N-input receiver: RFoG OBI mitigation with retransmission

We claim: 1. A bi-directional optical splitter/combiner functioning passively in a downstream direction and active in an upstream direction, the bi-directional optical splitter/combiner comprising: at least two optical fiber inputs for receiving upstream signals; at least one optical receiver for receiving a radio frequency over fiber (RFof) modulated signal, the at least one optical receiver including at least one optical detector that uses a photo detector having a size configured to detect and retransmit at an optical receiver output a signal that carries the total optical power received from a plurality of optical signals having different wavelengths, and without optical beat interference occurring in the retransmitted signal; a first optical transmitter for receiving the RFof modulated signal from the optical receiver output and re-transmitting the RFof modulated signal from the at least one receiver, the first optical transmitter providing an output; a first wave division multiplexer (WDM) optical combiner combining the output of the first optical transmitter in an upstream direction to a downstream optical signal in a downstream direction; an optical splitter for splitting the downstream optical signal to provide at least two split optical downstream signals; and a second WDM optical combiner combining each split optical downstream signal in the downstream direction with the upstream signals received by the at least two optical fiber inputs. 2. The bi-directional optical splitter/combiner of claim 1 , further comprising: at least one single mode to multi-mode optical combiner combining at least two signals received at the at least two optical fiber inputs to a multi-mode fiber output; and the at least one optical detector formed large enough to encompass an entire field of combined beams from the multi-mode fiber output. 3. The bi-directional optical splitter/combiner of claim 1 , further comprising wavelength selective optical components for directing upstream light at a first wavelength and passing downstream light at a second wavelength. 4. The bi-directional optical splitter/combiner of claim 1 , further comprising a multi-mode optical combiner (MMC) for combining inputs from one or more optical fibers for transmitting a multimode signal into a multimode fiber sufficiently large to transmit all light provided at the input to the MMC, the multimode fiber having a core larger than a single-mode fiber to preserve the light in the larger core multimode fiber. 5. The bi-directional optical splitter/combiner of claim 4 , wherein the at least one optical detector is large enough to provide a detector output signal to an amplifier, the amplifier driving the first transmitter and sending a signal to the first WDM optical combiner connected to a fiber extending to a headend. 6. The bi-directional optical splitter/combiner of claim 4 , wherein the at least one optical detector has a size large enough for detecting the multimode fiber signal from the larger core multimode fiber and a corresponding capacitance related to the size of the optical detector. 7. The bi-directional optical splitter/combiner of claim 1 , further comprising at least one optical receiver for receiving wavelengths sent upstream by optical network units that terminate radio frequency over glass (RFoG) at a customer premises with transmit and receive functions. 8. The bi-directional optical splitter/combiner of claim 1 , transmitting wavelengths downstream to optical network units that terminate radio frequency over glass (RFoG) at a customer premises with transmit and receive functions. 9. The bi-directional optical splitter/combiner of claim 8 , further comprising an erbium doped fiber amplifier (EDFA) that amplifies the downstream wavelengths.