Abstract: A structured optical fiber cabling system configured to connect first and second layers of switches in a mesh network is disclosed. The system comprises groups of fiber optic ports arranged side-by-side, with each group including a plurality of the fiber optic ports distributed in a vertical direction. A plurality of fiber optic jumper assemblies each include a horizontal segment and a plurality of legs and fiber optic connectors extending from the horizontal segment, with each fiber optic connector configured to connect to a corresponding fiber optic port of the plurality of the fiber optic ports at the same vertical location in each group of the array.

Abstract: A structured optical fiber cabling system configured to connect first and second layers of switches in a mesh network is disclosed. The system comprises groups of fiber optic ports arranged side-by-side, with each group including a plurality of the fiber optic ports distributed in a vertical direction. A plurality of fiber optic jumper assemblies each include a horizontal segment and a plurality of legs and fiber optic connectors extending from the horizontal segment, with each fiber optic connector configured to connect to a corresponding fiber optic port of the plurality of the fiber optic ports at the same vertical location in each group of the array.

Abstract: A structured optical fiber cabling system configured to connect first and second layers of switches in a mesh network is disclosed. The system comprises a plurality of fiber optic modules each including a plurality of first fiber optic ports distributed in a vertical direction when the fiber optic modules are installed in a chassis. A plurality of fiber optic jumper assemblies each include a horizontal segment and a plurality of legs and fiber optic connectors extending from the horizontal segment, with each fiber optic connector configured to connect to a corresponding fiber optic port of the plurality of first fiber optic ports at the same vertical location in each fiber optic module.

Abstract: An optical interconnect module comprises a housing including a front-facing portion that includes a first face and a second face, wherein the first face of the front-facing portion is angled relative to the second face of the front-facing portion. The housing also includes a rear-facing portion opposing the front facing portion, the rear-facing portion including a first face and a second face, wherein the first face of the rear-facing portion is angled relative to the second face of the rear-facing portion. The housing further includes an internal chamber disposed between the front-facing portion and the rear-facing portion. A first plurality of multifiber connectors is disposed on the front-facing portion of the housing, and a first plurality of multifiber connectors disposed on the rear-facing portion of the housing.

Abstract: A structured optical fiber cabling system configured to connect first and second layers of switches in a mesh network is disclosed. The system comprises a plurality of fiber optic modules each including a plurality of first fiber optic ports distributed in a vertical direction when the fiber optic modules are installed in a chassis. A plurality of fiber optic jumper assemblies each include a horizontal segment and a plurality of legs and fiber optic connectors extending from the horizontal segment, with each fiber optic connector configured to connect to a corresponding fiber optic port of the plurality of first fiber optic ports at the same vertical location in each fiber optic module.

Abstract: Bi-directional data center architectures employing a jacketless trunk cable are disclosed. The bi-directional data center architecture includes first and second coupling panels respectively having first adapters and second adapters. The architecture also includes a plurality of sub-racks having sub-rack adapters, and a jacketless trunk cable that includes a plurality of sub-unit sections, with each sub-unit section carrying one or more optical fibers. The plurality of sub-unit sections are configured to optically connect corresponding first and second adapters of the first and second coupling panels to the sub-rack adapters such that every optical fiber in each sub-unit section is used to establish an optical connection.

Abstract: An optical interconnect module comprises a housing including a front-facing portion that includes a first face and a second face, wherein the first face of the front-facing portion is angled relative to the second face of the front-facing portion. The housing also includes a rear-facing portion opposing the front facing portion, the rear-facing portion including a first face and a second face, wherein the first face of the rear-facing portion is angled relative to the second face of the rear-facing portion. The housing further includes an internal chamber disposed between the front-facing portion and the rear-facing portion. A first plurality of multifiber connectors is disposed on the front-facing portion of the housing, and a first plurality of multifiber connectors disposed on the rear-facing portion of the housing.

Abstract: Bi-directional data center architectures employing a jacketless trunk cable are disclosed. The bi-directional data center architecture includes first and second coupling panels respectively having first adapters and second adapters. The architecture also includes a plurality of sub-racks having sub-rack adapters, and a jacketless trunk cable that includes a plurality of sub-unit sections, with each sub-unit section carrying one or more optical fibers. The plurality of sub-unit sections are configured to optically connect corresponding first and second adapters of the first and second coupling panels to the sub-rack adapters such that every optical fiber in each sub-unit section is used to establish an optical connection.

Abstract: Bi-directional data center architectures employing a jacketless trunk cable are disclosed. The bi-directional data center architecture includes first and second coupling panels respectively operably connected to first and second trunk cables, wherein the first and second coupling panels respectively have first adapters and second adapters. The architecture also includes a plurality of sub-racks having sub-rack adapters, and a jacketless trunk cable that includes a plurality of sub-units, with each sub-unit carrying one or more optical fibers. The plurality of sub-units are configured to optically connect corresponding first and second adapters of the first and second coupling panels to the sub-rack adapters such that every optical fiber in each sub-unit is used to establish an optical connection.

Abstract: Fiber optic connector assemblies and subassembly are disclosed. In one embodiment, a fiber optic connector subassembly includes a body and a pivot arm. The body includes a first body shell and a second body shell having a joint portion. The first body shell is coupled to the second body shell. The pivot arm is rotatably coupled to the joint portion. In another embodiment, a fiber optic connector assembly includes a plurality of cable assemblies, a housing, a body, and a pivot arm. Each cable assembly includes a fiber optic cable having a plurality of optical fibers, and a ferrule. The plurality of optical fibers is coupled to the ferrule. The housing receives the ferrules of the plurality of cable assemblies. The body is coupled to the housing. The pivot arm is rotatably coupled to the body. The plurality of optical fibers is disposed within the pivot arm.

