Optically connecting two transceivers requires the transmitting portion of one transceiver matches with the receiving portion of the other transceivers. This requires that the polarity of the fiber optic connectors (attached to one another in a jumper) that connect the two transceivers is correct. Maintaining the correct polarity in the field can be confusing, time-consuming, and difficult to achieve. Not to mention that the installers need to make sure they have the correct number and polarity of the jumpers. This is further complicated when the fiber optic connectors are VSFF and have a key on a short side of the fiber optic connector. A system that involves an A-to-B patch cord and an opposed key adapter solves each of these issues. Only one type of patch cord (A-to-B) and one type of adapter is needed. With these components, an installer can connect the two transceivers without any mistakes.

A connection system includes a connector, a mating connector and a locking unit disposed on the connector and having a locking member. The connector and the mating connector each have a housing with a contact carrier disposed therein. The contact carriers are each connected to a signal conductor. The connector is movable in a mating direction into a connected position with the mating connector, in which the signal conductors are conductively connected. The contact carriers each have a through-opening disposed transverse to the mating direction. In the connected position, the through-openings are in alignment with each other, and the locking member is movable between a locking position, in which the locking member is located in the through-openings of both contact carriers, and an unlocking position, in which the locking member is located outside of the through-opening of at least one of the contact carriers.

An OSFP optical transceiver having split multiple fiber optical port using reduced amount of MPO terminations is provided that includes two adjacent sockets integrated into the optical port of the OSFP optical transceiver. The two adjacent sockets are vertically oriented with respect to the mounting baseplate of the OSFP optical transceiver, and each of the two adjacent sockets is adapted to receive an MPO receptacle that terminates the proximal end of a bundle of fibers. The OSFP optical transceiver also includes an optical connection between each socket and a corresponding lens in the OSFP optical transceiver, for transmitting optical signals received from other transceivers into the OSFP optical transceiver and optical signals generated in the OSFP optical transceiver to other transceivers.

Fiber optic network systems are implemented, at least in part, using very small form factor (VSFF) interconnect components such as VSFF duplex connector; VSFF mechanical transfer ferrule (MT) connector; VSFF duplex uniboot connector; VSFF MT uniboot connector; VSFF duplex adapter; VSFF MT adapter; VSFF duplex pluggable transceiver; VSFF MT pluggable transceiver; VSFF patch cable assembly; VSFF trunk cable; and/or VSFF breakout cable. The VSFF fiber optic network systems can define fiber breakout cabling that connects large trunk cables to many peripheral network locations. The network systems can define branches and sub-branches from a trunk cable. The network systems can define cross-connect sub-networks between sets of transceivers or adapters. The network systems can define a trunk-to-transceiver cabling assembly for connecting a trunk cable to at least 32 transceiver ports.

A latch configured to secure a module to a panel. The latch includes an outer latch and an inner latch configured to move independently of the outer latch. The outer latch and the inner latch are configured to provide at least two latching points between the latch and the panel.

Optical splitting adaptors and associated methods of manufacturing are provided. An example optical splitting adaptor includes a first connector housing that interfaces with a first optical transceiver having a first data rate, and the first connector housing accommodates a first type multi-fiber ferrule of a first number of fibers. The example optical splitting adaptor also includes a second connector housing that defines dual receptacles for interfacing with a second optical transceiver and a third optical transceiver, and the dual receptacles receive respective multi-fiber ferrules. The example optical splitting adaptor further includes a plurality of fibers operably connecting the first connector housing and the second connector housing such that, in operation, the plurality of fibers perform optical splitting between the first type multi-fiber ferrule of the first connector housing and the multi-fiber ferrules received by the dual receptacles of the second connector housing.

An example fiber optic connector label is provided that includes a main body section, a first group of fiber designations, and a second group of fiber designations. The main body section includes a top surface and an opposing bottom surface. The main body section includes a lateral axis extending through first and second side edges of the main body section, the lateral axis dividing the main body section into a first side and a second side. The first group of fiber designations is located on the first side of the main body section. The second group of fiber designations is located on the second side of the main body section.

An optical assembly includes a hermaphroditic cassette comprising a hood that includes a narrower section and a wider section. The narrower and wider sections are separated by slots such that the narrower section fits at least partially within a wider section of an identical mating hood of a mating optical assembly and the wider section receives a narrower section of the mating hood. The hood has first and second stop features configured to engage with second and first stop features of the mating hood. The first stop feature comprises a mating end of the narrower section of the hood and the second stop feature comprises a stop surface disposed within the wider section of the hood. Engagement of the stop features of the hood with stop features of the mating hood is configured to stop relative translational movement of the hood and the mating hood along the mating axis during mating.

A ferrule holder assembly can support groupings of a transceiver ferrules in an optical connector interface of an optical transceiver. A first holder body holds a first grouping of transceiver ferrules and has a holder-to-holder interface. A second, typically identical, holder body holds a second grouping of transceiver ferrules. The holder-to-holder interface of the first holder body engages the holder-to-holder interface of the second holder body to operatively align the first holder body with the second holder body to position the first grouping of transceiver ferrules and the second grouping of transceiver ferrules in the optical connector interface for making optical connections to one or more optical connectors plugged into the optical connector interface. The ferrule holder assembly can be used in combination with pre-terminated fiber arrays to couple an optical interface to a circuit board in a transceiver.

An optical ferrule includes an optical coupling member with a light redirecting element that redirects input light from a waveguide toward an output window. The optical coupling member has a mating surface configured to slidably mate with a mating optical coupling member along a longitudinal axis of the optical ferrule. The optical ferrule also includes at least one stacking member along a longitudinal edge of the optical coupling member. The stacking member has a distal end extending beyond one of the mating surface and a top surface opposed to the mating surface. The stacking member also has a contact surface opposed to the distal end. The contact surface is configured to rotatably interface with a corresponding distal end of a of an adjacently stacked optical ferrule.