Claims
- 1. A microstructured optical fiber, comprising:
a core for propagating light; a cladding disposed about said core, said cladding comprising a longitudinally extending array of voids; an end face region at one end of said fiber, said end face region for one of receiving or emanating light; a first section of said microstructured fiber having a normal mode field diameter; and a second section of said microstructured fiber terminating at said end face region and having a second mode field diameter that is substantially larger than said normal mode field diameter.
- 2. The microstructured optical fiber of claim 1 wherein said second mode field diameter monotonically increases from a location farther from said end face region to a location nearer said end face region.
- 3. The microstructured optical fiber of claim 1 wherein at a location along said second section each of a plurality of said voids has a diameter that is substantially different than a diameter of that void at a location along said first section of said fiber.
- 4. The microstructured optical fiber of claim 3 wherein said plurality of voids have diameters that monotonically decrease from a location farther from said end face region to a location nearer to said end face region.
- 5. The microstructured optical fiber of claim 1 wherein along said second section at least some of said-voids include matter having a selected index of refraction disposed therein.
- 6. A spliced optical fiber article having two optical fibers spliced together, comprising:
a microstructured optical fiber having a core and a cladding disposed about said core, said cladding comprising a longitudinally extending array of voids, a first section of said microstructured optical fiber having a normal mode field diameter and a selected section having an expanded mode field diameter that is substantially greater than said normal mode field diameter; a second optical fiber having a second mode field diameter that is greater than said normal mode field diameter; said microstructured optical fiber and said second optical fiber being spliced such that said selected section of said microstructured optical fiber is joined with said second optical fiber; and wherein said expanded mode field diameter is greater than said normal mode field diameter and less than or equal to said second mode field diameter for reducing the splice loss of said spliced optical fiber article.
- 7. The spliced optical fiber article of claim 6 wherein at least some of said voids present along said selected section have matter disposed therein, said matter having been disposed in said at least some voids prior to splicing said microstructured fiber and said second optical fiber.
- 8. The spliced optical fiber article of claim 7 wherein said matter includes a solid polymer disposed in said at least some voids when said polymer was in a liquid state.
- 9. The spliced optical fiber article of claim 6 wherein at a location along said first section of said fiber said cladding has a first effective refractive index, and wherein at a location along said second section of said fiber said cladding has a second effective refractive index that is substantially less than said first effective refractive index.
- 10. The spliced optical fiber article of claim 6 wherein said expanded mode field diameter varies monotonically from a location farther from said second fiber to a location nearer said second fiber.
- 11. The spliced optical fiber article of claim 6 wherein at a location along said second section each of a plurality said voids has a diameter substantially different than a diameter of that void at a location along said first section of said fiber.
- 12. The microstructured optical fiber of claim 11 wherein said plurality of voids have diameters that monotonically decrease from a location farther from said end face region to a location nearer to said end face region.
- 13. The spliced optical fiber article of claim 6 wherein said selected section is no greater than one centimeter in length.
- 14. An optical fiber article, comprising:
a microstructured optical fiber having a core for propagating light and a cladding disposed about said core, said cladding comprising a longitudinally extending array of voids; said microstructured optical fiber having a first section having a normal mode field diameter; and said microstructured optical fiber having a second section wherein a plurality of said voids include matter disposed therein such that at a location along said second section said fiber has a second mode field diameter that is substantially larger than said normal mode field diameter.
- 15. The optical fiber article of claim 14 wherein said matter includes a polymer.
- 16. The optical fiber article of claim 15 wherein said polymer is a solid polymer that was in a liquid state when disposed in said plurality of voids.
- 17. The optical fiber article of claim 14 wherein said second section is no greater than one centimeter in length.
- 18. The optical fiber article of claim 14 wherein said second section terminates in an endface region for one of radiating and receiving light.
- 19. The optical fiber article of claim 18 wherein said end face region is a cleaved end of said microstructured optical fiber.
