Claims
- 1. An optical device, comprising:
a pair of optical taps coupled to a fiber optic line, a first optical tap of the pair of optical taps tapping optical signals transmitted along the fiber optic line in a first direction and a second optical tap of the pair of optical taps tapping optical signals transmitted along the fiber optic line in a second direction; and first means for receiving optical signals from the pair of optical taps and generating at least one signal indicative of a direction of travel of optical signals traveling along the fiber optic line.
- 2. The optical device of claim 1, wherein the first means comprises:
second means for determining whether a signal tapped by the first optical tap has a carrier wavelength that is the same as a carrier wavelength of a signal tapped by the second optical tap, and generating a signal indicative of the determination.
- 3. The optical device of claim 2, wherein the second means comprises:
a first monitor means for measuring signal characteristics of signals tapped by the first optical tap; a second monitor means for measuring signal characteristics of signals tapped by the second optical tap; and means for comparing the measured signal characteristics of signals tapped by the first optical tap with measured signal characteristics of signals tapped by the second optical tap.
- 4. The optical device of claim 2, wherein the second means comprises:
tap coupling means for coupling optical signals tapped from the first and second optical taps onto a second fiber optical line; first switching means for selectively optically coupling the first optical tap to the tap coupling means; second switching means for selectively optically coupling the second optical tap to the tap coupling means; and monitor means for measuring signal characteristics of optical signals on the second fiber optic line while simultaneously individually controlling the first and second switching means to alternatively configure the first and second switching means between coupling and decoupling states.
- 5. The optical device of claim 4, wherein the monitor means controls the first and second switching means such that the monitor means measures optical signals appearing on the second fiber optic line while the first switching means is configured in the decoupling state, and measures optical signals appearing on the second fiber optic line while the second switching means is configured in the decoupling state.
- 6. The optical device of claim 1, wherein the second means comprises:
switching means for selectively and individually optically coupling the first optical tap and the second optical tap to a second fiber optic line; and monitor means for measuring signal characteristics of optical signals on the second fiber optic line while simultaneously controlling the switching means to alternatingly couple the first and second optical taps to the second fiber optic line.
- 7. The optical device of claim 6, further comprising:
a second pair of optical taps coupled to a third fiber optic line, a first tap of the second pair of optical taps tapping optical signals transmitted along the third fiber optic line in a first direction and a second tap of the second pair of optical taps tapping optical signals transmitted along the third fiber optic line in a second direction; wherein the switching means selectively and individually optically couples the first optical tap and the second optical tap of the second pair of optical taps to the second fiber optic line; and the monitor means measures signal characteristics of optical signals on the third fiber optic line while simultaneously controlling the switching means to alternatingly couple the first and second optical taps of the second pair of optical taps to the second fiber optic line.
- 8. The optical device of claim 1, wherein the means for receiving and generating comprises:
tap coupling means for placing optical signals tapped by the first optical tap and optical signals tapped by the second optical tap onto a second fiber optic line; switching means for selectively providing optical signals tapped by the first optical tap to the tap coupling means; and monitor means for measuring signal characteristics of optical signals appearing on the second fiber optic line and controlling the switching means to alternatingly configure the switching means between coupled and decoupled states.
- 9. The optical device of claim 8, wherein the monitor means measures optical signals appearing on the second fiber optic line while the switching means couples the first optical tap to the coupling means, and measures optical signals appearing on the second fiber optic line while the switching means decouples the first optical tap from the coupling means.
- 10. A method for monitoring optical signals transported over a fiber optic line, comprising:
tapping optical signals transported over the fiber optic line; detecting optical signals tapped during the step of tapping; for each optical signal detected, determining a direction of travel along the fiber optic line of the optical signal corresponding to the detected optical signal; and indicating each determined direction of travel.
- 11. The method of claim 10, wherein:
the step of tapping comprises tapping onto a second fiber optic line a portion of optical signals transported over the fiber optic line in a first direction, and tapping onto a third fiber optic line a portion of optical signals transported over the fiber optic line in a second direction; the method further comprises selectively coupling the second fiber optic line onto a fourth fiber optic line, and substantially continuously coupling the third fiber optic line to the fourth fiber optic line; and the step of detecting comprises detecting optical signals appearing on the fourth fiber optic line.
- 12. The method of claim 11, wherein the step of determining comprises:
measuring a power level of an optical signal appearing on the fourth fiber optic line when the second fiber optic line is decoupled from the fourth fiber optic line; measuring a power level of an optical signal appearing on the fourth fiber optic line when the second fiber optic line is coupled to the fourth fiber optic line; and comparing power levels measured during the time the second fiber optic line is decoupled from the fourth fiber optic line with power levels measured during the time the second fiber optic line is coupled to the fourth fiber optic line, the determined direction being based upon the comparison.
