Claims
- 1. An architecture for optically bypassing a terminal site comprising:
an optical de-coupler; an optical bypass switch optically coupled to an output port of said optical decoupler; an optical coupler optically coupled to an output port of said optical bypass switch.
- 2. The architecture of claim 1 further comprising:
a second optical decoupler, a second optical bypass wavelength switch optically coupled to an output port of said second optical de-coupler, a second optical coupler optically coupled to an output port of said second optical bypass switch.
- 3. The architecture of claim 1 wherein the optical decoupler is a thin film optical decoupler.
- 4. The architecture of claim 1 wherein the optical decoupler is a fused optical decoupler.
- 5. The architecture of claim 1 wherein the optical coupler is a thin film coupler.
- 6. The architecture of claim 1 wherein the optical coupler is a fused optical coupler.
- 7. The architecture of claim 1 wherein the bypass switch is a dynamic spectral equalizer.
- 8. A terminal for use in an optical bypass system comprising:
an optical splitter connected to an incoming optical fiber; a first amplifier connected to the optical splitter; at least one optical receiver connected to the optical amplifier; an optical combiner connected to an outgoing optical fiber; a second amplifier connected to the optical combiner; at least one optical transmitter connected to the second amplifier.
- 9. The terminal of claim 8 wherein the first amplifier is a multi stage amplifier.
- 10. The terminal of claim 9 wherein a dispersion compensation module is interposed in the first amplifier.
- 11. The terminal of claim 8 wherein the second amplifier is a multi stage amplifier.
- 12. The terminal of claim 11 wherein a dispersion compensator module is interposed in the second amplifier.
- 13. The terminal of claim 8 wherein the optical splitter is connected to a first bypass switch.
- 14. The terminal of claim 13 wherein the first bypass switch is a dynamic spectral equalizer.
- 15. The terminal of claim 8 wherein the optical combiner is connected to a second bypass switch.
- 16. The terminal of claim 15 wherein the second bypass switch is a dynamic spectral equalizer.
- 17. A terminal for use in an optical bypass system comprising:
a first amplifier connected an incoming optical fiber; an optical splitter connected to the first amplifier; at least one optical receiver connected to the optical splitter; a second amplifier connected to an outgoing optical fiber; an optical combiner connected to the second amplifier; at least one optical transmitter connected to the optical combiner.
- 18. The terminal of claim 17 wherein the first amplifier is a multi stage amplifier.
- 19. The terminal of claim 18 wherein a dispersion compensation module is interposed in the first amplifier.
- 20. The terminal of claim 17 wherein the second amplifier is a multi stage amplifier.
- 21. The terminal of claim 20 wherein a dispersion compensator module is interposed in the second amplifier.
- 22. The terminal of claim 17 wherein the optical splitter is connected to a first bypass switch.
- 23. The terminal of claim 22 wherein the first bypass switch is a dynamic spectral equalizer.
- 24. The terminal of claim 17 wherein the optical combiner is connected to a second bypass switch.
- 25. The terminal of claim 24 wherein the second bypass switch is a dynamic spectral equalizer.
- 26. A terminal for use in an optical bypass system comprising:
a first amplifier connected to an incoming optical fiber; an optical splitter connected to the first amplifier; at least one optical receiver connected to the optical splitter; an optical combiner connected to an outgoing optical fiber; a second amplifier connected to the optical combiner; at least one optical transmitter connected to the second amplifier.
- 27. The terminal of claim 26 wherein the first amplifier is a multi stage amplifier.
- 28. The terminal of claim 27 wherein a dispersion compensation module is interposed in the first amplifier.
- 29. The terminal of claim 26 wherein the second amplifier is a multi stage amplifier.
- 30. The terminal of claim 29 wherein a dispersion compensator module is interposed in the second amplifier.
- 31. The terminal of claim 26 wherein the optical splitter is connected to a first bypass switch.
- 32. The terminal of claim 31 wherein the first bypass switch is a dynamic spectral equalizer.
- 33. A terminal for use in an optical bypass system comprising:
an incoming multi stage amplifier having at least an incoming first stage and an incoming second stage connected to an incoming optical fiber; a first dispersion compensation module connected to the incoming first stage; an optical splitter connected to the first dispersion compensation module and to the incoming second stage; at least one optical receiver connected to the incoming second stage; an outgoing multi stage amplifier having at least an outgoing first stage and an outgoing second stage connected to an outgoing optical fiber; an optical combiner connected to the outgoing second stage; a dispersion compensator module connected to the optical combiner; the outgoing first stage connected to the dispersion combiner; at least one optical transmitter connected to the outgoing first stage.
- 34. The terminal of claim 33 wherein the optical splitter is connected to a first bypass switch.
- 35. The terminal of claim 34 wherein the first bypass switch is a dynamic spectral equalizer.
- 36. A method for optically bypassing a terminal site comprising the steps of:
installing a terminal at an optical site in an optical network; installing an optical splitter and an optical combiner in conjunction with the terminal; adding one or more channels to the optical network; deploying one or more optical bypass switches if economically justified; recovering redundant hardware in the optical network.
- 37. A method for adding splitters and combiners at a terminal site comprising the steps of:
installing a terminal at an optical site an optical network; adding one or more channels to the optical network; determing if the splitter and combiner are economically justified; if adding the splitter and combiner are justified then taking traffic out of surface, installing the splitters and combiners, installing an optical bypass switch and recovering hardware in the optical network; and if adding the splitter and combiner are not justified, continuing to add one or more channels to the optical network.
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims priority to Provisional Application Ser. No. 60/386,084 entitled “Optical Bypass Method and Architecture”, by Young, filed Jun. 4, 2002.