Abstract: A method includes connecting a first end of an optoelectronic device with an electrical back plate including blind mating; and connecting a second end of the optoelectronic device with an optical back plate including blind mating. An apparatus includes an optoelectronic device including a first end having an electrical interface for blind mating and a second end having an optical interface for blind mating.

Abstract: A method includes hosting a plurality of transmitter modules with a host module, where the host module includes common circuitry shared by the plurality of pluggable transmitter modules. An apparatus includes a host module; and a plurality of transmitter modules coupled to the host module, where the host module includes common circuitry shared by the plurality of pluggable transmitter modules.

Abstract: A method includes tuning a host module to a reference module standard; and adjusting each of a plurality of pluggable optical modules coupled to the host module to mimic the reference module standard for a set of load conditions. An apparatus includes a host module tuned to a reference module standard; and a plurality of pluggable optical modules coupled to the host module, wherein each of the plurality of pluggable optical modules mimics the reference standard for a specific set of load conditions.

Abstract: A method includes reading operation parameters from a non-volatile memory located in a pluggable module that is coupled to a host module; processing the operational parameters with a processor located in the host module to control operation of a predistortion circuit located in the host module; adding predistortion to a signal with the predistortion circuit located in the host module and then sending the predistorted signal to the pluggable module. An apparatus includes a host module including a predistortion circuit and a processor coupled to the predistortion circuit; and a pluggable module coupled to the host module, wherein the pluggable module includes a non-volatile memory containing operational parameters for the predistortion circuit of the host module, wherein the operational parameters are processed by the processor of the host module to control the predistortion circuit of the host module.

Abstract: Systems and methods are described for optically powered and controlled optical switches. A method includes powering an optical switch with a communications data signal; and controlling the optical switch with the communications data signal.

Abstract: Systems and methods are described for reverse digitized communications. A method includes: providing at least one optical fiber from at least one member selected from the group consisting of a headend and a hub, a minifibernode coupled to said at least one optical fiber, and an electrical conductor coupled to said minifibernode; transforming a forward optical signal from said at least one optical fiber to a forward analog electrical signal on said electrical conductor at said minifibernode; and transforming a reverse analog electrical signal on said electrical conductor to a reverse digital optical signal at said minifibernode. The systems and methods provide advantages because the need for muxnode units is eliminated, the cost of the node units is reduced, the amount of optical fiber is reduced and the reverse bandwidth is increased.

Abstract: Systems and methods are described for a connector mounting. A method includes: providing a connector mounting with a compressive connector bracket and a channel conduit; inserting a connector into the connector mounting via the compressive connector bracket; and resting a connector feed assembly in the channel via a connector feed assembly pass-through slot by penetrating a volume defined by the connector feed assembly pass-through slot with the connector at an angle to a principle plane defined by the connector mounting and then rotating a proximal end of the connector toward the principle plane.