Performance analysis of a 400-Gbps DWDM-FSO system using advanced modulation formats and under adverse weather conditions

• Published in: Discover sustainability Vol. 5; no. 1; pp. 301 - 16
• Main Authors: Obaid, Hafiz Muhammad, Javaid, Zaid Bin, Mazhar, Tehseen, Nadeem, Muhammad Asgher, Saeed, Mamoon M., Hamam, Habib
• Format: Journal Article
• Language: English
• Published: Cham Springer International Publishing 27.09.2024; Springer Nature B.V; Springer
• Subjects: Artificial intelligence; BER; Business metrics; Communications systems; DWDM; Earth and Environmental Science; Energy efficiency; Environment; Free space optics; Internet of Things; Investigations; Machine learning; Mathematical models; Modulation formats; Optics; Optimization techniques; Performance evaluation; Q-factor; Rain; Satellite communications; Simulation; Sustainable Development; Wave division multiplexing; Wireless communications; Q-factor; Modulation formats; Free space optics; DWDM; BER
• ISSN: 2662-9984; 2662-9984
• DOI: 10.1007/s43621-024-00474-1

Free space optical (FSO) systems offer an attractive and cost-effective solution for providing communication services in remote regions, as they allow secure transmission without the need for licensing and with lower deployment costs. However, the performance of FSO systems can be significantly impacted by atmospheric turbulences, creating considerable challenges to their deployment. To meet the expanding bandwidth requirements in optical networks, dense wavelength division multiplexing (DWDM) has emerged as a viable option. The development of a 400-Gbps DWDM-FSO system with advanced modulation formats is the subject of this paper. To ensure efficient energy conservation in such a system, power consumption needs to be minimized while maintaining performance level; this calls for optimization of different components within the system. The system is made up of 10 channels and each channel can transmit data at 40 Gbps. Various modulation schemes like carrier-suppressed return-to-zero, modified duo binary return-to-zero, differential phase shift keying, and duo binary return-to-zero are studied for their impact on system performance parameters Q-factor and bit error rate (BER) in C-band around 1550 nm wavelengths. The assessment is also extended to the effects that changing FSO length, input power, and data rate have on these two parameters as well as an evaluation regarding how differing atmospheric conditions influence the FSO system’s effectiveness.