Bent-Bent Waveguide Coupling System
##plugins.themes.bootstrap3.article.main##
In this paper, the mechanism of energy transfer between two bent-bent waveguides is analyzed. Focus is done to the effect that some parameters like the refractive index of the substrate and the wavelength cause in the energy rate transfer between the waveguides. Results were validated by using the Finite Element Method (FEM).
References
-
João Torres, António Baptista, and Victor Maló Machado, “Coupling analysis in concentric ring waveguides”. Journal of lightwave technology 31.13: 2140-2145, 2013.
Google Scholar
1
-
R. Stoffer, K. R. Hiremath, and M. Hammer, “Comparison of Coupled Mode Theory and FDT Simulations Of Coupling between Bent and Straigth Optical Waveguides.” International School of Quantum Eletronics, 39yh Course: Erice, Italy, 18-25, Oct. 2004.
Google Scholar
2
-
K.R. Hiremath, R. Stoffer and M. Hammer, “Coupled Mode Theory and FDT Simulations of the Coupling Between Bent and Staigth Optical Waveguides”, Proceedings Symposium IEEE/Leos Benelux Chapter, 2003 [4] L. Djaloshinski and M. Orenstein, “Disk and Ring Microcavity Lasers and Their concentric Coupling”, IEEE J. Quantum Electronics, vol. 35, no. 5, pp. 737-744, May 1999.
Google Scholar
3
-
J. Ctyroký, I. Richter and M. Sinor, “Dual Resonance in a Waveguidecouple ring microresonator”, Springer Optical and Quantum Electronics, vol. 38, pp. 781-797, 2006.
Google Scholar
4
-
J. Torres, A. Baptista, V. M. Machado, “Analysis of dielectric ring slab waveguides with interband absortion”, EUROCON 2011 proceedings, Lisbon, 27-28 April 2011.
Google Scholar
5
-
J. Torres, A. Baptista, V. M. Machado, “Analysis of dielectric optical ring slab waveguides with a layred refractive index”, 18th Telecomunication Forum, TELFOR 2010 proceedings, Belgrade, Serbia, 23-25 Nov. 2010.
Google Scholar
6
-
J. Torres, A. Baptista, V. M- Machado, “Curvature Losses Of Slab Waveguides Using Analytical and FEM Analysis” ODEF10 Proceedings, Japan, 2010.
Google Scholar
7
-
E. A. Maracatili, “Bends in Optical Dielectric Guides”, The Bell System Technical Journal, pp. 2103-2160 Sept. 1969.
Google Scholar
8
-
D. Marcuse, “Bending losses of the Asymmetric Slab waveguide”, Bell System Technical Journal, vol. 50, no. 8, Oct. 1971
Google Scholar
9
-
M. Heiblum, J. H. Harris, “Analysis of Curved Optical Waveguides by Conformal Transformation”, IEEE J. Quantum Electronics, vol. QE-11, no. 2 Feb. 1975.
Google Scholar
10
-
K. R. Hiremath, M. Hammer, R. Stoffer, L. Prkna and J. Ctyroky, “Analytic approach to dielectric bent slab waveguides”, Springer Optical and Quantum Electronics, vo. 37, pp. 37-61, 2005.
Google Scholar
11
-
T. Yamamoto and M. Koshiba, “Numerical Analysis of Curvature Loss in Optical Waveguides by the Finite-Element Method”, vol. 11, no. 10, pp. 1579-1583, Oct. 1993.
Google Scholar
12
-
D. Marcuse, The coupling of degenerate modes in tow parallel dielectric waveguides, The Bell System Technical Journal, vol. 50, no. 6, pp. 1791-1815, July-August 1971.
Google Scholar
13
-
A. Hardy and W. Streifer, “Coupled Mode Theory of Parallel Waveguides”, IEEE, J. Ligthwave Tecnhology, vol. LT-3, no. 5, pp. 1135-1146, Oct 1985.
Google Scholar
14
-
H. A. Haus, W. P. Haung, S. Kawakami and N. A. Whitaker, “CoupledMode Theory of Optical Waveguides”, IEEE J. Ligthwave Tecnhology, vol. LT-5, no. 1, pp. 16-23, Jan 1987.
Google Scholar
15
-
B. E Little and W. P. Huang, “Coupled-mode theory for optical waveguides”, Progress In Electromagnetics Research, Pier 10, pp. 217- 270, 1995.
Google Scholar
16
-
H. A. Haus, “Waves and Fields in Optoelectronics”, Prentice-Hall Series in Solid State Physical Electronics, Nick Holopvak Jr. Editor.
Google Scholar
17
-
A. Yariv, “Critical Coupling and Its Control Optical Waveguide- Ring Resonator Systems”, vol. 14, no. 4, April 2002.
Google Scholar
18
-
M. A. McHenry and D. C. Chang, “Coupled Mode Theory of Tow Non-parallel Dielectric Waveguides”, Scientific Report no. 73 Electromagnetics Laboratory Department of Electrical Engineering University of Colorado Boulder, Colorado.
Google Scholar
19
-
R. A. Marques Lameirinhas, J. P. N. Torres and A. Baptista, “The Influence of Structure Parameters on Nanoantennas’ Optical Response”. Chemosensors, 8, 42, 2020.
Google Scholar
20
-
R. A. Marques Lameirinhas, J. P. N. Torres and A. Baptista, “Sensors Based on Nanoantennas: Fundamentals”. European Journal of Applied Physics, 2, 3, 2020.
Google Scholar
21
-
R. A. Marques Lameirinhas, J. P. N. Torres and A. Baptista, “A Sensor Based on Nanoantennas”. Applied Sciences 10.19: 6837, 2020.
Google Scholar
22
-
T. Bonnal, et al, “How to determine the complex refractive index from infrared reflectance spectroscopy?”. SN Applied Sciences 2.12: 1-9, 2020.
Google Scholar
23
-
Joao Paulo N. Torres, V. Machado, and Antonio Baptista, “A New Hybrid Finite Element Method: Electromagnetic Propagation in Bent Waveguides”. IPhoJ 12.1: 2966256, 2020.
Google Scholar
24
Most read articles by the same author(s)
-
Ricardo A. Marques Lameirinhas,
João Paulo N. Torres,
António Baptista,
Sensors Based on Nanoantennas: Fundamentals , European Journal of Applied Physics: Vol. 2 No. 3 (2020) -
André Ferreira,
João Torres,
Maria Martins,
Antonio Baptista,
Tactical Communications between Military Vehicles , European Journal of Applied Physics: Vol. 3 No. 1 (2021) -
João Paulo N. Torres,
Carlos A. F. Fernandes,
Ricardo A. Marques Lameirinhas,
Numerical Analysis of Dielectric Optical Waveguides , European Journal of Applied Physics: Vol. 3 No. 1 (2021)