Theoretical Analysis of Fiber Bragg Grating  Tunable Filter Utilizing Tensile /Compression Technique

Ayad Z. Mohammed; A. K. Abass; Samar K. Ibrahim; Wail Yass Nassir

doi:10.24237/djes.2018.11207

Authors

Ayad Z. Mohammed
140042@uotechnology.edu.iq
Department of Laser and Optoelectronics Engineering, University of Technology, Iraq
A. K. Abass Department of Laser and Optoelectronics Engineering, University of Technology, Iraq
Samar K. Ibrahim Department of Laser and Optoelectronics Engineering, University of Technology, Iraq
Wail Yass Nassir Department of Laser and Optoelectronics Engineering, University of Technology, Iraq

Keywords:

Fiber Bragg grating, tunable filter, tensile/compression technique

Abstract

In this paper a wideband tunable filter based on fiber Bragg grating (TF-FBG) utilizing tensile/ compression technique is theoretically investigated. According to the results, a wide tuning range is achieved about 48.36 nm in Cband region from 1513.7 nm to 1562.1 nm; 12.09 nm for tension and 36.27 nm for compression (C-band refers to the wavelength range 1530–1565 nm). While, for L-band region the wavelength shift is slightly greater than in the C-band region about 49.272 nm from 1543 nm to 1592.3 nm; 12.3 nm for tension and 36.972 nm for compression (Lband refers to the wavelength range 1565 –1625 nm).

Downloads

Download data is not yet available.

References

J. H. Ng, X. Zhou, X. Yang, and J. Hao, A simple temperature-insensitive fiber Bragg grating displacement sensor, Opt. Commun., 273, (2), (2007), 398–401.

J. A. S. Dias, R. L. Leite, and E. C. Ferreira, Electronic technique for temperature compensation of fibre Bragg gratings sensors, Int. J. Electron. Commun., 62, (1), (2008), 72–76.

M. Rosenberger, S. Hessler, S. Belle, B. Schmauss, and R. Hellmann, Compressive and tensile strain sensing using a polymer planar Bragg grating, Opt. Soc. Am., 22, (5), (2014), 5483–5490.

Z. Yu, Q. Jiang, H. Zhang, and J. Wang, Theoretical and experimental investigation of fiber Bragg gratings with different lengths for ultrasonic detection, Springerlink, 6, (2), (2016), 187–192.

R. A. Drainville and G. Das, Widely Tunable Fiber Bragg Grating and its Application in Fiber Lasers, Microw. Opt. Technol. Lett., 55, (12), (2013), 2824–2826.

L. Wang, J. Ren, H. Li, T. Zhao, Q. Xu, X. Changa, and L. Zhao, Fiber Bragg grating and its application in external cavity semiconductor laser, Opt. - Int. J. Light Electron Opt., 124, (19), (2013), 3816–3818.

S. Liaw, K. Hung, Y. Lin, C.-C. Chiang, and C.-S. Shin, C-band continuously tunable lasers using tunable fiber Bragg gratings, Opt. Laser Technol., 39, (6), (2007), 1214–1217.

M. Tang, Y. D. Gong, and P. Shum, Dynamic Properties of Double-Pass Discrete Raman Amplifier With FBG-Based All-Optical Gain Clamping Techniques, IEEE Photonics Technol. Lett., 16, (3), (2004), 768–770.

A. Iocco, H. G. Limberger, R. P. S. E, L. A. Everall, K. E. Chisholm, J. A. R. Williams, and I. Bennion, Bragg grating fast tunable filter for wavelength division multiplexing, J. Light. Technol., 17, (7), (1999), 1217–1221.

S. Y. Li, N. Q. Ngo, S. C. Tjin, P. Shum, and J. Zhang, Thermally tunable narrow-bandpass filter based on a linearly chirped fiber Bragg grating, Opt. Lett., 29, (1), (2004), 29–31.

L. Huang, P. Ma, R. Tao, C. Shi, X. Wang, and P. Zhou, Experimental investigation of thermal effects and PCT on FBGs-based linearly polarized fiber laser performance, Opt. Soc. Am., 23, (8), (2015), 10506–10520.

B. A. Ribeiro, M. M. Werneck, F. B. V. de Nazaré, and M. N. Gonçalves, A Bragg grating tunable filter based on temperature control system to demodulate a voltage sensor, in International Conference on Optical Fibre Sensors, 2015.

H. A. Fayed, M. Mahmoud, A. K. Aboulseoud, and M. H. Aly, “A Wide Range Tunable Fiber Bragg Grating Using Fast Changeable Electromagnetic Force,” in Photonics North, 7750, ( 77501R–1–10), (2010).

N. Mohammad, W. Szyszkowski, W. J. Zhang, E. I. Haddad, J. Zou, W. Jamroz, and R. Kruzelecky, “Analysis and development of a tunable fiber Bragg grating filter based on axial tension/compression,” J. Light. Technol., 22, (8), (2004), 2001–2013.

A. A. S. Falah, M. R. Mokhtar, Z. Yusoff, and M. Ibsen, Reconfigurable Phase-Shifted Fiber Bragg Grating Using Localized Micro-Strain, IEEE Photonics Technol. Lett., 28, (9), (2016), 951–954.

G. Chen, L. Liu, H. Jia, J. Yu, L. Xu, and W. Wang, Simultaneous pressure and temperature measurement using Hi-Bi fiber Bragg gratings, Opt. Commun., 228, (1–3), (2003), 99–105.

N. Mohammad, Analysis and Development of a Tunable Fiber Bragg Grating Filter Based on Axial Tension / Compression, 2005.