1. Field of the invention
The present invention relates to a micro-structured fiber having an array of micrometer-sized air holes, and more particularly, to a micro-structured fiber having a plurality of air holes with different diameters.
2. Description of the Related Art
Referring to
In order to achieve the chromatic dispersion related application, such as flattened dispersion, dispersion compensation or shifted dispersion, the value of the diameter d of the air holes 13 and the pitch Λ between the air holes 13 should be adjusted. In general, the larger ratio of the diameter d to the pitch Λ (d/Λ) of the air holes 13 represents that the light communication band has a larger normal dispersion value to realize dispersion compensation, whereas the smaller ratio of the diameter d to the pitch Λ (d/Λ) of the air holes 13, such as 0.25, realizes the flattened dispersion. In most cases, the pitch Λ is usually about 2.6 μm, and the diameter d is usually about 0.624 μm.
U.S. Pat. Nos. 6,636,677 and 6,718,105 disclose the fibers that achieve a better dispersion compensation by combining the technique of controlling the distribution of the refractive index around the core region and the structure of the micrometer-sized air holes. Additionally, U.S. Pat. Nos. 6,571,045 and 6,445,862 also achieve a better dispersion compensation caused by the effect of different distribution of the refractive index around the core region by controlling the air holes to have a uniform structure period.
Referring to
Recently, a second prior art of a design of photonic crystal fiber (PCF) with four or five rings of different air-hole diameters for each ring was proposed for achieving ultralow ultra-flattened dispersion (see “K. Saitoh and M. Koshiba, “Chromatic dispersion control in photonic crystal fibers: Application to ultra-flattened dispersion,” Opt. Expr., vol. 11, pp. 843-852, 2003”, “K. Saitoh and M. Koshiba, “Unique Dispersion Properties of Photonic Crystal Fibers,” ICICS-PCM 2003, pp. 171-175, December 2003” and “F. Poli, A. Cucinotta, S. Selleri, and A. H. Bouk, “Tailoring of Flattened Dispersion in Highly nonlinear Photonic Crystal Fibers,” IEEE Photon. Technol. Lett., vol. 16, pp. 1065-1067, April 2004”). This design significantly reduces the ring number of the air holes, but the design procedure becomes complicated due to several geometrical parameters, five (four kinds of air-hole diameters and one pitch) for the four-ring case and six (five kinds of air-hole diameters and one pitch) for the five-ring case, which are needed to be simultaneously optimized to achieve the flattened dispersion behavior of the PCF.
Consequently, there is an existing need for a novel and improved broadband ultra-flattened dispersion micro-structured fiber to solve the above-mentioned problems.
One objective of the present invention is to improve the shortcomings of high manufacture difficulty and high confinement loss of the conventional micro-structured fiber caused by reducing the diameter of the air holes and enlarging the pitch between the air holes when being designed in the consideration of flattened dispersion. The micro-structured fiber of the present invention has the advantages of broader band of nearly zero dispersion, less confinement loss, being easier to design due to less geometrical parameters needed to be optimized, and being easier to fabricate.
Another objective of the present invention is to provide a micro-structured fiber comprising a core region and a cladding region, wherein the material of the core region is the same as that of the cladding region. The cladding region has a plurality of air holes regularly arranged on a plurality of hexagonal rings, wherein the innermost ring of the fiber defines the core region. The cladding region comprises an inner circumference portion and an outer circumference portion; the inner circumference portion comprises at least one ring, wherein the air holes on each ring of the inner circumference portion have equal diameters and pitches therebetween. The outer circumference portion comprises at least one ring, wherein the air holes on each ring of the outer circumference portion have equal diameters and pitches therebetween. The diameter of the air hole on the outer circumference portion is larger than that of the air hole on the inner circumference portion.
The characteristic of the present invention is that the cladding region 32 comprises an inner circumference portion 321 and an outer circumference portion 322, the inner circumference portion 321 comprises at least one ring, and the outer circumference portion 322 comprises at least one ring. In the embodiment, the inner circumference portion 321 comprises two rings 33, 34, the outer circumference portion 322 comprises two rings 35, 36. There are four rings in total in the fiber 30. It is understood that the present invention is not limited to four rings, the inner circumference portion 321 may comprise two to six rings, and the outer circumference portion 322 may comprise one to six rings.
Taking ring 33 for example, all the air holes 331, 332, 333 on the ring 33 of the inner circumference portion 321 have equal first diameters d1, and all first pitches Λ, between the air holes 331, 332 on the ring 33 are equal. Taking ring 36 for example, all the air holes 361, 362, 363 on the ring 36 of the outer circumference portion 322 have equal second diameters d2, and all second pitches Λ2 between the air holes 361, 362 on the ring 36 are equal. In this embodiment, the second diameter d2 of the air holes 363 on the outer circumference portion 322 is larger than the first diameter d1 of the air holes 333 on the inner circumference portion 321. Additionally, the second pitch Λ2 between the air holes 361, 362 on the ring 36 of the outer circumference 322 is equal to the first pitch Λ1 between the air holes 331, 332 on the ring 33 of the inner circumference 321. Alternatively, the second pitch Λ2 may be larger or small than the first pitch Λ1.
The advantage of the present invention is that when being designed for the consideration of flattened dispersion, the micro-structured fiber 30 has the following geometrical parameters: first diameter d1 and first pitch Λ1 of the inner circumference portion 321, second diameter d2 and second pitch Λ2 of the outer circumference portion 322. Compared with the conventional micro-structured fiber 10 of
The procedures for designing the micro-structured fiber 30 of the present invention are as follows. First, the ratio of d2/Λ2 is chosen from the range of 0.5 to 0.99 under the consideration of confinement loss. It is found that larger ratio of d2/Λ2 will cause less confinement loss. Then, d1/Λ1, Λ1 and Λ2/Λ1 are adjusted in sequence to get the desired flattened dispersion property, wherein the ratio of d1/Λ1 will influence the slope behavior of the chromatic dispersion curves, the value of Λ1 will influence the chromatic dispersion values, and the ratio of Λ2/Λ1 will influence the size of bandwidth.
The micro-structured fiber represented by curve B comprises four rings, wherein the inner circumference portion comprises two rings, and the outer circumference portion comprises two rings. The geometrical parameters of Λ1, d1, Λ2 and d2 of the fiber are determined to be 1.68 μm, 0.51072 μm, 1.428 μm and 1.2852 μm, respectively. The fiber has a dispersion of ±0.5 ps/km/nm from 1245 nm to 1740 nm wavelength, which has a bandwidth of 495 nm covering total band of light communication.
While several embodiments of the present invention have been illustrated and described, various modifications and improvements can be made by those skilled in the art. The embodiments of the present invention are therefore described in an illustrative but not restrictive sense. It is intended that the present invention may not be limited to the particular forms as illustrated, and that all modifications which maintain the spirit and scope of the present invention are within the scope as defined in the appended claims.
Number | Date | Country | Kind |
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093119657 | Jun 2004 | TW | national |