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Role of Wavelength Division Multiplexing Scheme in Free Space Optical Communication Systems

by Bindu Sharma, Veena Kumari Thapa, Abhishek Sharma
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International Journal of Computer Applications
Foundation of Computer Science (FCS), NY, USA
Volume 178 - Number 28
Year of Publication: 2019
Authors: Bindu Sharma, Veena Kumari Thapa, Abhishek Sharma
10.5120/ijca2019919103

Bindu Sharma, Veena Kumari Thapa, Abhishek Sharma . Role of Wavelength Division Multiplexing Scheme in Free Space Optical Communication Systems. International Journal of Computer Applications. 178, 28 ( Jun 2019), 10-14. DOI=10.5120/ijca2019919103

@article{ 10.5120/ijca2019919103,
author = { Bindu Sharma, Veena Kumari Thapa, Abhishek Sharma },
title = { Role of Wavelength Division Multiplexing Scheme in Free Space Optical Communication Systems },
journal = { International Journal of Computer Applications },
issue_date = { Jun 2019 },
volume = { 178 },
number = { 28 },
month = { Jun },
year = { 2019 },
issn = { 0975-8887 },
pages = { 10-14 },
numpages = {9},
url = { https://ijcaonline.org/archives/volume178/number28/30712-2019919103/ },
doi = { 10.5120/ijca2019919103 },
publisher = {Foundation of Computer Science (FCS), NY, USA},
address = {New York, USA}
}
%0 Journal Article
%1 2024-02-07T00:51:40.057710+05:30
%A Bindu Sharma
%A Veena Kumari Thapa
%A Abhishek Sharma
%T Role of Wavelength Division Multiplexing Scheme in Free Space Optical Communication Systems
%J International Journal of Computer Applications
%@ 0975-8887
%V 178
%N 28
%P 10-14
%D 2019
%I Foundation of Computer Science (FCS), NY, USA
Abstract

Swift demand of data rate supporting advanced number of end consumers at high speed has steered researchers to harvest Free Space Optics (FSO). This work is focused on engaging 2 × 10 Gbps return-zero (RZ) encoded wavelength-division (WDM) multiplexed Free Space Optics Communication system. The signal received is analyzed using BER analyzer and Eye diagrams

