Method and system for providing dedicated service on a passive optical network

What is claimed is: 1. A method comprising: generating, at an optical line terminal, a multi-wavelength optical signal comprising a plurality of sub-signals corresponding to carrier wavelengths; modulating, at the optical line terminal, the plurality of sub-signals simultaneously with a content signal; amplifying, at the optical line terminal, the modulated multi-wavelength optical signal; assigning, at the optical line terminal, the carrier wavelengths to the one or more respective subscribers; separating, at the optical line terminal, the modulated multi-wavelength optical signal into the plurality of sub-signals via an optical multiplexer; transmitting, at the optical line terminal, the plurality of sub-signals individually from the optical line terminal to one or more respective subscribers over an optical distribution network; receiving, at the optical line terminal, over the optical distribution network, a plurality of upstream signals from the respective one or more subscribers; and combining, at the optical line terminal, the plurality of upstream signals, wherein separating the modulated multi-wavelength optical signal into the plurality of sub-signals via the optical multiplexer comprises: providing the amplified modulated multi-wavelength optical signal to an optical isolator, providing an output of the optical isolator to a collimator, and propagating, in open space, outputs of the collimator to the optical multiplexer. 2. A method according to claim 1 , wherein the modulated multi-wavelength optical signal is separated by diffraction. 3. A method according to claim 1 , wherein the multi-wavelength optical signal is generated by a comb laser. 4. A method according to claim 1 wherein the carrier wavelengths of the plurality of upstream signals are different from the carrier wavelengths of the plurality of sub-signals. 5. A method according to claim 4 , wherein the plurality of upstream signals are combined by diffraction. 6. A method according to claim 4 , wherein the plurality of upstream signals and the plurality of sub-signals are symmetrical. 7. A method according to claim 1 , wherein the optical distribution network is a passive optical network (PON). 8. An optical line terminal comprising: at least one processor; and at least one memory including computer program code for one or more programs, the at least one memory and the computer program code configured to, with the at least one processor, cause the optical line terminal to perform at least the following, generate a multi-wavelength optical signal comprising a plurality of sub-signals corresponding to carrier wavelengths; modulate the plurality of sub-signals simultaneously with a content signal; amplify the modulated multi-wavelength optical signal; assign the carrier wavelengths to the one or more respective subscribers; and separate the modulated multi-wavelength optical signal into the plurality of sub-signals; transmit the plurality of sub-signals individually from the optical line terminal to one or more respective subscribers over an optical distribution network; receive, over the optical distribution network, a plurality of upstream signals from the respective one or more subscribers; and combine the plurality of upstream signals, wherein to separate the modulated multi-wavelength optical signal into the plurality of sub-signals, the optical line terminal is further caused to perform: provide the amplified modulated multi-wavelength optical signal to an optical isolator, provide an output of the optical isolator to a collimator, and propagate, in opens outputs of the collimator to an optical multiplexer. 9. An optical line terminal according to claim 8 , wherein the modulated multi-wavelength optical signal is separated by diffraction. 10. An according to claim 8 , wherein the multi-wavelength optical signal is generated by a comb laser. 11. An optical line terminal according to claim 8 , wherein the carrier wavelengths of the plurality of upstream signals are different from the carrier wavelengths of the plurality of sub-signals. 12. An optical line terminal according to claim 11 , wherein the plurality of upstream signals are combined by diffraction. 13. A optical line terminal according to claim 11 , wherein the plurality of upstream signals and the plurality of sub-signals are symmetrical. 14. An optical line terminal according to claim 8 , wherein the optical distribution network is a passive optical network (PON). 15. A system comprising: a dedicated service platform configured to generate a multi-wavelength optical signal comprising a plurality of sub-signals corresponding to carrier wavelengths, modulate the plurality of sub-signals simultaneously with a content signal, amplify the modulated multi-wavelength optical signal, assign the carrier wavelengths to the one or more respective subscribers, separate the modulated multi-wavelength optical signal into the plurality of sub-signals, transmit the plurality of sub-signals individually from the dedicated service platform to one or more respective subscribers over an optical distribution network, receive, over the optical distribution network a plurality of upstream signals from the respective one or more subscribers, and combine the plurality of upstream signals, wherein to separate the modulated multi-wavelength optical signal into the plurality of sub-signals, the dedicated service platform configured to: provide the amplified modulated multi-wavelength optical signal to an optical isolator, provide an output of the optical isolator to a collimator, and propagate, in open space, outputs of the collimator to an optical multiplexer. 16. A system according to claim 15 , wherein the optical multiplexer is configured to separate the modulated multi-wavelength optical signal into the plurality of sub-signals, and wherein the carrier wavelengths of the plurality of upstream signals are different from the carrier wavelengths of the plurality of sub-signals. 17. A system according to claim 16 , wherein the optical multiplexer is an optical diffraction grating. 18. A system according to claim 17 , further comprising: one or more tunable lasers configured to transmit the respective plurality of upstream signals over the optical distribution network.