Claims
- 1. A method of controlling amplifier output power in an optical communications network, the method comprising:
for a first amplifier, determining a first transmission parameter associated with the output power of the first amplifier and a second transmission parameter associated with the output power of the first amplifier;
for a second amplifier downstream from the first amplifier; determining a second signal output power for the second amplifier; determining an amount of amplified spontaneous emission generated at the second amplifier; and determining an output power for the second amplifier in response to the second signal output power, the first transmission parameter, the second transmission parameter and the amount of amplified spontaneous emission generated at the second amplifier; and controlling output power of the second amplifier in response to the determined output power for the second amplifier.
- 2. The method of claim 1 wherein the first transmission parameter for the first amplifier is a composite express signal-to-noise ratio.
- 3. The method of claim 2 wherein the composite express signal-to-noise ratio is determined by:
determining a first signal output power for the first amplifier; determining a composite express output power for the first amplifier; and determining the composite express signal-to-noise ratio in response to the first signal output power and the composite express output power.
- 4. The method of claim 1 wherein the second transmission parameter for the first amplifier is a composite signal-to-noise ratio.
- 5. The method of claim 4 wherein the composite signal-to-noise ratio is determined by:
determining a first signal output power for the first amplifier; determining a composite output power for the first amplifier in response to added and blocked channels; and determining the composite signal-to-noise ratio in response to the first signal output power and the composite output power.
- 6. The method of claim 1 further comprising broadcasting the first transmission parameter and the second transmission parameter to downstream amplifiers in the optical communications network.
- 7. The method of claim 1 further comprising broadcasting the first transmission parameter and the second transmission parameter to upstream and downstream amplifiers in the optical communications network.
- 8. The method of claim 1 wherein said controlling output power of the second amplifier includes adding a power offset to provide for a service channel.
- 9. A method of controlling amplifier output power in an optical communications network, the method comprising:
for a first amplifier:
determining a first signal output power for the first amplifier; determining a composite express output power for the first amplifier; determining a composite output power for the first amplifier in response to added and blocked channels; determining a composite express signal-to-noise ratio in response to the first signal output power and the composite express output power; determining a composite signal-to-noise ratio in response to the first signal output power and the composite output power; for a second amplifier downstream from the first amplifier;
determining a second signal output power for the second amplifier; determining an amount of amplified spontaneous emission generated at the second amplifier; and determining an output power for the second amplifier in response to the second signal output power, composite express signal-to-noise ratio, composite signal-to-noise ratio and the amount of amplified spontaneous emission generated at the second amplifier; and, controlling output power of the second amplifier in response to the determined output power for the second amplifier.
- 10. An optical communications network comprising:
a first amplifier; a processor associated with said first amplifier, said processor associated with said first amplifier determining a first transmission parameter associated with the output power of the first amplifier and a second transmission parameter associated with the output power of the first amplifier; a second amplifier downstream from said first amplifier; a processor associated with said second amplifier, said processor associated with said second amplifier:
determining a second signal output power for said second amplifier; determining an amount of amplified spontaneous emission generated at said second amplifier; and determining an output power for said second amplifier in response to the second signal output power, the first transmission parameter, the second transmission parameter and the amount of amplified spontaneous emission generated at said second amplifier; and controlling output power of said second amplifier in response to the determined output power for said second amplifier.
- 11. The network of claim 10 wherein the first transmission parameter for said first amplifier is a composite express signal-to-noise ratio.
- 12. The network of claim 11 wherein the composite express signal-to-noise ratio is determined by:
determining a first signal output power for said first amplifier; determining a composite express output power for said first amplifier; and determining the composite express signal-to-noise ratio in response to the first signal output power and the composite express output power.
- 13. The network of claim 10 wherein the second transmission parameter for said first amplifier is a composite signal-to-noise ratio.
- 14. The network of claim 13 wherein the composite signal-to-noise ratio is determined by:
determining a first signal output power for said first amplifier; determining a composite output power for said first amplifier in response to added and blocked channels; and determining the composite signal-to-noise ratio in response to the first signal output power and the composite output power.
- 15. The network of claim 10 wherein said processor associated with said first amplifier broadcasts the first transmission parameter and the second transmission parameter to downstream amplifiers in the optical communications network.
- 16. The network of claim 10 wherein said processor associated with said first amplifier broadcasts the first transmission parameter and the second transmission parameter to upstream and downstream amplifiers in the optical communications network.
- 17. The network of claim 10 wherein said processor associated with said second amplifier controls output power of said second amplifier by adding a power offset to provide for a service channel.
- 18. The network of claim 10 wherein said processor associated with said first amplifier and said processor associated with said second amplifier are the same processor.
- 19. The network of claim 10 wherein said processor associated with said first amplifier and said processor associated with said second amplifier are separate processors.
- 20. An optical communications network comprising:
a first amplifier; a processor associated with said first amplifier, said processor associated with said first amplifier:
determining a first signal output power for said first amplifier; determining a composite express output power for said first amplifier; determining a composite output power for said first amplifier in response to added and blocked channels; determining a composite express signal-to-noise ratio in response to the first signal output power and the composite express output power; determining a composite signal-to-noise ratio in response to the first signal output power and the composite output power; a second amplifier; a processor associated with said second amplifier, said processor associated with said second amplifier:
determining a second signal output power for said second amplifier; determining an amount of amplified spontaneous emission generated at said second amplifier; and determining an output power for said second amplifier in response to the second signal output power, composite express signal-to-noise ratio, composite signal-to-noise ratio and the amount of amplified spontaneous emission generated at said second amplifier; and, controlling output power of said second amplifier in response to the determined output power for said second amplifier.
- 21. The network of claim 20 wherein said processor associated with said first amplifier and said processor associated with said second amplifier are the same processor.
- 22. The network of claim 20 wherein said processor associated with said first amplifier and said processor associated with said second amplifier are separate processors.
- 23. A method of determining amplifier power for an amplifier in an optical communications network, the method comprising:
determining an amount of ASE power blocked at a network element upstream of the amplifier; and, determining output power for the amplifier in response to the amount of ASE power blocked at the network element upstream of the amplifier.
- 24. The method of claim 23 wherein said determining the amount of ASE power blocked at the network element upstream of the amplifier includes receiving a transmission parameter indicative of the amount of ASE power blocked at the network element upstream of the amplifier.
- 25. The method of claim 24 wherein the transmission parameter includes a composite express signal-to-noise ratio.
- 26. The method of claim 24 wherein the transmission parameter includes a composite signal-to-noise ratio.
- 27. An optical communications network comprising:
an amplifier; and a processor associated with said amplifier, said processor:
determining an amount of ASE power blocked at a network element upstream of said amplifier; and, determining output power for said amplifier in response to the amount of ASE power blocked a +t the network element upstream of the amplifier.
- 28. The network of claim 27 wherein said processor receives a transmission parameter indicative of the amount of ASE power blocked at the network element upstream of said amplifier.
- 29. The network of claim 28 wherein the transmission parameter includes a composite express signal-to-noise ratio.
- 30. The network of claim 28 wherein the transmission parameter includes a composite signal-to-noise ratio.
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims the benefit of U.S. provisional application serial No. 60/289,672, filed May 9, 2001, the entire contents of which are incorporated herein by reference.
Provisional Applications (1)
|
Number |
Date |
Country |
|
60289672 |
May 2001 |
US |
Divisions (1)
|
Number |
Date |
Country |
Parent |
09917042 |
Jul 2001 |
US |
Child |
10368031 |
Feb 2003 |
US |