Abstract: Aspects of the present disclosure are directed toward apparatuses, systems, and methods that include a first gateway circuit in an optical access network connecting a plurality of end-of-network users to a central node, the first gateway circuit connecting one of the plurality of end-of-network users to the central node via fiber optic data lines. Further, the first gateway circuit is configured and arranged to: relay a first set of data between the end-of-network user and the central node using a packet-switching communication protocol, and relay a second set of data between the end-of-network user and the central node using an optical flow switching communication protocol.

Abstract: Aspects of the present disclosure are directed toward apparatuses, systems, and methods that include a first gateway circuit in an optical access network connecting a plurality of end-of-network users to a central node, the first gateway circuit connecting one of the plurality of end-of-network users to the central node via fiber optic data lines. Further, the first gateway circuit is configured and arranged to: relay a first set of data between the end-of-network user and the central node using a packet-switching communication protocol, and relay a second set of data between the end-of-network user and the central node using an optical flow switching communication protocol.

Abstract: A passive optical network is disclosed that enables burst mode operation without some of the disadvantages for doing so in the prior art. An embodiment of the present invention comprises a receiver that receives optical signals from transmitters of a plurality of optical network units. For each transmission from an optical network unit, the receiver provides an output signal based on a comparison of the optical signal and a reference voltage that is specific to that optical network unit. A digital-to-analog converter generates the reference voltage in a data rate-independent manner based on information provided to it from the control plane.

Abstract: A passive optical network is disclosed that enables burst mode operation without some of the disadvantages for doing so in the prior art. An embodiment of the present invention comprises a receiver that receives optical signals from transmitters of a plurality of optical network units. For each transmission from an optical network unit, the receiver provides an output signal based on a comparison of the optical signal and a reference voltage that is specific to that optical network unit. A digital-to-analog converter generates the reference voltage in a data rate-independent manner based on information provided to it from the control plane.

Abstract: At the transmitting end of an optical transmission system, a wide linewidth LED (31) is intensity modulated by a first digital information signal and a narrow linewidth DFB (Distributed Feedback) laser (32) is frequency modulated by a second digital information signal and the two modulated optical signals are combined (33) for transmission over a single mode optical fiber (34). At the receiving end, the intensity modulating digital signal is recovered from the received optical signal by a photodetctor (52). The frequency modulating digital signal is recovered by a coherent receiver (53) which includes a local oscillator (55) the output of which is optically combined (54) with the received optical signal. A photodetector (56) converts this combined optical signal to an electrical IF signal, and an IF demodulator (57) reconstructs the second digital signal therefrom.