A network interface device bracket and a method of connecting a network device to a network via the network interface device bracket is provided. According to an example, the network interface device bracket may be adapted to be removably attached to the network interface device and removably mounted to a mounting surface. The network interface device bracket may include an internal housing that is adapted to connect a jumper cable connected to the network interface device to a drop cable connected to a service provider network and to store excess drop cable.

A space active optical cable (SAOC) includes a cable including one or more optical fibers, and two or more electrical transceivers on opposing ends of the cable and interconnected by the cable. Each of the electrical transceivers includes an enclosure that encloses one or more light sources, one or more light detectors, and control electronics. Also included in the enclosure are a coupling medium to couple light into and out of the one or more optical fibers. The coupling medium can be reflecting surface or an on-axis mount. The enclosure provides a suitable heat propagation and electromagnetic interference (EMI) shielding, and the cable and the two or more electrical transceivers are radiation resistant. SAOC features optionally support a health check algorithm that allows trending optical performance in the absence of an optical connector and a potential surface treatment to increase nominally low emissivity of an EMI conductive surface.

An optical receptacle connector includes a receptacle housing having housing walls defining a contact cavity and an optical cavity. The receptacle housing includes an upper wall and a lower wall at a front of the receptacle housing defining a card slot receiving a mating edge of an optical module circuit board of a pluggable optical generator module. The upper wall includes an upper wall opening above the card slot. A contact assembly having receptacle contacts is received in the contact cavity to supply power to the pluggable optical generator module to operate a light source of the pluggable optical generator module. A receive optical connector is coupled to the receptacle housing above the upper wall opening and mated with a supply optical connector of the pluggable optical generator module to receive optical signals from the supply optical connector.

An optical receptacle connector includes a receptacle housing defining a contact cavity, an optical cavity, and a card slot at a front of the receptacle housing configured to receive an edge of an optical module circuit board. A contact assembly having receptacle contacts is received in the contact cavity and extend into the card slot to supply power to the pluggable optical generator module to operate a light source. The optical receptacle connector includes a receive optical connector coupled to the receptacle housing having a ferrule holding at least one optical fiber configured to be mated with a supply optical connector of the pluggable optical generator module to receive optical signals from the supply optical connector.

An optical module includes: a housing, a heat sink arranged in the housing, a laser emitter arranged on the heat sink, a PCB partially arranged on the heat sink, and an optical system arranged in the housing. The optical module has an optical interface on one end and an electrical interface on the other end. The optical system is arranged between the laser emitter and the optical interface. The PCB is constructed as a rigid board. The laser emitter is electrically connected to the PCB. One end of the PCB is fixed on the heat sink, and the other end of the PCB is constructed as the electrical interface. The optical system transmits light emitted from the laser emitter to the optical interface.

An optical system includes a cage and an optical transceiver. The optical transceiver is inserted into the cage in a pluggable manner, and includes a housing, a partition component provided on the housing, and a fastening component movably disposed on the housing. The fastening component is detachably fastened with the cage. The partition component is located between the fastening component and the cage to separate at least a part of the fastening component from the cage.

A housing for an electronic device includes a panel, where the panel includes a window. A cage includes a plurality of panels and a first end and a second end that opposes the first end. The cage further includes an opening at its first end and an enclosure disposed between the panels of the cage. Connecting structure is disposed at the first end of the cage, where the connecting structure secures the first end of the cage to the panel. The cage is suitably dimensioned to receive and retain a portion of a pluggable module within the enclosure when the pluggable module is inserted within the opening at the first end of the cage.

A module for multiple network pluggable optics is disclosed. The module includes a Printed Circuit Board (PCB); a faceplate connected to the PCB; a plurality of cage assemblies connected to the PCB, each cage assembly is configured to receive a pluggable optical module via a corresponding opening in the faceplate; and a shared heat exchanger that is integrally formed and substantially covers the plurality of cage assemblies, wherein the shared heat exchanger is configured to cool multiple pluggable optics in the plurality of cage assemblies.

A pluggable free-space photoelectric hybrid connector including a female connector and a male connector is provided. The female connector includes a first insulating substrate, metal elastic clips, a first circuit board, and a first optical communication module. An insertion cavity is formed at the front end of the first insulating substrate, and a first fiber mounting hole and first electrode mounting holes are formed at the rear end thereof. The metal elastic clips are mounted in the first electrode mounting holes respectively, where contact portions of at least one set of metal elastic clips are exposed from the top of the insertion cavity, and contact portions of at least another set of metal elastic clips are exposed from the bottom of the insertion cavity. The first circuit board is mounted at the rear end of the first insulating substrate and is electrically connected to the metal elastic clips.

Optical sensor modules and methods of fabrication are described. In an embodiment, an optical component is mounted on a module substrate. In an embodiment, a pillar of stacked wireballs adjacent the optical component is used for vertical connection between the module substrate and a top electrode pad of the optical component.