Free Space Optical Communication System under Different Weather Conditions
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Mohammad Yawar Wani
und
Anil Kumar
Abstract
Free space optical communication systems (FSO’s) have surfaced as admired means of communication in the past few years. High speed of operation, low bandwidth requirements and system reliability are the major factors responsible for their wide range of applications. These communication systems use air as a medium of transmission. Since there is no component like fiber or cable, but air is only medium, the variations in atmospheric conditions play a vital role in performance of these networks. The reason behind is that the conditions like presence of humidity, haze, snowfall, rain, dust or smoke changes the attenuation coefficient of medium. The raised attenuation levels results in increased losses and need to be carefully monitored. The present work analyzes the influence of rain on the performance of FSO network in terms of quality of transmission. The paper discusses the impact of rainfall on attenuation coefficient of air. Then impact of this attenuation on network transmission is presented in terms of BER and Q-factor. In order to demonstrate the impact, BER and Q-value is calculated for 10 Gbps FSO link for clear weather and rainfall conditions.
References
1. Kolka Z, Wilfert O, Kvicala R, Fiser O. Complex model of terrestrial FSO links. Proc SPIE. 2007;6709:67091 j.10.1117/12.732421Suche in Google Scholar
2. Davis CC, Smolyaninov II. Effect of atmospheric turbulence on bit-error rate in an on-off-keyed optical wireless system. Proc SPIE. 2002;4489:126–37.10.1117/12.453236Suche in Google Scholar
3. Kaur K, Singh H. Analysis of single-mode fiber link performance for attenuation in long-haul optical networks. J Opt Commun. 2017;38:27–32.10.1515/joc-2016-0027Suche in Google Scholar
4. Ijaz M, Ghassemlooy Z, Pesek J, Fiser O, Le Minh H, Bentley E. Demonstrating of mist and smoke constriction in free space optical correspondences connect under controlled research facility conditions. J Lightwave Technol. 2013;31:1720–6.10.1109/JLT.2013.2257683Suche in Google Scholar
5. Ghassemlooy Z, Perez J, Leitgeb E. On the execution of FSO interchanges interfaces under dust storm conditions. In: Procedures of the twelfth International Conference on Telecommunications (ConTEL ‘13), IEEE, Zagreb, Croatia, June 2013:53–8.Suche in Google Scholar
6. Rammprasath K, Ruler S. Breaking down the cloud weakening on the execution of free space optical correspondence. In: Proceedings of the second International Conference on Correspondence and Signal Processing (ICCSP‘13), Melmaruvathur, India, April 2013:791–4.Suche in Google Scholar
7. Al-Gailani SA, Mohammad AB, Shaddad RQ, Jamaludin MY. Single and multiple handset simulation modules for nothing space optical direct in tropical Malaysian climate. In: Proceedings of the IEEE Business Engineering and Industrial Applications Colloquium (BEIAC‘13), Langkawi, Malaysia, April 2013:613–16.10.1109/BEIAC.2013.6560203Suche in Google Scholar
8. Rahman AK, Anuar MS, Aljunid SA, Junita MN. Investigation of rain constriction result in free space optic transmission. In: Proceedings of the 2nd Malaysia Conference on Photonics Telecommunication Technologies (NCTT-MCP‘08), IEEE, Putrajaya, Malaysia, August 2008:64–70.10.1109/NCTT.2008.4814239Suche in Google Scholar
9. Suriza AZ, Rafiqul IM, Wajdi AK, Naji AW. Impacts of rain force minor departure from rain weakening forecast for Free Space Optics (FSO) joins. In: Proceedings of the International Meeting on Computer and Communication Engineering (ICCCE‘12), IEEE, Kuala Lumpur, Malaysia, July 2012:680–5.Suche in Google Scholar
10. International Station Meteorological Climate Summary. Ver. 4.0, Federal Climate Complex Asheville, 1996.Suche in Google Scholar
11. Kim I, Korevaar E. Availability of Free Space Optics (FSO) and Hybrid FSO/RF systems In: Proc. SPIE Optical Wireless Communication IV, Vol. 530, Denver, CO, August 21–22, 2001:84–95.10.1117/12.449800Suche in Google Scholar