- 13. The method of claim 10, wherein:
the step of tapping comprises selectively tapping onto a second fiber optic line a portion of optical signals transported over the fiber optic line in a first direction, and selectively tapping onto a third fiber optic line a portion of optical signals transported over the fiber optic line in a second direction; and the method further comprises determining whether a signal on the second fiber optic line has a carrier wavelength that is the same as carrier wavelength of a signal on the third fiber optic line, and generating a signal indicative of the determination.
- 14. The method of claim 13, further comprising:
during a first time period, selectively coupling the second fiber optic line to a fourth fiber optic line while decoupling the third fiber optic line from the fourth fiber optic line; and during a second time period, selectively coupling the third fiber optic line to the fourth fiber optic line while decoupling the second fiber optic line from the fourth fiber optic line; wherein the step of determining whether a signal on the second fiber optic line has a carrier wavelength that is the same as carrier wavelength of a signal on the third fiber optic line comprises: measuring carrier wavelength of an optical signal appearing on the fourth fiber optic line during the first time period; measuring carrier wavelength of an optical signal appearing on the fourth fiber optic line during the second time period; and comparing the carrier wavelengths measured during the first time period with carrier wavelengths measured during the second time period.
- 15. The method of claim 13, wherein the step of determining whether a signal on the second fiber optic line has a carrier wavelength that is the same as carrier wavelength of a signal on the third fiber optic line comprises individually measuring the carrier wavelength of signals appearing on the second fiber optic line and the third fiber optic line, and comparing the measured carrier wavelengths.
- 16. The method of claim 10, wherein:
the step of tapping comprises selectively tapping onto a second fiber optic line a portion of optical signals transported over the fiber optic line in a first direction, selectively tapping onto the second fiber optic line a portion of optical signals transported over the fiber optic line in a second direction, selectively tapping onto the second fiber optic line a portion of optical signals transported over a third fiber optic line in a first direction, and selectively tapping onto the second fiber optic line a portion of optical signals transported over the third fiber optic line in a second direction; and the method further comprises determining whether a signal on the fiber optic line in the first direction has a carrier wavelength that is the same as carrier wavelength of a signal on the fiber optic line traveling in the second direction, determining whether a signal on the third fiber optic line traveling in the first direction has a carrier wavelength that is the same as carrier wavelength of a signal on the third fiber optic line traveling in the second direction, and generating at lease one signal indicative of the determinations.
- 17. An optical device, comprising:
a first optical tap, coupled to a first fiber optic line, for placing onto a second fiber optic line a portion of optical signals transported over the fiber optic line in a first direction; a second optical tap, coupled to the fiber optic line, for placing onto a third fiber optic line a portion of optical signals transported over the fiber optic line in a second direction; a first optical switch in optical communication with the second fiber optic line and being configurable in open and closed states; a tap coupler in optical communication with the first optical switch and the third fiber optic line, for placing onto a fourth fiber optic line optical signals generated at an output of the first optical switch and appearing on the third fiber optic line; and an optical performance monitor coupled to the fourth fiber optic line and operable to measure power levels of optical signals appearing on the fourth fiber optic line, generate a control signal for configuring the first optical switch and determine a direction of travel of signals transported along the first fiber optic line based upon the power levels measured.
- 18. The optical device of claim 17, wherein:
the optical performance monitor measures power levels of optical signals appearing on the fourth fiber optic line during a first time period when the first optical switch is configured in a closed state and during a second time period when the first optical switch is configured in a open state.
- 19. The optical device of claim 18, wherein:
the optical performance monitor compares measured power levels of optical signals appearing on the fourth fiber optic line during the first time period with measured power levels of optical signals appearing on the fourth fiber optic line during the second time period, and indicates a direction of travel of signals transported along the first fiber optic line based upon the comparison.
- 20. The optical device of claim 17, further comprising:
a first light element; and a second light element; wherein the optical performance monitor activates the first light element when an optical signal transported on the first fiber optic line is determined to travel in a first direction, and activates the second light element when an optical signal transported on the first fiber optic line is determined to travel in a second direction.
- 21. An optical device, comprising:
a first optical tap, coupled to a first fiber optic line, for placing onto a second fiber optic line signals transported over the fiber optic line in a first direction; a second optical tap, coupled to the fiber optic line, for placing onto a third fiber optic line signals transported over the fiber optic line in a second direction; a first optical switch in optical communication with the second fiber optic line and being configurable in open and closed states; a second optical switch in optical communication with the third fiber optic line and being configurable in open and closed states; a tap coupler in optical communication with the first and second optical switches, for placing onto a fourth fiber optic line optical signals generated at an output of each of the first and second optical switches; and an optical performance monitor coupled to the fourth fiber optic line and operable to measure carrier wavelengths of optical signals appearing on the fourth fiber optic line, generate a first control signal for controlling the first optical switch and a second control signal for controlling the second optical switch, and determine whether a carrier wavelength of an optical signal transported along the first fiber optic line in the first direction is substantially the same as a carrier wavelength of an optical signal transported along the first fiber optic line in the second direction.
