10 Gbps CPFSK FSO system under various adverse atmospheric conditions: performance analysis

被引:0
作者
A. R. Palanisamy
K. C. Ramya
J. Roopa Jayasingh
R. Maheswar
P. Roshini
Moustafa H. Aly
机构
[1] Park College of Technology,Department of ECE
[2] Sri Krishna College of Engineering and Technology,Department of EEE
[3] Karunya Institute of Technology and Sciences,Department of ECE
[4] KPR Institute of Engineering and Technology,Department of ECE, Centre for IoT and AI (CITI)
[5] Society for Applied Microwave Electronics and Engineering Research (SAMEER) - Centre for Electromagnetics,Depatrment of Electronics and Communications Engineering
[6] Arab Academy for Science,undefined
[7] Technology,undefined
[8] and Maritime Transport,undefined
来源
Optical and Quantum Electronics | 2023年 / 55卷
关键词
CPFSK; FSO; BER; Maximum Q-factor; Received power; Beam divergence;
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学科分类号
摘要
A 10 Gbps Continuous Phase Frequency Shift Keying (CPFSK) modulation is proposed for a Free Space Optical (FSO) communication system. The system performance is analyzed by considering effects of atmospheric conditions, beam divergence, transmitter and receiver antenna aperture diameters for 1550 nm operation. In this paper, we evaluate the system maximum Quality-factor (Q-factor), Bit Error Rate (BER), and received power, where the system is greatly affected by th e mentioned parameters. This simulation is performed by using the Optiwave system software. The obtained simulation results show that CPFSK modulated FSO system with low beam divergence and high aperture diameter is upgrading maximum Q-factor and degrading minimum BER.
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  • [1] Abou-Rjeily C(2011)On the optimality of the selection transmit diversity for MIMO-FSO links with feedback IEEE Commun. Lett. 15 641-643
  • [2] Abtahi M(2006)Suppression of turbulence-induced scintillation in free-space optical communication systems using saturated optical amplifiers J. Lightwave Technol. 24 4966-4973
  • [3] Lemieux P(2011)Performance analysis of free space terrestrial optical system in the presence of absorption, scattering and pointing error J. Opt. Eng. 50 075007-200
  • [4] Mathlouthi W(2003)Understanding the performance of free-space optics J. Opt. Netw. 2 178-1730
  • [5] Rusch LA(2006)Analysis of the performance of a wireless optical multi-input to multi-output communication system J. Opt. Soc. Am. A23 1722-3973
  • [6] Abushagur AG(2021)Design of 320 gbps hybrid AMI-PDM-WDM FSO link and its performance comparison with traditional models under diverse weather conditions J. Opt. Commun. 124 3969-37
  • [7] Abbou FM(2013)Optimization of free space optics parameters: an optimum solution for bad weather conditions Optik 4214 26-498
  • [8] Abdullah M(2001)Comparison of laser beam propagation at 785 nm and 1550 nm in fog and haze for optical wireless communications Proc. SPIE 53 076105-35
  • [9] Misran N(2014)Performance analysis of free-space optical systems employing binary polarization shift keying signaling over gamma-gamma channel with pointing errors Opt. Eng. 57 492-1697
  • [10] Bloom S(2009)Free-space optics optimization models for building sway and atmospheric interference using variable wavelength Fiber Integr. Opt. 6 28-218
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