Actas de congresos
Improving Dispersion Compensation Of Photonic Crystal Fibers Through Air Hole Core Insertion
Registro en:
9781457716621
Sbmo/ieee Mtt-s International Microwave And Optoelectronics Conference Proceedings. , v. , n. , p. 121 - 124, 2011.
10.1109/IMOC.2011.6169388
2-s2.0-84860442036
Autor
Malheiros-Silveira G.N.
Mores Jr. J.A.
Hernandez-Figueroa H.E.
Institución
Resumen
The analysis of the insertion of one air hole centered in the core region of a Dispersion Compensating Photonic Crystal Fiber (DCPCF) was done by numerical modeling via Finite Element Method (FEM). A case study of this kind of optical fiber was evaluated. Based on this study, it was observed that the simple insertion of the air hole in the central region of the DCPCF and the variation of its diameter can produce significant improvements in fibers designed for this purpose. © 2011 IEEE.
121 124 Poli, F., Cucinotta, A., Fuochi, M., Selleri, S., Vincetti, L., Characterization of microstructured optical fibers for wideband dispersion compensation (2003) J. Opt. Soc. Am. A, 20, pp. 1958-1962 Huttunen, A., Törmä, P., Optimization of dual-core and microstructure fiber geometries for dispersion compensation and large mode area (2005) Opt. Express, 13, pp. 627-635 Zhao, X., Zhou, G., Li, S., Liu, Z., Wei, D., Hou, Z., Hou, L., Photonic crystal fiber for dispersion compensation (2008) Appl. Opt., 47, pp. 5190-5196 Da Silva, J.P., Rodríguez-Esquerre, V.F., Bezerra, D.S., Iguatemi, F.E., Hernández-Figueroa, H.E., Ge-Doped Defect-Core Microstructured Fiber Design by Genetic Algorithm for Residual Dispersion Compensation (2010) IEEE Photonics Technology Letters, 22, pp. 1337-1339 Mores Jr., J.A., Malheiros-Silveira, G.N., Fragnito, H.L., Hernández- Figueroa, H.E., Efficient calculation of higher-order optical waveguide dispersion (2010) Opt. Express, 18, pp. 19522-19531 Koshiba, M., Tsuji, Y., Curvilinear Hybrid Edge/Nodal Elements with Triangular Shape for Guided-Wave Problems (2000) J. Lightwave Technol., 18, p. 737 Ramaswami, R., Sivarajan, K.N., (2002) Optical Networks: A Practical Perspective, , Academic Press Canning, J., Buckley, E., Lyytikainen, K., Multiple source generation using air-structured optical waveguides for optical field shaping and transformation within and beyond the waveguide (2003) Opt. Express, 11, pp. 347-358 Wang, J., Jiang, C., Hu, W., Gao, M., Properties of index-guided PCF with air-core (2007) Optics & Laser Technology, 39 (2), pp. 317-321. , March Saitoh, K., Florous, N., Koshiba, M., Ultraflattened chromatic dispersion controllability using a defected-core photonic crystal fiber with low confinement losses (2005) Opt. Express, 13, pp. 8365-8371 Wu, M., Huang, D., Liu, H., Tong, W., Broadband dispersion compensating fiber using index-guiding photonic crystal fiber with defected core (2008) Chin. Opt. Lett., 6, pp. 22-24 Nguyen, H.C., Kuhlmey, B.T., Steel, M.J., Smith, C.L., Mägi, E.C., McPhedran, R.C., Eggleton, B.J., Leakage of the fundamental mode in photonic crystal fiber tapers (2005) Opt. Lett., 30, pp. 1123-1125