An optical module, a communication device, and a Power over Ethernet (PoE) device are provided. The optical module includes a housing, an optical component, and a power supply component. The housing has a first socket and a second socket. The optical component also includes a first optical connector, an optical-to-electrical conversion component, and a second optical connector that are sequentially connected. The power supply component includes a first electrical connector, a power supply line, and a second electrical connector that are sequentially connected. The first socket is configured to insert a composite cable that matches the optical module. A power connector of the composite cable can be connected to the communication device by using the optical module, and the power connector of the composite cable does not need to be inserted into the communication device, so that panel space of the communication device can be reduced and miniaturization facilitated.

An end closure for a cable having a core, at least two electrical cable wires and at least one optical transmission element, the core is surrounded by a metal wire reinforcement. On the end of the electrical cable wires an electrically suitable connection set is mounted, which at least partially protrudes out of a pipe. A connection unit is mounted on the end of the optical transmission element, which also partially protrudes from the pipe. The connection unit has a pot shaped tension element mounted tension proof on the free end of the pipe and surrounds, moisture tight and pressure tight, the part of the connection set and the connection unit that protrudes out of the pipe.

A connector assembly includes a first connector that has an attachment feature. A second connector is removably attachable to the attachment feature of the first connector without establishing communication with the first connector. One of the first and second connectors is an optical connector, and another of the first and second connectors is an electrical connector.

A composite connector includes modular data connectors, electrical power connectors, a fluid exchange connector, an alignment feature, and a housing. The modular data connectors include electrical data connectors and optical data connectors and are configured to carry data. The electrical power connectors are configured to carry electrical power, and the fluid exchange connector is configured to carry cooling fluid. The composite connector includes an alignment feature to align the composite connector with a complementary connector. The housing of the composite connector is configured to contain the modular data connectors, the electrical power connectors, the fluid exchange connector, and the alignment feature in a confined physical space.

A fiber optic connector may include a body, a first fiber ferrule, and a second fiber ferrule. The first fiber ferrule may extend in a length direction of the body from a module-side end of the body. The second fiber ferrule may extend in the length direction of the body from the module-side end of the body and may be spaced apart from the first fiber ferrule in a width direction of the body. A maximum width in the width direction of a portion of the body configured to be received in a port of an optoelectronic communication module may be less than half a width of a fiber-side end of the optoelectronic communication module.

Various techniques are provided for manufacturing an optical connector. In one example, a technique may include applying an optical adhesive to a first end of the optical fiber, translating the optical fiber towards a lens to at least partially adhere the end of the optical fiber to the lens by the optical adhesive, and suspending the lens from the optical fiber to align a center of gravity of the lens with an optical path of the optical fiber to maintain optical beam power loss below a power loss threshold. Additional methods, systems, and apparatus are also provided.

An optical connector ferrule, an optical connector, and a composite fiber connecting assembly are provided. The optical connector ferrule includes a stationary ferrule having a first through-hole, a composite fiber, and a connecting ferrule having a second through-hole. The composite fiber includes a first optical fiber and a signal wire, and is placed in the first through-hole in the stationary ferrule. The connecting ferrule includes a conductive path. The stationary ferrule has a second end face abutting a third end face of the connecting ferrule. The first optical fiber has an end connected to an end of the second through-hole. The signal wire and the conductive path are connected to each other.

An adapter with novel alignment features engages alignment features on a plug, providing general alignment of the ferrule holders and ferrules in the plug. After the plug engages the adapter, the ferrule holders engage a second set of alignment features in the adapter to provide fine alignment for the ferrules.

A connector, a system, and a method provide a single interface at a device for power and optical inputs or outputs. A single interface at the DC source allows for a single connection to the power and optical signals from the splitter. The connector can be used at other locations needing both power and optical signal connectivity.

A plug connector for a hybrid cable comprises a fiber and wire holder to hold at least one optical fiber and at least one electrical conductor of the hybrid cable. The plug connector comprises at least one optical device being configured such that a light beam received from the at least one optical fiber at a first side of the at least one optical device is collimated and coupled out at the second side of the at least one optical device. The plug connector comprises an electrical contact pin to be coupled to the at least one electrical conductor of the hybrid cable. The electrical contact pin has a structure being configured to be engaged in a complimentary receptacle to mechanically fix the plug connector to the receptacle.