Optical and RF techniques for aggregation of photo diode arrays

We claim: 1. An optical splitter/combiner operable as a splitter in a downstream direction and a combiner in an upstream direction, the optical splitter/combiner comprising: a first plurality of fiber links for carrying upstream signals from and downstream signals to one or more wavelength division multiplexers (WDMs); a passive splitter for splitting optical signals in a downstream path for receipt by the one or more wavelength division multiplexers (WDMs) using the first plurality of fiber links; the one or more wavelength division multiplexers (WDMs) for separating upstream optical signals received over a second plurality of fibers from the downstream optical signals received over the first plurality of fibers, and configured for selectively directing upstream optical signals of different wavelengths along different paths, wherein optical signals having a first wavelength are directed from the one or more WDMs towards multiple detectors and optical signals having a second wavelength are directed towards the passive splitter over the first plurality of fiber links; the multiple detectors, each for detecting upstream optical signals directed from a respective one of the one or more wavelength division multiplexers, wherein the outputs from the multiple detectors are combined into a single radio frequency signal and converted to an optical signal; and another wavelength division multiplexer (WDM) in a path upstream from the one or more wavelength division multiplexers, the another wavelength division multiplexer for receiving the optical output representing the combined output from the multiple detectors and reflecting the optical output upstream. 2. The optical splitter/combiner of claim 1 , wherein the multiple detectors are concatenated in a transmission line, wherein at least one side of the transmission line comprising the multiple detectors terminates with an impedance matching a characteristic impedance of the transmission line. 3. The optical splitter/combiner of claim 2 , wherein the transmission line has inductive matching elements for matching a parasitic capacitance of the multiple detectors to said impedance. 4. The optical splitter/combiner of claim 1 , further comprising an amplifier, wherein at least one side of the transmission line is connected to the amplifier. 5. The optical splitter/combiner of claim 4 , further comprising at least one optical transmitter re-transmitting the single radio frequency signal after amplification by the amplifier. 6. The optical splitter/combiner of claim 5 , further comprising at least one of an electrical power connection, a solar panel or battery backup for providing power to at least one of the amplifier or transmitter. 7. The optical splitter/combiner of claim 1 , wherein at least one of the upstream optical signals received by the optical splitter/combiner is an upstream optical signal that has not been radio frequency combined. 8. The optical splitter/combiner of claim 1 , further comprising an Erbium Doped Fiber Amplifier (EDFA) for amplifying the downstream optical signal prior to the splitting. 9. The optical splitter/combiner of claim 1 , further comprising an Erbium Doped Fiber Amplifier (EDFA) in the downstream path between the another WDM and the passive splitter, the EDFA amplifying downstream signals in a first wavelength band and bypassing one or more downstream signals in a wavelength band different from the first wavelength band around the EDFA to the passive splitter. 10. The optical splitter/combiner of claim 9 , wherein the bypass enables passive optical network (PON) compatibility by passing PON wavelengths to the passive splitter. 11. The optical splitter/combiner of claim 1 , further comprising wavelength selective components in each of the one or more wavelength division multiplexers for fractional reflections at one or more downstream wavelengths, increasing from a value of (1−N)/N, where N is a whole number of WDM output ports of at least 1. 12. The optical splitter/combiner of claim 1 , wherein the optical splitter/combiner is positioned between a cable modem termination system (CMTS) and an optical network unit (ONU) and converts a radio frequency over glass (RFoG) network to an active network. 13. The optical splitter/combiner of claim 1 , wherein the multiple detectors are concatenated in a transmission line, and wherein the transmission line structure has a 100 ohm or lower impedance of the transmission line. 14. The optical splitter/combiner of claim 1 , wherein the multiple detectors are concatenated in a transmission line, and wherein the detectors are photodetectors and the transmission line is formed using multiple photodetectors and matching inductors. 15. The optical splitter/combiner of claim 1 , wherein the multiple detectors are concatenated in a transmission line, and wherein the transmission line is balanced with a 100ohm or higher differential impedance. 16. The optical splitter/combiner of claim 1 , wherein the multiple detectors are concatenated in a transmission line, and wherein the multiple detectors are configured with WDM selective components to receive a wavelength band around 1610 nm and direct all other wavelengths away from a detector functionality of the multiple detectors. 17. The optical splitter/combiner of claim 16 , further comprising an additional one or more detectors configured to receive a wavelength band around 1310 nm. 18. The optical splitter/combiner of claim 16 , further comprising an additional one or more detectors configured to receive all wavelengths except a band around 1550 nm. 19. The optical splitter and combiner of claim 1 , wherein the one or more WDMs include micro-optic mirrors with fractional reflections for equally fractioning downstream light. 20. The optical splitter/combiner of claim 1 , further comprising splitter and wavelength selective components for: reflecting downstream light of a first wavelength band away from the multiple detectors to output fibers, and passing upstream light from an output fiber of a second wavelength to the multiple detectors that provide a signal to at least one upstream transmitter. 21. The optical splitter/combiner of claim 1 , further comprising splitter and wavelength selective components for: passing upstream light from one or more output fibers at wavelengths in at least a first wavelength band to the multiple detectors that provide a signal to at least one upstream transmitter, and directing light from the at least one upstream transmitter to an input fiber, and directing downstream and upstream light at a wavelength outside the first wavelength band from the input and output fibers through a passive splitter without modification to the downstream and upstream light. 22. The optical splitter/combiner of claim 1 , further comprising splitter and wavelength selective components for: directing upstream light from one or more output fibers at wavelengths in at least a first wavelength band to the multiple detectors that provide a signal to at least one upstream transmitter, and directing light from the at least one upstream transmitter to an input fiber, and passing downstream and upstream light at a wavelength outside the first wavelength band from the input and output fibers and at least one upstream transmitter through a passive splitter. 23. The optical splitter/combiner of claim 1 , wherein the multiple detectors are concatenated in a transmission line, and where an output of a trans