Abstract: Optical data center connector systems including a fiber optic plug assembly and a fiber optic receptacle assembly. In one embodiment, a fiber optic plug assembly includes a plug body having an insertion surface and a plug body opening at the insertion surface, wherein the plug body defines a ferrule enclosure coupled in free space to the plug body opening, and a ferrule element disposed within the ferrule enclosure of the plug body. The ferrule element includes a mechanical coupling face, an optical interface surface, and a plurality of lens elements at the optical interface surface. The ferrule element is disposed within the ferrule enclosure such that the optical interface surface is recessed with respect to the insertion surface of the plug body.

Abstract: Disclosed are optical transceiver modules for use with electronic devices. In one embodiment, an optical transceiver module has a circuit board assembly for receiving and transmitting optical signals with a connector shell that is attached to the circuit board so that the circuit board is disposed outside the shell. The optical transceiver module also includes a faceplate that may have one or more attachment features for securing the faceplate and/or optical transceiver module to a device. By arranging the circuit board outside the shell of the optical transceiver module the footprint of the module is greatly reduced, thereby providing an advantageous arrangement for fitting into electronic devices having a relatively thin profile. Further, the optical transceiver module may optionally include one or more electrical contacts.

Abstract: Datacenter connection systems for use in datacenter enclosures are disclosed. In one embodiment, a datacenter connection system includes a first module and a feed-through optical cable assembly. The first module includes a first faceplate having at least one first feed-through opening, a first surface, and at least one first module connector disposed on the first surface. The feed-through optical cable assembly includes an optical cable having at least one optical fiber, a first feed-through attach member coupled to the optical cable, and a first optical connector coupled to a first end portion of the at least one optical fiber. The at least one optical fiber passes through the first feed-through attach member, and the first feed-through attach member is disposed within the at least one first feed-through opening. The first optical connector is coupled to the at least one first module connector.

Abstract: Disclosed are optical connections having a coupling portion that includes a piston and a magnet along with complimentary optical connections. In one embodiment, the optical connection includes an optical interface portion having at least one optical channel and a coupling portion. The coupling portion includes a piston that is movable between a first position and a second position, a resilient member for biasing the piston to the first position and a magnet for retaining the piston at the second position. In one embodiment, the piston may be disposed in a body of the optical connection. The piston may be formed from a ferrous material and since it is not magnetic it does not attract metal trash; however, it still allows coupling (e.g., mating) of optical connections using magnetic retention. Additionally, the piston may optionally include a cover portion if desired.

Abstract: A fiber optic cable includes a polymeric jacket, an optical fiber, and first and second longitudinal strength elements. The jacket defines an outer periphery and a cavity interior thereto. The cavity is elongate and the outer periphery is polygonal. The optical fiber is positioned within the cavity of the jacket. The first and second longitudinal strength elements are embedded in the jacket on an opposite sides of the cavity from one another. The cable resists bending in a non-preferential plane by no more than five times as much as the cable resists bending in a preferential plane.

Abstract: A fiber optic cable includes a polymeric jacket, an optical fiber, and first and second longitudinal strength elements. The jacket defines an outer periphery and a cavity interior thereto. The cavity is elongate and the outer periphery is polygonal. The optical fiber is positioned within the cavity of the jacket. The first and second longitudinal strength elements are embedded in the jacket on an opposite sides of the cavity from one another. The cable resists bending in a non-preferential plane by no more than five times as much as the cable resists bending in a preferential plane.

Abstract: Disclosed are optical transceiver modules for use with electronic devices. In one embodiment, an optical transceiver module has a circuit board assembly for receiving and transmitting optical signals with a connector shell that is attached to the circuit board so that the circuit board is disposed outside the shell. The optical transceiver module also includes a faceplate that may have one or more attachment features for securing the faceplate and/or optical transceiver module to a device. By arranging the circuit board outside the shell of the optical transceiver module the footprint of the module is greatly reduced, thereby providing an advantageous arrangement for fitting into electronic devices having a relatively thin profile. Further, the optical transceiver module may optionally include one or more electrical contacts.

Abstract: Datacenter connection systems for use in datacenter enclosures are disclosed. In one embodiment, a datacenter connection system includes a first module and a feed-through optical cable assembly. The first module includes a first faceplate having at least one first feed-through opening, a first surface, and at least one first module connector disposed on the first surface. The feed-through optical cable assembly includes an optical cable having at least one optical fiber, a first feed-through attach member coupled to the optical cable, and a first optical connector coupled to a first end portion of the at least one optical fiber. The at least one optical fiber passes through the first feed-through attach member, and the first feed-through attach member is disposed within the at least one first feed-through opening. The first optical connector is coupled to the at least one first module connector.

