pockets and one of the pockets may include a magnet for securing a plug to the optical port. The optical port may optionally have a minimalist optical port footprint so that the complimentary mating optical plug engages a portion of the frame during mating.

Abstract: Optical connections for optical communication having in-line optical paths and magnetic coupling portions are disclosed. In one embodiment, an optical connection includes a lens block having an optical interface portion that defines an in-line optical path without an optical turn for optical signals propagating through the lens block, and a magnetic coupling portion disposed about at least a portion of the lens block. In another embodiment, a method of making an optical connection that includes providing a circuit board having one or more active components and placing a lens block on the circuit board. The lens block includes an optical interface portion defining an in-line optical path. The method further includes placing at least one magnetic coupling portion about the lens block. The at least one magnetic coupling portion is configured as a bulk magnetic material. Electronic devices and fiber optic cable assemblies are also disclosed.

Abstract: Optical backplane extension modules and related assemblies suitable for establishing optical connections to information processing modules disposed in equipment racks are disclosed. In one embodiment, an optical backplane extension module is provided. The optical backplane extension module comprises an extension module housing comprising an interior space defined by a base, a left side disposed on a left end of the base, a right side disposed on a right end of the base opposite the left end, and a rear side disposed on a rear end of the base. A plurality of backplane fiber optic connectors are disposed through the rear side of the extension module housing and accessible through an exterior side of the rear side. The plurality of backplane fiber optic connectors configured to be directly optically connected to a plurality of blade fiber optic connectors disposed in a plurality of information processing modules disposed in a rack module housing.

Abstract: Disclosed are optical ports and devices having a minimalist footprint. Specifically, the optical ports and devices have a footprint where the optical elements are exposed at a frame of the device. Additionally, a frame of the device provides a portion of the mating surface for engaging a complimentary optical plug during mating with the optical port on the device. This minimalist footprint advantageously allows for a smaller portion of the optical port to be exposed to the environment and subject to damage and/or wear. Further, the optical port provides a clean and sleek optical port on the device with a relatively small surface that may be cleaned or wiped by the user as necessary.

Abstract: A connector for a traceable cable having a tracing optical fiber, and a cable assembly having the same. The connector includes a connector housing and a light pipe positioned at least partially within the connector housing. The light pipe has at least one tracing optical fiber interface configured to be optically coupled to the tracing optical fiber. The light pipe also has at least one tracer light interface optically accessible from outside of the connector housing. The light pipe defines an optical path configured to direct tracer light from the at least one tracing optical fiber interface to the at least one tracer light interface. The at least one tracer light interface is configured to receive and emit the tracer light directed by the optical path.

Abstract: Disclosed are methods for creating a demarcation of at least one optical fiber in a structure along with a fiber optic cable. The method may include the steps of providing at least one optical fiber having a covering, heating a portion of the covering, and deforming the covering about the at least one optical fiber at a first location to inhibit movement of the at least one optical fiber with respect to the covering. The method may be applied to one or more optical fibers within a covering such as bare loose fibers, ribbonized fibers, buffered fibers or the like.

Abstract: Disclosed are lens blocks and methods for making the same. In one embodiment, the lens block includes at least one optical channel having an optical interface portion on a first side, and one or more magnetic materials attached to the lens block. In one embodiment, the lens block may include one or more opening for receiving the one or more magnetic materials. The one or more openings may be located on any suitable side of the lens block as desired. The magnetic materials provide attachment with a complimentary device having an optical interface. Consequently, the lens block allows for quick and easy assembly along with a robust structure for a large number of mating/unmating cycles. In other embodiments, the lens blocks disclosed may further include one or more electrical contacts for making a hybrid connection.

Abstract: A fiber optic cable assembly for terminating a cable using an interior seal component in a passage of a retention body and methods for making the same. The interior seal component inhibits a bonding material from passing through to unintended portions of the retention body, and also serves to position the cable within the retention body during termination. Embodiments may include an optional end seal for inhibiting the bonding agent from escaping the retention body.

Abstract: Optical connector assemblies for device-to-device optical connections are disclosed. In one embodiment, an optical connector assembly includes a housing having a mating surface, an optical coupling body, a first contact pin, and a second contact pin. The optical coupling body includes an optical coupling face such that the optical coupling face is exposed at the mating surface of the housing. The optical connector assembly further includes a plurality of GRIN lenses disposed within the optical coupling body, wherein each GRIN lens has a coupling surface positioned at the optical coupling face of the optical coupling body. The first and second contact pins extend from the mating surface of the housing such that they are positioned on opposite sides of the optical coupling body. Optical connector assemblies incorporating a total-internal-reflection surface are also disclosed.

Abstract: Disclosed are interposer structures having an optical fiber connection and a related fiber optic ferrule that can form a portion of an optical assembly. The interposer structure is useful for transmitting optical signals to/from an integrated circuit that may be attached to the interposer. Specifically, the interposer structure and the related ferrule of the optical connector provide a passively aligned structure having a matched thermal response to maintain a suitable optical connection between the devices over a range of temperatures.