Transient and switching event stabilization of fiber optic transport systems

What is claimed is: 1. A method for power control of signals carried by an optical fiber, the method comprising: adding one or more data-bearing channels to the optical fiber, the data-bearing channels distributed among a plurality of frequency bins; adding a set of control channels to the optical fiber, each control channel comprising a pair of signals at separate frequencies, at least one control channel in each of the plurality of frequency bins, each signal of a pair being cross-polarized with respect to the other signal of the pair, adding a set of dummy channels to the optical fiber, at least one dummy channel in each of the plurality of frequency bins with a corresponding at least one control channel, wherein the set of dummy channels are generated by one or more broadband amplitude spontaneous emission (ASE) sources; measuring an optical power in at least one of the plurality of frequency bins; and responsive to a change in the optical power in the at least one of the plurality of frequency bins based on associated dummy channels, adjusting an optical power of one or more control channels to maintain a substantially constant power of a frequency bin that contains the adjusted control channels to ensure that non-linear interactions are managed to accommodate the change in the optical power of the associated dummy channels. 2. The method of claim 1 , wherein the pair of signals is generated by a pair of low line width lasers. 3. The method of claim 1 , wherein the separate frequencies of the pair of signals are selected to reduce four-wave mixing products on adjacent data-bearing channels. 4. The method of claim 1 , wherein each of the separate frequencies of the pair of signals of a control channel are selected so that a difference between the separate frequencies is greater than a bandwidth of a receiver of an adjacent data-bearing channel. 5. The method of claim 1 , wherein the data bearing channels are centered at predetermined frequency intervals. 6. The method of claim 1 , wherein the data-bearing channels are centered at regular frequency intervals and wherein each of the separate frequencies of the pair of signals of a control channel are selected so that a difference between the separate frequencies is substantially one half a frequency interval. 7. The method of claim 1 , wherein an average frequency of the separate frequencies is at a midpoint of a frequency interval. 8. The method of claim 1 , wherein adjustment of a control channel occurs within 1 microsecond to 100 microseconds of a change in optical power of the corresponding frequency bin. 9. An optical control channel signal generator, comprising: a plurality of broadband amplitude spontaneous emission (ASE) sources configured to produce a set of dummy channels; one or more optical sources configured to produce at least one signal pair, each signal pair forming a control channel in a corresponding frequency bin with a corresponding dummy channel, the signals of each signal pair separated by a first frequency interval; a combiner configured to combine a first signal and a second signal of a signal pair, wherein a polarization of the first signal is orthogonal to a polarization of the second signal at the output of the combiner; and at least one attenuator each configured to attenuate a corresponding signal pair based on a measured optical power of a corresponding frequency bin and responsive to a change in the measured optical power in the corresponding frequency bin based on associated dummy channels to ensure that non-linear interactions are managed to accommodate the change in the measured optical power of the associated dummy channels. 10. The optical control channel signal generator of claim 9 , wherein the combiner includes a polarization beam splitter. 11. The optical control channel signal generator of claim 10 , wherein the at least one attenuator controls amplitudes of corresponding ones of the plurality of ASE sources. 12. The optical control channel signal generator of claim 11 , wherein the at least one attenuator is a variable optical attenuator. 13. The optical control channel signal generator of claim 12 , further comprising: a plurality of detectors, the plurality of detectors configured to detect power in each of a plurality of optical signals to be transmitted in the corresponding frequency bin; and a control circuit, the control circuit configured to measure the optical power of the corresponding frequency bin and to provide the measured optical power to the at least one attenuator. 14. The optical control channel signal generator of claim 13 , wherein the control circuit is an analog circuit. 15. The optical control channel signal generator of claim 13 , wherein the control circuit is a digital processor. 16. The optical control channel signal generator of claim 13 , wherein each signal pair is separated by substantially one half of a frequency interval that separates adjacent data-bearing signals carried by an optical fiber that carries the control channel. 17. The optical control channel signal generator of claim 16 , wherein an average frequency of each signal pair is substantially at a midpoint of a frequency interval. 18. A device for power control of signals carried by an optical fiber, comprising: a wavelength selective switch (WSS) adapted to add one or more data-bearing channels to the optical fiber, the data-bearing channels distributed among a plurality of frequency bins; a processor adapted to add a set of control channels to the optical fiber, each control channel comprising a pair of signals at separate frequencies, at least one control channel in each of the plurality of frequency bins, and the processor further adds a set of dummy channels to the optical fiber, at least one dummy channel in each of the plurality of frequency bins with a corresponding at least one control channel; optical detectors adapted to measure an optical power in at least one of the plurality of frequency bins; and optical power control adapted to adjust an optical power of one or more control channels responsive to a change in the optical power in the at least one of the plurality of frequency bins based on associated dummy channels to maintain a substantially constant power of a frequency bin that contains the adjusted control channels to ensure that non-linear interactions are managed to accommodate the change in the optical power of the associated dummy channels. 19. The device of claim 18 , wherein the separate frequencies of the pair of signals are selected to reduce four-wave mixing products on adjacent data-bearing channels. 20. The device of claim 19 , wherein each of the separate frequencies of the pair of signals of a control channel are selected so that a difference between the separate frequencies is greater than a bandwidth of a receiver of an adjacent data-bearing channel.