References
  1. Olivier Bouchet, Hervé Sizun, Christian Boisrobert, Frédérique de Fornel, Pierre-Noël Favennec, Free-Space Optics: Propagation and Communication, Wiley-ISTE, ISBN: 978-0-470-39441-0 (2010) 1-219.
  2. J. He, R.A. Norwood, M.B. Pearce, I.B. Djordjevic, M. Cvjetic, S. Subramaniam, R. Himmelhuber, C. Reynolds, P. Blanche, B. Lynn, N. Peyghambarian, A survey on recent advances in optical communications, Comput. Electr. Eng. 40 (2014) 216–240.
  3. M. Khalighi and M. Uysal, Survey on Free Space Optical Communication, A Communication Theory Perspective,” IEEE Commun. Surveys & Tutorials 16 (2014) 2231–58.
  4. K. Kazaura et al., Experimental Demonstration of Next-Generation FSO Communication System, Optics East 2006, Int’l. Society for Optics and Photonics, (2006) 63 900–63 912.
  5. Sushank Chaudhary, Angela Amphawan, Kashif Nisar, Realization of free space optics with OFDM under atmospheric turbulence, Optik-International Journal for Light and Electron Optics 125 (2014) 5196-5198.
  6. Wei Liu, Wenxiao Shi, Jingtai Cao, Yaowen Lv, Kainan Yao, Shuai Wang, Jihong Wang, Xuefen Chi, Bit error rate analysis with real-time pointing errors correction in free space optical communication systems, Optik - International Journal for Light and Electron Optics 125 (2014) 324-328.
  7. Flohberger, M, Gappmair and Koudelka, W., Error performance of coded FSO links in Turbulent atmosphere modeled by Gamma Gamma distribution, IEEE Transactions on wireless communications 8 (2009) 2209 – 2213.
  8. E. Lee and V. Chan, Part 1: Optical communication over the clear turbulent atmospheric channel using diversity, IEEE Journal on Selected Areas in Communications 22 (2004) 1896–1906.
  9. T. Tsiftsis, H. Sandalidis, G. Karagiannidis, and M. Uysal, Optical wireless links with spatial diversity over strong atmospheric turbulence channels, IEEE Transactions on Communications 8 (2009) 951–957.
  10. Mohammad Abtahi, Suppression of Turbulence-Induced Scintillation in Free-Space Optical Communication Systems Using Saturated Optical Amplifiers, IEEE 24 (2007) 4966 – 4973.
  11. Sandalidis Harilaos G., Coded Free space optical links over strong turbulence and misalignme Fading channels, IEEE 59 (2011) 1389-1399.
  12. Chaudhary S, Amphawan A. The role and challenges of free space optical systems. J Opt Commun. 2014;35:327–34.
  13. Chaudhary S, Amphawan A, Nisar K. Realization of free space optics with OFDM under atmospheric turbulence. Optik Int J Light Electron Optics. 2014;125:5196–8.
  14. Chaudhary S, Sharma A. 6 x 20 Gbps long reach WDM-PI based high altitude platform inter-satellite communication system. Int J Comput Appl. 2015;122:22.
  15. Chaudhary S, Sharma A, Chaudhary N. 6 × 20 Gbps hybrid WDM–PI inter-satellite system under the influence of transmitting pointing errors. J Opt Commun. 2016;37:375–9.
  16. Sharma A, Chaudhary S, Thakur D, Dhasratan V. A cost-effective high-speed radio over fibre system for millimeter wave applications. J Opt Commun. Published Online 15 December 2017. DOI:10.1515/joc-2017-0166.
  17. Chaudhary S, Chauhan P, Sharma A. High speed 4 × 2.5 Gbps-5 GHz AMI-WDM-RoF transmission system for WLANs. J Opt Commun. Published Online 18 July 2017. DOI:10.1515/joc-2017-0082.
  18. Chaudhary S, Thakur D, Sharma A. 10 Gbps-60 GHz RoF transmission system for 5G applications. J Opt Commun. Published Online 22 July 2017. DOI:10.1515/joc-2017-0079.
  19. Kapoor R, Sharma A, Chaudhary S. Empirical evaluation of 4 QAM and 4 PSK in OFDM-based inter-satellite communication system. J Opt Commun. Published Online 29 June 2017. DOI:10.1515/joc-2017-0059.
  20. Sharma A. Neetu, analysis and mitigation of receiver pointing error angle on inter-satellite communication. Int J Innov Tech Res. 2015 Nov;3:2540–44.
  21. Chaudhary S, Sharma A. Neetu, “6 x 20 Gbps long reach WDMPI based high altitude platform inter-satellite communication system. Int J Comput Appl. 2015 July;122:41–5.
  22. Rana S, Sharma A. Comprehensive study of radio over fiber with different modulation techniques – a review. Int J Comput Appl. 2017 Aug;170:22–5. DOI:10.5120/ijca2017914829.
  23. Sharma A, Thakur D. A review on wlans with radio-over-fiber technology. Int J Electron Commun Eng. 2017 Aug;6:1–6.