- 22. The optical device of claim 21, wherein:
the optical performance monitor indicates a result of the determination.
- 23. The optical device of claim 22, further comprising:
a first light element, wherein the optical performance monitor activates the first light element upon an affirmative determination that a carrier wavelength of an optical signal transported along the first fiber optic line in the first direction is substantially the same as a carrier wavelength of an optical signal transported along the first fiber optic line in the second direction.
- 24. The optical device of claim 21, wherein:
the optical performance monitor measures carrier wavelengths of an optical signal appearing on the fourth fiber optic line during a first time period when the first optical switch is configured in a closed state and the second optical switch is configured in a open state, measures carrier wavelengths of an optical signal appearing on the fourth fiber optic line during a second time period when the second optical switch is configured in a closed state and the first optical switch is configured in a open state, and compares the carrier wavelengths measured during the first time period with carrier wavelengths measured during the second time period.
- 25. The optical device of claim 21, wherein:
the optical performance monitor measures power levels of optical signals appearing on the fourth fiber optic line, and determines a direction of travel of an optical signal on the fiber optic line based upon measured power levels.
- 26. The optical device of claim 25, wherein:
the optical performance monitor measures a power level of an optical signal appearing on the fourth fiber optic line during a first time period when the first optical switch is configured in the open state and the second optical switch is configured in the closed state and during a second time period when the first and second optical switches are configured in the closed state, and compares the power level measured during the first time period with power level measured during the second time period.
- 27. The optical device of claim 25, further comprising:
a first light element; and a second light element; wherein the optical performance monitor activates the first light element upon an affirmative determination that the optical signal is transported along the first fiber optic line in the first direction, and activates the second light element upon an affirmative determination that the an optical signal is transported along the first fiber optic line in the second direction.
- 28. An optical device for an optical communications system, comprising:
a first optical tap, coupled to a first fiber optic line, for placing onto a second fiber optic line a portion of signals transported over the fiber optic line in a first direction; a second optical tap, coupled to the fiber optic line, for placing onto a third fiber optic line a portion of signals transported over the fiber optic line in a second direction; a first optical performance monitor in optical communication with the second fiber optic and operable to measure optical signals appearing on the second fiber optic line; and a second optical performance monitor in optical communication with the third fiber optic line and operable to measure optical signals appearing on the third fiber optic line, the first and second optical performance monitors determining a direction of travel of optical signals transported along the first fiber optic line.
- 29. The optical device of claim 28, further comprising:
a first light element; and a second light element; wherein the first optical performance monitor activates the first light element when the determined direction of travel along the fiber optic line is in a first direction, and the second optical performance monitor activates the second light element when the determined direction of travel along the fiber optic line is in a second direction.
- 30. The optical device of claim 28, wherein the first and second optical performance monitors determine whether a wavelength of an optical signal transported over the fiber optic line in the first direction is the same as a wavelength of an optical signal transported over the fiber optic line in the second direction, based upon the optical signals measured by the first and second optical performance monitors.
- 31. An optical device, comprising:
a first optical tap, coupled to a first fiber optic line, for placing onto a second fiber optic line signals transported over the fiber optic line in a first direction; a second optical tap, coupled to the first fiber optic line, for placing onto a third fiber optic line signals transported over the fiber optic line in a second direction; an optical switch having inputs in optical communication with the second and third fiber optic lines and being configurable to selectively and individually optically couple the second and third fiber optic lines to a fourth fiber optic line; and an optical performance monitor coupled to the fourth fiber optic line and operable to measure carrier wavelengths of optical signals appearing on the fourth fiber optic line, generate a control signal for controlling the optical switch, and determine whether a carrier wavelength of an optical signals transported along the first fiber optic line in the first direction is substantially the same as a carrier wavelength of an optical signal transported along the first fiber optic line in the second direction.
- 32. The optical device of claim 31, wherein:
the optical performance monitor indicates a result of the determination.
- 33. The optical device of claim 31, wherein:
the optical performance monitor measures carrier wavelengths of an optical signal appearing on the fourth fiber optic line during a first time period when the optical switch is configured to optically couple the second and fourth fiber optic lines, measures carrier wavelengths of an optical signal appearing on the fourth fiber optic line during a second time period when the optical switch is configured in a state to optically couple the third and fourth fiber optic lines, and compares the carrier wavelengths measured during the first time period with carrier wavelengths measured during the second time period.
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This patent application is related to and claims priority from U.S. patent application Ser. No. 60/208,481, filed Jun. 2, 2000 (Attorney Docket No. 34013-30USPL).
Provisional Applications (1)
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Number |
Date |
Country |
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60208481 |
Jun 2000 |
US |