Fiber Communication System Based on FBG As Dispersion Compensator, Design And Experimental Setup
Keywords:Fiber Bragg Gratings, Dispersion Compensation, Wavelength Division Multiplexing, Fiber Bragg Grating Applications.
The technological progress in the means of transmission of information is very fast and it becomes necessary to obtain high speed in data transmission and high data rate. The developments in optical communication systems cover these needs, so the developments in these systems become an urgent need. However, despite all characteristics and advantages of optical communication systems, there is the dis-persion problem. In this research we will get rid of this problem in practice through the use of fiber Bragg grating connected to two separate and different wavelengths then connecting them to the Wavelength Division Multiplexing and send them to a distance of 3 Km then calculate the amount of dispersion in the signal with and without fiber Bragg grating and compare the results.
 Sharma V., and Kaur D., â€œReview on Multiplexing Techniques in Optical Communication Systemsâ€ European Scientific Journal, Vol.2 ISSN: 1857 â€“ 7881, (2015), pp.88-94.
 P1 G., and Thomas S., â€œPerformance Analysis of Dispersion Compensation using FBG and DCF in WDM Systemsâ€, International Journal of Advanced Research in Computer and Communication Engineering, Vol. 4, (2015),Issue 10.
 Watanabe Sh., Kato T., Okabe R., Elschner R.; Ludwig R., and Schubert C., â€œALL-Optical Data Frequency Multiplexing on single-wavelength carrier Light by Sequentially Provided Cross-Phase Modulation in Fiber.â€ IEEE journal of Selected Topics in Quantum Electronics, Vol. 18, No. 2, (2012), pp.577-584. https://doi.org/10.1109/JSTQE.2011.2111358.
 Arora O., and Garg A., â€œImpact of Fiber Bragg Grating as Dispersion Compensator on the Receiver Characteristicsâ€, Global Journal of Researches in Engineering Electrical and Electronics Engineering, Vol.11, (2011), 19-23.
 Hill K. and Meltz G., â€œFiber Bragg grating technology: Fundamentals and overview,â€ J. Light w. Technol., vol. 15, no. 8 (1997), pp. 1263â€“1276, Erdogan T., â€œFiber grating spectra,â€ J. Light w. Technol., vol. 15, no. 8, (1997), pp. 1277â€“1294.
 Prasad B., Patra K., Barpanda K.,â€ Performance Analysis of Fiber Optical Communication using Fiber Bragg Grating as Dispersion Compensatorâ€, International Journal of Advanced Research Electrical,Electronics and Instrumentation Engineering ,Vol. 5, (2016) Issue 4.
 Oâ€™Flaherty F.J., Ghassemlooy Z., Mangat P., and Dowker K. â€œTemperature Characterization of Long-Period Gratings for Sensor Applicationsâ€ Microwave & Optical Technology Letters, vol. 42, no. 5, (2004) pp. 402-405. https://doi.org/10.1002/mop.20317.
 Jopson R. â€œCompensation of fiber chromatic dispersion by spectral inversionâ€, Electron. Lett, Vol.29, (1993) pp.576- 578. https://doi.org/10.1049/el:19930387.
 Nishide K. â€œ1.55 Âµm Single Mode Fibers with Large Chromatic Dispersionâ€, IEICE spring conference, C-575, (1989).
 WÃ³jcik, W., KisaÅ‚a P., Yussupova P., Kussambayeva N., Kashaganova G. and Harasim D. , â€œAnalysis of the Possibilities for Using a Uniform Bragg Grating in a Tunable Dispersion Compensatorâ€, Intl Journal Of Electronics And Telecommunications, Vol. 61, No. 4, (2015) Pp. 381-387 https://doi.org/10.2478/eletel-2015-0050.