  24. Thakur K, Sharma A. Comparison of MDRZ, CSRZ and DRZ schemes using different communiation channels. Int J Comput Appl. 2017 Aug. DOI:10.5120/ijca2017915106.
  25. Thakur K, Sharma A. Study of radio over fiber with different coding channel – a review. Int J Comput Appl. 2017 Aug. DOI:10.5120/ijca2017915033.
  26. Sharma A, Chauhan P. A study of radio over fiber technology in WLAN applications. Int J Res Appl Sci Eng Technol. 2017 August;5:416–20.
  27. Sharma A, Kapoor R. Study of various challenges in is OWC: a review. Int J Res Appl Sci Eng Technol. 2017 August;5:802–07.
  28. Sharma A, Rana S. Implementation of radio over fiber technology with different filtration techniques. Int J Res Appl Sci Eng Technol. 2017 August;5:783–89.
  29. Sharma A, Chauhan P. High speed radio over fiber system for wireless local area networks by incorporating alternate mark inversion scheme. J Opt Commun. 2018. DOI:10.1515/joc-2018-0084.
  30. Amphawan A, Chaudhary S, Free-space optical mode division multiplexing for switching between millimeter-wave picocells, In: International Conference on Optical and Photonic Engineering (icOPEN2015), 2015: 95242H-95242H-6.
  31. Amphawan A, Chaudhary S, Chan V. 2 × 20 Gbps-40 GHz OFDM Ro-FSO transmission with mode division multiplexing. J Eur Opt Soc Rapid Publ. 2014;9:14041 (1–6).
  32. Amphawan A, Chaudhary S, Din R, Omar MN, “5 Gbps HG 0, 1 and HG 0, 3 optical mode division multiplexing for RoFSO,” in signal processing & its applications (CSPA), 2015. IEEE 11th International Colloquium on, 2015:145–9.
  33. Amphawan A, Chaudhary S, Elfouly T, Abualsaud K. Optical mode division multiplexing for secure Ro-FSO WLANs. Adv Sci Lett. 2015;21:3046–9.
  34. Bansal U, Kaur K, Chaudhary S. Role of laser linewidth in high speed DWDM system by incorporating duobinary modulation scheme. Int J Comput Appl. 2015;109:30–2.
  35. Chaudhary S, Amphawan A. High-speed millimeter communication through radio-over-free-space-optics network by mode division multiplexing. Opt Eng. 2017;56:116112.
  36. Chaudhary S, Bansal P, Lumb M. Effect of beam divergence on WDM-FSO transmission system. Int J Comput Appl. 2014;93:28–32.
  37. Chaudhary S, Bansal P, Singh G. Implementation of FSO network under the impact of atmospheric turbulences. Int J Comput Appl. 2013;75:34–8.
  38. Chaudhary S, Chaudhary N, Sharma S, Choudhary B. High speed inter-satellite communication system by incorporating hybrid polarization-wavelength division multiplexing scheme. J Opt Commun. 2017;39:87–92.
  39. Chaudhary S, Sharma S. Role of turbulences in WDM-polarization interleaving scheme based inter-satellite communication system. Int J Comput Appl. 2014;104:1–7.
  40. Kaur P, Kaur R, Chaudhary S. Implementation of high speed long reach hybrid radio over multimode transmission system. Int J Comput Appl. 2014;91:42–7.
  41. Kaur R, Chaudhary S. Simulative investigation of laser line-width and channel spacing for realization of DWDM systems under the impact of four wave mixing. J Opt Commun. 2014;35:157–65.
  42. Sharma V. High speed CO-OFDM-FSO transmission system. Optik Int J Light Electron Optics. 2014;125:1761–3.
  43. Sharma V, Chaudhary S. Implementation of hybrid OFDM-FSO transmission system. Int J Comput Appl. 2012;58:37–40.
  44. Sharma V, Kumar S. Empirical evaluation of wired-and wireless hybrid OFDM–OSSB–RoF transmission system. Optik Int J Light Electron Optics. 2013;124:4529–32.
  45. Amphawan A, Chaudhary S, Neo T-K. Hermite-Gaussian mode division multiplexing for free-space optical interconnects. Adv Sci Lett. 2015;21:3050–53.
  46. Upadhyay KK, Srivastava S, Shukla N, Chaudhary S. High-speed 120 Gbps AMI-WDM-PDM free space optical transmission system. J Opt Commun. 2017.
  47. Chaudhary S, Lin B, Tang X, Wei X, Zhou Z, Lin C, et al. 40 Gbps–80 GHz PSKMDM based RoFSO transmission system. Opt Quant Electron. 2018;50:321. Doi:10.1007/s11082-018-1592-z.
  48. Chaudhary S, Amphawan A. High speed MDM-Ro-FSO communication system by incorporating AMI scheme. Int J Electron Lett. OI:10.1080/21681724.2018.1494318.
Index Terms

Computer Science
Information Sciences

Keywords

RZ WDM BER Eye Diagram

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