Effect of pointing errors on the performance of hybrid FSO/RF networks
The performance of a free space optics (FSO) transmission suffers from the atmospheric turbulence and the attenuation in foggy environment. By employing relay nodes, the error rate and the coverage area of the FSO communication system can be significantly improved. However, the pointing errors, g...
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Main Authors: | , , |
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Other Authors: | |
Format: | Article |
Language: | English |
Published: |
2020
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Subjects: | |
Online Access: | https://hdl.handle.net/10356/144832 |
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Institution: | Nanyang Technological University |
Language: | English |
Summary: | The performance of a free space optics (FSO) transmission suffers from the atmospheric
turbulence and the attenuation in foggy environment. By employing relay nodes, the error rate and the
coverage area of the FSO communication system can be significantly improved. However, the pointing
errors, generated because of the building sway, have the potential to eradicate the benefits of the relay-based
FSO communication system. The effect of pointing errors in the presence of Gamma Gamma atmospheric
fading together with path loss attenuation is considered in this paper. To counteract the adverse affects
of the FSO link, a reliable millimeter-wave radio frequency (MMW RF) link is used as a backup. In this
context, this paper proposes a cooperative decode-and-forward (DF)-relaying-based hybrid FSO/RF system
with maximal-ratio-combining (MRC) at the destination. The system consists of FSO and RF sub-systems,
where FSO sub-system has the priority to transmit and RF sub-system serves as a back up when the FSO
sub-system is in outage. The exact and asymptotic outage probability and average symbol error rate (SER)
expressions for the proposed system are derived in closed-form and the diversity order is determined. The
effect of pointing errors on the system performance is analyzed extensively. The optimum values of transmit
beam waist and radius of receiver aperture are determined. The theoretical results, which are validated by
Monte-Carlo simulations, show that the proposed cooperative hybrid FSO/RF system drastically improves
the system performance compared to single hop (SH) hybrid FSO/RF and cooperative FSO systems
especially for large pointing errors scenario. |
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