Claims
- 1. An optical package comprising:an input ferrule comprising at least one capillary extending axially through said ferrule; at least two pair of optical fibers extending through said at least one capillary, said fibers comprising a first input fiber, a first reflected fiber, a second input fiber and a second reflected fiber, said fibers screened for a pre-determined tolerance for a characteristic selected from the group consisting of core concentricity, ovality, and diameter, wherein the pre-determined tolerance for ovality is equal to or less than about 0.8 percent; and an optical filter optically aligned with said optical fibers such that a first wavelength of optical signals transmitted through said first input fiber are reflected by said filter to said first reflected fiber and a second wavelength of optical signals transmitted through said second input fiber are reflected by said filter to said second reflected fiber.
- 2. The optical package of claim 1, further comprising an aspheric lens optically coupling said first input fiber to said filter.
- 3. The optical package of claim 1, wherein said filter is selected from a group consisting of a gain flattening filter, a notch filter, a band pass filter, and a shaping filter.
- 4. The optical package of claim 1, wherein said first reflected fiber is coupled to said second input fiber.
- 5. The optical package of claim 4, further comprising an optical device coupled between said first reflected fiber and said second input fiber.
- 6. The optical package of claim 5, wherein said optical device comprises an optical amplifier.
- 7. The optical package of claim 1, further comprising:an output ferrule comprising a capillary extending axially through said ferrule; and a transmitted fiber extending through said output ferrule capillary, said transmitted fiber optically coupled to said first input fiber.
- 8. The optical package of claim 7, further comprising an aspheric lens optically coupling said transmitted fiber to said filter.
- 9. The optical package of claim 7, further comprising an energy dissipating device coupled to said transmitted fiber and dissipating a signal communicated from said first input fiber.
- 10. A multiple-port optical package comprising:an input ferrule comprising at least one capillary extending axially through said ferrule; at least two pair of optical fibers extending through said at least one capillary, said fibers comprising a first input fiber, a first reflected fiber, a second input fiber and a second reflected fiber, said fibers screened for a pre-determined tolerance for a characteristic selected from the group consisting of core concentricity, ovality, and diameter, wherein the pre-determined tolerance for core concentricity is equal to or less than about 1.0 μm; an optical filter in communication with said optical fibers such that a first wavelength of optical signals transmitted through said first input fiber are reflected by said filter to said first reflected fiber and a second wavelength of optical signals transmitted through said second input fiber are reflected by said filter to said second reflected fiber; an output ferrule comprising at least one output capillary extending axially through said ferrule; and at least two output optical fibers extending through said at least one output capillary and receiving light signals transmitted through said filter.
- 11. The multiple-port optical package of claim 10, wherein said output optical fibers comprise a first output fiber and a second output fiber, and wherein said first output fiber is in optical communication with said first input fiber and said second output fiber is in communication with said second input fiber.
- 12. The multiple-port optical package of claim 10, wherein said output optical fibers comprise a first output fiber and a second output fiber, and wherein said first output fiber is in optical communication with said first reflected fiber and said second output fiber is in communication with said second reflected fiber.
- 13. The multiple-port optical package of claim 10, wherein said output optical fibers comprise a first output fiber and a second output fiber, and wherein said first output fiber is in optical communication with said first input fiber and said second output fiber is in communication with said second reflected fiber.
- 14. The multiple-port optical package of claim 10, wherein at least one of said reflected fibers is coupled to a power-dissipating device.
- 15. The multiple-port optical package of claim 10, wherein at least two of said reflected fibers are coupled to a power-dissipating device.
- 16. The multiple-port optical package of claim 10, wherein at least one of said output optical fibers is coupled to a power-dissipating device.
- 17. The multiple-port optical package of claim 10, wherein at least two of said output optical fibers are coupled to a power-dissipating device.
- 18. An add/drop optical module comprising:first and second six-port optical packages, each of said packages comprising a first input fiber, a first reflected fiber, a second input fiber, a second reflected fiber, a drop fiber, and an add fiber, said drop fiber optically coupled to said first input fiber and said add fiber optically coupled to said second reflected fiber; wherein said first reflected fiber of said first package is coupled to said first input fiber of said second package; and wherein said second input fiber of said first package is coupled to said second reflected fiber of said first package.
CROSS-REFERENCE TO RELATED APPLICATION
This application is a continuation-in-part of U.S. patent application Ser. No. 09/599,168, filed on Jun. 22, 2000, entitled “THREE-PORT FILTER AND METHOD OF MANUFACTURE,” by Scott M. Hellman et at., now U.S. Pat. No. 6,343,166, the entire disclosure of which is incorporated herein by reference.
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Country |
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Dec 1993 |
EP |
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Jul 1994 |
EP |
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Continuation in Parts (1)
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Number |
Date |
Country |
Parent |
09/599168 |
Jun 2000 |
US |
Child |
09/945313 |
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US |