The United States of America as represented by the Secretary of the Air Force
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초록▼
Single transverse mode fiber amplifier and laser operation is obtained with a multi-mode signal core surrounded by cladding containing irregular microstructuring that causes loss in all of the core modes except the fundamental while maintaining robust guiding of the fundamental mode resulting in hig
Single transverse mode fiber amplifier and laser operation is obtained with a multi-mode signal core surrounded by cladding containing irregular microstructuring that causes loss in all of the core modes except the fundamental while maintaining robust guiding of the fundamental mode resulting in higher fiber laser power capacity.
대표청구항▼
The invention claimed is: 1. A method for designing a tuned cladding fiber for laser or amplification operation at a desired fundamental wavelength mode, said tuned cladding fiber comprised of an outer cladding of uniform index of refraction of n3 and an inner cladding with a large, multimode centr
The invention claimed is: 1. A method for designing a tuned cladding fiber for laser or amplification operation at a desired fundamental wavelength mode, said tuned cladding fiber comprised of an outer cladding of uniform index of refraction of n3 and an inner cladding with a large, multimode central core doped with an active lasing ionic species designed for operation at a desired fundamental wavelength mode, said inner cladding having material comprised of glass of index n1 and a plurality of air holes yielding an average index of refraction n2, n2 being less than n1 and less than n3, said multimode central core being the transmission path for guiding said desired fundamental wavelength mode and undesired, higher order guided modes, and said inner cladding further comprised of tuned elements designed to provide a path for said undesired, higher order guided modes to be coupled out to said uniform index cladding layer, the method comprised of: a. choosing a core size and geometry for the central core; b. specifying an average index of refraction for said tuned cladding fiber material that will achieve a desired fundamental mode loss for the particular operating parameters of a selected laser or amplifier; c. calculating the effective index of refraction for all the guided modes in said multimode central core; d. specifying for each undesired, higher order guided mode, a tuned element geometry whose fundamental mode effective index matches the effective index of that guided mode, beginning with a tuned element size approximately equal to the size of the local maxima in the intensity in that mode and calculating the effective index, such that if the calculated effective index is higher than the effective index of the specified core mode, making said tuned element slightly smaller, and if it is lower than the effective index of the specified core mode, making said tuned element slightly larger, refining said tuned element geometry in this manner until the effective indices match to within the manufacturing tolerances for said fiber; e. checking to see if any of the undesired, higher order modes of said tuned element match any of the higher order modes of said multimode central core, whereby if such a match occurs, these higher order modes do not need a separate tuned element with matching fundamental mode; f. placing all of the required tuned elements within said inner cladding in multiple instances leading from the neighboring region of said central core to said uniform cladding area; g. calculating the modes of the overall structure and slightly varying the size of each tuned element whereby there are no undesired, higher order modes localized in said central core and the fundamental core mode is the only localized mode or so the loss in the higher order modes is maximized relative to that of the fundamental mode, whereby the design may be incorporated into a fiber pre-form and the fiber fabricated through the normal draw process and thereafter incorporated into a laser or amplifier in the standard fashion. 2. A high-powered, fiber amplifier having uniform cross-sectional characteristics throughout its length and a large core area that operates essentially in a single propagating transverse mode, said fiber amplifier comprised of: a. an outer cladding with uniform index of refraction of n 3; and b. an inner cladding with a large, multimode central core doped with an active lasing ionic species designed for operation at a desired fundamental wavelength mode, said inner cladding having material comprised of glass of index n1 and a plurality of photonic crystal fiber-type air holes yielding an average index of refraction n 2, n2 being less than n1 and less than n3, said multimode central core being the transmission path for guiding said designed for fundamental wavelength mode and undesired, higher order guided modes, said inner cladding further comprised of a plurality of calculated microstructure elements comprised of irregular cross-sectional glass areas whose shape in cross-section is defined by the positioning of said air holes, the size, shape, and location of said microstructure elements being calculated to produce cladding modes that efficiently couple to the undesired guided modes but not the fundamental mode whereby said large core area essentially functions as a single mode transmission path capable of passing a high-powered, diffraction-limited beam. 3. The high-powered, fiber amplifier of claim 2, wherein said large central core effectively operating as a single mode transmission path has a diameter between 30 microns and 100 microns. 4. A high-powered, fiber laser having essentially uniform cross-sectional characteristics throughout its length and a large core area that operates essentially in a single propagating transverse mode, said fiber amplifier comprised of: a. an outer cladding with uniform index of refraction of n 3; and b. an inner cladding with a large, multimode central core doped with an active lasing ionic species designed for operation at a desired fundamental wavelength mode and having a resonant cavity contained within at least a portion of said fiber laser, said inner cladding having material comprised of glass of index n1 and a plurality of photonic crystal fiber-type air holes yielding an average index of refraction n2, n2 being less than n1 and less than n3, said multimode central core being the transmission path for guiding said designed for fundamental wavelength mode and undesired, higher order guided modes, said inner cladding further comprised of a plurality of calculated microstructure elements comprised of irregular cross-sectional glass areas whose shape in cross-section is defined by the positioning of said air holes, the size, shape, and location of said microstructure elements being calculated to produce cladding modes that efficiently couple to the undesired guided modes but not the fundamental mode whereby said large core area essentially functions as a single mode transmission path capable of passing a high-powered, diffraction-limited beam. 5. The high-powered, fiber laser of claim 4, wherein said large central core effectively operating as a single mode transmission path has a diameter between 30 microns and 100 microns.
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이 특허에 인용된 특허 (2)
Eggleton, Benjamin John; Hale, Arturo; Kerbage, Charles; Windeler, Robert Scott, Fiber apparatus and method for manipulating optical signals.
Hugonnot, Emmanuel; Lago, Laure; Mussot, Arnaud; Quimquenpois, Yves; Bouwmans, Géraud; Bigot, Laurent; Valentin, Constance, Microstructured optical fibre having a large core and a flattened fundamental mode, production method thereof and use of same in laser microfabrication.
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