12. Willebrand H, Ghuman SB. Free-space optics: Enabling optical connectivity in today’s network, Sams Publishing, Indiana, USA, 2002.Suche in Google Scholar
13. Fadhil HA, Amphawan A, Shamsuddin HAB, Hussein Abd T, Al-Khafaji HMR, Aljunid SA, Ahmed N. Optimization of free space optics parameters: an optimum solution for bad weather conditions In: G Model Ijleo-52845© 2013 Elsevier Gmbh.10.1016/j.ijleo.2012.11.059Suche in Google Scholar
© 2019 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- Amplifiers
- Unified Formalism for Erbium-Doped Fiber Amplifiers and Lasers
- Nonlinear Effects with Semiconductor Optical Amplifiers
- Average Power Model of Optical Raman Amplifiers Based on Frequency Spacing and Amplifier Section Stage Optimization
- Devices
- An Optical Half Adder Using Nonlinear Ring Resonator Based on Photonic Crystal
- Implementation of Polarization-Encoded Quantum Fredkin Gate Using Kerr Effect
- Lasers
- Spatial Continuous Wave Laser and Spatiotemporal VCSEL for High-Speed Long Haul Optical Wireless Communication Channels
- Measurements
- Graphene Oxide Effect on Improvement of Silver Surface Plasmon Resonance D-Shaped Optical Fiber Sensor
- Networks
- High-Speed Light Sources in High-Speed Optical Passive Local Area Communication Networks
- RSVP-TE Bilateral-Recursive Region Re-Routing Crankback Mechanism for Large-Scale Optical Networks
- An Intelligent Vehicle Control System for Enhancing Road Safety Using Optimal Visible Light Communication Network
- Systems
- Design and Parameter Analysis of Underwater Wireless Optical Communication with Different Water Samples
- Free Space Optical Communication System under Different Weather Conditions
- Windowing Techniques for Reducing PAPR of OFDM in Li-Fi Systems
- Effects of Order Super Gaussian Pulses on the Performance of High Data Rate Optical Fiber Channel in the Presence of Self Phase Modulation
- Evaluation of Proposed Coherent Optical OFDM Link Using X-QAM with Polarization Division Multiplexing
- Theory
- Mathematical Model Analysis of Dispersion and Loss in Photonic Crystal Fibers
- Simulation of Optical ISL with 48 Transponders and Performance Analysis Using Ber and Q-Factor
Artikel in diesem Heft
- Frontmatter
- Amplifiers
- Unified Formalism for Erbium-Doped Fiber Amplifiers and Lasers
- Nonlinear Effects with Semiconductor Optical Amplifiers
- Average Power Model of Optical Raman Amplifiers Based on Frequency Spacing and Amplifier Section Stage Optimization
- Devices
- An Optical Half Adder Using Nonlinear Ring Resonator Based on Photonic Crystal
- Implementation of Polarization-Encoded Quantum Fredkin Gate Using Kerr Effect
- Lasers
- Spatial Continuous Wave Laser and Spatiotemporal VCSEL for High-Speed Long Haul Optical Wireless Communication Channels
- Measurements
- Graphene Oxide Effect on Improvement of Silver Surface Plasmon Resonance D-Shaped Optical Fiber Sensor
- Networks
- High-Speed Light Sources in High-Speed Optical Passive Local Area Communication Networks
- RSVP-TE Bilateral-Recursive Region Re-Routing Crankback Mechanism for Large-Scale Optical Networks
- An Intelligent Vehicle Control System for Enhancing Road Safety Using Optimal Visible Light Communication Network
- Systems
- Design and Parameter Analysis of Underwater Wireless Optical Communication with Different Water Samples
- Free Space Optical Communication System under Different Weather Conditions
- Windowing Techniques for Reducing PAPR of OFDM in Li-Fi Systems
- Effects of Order Super Gaussian Pulses on the Performance of High Data Rate Optical Fiber Channel in the Presence of Self Phase Modulation
- Evaluation of Proposed Coherent Optical OFDM Link Using X-QAM with Polarization Division Multiplexing
- Theory
- Mathematical Model Analysis of Dispersion and Loss in Photonic Crystal Fibers
- Simulation of Optical ISL with 48 Transponders and Performance Analysis Using Ber and Q-Factor