Abstract: Bi-directional data center architectures employing a jacketless trunk cable are disclosed. The bi-directional data center architecture includes first and second coupling panels respectively operably connected to first and second trunk cables, wherein the first and second coupling panels respectively have first adapters and second adapters. The architecture also includes a plurality of sub-racks having sub-rack adapters, and a jacketless trunk cable that includes a plurality of sub-units, with each sub-unit carrying one or more optical fibers. The plurality of sub-units are configured to optically connect corresponding first and second adapters of the first and second coupling panels to the sub-rack adapters such that every optical fiber in each sub-unit is used to establish an optical connection.

Abstract: Port tap fiber optic modules and related systems and methods for monitoring optical networks are disclosed. In certain embodiments, the port tap fiber optic modules disclosed herein include connections that employ a universal wiring scheme. The universal writing scheme ensure compatibility of attached monitor devices to permit a high density of both live and tap fiber optic connections, and to maintain proper polarity of optical fibers among monitor devices and other devices. In other embodiments, the port tap fiber optic modules are provided as high-density port tap fiber optic modules. The high-density port tap fiber optic modules are configured to support a specified density of live and passive tap fiber optic connections. Providing high-density port tap fiber optic modules can support greater connection bandwidth capacity to provide a migration path for higher data rates while minimizing the space needed for such fiber optic equipment.

Abstract: Fiber optic connector assemblies and subassembly are disclosed. In one embodiment, a fiber optic connector subassembly includes a body and a pivot arm. The body includes a first body shell and a second body shell having a joint portion. The first body shell is coupled to the second body shell. The pivot arm is rotatably coupled to the joint portion. In another embodiment, a fiber optic connector assembly includes a plurality of cable assemblies, a housing, a body, and a pivot arm. Each cable assembly includes a fiber optic cable having a plurality of optical fibers, and a ferrule. The plurality of optical fibers is coupled to the ferrule. The housing receives the ferrules of the plurality of cable assemblies. The body is coupled to the housing. The pivot arm is rotatably coupled to the body. The plurality of optical fibers is disposed within the pivot arm.

Abstract: A fiber optic assembly for supporting optical connections in a fiber optic network employing parallel optical configurations is described. In one embodiment, the fiber optic assembly includes at least two live multi-fiber components and at least one tap multi-fiber component. Optical signals are routed from one live multi-fiber component to another in a parallel optical connection configuration, with each group of optical signals corresponding to a respective group of fiber positions on each live multi-fiber component. Each group of optical signals is also routed to one of the first and second groups of fiber positions of the at least one tap multi-fiber component in a parallel optical connection configuration. In this manner, fiber optic signals can be simultaneously provided and monitored within an active fiber optic network using a parallel optical configuration without the need for interrupting network operations.

Abstract: A fiber optic assembly for supporting optical connections in a fiber optic network employing parallel optical configurations is described. In one embodiment, the fiber optic assembly includes at least two live multi-fiber components and at least one tap multi-fiber component. Optical signals are routed from one live multi-fiber component to another in a parallel optical connection configuration, with each group of optical signals corresponding to a respective group of fiber positions on each live multi-fiber component. Each group of optical signals is also routed to one of the first and second groups of fiber positions of the at least one tap multi-fiber component in a parallel optical connection configuration. In this manner, fiber optic signals can be simultaneously provided and monitored within an active fiber optic network using a parallel optical configuration without the need for interrupting network operations.

Abstract: Fiber optic equipment that supports 8-fiber MPO configurations that enable migration between duplex transmission and 8-fiber parallel transmission is disclosed. The fiber optic equipment comprises at least one front multi-fiber adapter at a front end of the panel assembly, each adapter having a front side and a rear side. The fiber optic equipment also comprises at least one pass-through channel configured to receive at least one optical multi-fiber cable therethrough, wherein the rear side of the at least one front multi-fiber adapter is configured to optically connect to a first multi-fiber optical cable extending from a rear end of the panel assembly toward the front end. The front side of the at least one front multi-fiber adapter is configured to optically connect to a second multi-fiber optical cable extending from the rear end of the panel assembly toward the front end of panel assembly and passing through the at least one pass through channel.

Abstract: Fiber optic equipment that supports 8-fiber MPO configurations that enable migration between duplex transmission and 8-fiber parallel transmission is disclosed. The fiber optical equipment comprises a hybrid fiber optic module having a front end and a rear end and a linear array of single fiber optical connector adapters arranged in a width direction at the front end, each of the single fiber optical adapters having a front side and a rear side. The hybrid module also comprises a front multi-fiber adapter at the front end, the front multi-fiber adapter having a front side and a rear side and a rear multi-fiber adapter at the rear end of the module, the rear multi-fiber adapter having a front side and a rear side.

Abstract: Fiber optic equipment that supports 8-fiber MPO configurations that enable migration between duplex transmission and 8-fiber parallel transmission and vice-versa. The fiber optical equipment comprises a tray for mounting fiber optic equipment. The tray comprises a base for supporting a plurality of BASE-8 fiber optic equipment. The tray also comprises one or more support rails of the base for movably mounting the tray in a fiber optic equipment chassis. The tray further comprises a plurality of equipment support rails of the base for movably mounting the plurality of BASE-8 fiber optic equipment to the tray.