Real-time Raman gain monitoring

What is claimed is: 1. An optical node comprising: a Raman amplifier configured to amplify an optical signal having a second wavelength; a photodiode; and a processor configured to: determine an amount of current generated by the photodiode that receives, from a previous optical node, an optical signal having a first wavelength; receive information based on a correction factor, the correction factor is indicative of an amount of optical power loss that the Raman amplifier causes in the optical signal having the first wavelength that is transmitted by the previous optical node; determine the Raman amplifier gain for optical signals having the second wavelength based on the determined amount of current generated by the photodiode and the received information; and set the Raman amplifier gain of the Raman amplifier for the Raman amplifier to amplify the optical signal having the second wavelength. 2. The optical node of claim 1 , wherein the processor is configured to: determine a first optical power loss in an optical link for optical signals having the first wavelength based on the determined amount of current generated by the photodiode and the received information based on the correction factor; and determine a second optical power loss in the optical link for optical signals having the second wavelength based on the determined first optical power loss, wherein the processor is configured to determine the Raman amplifier gain of the Raman amplifier based on the determined second optical power loss, transmitted optical power from previous node at the second wavelength, and the received optical power at the current node at the second wavelength. 3. The optical node of claim 1 , wherein to receive information based on the correction factor, the processor is configured to receive information of the correction factor. 4. The optical node of claim 1 , wherein to receive information based on the correction actor, the processor is configured to receive information generated from the correction factor, the information is indicative of an amount of optical power outputted by a laser in the previous optical node that outputs optical signal having the first wavelength and optical signal having the second wavelength. 5. The optical node of claim 1 , wherein the processor is configured to calibrate the Raman amplifier at an initialization of the Raman amplifier to determine an optical power loss ratio between optical signals having the first wavelength and optical signals having the second wavelength, and wherein the processor is configured to determine the Raman amplifier gain based on the determined amount of current generated by the photodiode, the received information, and the optical power loss ratio. 6. A method comprising: determining, with an optical node, an amount of current generated by a photodiode that receives an optical signal having a first wavelength that is transmitted by a previous optical node; receiving, with the optical node, information based on a correction factor, the correction factor is indicative of an amount of optical power loss that a Raman amplifier causes in the optical signal having the first wavelength that is transmitted by the previous optical node; determining, with the optical node, a Raman amplifier gain of a Raman amplifier for optical signals having a second wavelength based on the determined amount of current generated by the photodiode and the received information; setting, with the optical node, the Raman amplifier gain of the Raman amplifier based on the determined Raman amplifier gain; and amplifying, with the optical node, the optical signals having the second wavelength with the Raman amplifier. 7. The method of claim 6 , further comprising: determining a first optical power loss in an optical link for optical signals having the first wavelength based on the determined amount of current generated by the photodiode and the received information based on the correction factor; and determine a second optical power loss in the optical link for optical signals having the second wavelength based on the determined first optical power loss, wherein determining the Raman amplifier gain of the Raman amplifier comprises determining the Raman amplifier gain of the Raman amplifier based on the determined second optical power loss. 8. The method of claim 6 , wherein receiving information based on the correction factor comprises receiving information of the correction factor. 9. The method of claim 6 , wherein receiving information based on the correction actor comprises receiving information generated from the correction factor, the information is indicative of an amount of optical power outputted by a laser in the previous optical node that outputs optical signal having the first wavelength. 10. The method of claim 6 , further comprising: calibrating the Raman amplifier at an initialization of the Raman amplifier to determine an optical power loss ratio between optical signals having the first wavelength and optical signals having the second wavelength, wherein the determining the Raman amplifier gain comprises determining the Raman amplifier gain based on the determined amount of current generated by the photodiode, the received information, and the optical power loss ratio.