Preferences help
enabled [disable] Abstract
Number of results
2019 | 137 | 42-57
Article title

Investigation of Performance for a Two Regions Superstructure Fiber Bragg Grating

Title variants
Languages of publication
A Superstructure Fiber Bragg Grating (SFBG) with a two grating regions has been studied experimentally and analytically. Both transmitted and reflected spectra for SFBG were investigated in a constant temperature (room temperature). Data that archived by Spectrometer & Detector was analyzed. In the same circumstances, a set of equations considered to simulate the experimental configuration. The SFBG spectrum characterized by important parameters: Bragg wavelength, bandwidth and efficiency. Bragg wavelength is very popular and has been used by the researchers to determine the physical quantities, it represent the reflected wavelength which satisfy Bragg condition. The behavior of these spectral parameters are presented and studied in this paper. The effect of grating region on the bandwidth and efficiency of SFBG was also studied. The SFBG has been found worked as a filter for the laser source wavelengths, which is used. Furthermore, this special FBG can be developed to optimize a sensor for temperature and pressure.
Physical description
  • Department of Physics, College of Sciences, University of Al-Nahrain, Jaddereah District, Baghdad, Iraq
  • Department of Physics, College of Education, Mustansiriyah University, Mustansiriyah District, Baghdad, Iraq
  • Department of Physics, College of Sciences, University of Al-Nahrain, Jaddereah District, Baghdad, Iraq
  • [1] L. Bundalo, Fiber Bragg Grating and Long Period Grating Sensors in Polymer Optical Fibers. Ph.D. thesis, Department of Photonics Engineering Technical University of Denmark, (2017), 133.
  • [2] S. Dewra, Vikas and A. Grover, Fabrication and Applications of Fiber Bragg Grating. Advanced Engineering Technology and Application, 4(2) (2015) 15-25.
  • [3] K. O. Hill and G. Meltz, Fiber Bragg Grating Technology Fundamentals and Overview. Journal of Lightwave Technology IEEE 15(8) (1997) 1263-1276.
  • [4] M. B. El-Mashade, Analysis of Weak and Strong Fiber Bragg Grating. British Journal of Applied Science & Technology 6 (2015) 1-17.
  • [5] Fiber Gratings: Basic Theory and Sensing Principle. Chapter 2.
  • [6] K. T.V. Grattan & B. T. Meggitt, Optical Fiber, Sensor Technology, Advanced Applications -Bragg Gratings and Distributed Sensors. e-book Edited by Springer Science Business Media New York (2000).
  • [7] M. Celikin D. Barba, B. Bastola, A. Ruediger and F. Rosei, Development of regenerated fiber Bragg grating sensors with long-term stability. Optics Express 24(19) (2016) 21897-21909.
  • [8] A. Z. Mohammed, A. K. Abass S. K. Ibrahim, Wail Yass Nassir, Theoretical Analysis of Fiber Bragg Grating Tunable Filter Utilizing Tensile /Compression Technique. Diyala Journal of Engineering Sciences 11(2) (2018) 55-59.
  • [9] C. E. Campanella, A. Cuccovillo, C. Campanella, A. Yurt and V. M. N. Passaro, fiber Bragg Grating Based Strain Sensors: Review of Technology and Applications. Sensors 18 (2018) 27.
  • [10] M. M. Werneck Regina, C. S. B. Allil, B. A. Ribeiro and F. V. B. de Nazare, A Guide to Fiber Bragg Grating Sensors. Chapter 1. InTech Open, Croatia (2013).
  • [11] S. C. Chapra, Applied Numerical Methods with MATLAB for Engineers and Scientists. Third Edition McGraw-Hill (2012).
  • [12] Chapter 4, Efficiency of Energy Conversion. (1995) 53-76.
  • [13] B. DeVarney, W. Bahnzaf, and W. Silver. A Tutorial on the Decibel. Rexburg Hams 1-6.
  • [14] G. Pereira M. McGugan, L.P. Mikkelsen, FBG SiMul V1.0: Fibre Bragg grating signal simulation tool for finite element method models. SoftwareX Volume 5, 2016, Pages 163-170
  • [15] A-Ping Zhang ; Bai-Ou Guan ; Xiao-Ming Tao ; Hwa-Yaw Tam Mode couplings in superstructure fiber Bragg gratings. IEEE Photonics Technology Letters Volume: 14, Issue: 4, April 2002, 489-491
  • [16] B. J. Eggleton, P. A. Krug, L. Poladian, F. Ouellette, Long periodic superstructure Bragg gratings in optical fibers, Electron. Lett. vol. 30, no. 19, pp. 1620-1622, Sept. 1994
  • [17] Xiang-Kai Zeng, Application of Fourier Mode Coupling Theory to Real-Time Analyses of Nonuniform Bragg Gratings, Photonics Technology Letters IEEE, vol. 23, no. 13, pp. 854-856, 2011.
  • [18] Somnath Sengupta, Swapan Kumar Ghorai, Palas Biswas, "Design of Superstructure Fiber Bragg Grating With Efficient Mode Coupling for Simultaneous Strain and Temperature Measurement With Low Cross-Sensitivity, Sensors Journal IEEE, vol. 16, no. 22, pp. 7941-7949, 2016
  • [19] Ming-Yue Fu, Chia-Min Lin, Wen-Fung Liu, Lung Ai, The induced cladding modes of a superstructure fiber grating, Optical Fiber Technology, vol. 14, pp. 16, 2008.
  • [20] Yue-Jing He, Wei-Chih Hung, Zhe-Ping Lai, Using Finite Element and Eigenmode Expansion Methods to Investigate the Periodic and Spectral Characteristic of Superstructure Fiber Bragg Gratings, Sensors, vol. 16, pp. 192, 2016.
  • [21] Bao Yang, Su Liu, Xi Wang, Rong Yin, Ying Xiong, Xiaoming Tao, Highly Sensitive and Durable Structured Fibre Sensors for Low-Pressure Measurement in Smart Skin, Sensors, vol. 19, pp. 1811, 2019.
  • [22] Zhengyong Liu, Zhi Feng Zhang, Hwa-Yaw Tam, Xiaoming Tao, Multifunctional Smart Optical Fibers: Materials Fabrication and Sensing Applications, Photonics, vol. 6, pp. 48, 2019.
Document Type
Publication order reference
YADDA identifier
JavaScript is turned off in your web browser. Turn it on to take full advantage of this site, then refresh the page.