- 20. The optical fiber article of claim 14 comprising another fiber spliced with said second section of said microstructured optical fiber, said another fiber having a third mode field diameter, and wherein said second mode field diameter is less than said third mode field diameter for tending to reduce the splice loss to said another fiber.
- 21. An optical fiber article, comprising:
a microstructured optical fiber having a core for propagating light and a cladding disposed about said core, said cladding comprising a longitudinally extending array of voids; said microstructured optical fiber having a first section having a normal mode field diameter; and said microstructured optical fiber having a selected section where for a plurality of said voids, each void has a diameter that is substantially different than the diameter of that void at a location along said first section of said fiber, said substantially different diameters for expanding the mode field diameter to be larger along said selected section than said normal mode field diameter.
- 22. The optical fiber article of claim 21 wherein the diameters of said plurality of voids monotonically decrease from a location nearer to said first section of fiber to a location farther from said first section of the fiber.
- 23. The optical fiber article of claim 21 wherein said selected section is no greater than one centimeter in length.
- 24. The optical fiber article of claim 21 wherein said selected section terminates in an endface region for one of radiating and receiving light.
- 25. The optical fiber article of claim 21 comprising another fiber spliced with said selected section of said microstructured optical fiber, said another fiber having a third mode field diameter, and wherein said second mode field diameter is less than said third mode field diameter for tending to reduce the splice loss to said another fiber.
- 26. An optical fiber article, comprising
an optical fiber having a core and a cladding disposed about said core, said cladding having a normal effective refractive index that is lower than the refractive index of said core, said optical fiber comprising a selected section wherein said cladding has a selected effective refractive index that is substantially higher than said normal effective refractive index for expanding the mode field diameter of said fiber along said selected section of the optical fiber to be substantially larger than said normal mode field diameter.
- 27. The optical fiber article of claim 26 wherein said core has a diameter that is substantially the same along said optical fiber.
- 28. The optical fiber article of claim 26 wherein said core has a refractive index that is substantially the same along the optical fiber.
- 29. A method of providing an optical fiber article, comprising:
providing a section of optical fiber having a core, a cladding disposed about the core and a normal mode field diameter, the core having an effective refractive index that is less than the core for tending to confine light propagating in the core to the core; and raising the effective refractive index of the cladding over a selected section of the fiber, the selected section shorter than the section; whereby the selected section has a second mode field diameter that is substantially different than the normal mode field diameter.
- 30. The method of claim 29 comprising refraining from substantially changing the refractive index of the core of the fiber.
- 31. The method of claim 29 comprising refraining from substantially changing the diameter of the core of the fiber.
- 32. The method of claim 29 wherein providing a section of optical fiber includes providing a section of microstructured optical fiber wherein the cladding includes a longitudinally extending array of voids.
- 33. The method of claim 32 wherein lowering the effective refractive index of the cladding includes disposing matter in a plurality of the voids present along the selected section.
- 34. The method of claim 33 wherein the matter includes a polymer disposed in the plurality of the voids when in a liquid state.
- 35. The method of claim 32 wherein lowering the effective refractive index of the cladding includes reducing the diameters of a plurality of the voids.
- 36. The method of claim 32 wherein lowering the effective refractive index of the cladding includes heating the fiber.
- 37. The method of claim 29 comprising shortening the selected section such that said second mode field diameter has a selected size at one end of the shortened selected section.
- 38. The method of claim 37 comprising forming an end face region at the one end for one of radiating and receiving light.
- 39. The method of claim 32 comprising splicing another fiber having a mode field diameter larger than the normal mode field diameter onto one end of the selected section of the fiber.
CROSS-REFERENCE TO RELATED APPLICATION
[0001] This application claims priority to provisional patent application No. 60/381,241, filed May 16, 2002 and entitled “Optical Fiber Having An Expanded Mode Field Diameter And Methods Of Providing Such A Fiber,” and which is herein incorporated by reference.
Provisional Applications (1)
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Number |
Date |
Country |
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60381241 |
May 2002 |
US |