Abstract: Fiber optic connector adapter modules for use in optic communications networks are disclosed. In one embodiment, a fiber optic connector adapter module includes an adapter plate having a first surface and a second surface, an array of fiber optic connector adapters with a first port extending from the first surface of the adapter plate, wherein the first port of each fiber optic connector adapters of the array is configured to receive a first fiber optic connector, and at least one reinforcement member connecting the first port of adjacent fiber optic connector adapters of the array. In other embodiments, the first port of the fiber optic connector adapters are offset with respect to one another to provide better access to the first ports.

Abstract: A fiber optic cable includes a polymeric jacket defining an outer periphery and a cavity interior thereto, an optical fiber positioned within the cavity, and first and second longitudinal strength elements fully embedded in the jacket on opposite sides of the cavity from one another, where the strength elements define a bend axis of the cable passing there through that is orthogonal to the length of the cable, and the bend axis and the length of the cavity define a preferential plane for bending. The cable resists bending about a third axis that is orthogonal to the length of the cable and the bend axis, where the third axis and the length of the cable define a non-preferential plane for bending. The difference in flexural rigidity between the preferential and non-preferential planes limits formation of spontaneous knots in a coil of the cable while providing flexibility for ease of handling.

Abstract: A fiber optic cable includes a polymeric jacket defining an outer periphery and a cavity interior thereto, an optical fiber positioned within the cavity, and first and second longitudinal strength elements fully embedded in the jacket on opposite sides of the cavity from one another, where the strength elements define a bend axis of the cable passing there through that is orthogonal to the length of the cable, and the bend axis and the length of the cavity define a preferential plane for bending. The cable resists bending about a third axis that is orthogonal to the length of the cable and the bend axis, where the third axis and the length of the cable define a non-preferential plane for bending. The difference in flexural rigidity between the preferential and non-preferential planes limits formation of spontaneous knots in a coil of the cable while providing flexibility for ease of handling.

Abstract: Optical data center connector systems including a fiber optic plug assembly and a fiber optic receptacle assembly. In one embodiment, a fiber optic plug assembly includes a plug body having an insertion surface and a plug body opening at the insertion surface, wherein the plug body defines a ferrule enclosure coupled in free space to the plug body opening, and a ferrule element disposed within the ferrule enclosure of the plug body. The ferrule element includes a mechanical coupling face, an optical interface surface, and a plurality of lens elements at the optical interface surface. The ferrule element is disposed within the ferrule enclosure such that the optical interface surface is recessed with respect to the insertion surface of the plug body.

Abstract: Disclosed are optical connections having a coupling portion that includes a piston and a magnet along with complimentary optical connections. In one embodiment, the optical connection includes an optical interface portion having at least one optical channel and a coupling portion. The coupling portion includes a piston that is movable between a first position and a second position, a resilient member for biasing the piston to the first position and a magnet for retaining the piston at the second position. In one embodiment, the piston may be disposed in a body of the optical connection. The piston may be formed from a ferrous material and since it is not magnetic it does not attract metal trash; however, it still allows coupling (e.g., mating) of optical connections using magnetic retention. Additionally, the piston may optionally include a cover portion if desired.

Abstract: A fiber optic cable includes a polymeric jacket defining an outer periphery and a cavity interior thereto, an optical fiber positioned within the cavity, and first and second longitudinal strength elements fully embedded in the jacket on opposite sides of the cavity from one another, where the strength elements define a bend axis of the cable passing there through that is orthogonal to the length of the cable, and the bend axis and the length of the cavity define a preferential plane for bending. The cable resists bending about a third axis that is orthogonal to the length of the cable and the bend axis, where the third axis and the length of the cable define a non-preferential plane for bending. The difference in flexural rigidity between the preferential and non-preferential planes limits formation of spontaneous knots in a coil of the cable while providing flexibility for ease of handling.

Abstract: A fiber optic cable includes a polymeric jacket defining an outer periphery and a cavity interior thereto, an optical fiber positioned within the cavity, and first and second longitudinal strength elements fully embedded in the jacket on opposite sides of the cavity from one another, where the strength elements define a bend axis of the cable passing there through that is orthogonal to the length of the cable, and the bend axis and the length of the cavity define a preferential plane for bending. The cable resists bending about a third axis that is orthogonal to the length of the cable and the bend axis, where the third axis and the length of the cable define a non-preferential plane for bending. The difference in flexural rigidity between the preferential and non-preferential planes limits formation of spontaneous knots in a coil of the cable while providing flexibility for ease of handling.