Your search keyword '"Al-Sallami, Farah"' showing total 5 results

1. FSO Basics

Author

Al-Sallami, Farah, Rajbhandari, Sujan, Ata, Yalçın, Monteiro, Paulo P., Section editor, and Kawanishi, Tetsuya, editor

Published

2024

2. Impact of dynamic traffic on vehicle-to-vehicle visible light communication

Author

Al-Sallami, Farah, Rajbhandari, Sujan, Ahmad, Zahir, and Haas, Olivier

Abstract

Due to the directional nature of the visible light signals propagation, the performance of visible light communications (VLC) systems depends on the geometry of the link. In dynamic vehicle to-vehicle VLC (V2V-VLC) systems, the geometry of the VLC link changes continuously due to the unpredictable movement patterns of the transmitter, receiver and surrounding vehicles. This thesis investigates the impact of dynamic traffic conditions during different times of the day to establish a statistical channel model for the V2V-VLC systems. The study considers the geometrical variation due to the variable inter-vehicle spacing and radiation pattern of vehicles' sources. The results showed that the statistical model of channel path loss is given by a convolution of the distributions of the inter-vehicle spacing and the radiation pattern of vehicles' sources. Based on the measured traffic, the line of sight (LOS) and non-LOS path loss are developed for the radiation pattern of vehicles' sources which depends on the manufactures. The study shows that the LOS path loss distribution depends on the radiation pattern, whereas it has a less significant effect on the non-LOS path loss distribution. Furthermore, the existence of multiple reflectors decreases path loss and enhances the communication link's performance. Different weather conditions add attenuation that increases the mean path loss value without changing the statistical distribution of the path loss. Studying the temporal properties of the V2V-VLC channel shows that the channel can be described as time-variant non-stationary with flat and slow fading behaviour. The bit-error-rate (BER) and signal-to-noise (SNR) ratio performance, when the on-off-keying (OOK) modulation scheme is used, depends on the dynamic traffic and the existence of other vehicles in the adjacent lanes. A difference of at least 2 dB between the required SNR values to achieve comparable BER performance in different lanes is observed.

Published

2021

3. LiNEV: Visible Light Networking for Connected Vehicles

Author

Saied, Osama, primary, Kaiwartya, Omprakash, additional, Aljaidi, Mohammad, additional, Kumar, Sushil, additional, Mahmud, Mufti, additional, Kharel, Rupak, additional, Al-Sallami, Farah, additional, and Tsimenidis, Charalampos C., additional

Published

2023

4. LiNEV: Visible Light Networking for Connected Vehicles

Author

Saied, Osama, Kaiwartya, Omprakash, Aljaidi, Mohammad, Kumar, Sushil, Mahmud, Mufti, Kharel, Rupak, Al-Sallami, Farah, Tsimenidis, Charalampos C., Saied, Osama, Kaiwartya, Omprakash, Aljaidi, Mohammad, Kumar, Sushil, Mahmud, Mufti, Kharel, Rupak, Al-Sallami, Farah, and Tsimenidis, Charalampos C.

Abstract

DC-biased optical orthogonal frequency division multiplexing (DCO-OFDM) has been introduced to visible light networking framework for connected vehicles (LiNEV) systems as a modulation and multiplexing scheme. This is to overcome the light-emitting diode (LED) bandwidth limitation, as well as to reduce the inter-symbol interference caused by the multipath road fading. Due to the implementation of the inverse fast Fourier transform, DC-OFDM suffers from its large peak-to-average power ratio (PAPR), which degrades the performance in LiNEV systems, as the LEDs used in the vehicles’ headlights have a limited optical power-current linear range. To tackle this issue, discrete Fourier transform spread-optical pulse amplitude modulation (DFTS-OPAM) has been proposed as an alternative modulation scheme for LiNEV systems instead of DCO-OFDM. In this paper, we investigate the system performance of both schemes considering the light-emitting diode linear dynamic range and LED 3 dB modulation bandwidth limitations. The simulation results indicate that DCO-OFDM has a 9 dB higher PAPR value compared with DFTS-OPAM. Additionally, it is demonstrated that DCO-OFDM requires an LED with a linear range that is twice the one required by DFTS-OPAM for the same high quadrature amplitude modulation (QAM) order. Furthermore, the findings illustrate that when the signal bandwidth of both schemes significantly exceeds the LED modulation bandwidth, DCO-OFDM outperforms DFTS-OPAM, as it requires a lower signal-to-noise ratio at a high QAM order.

Published

2023

5. Average Channel Capacity Bounds of a Dynamic Vehicle-to-Vehicle Visible Light Communication System

Author

Al-Sallami, Farah Mahdi, Benkhelifa, Fatma, Ashour, Danah, Ghassemlooy, Zabih, Haas, Olivier C.L., Ahmad, Zahir, and Rajbhandari, Sujan

Abstract

As vehicles trajectories are unpredictable and changing dynamically, vehicle-to-vehicle visible light communication (V2V-VLC) experiences a dynamic channel. In this work, we conduct measurements taking into account different realistic inter-vehicle distances and ambient noise levels at different times of the day in order to model and verify the dynamic V2V-VLC channel. We also derive the average channel capacity bounds by considering the impact of traffic at different times of the day, atmospheric turbulence and fog. Considering both peak and average optical power levels constraints, we derive the upper and lower bounds by using sphere packing and constraint relaxation methods, as well as truncated-exponential and truncated Gaussian distributions, respectively. The results show that the constraint relaxation method provides an improved estimation for the upper bound, whereas the truncated exponential distribution tightens the lower bound with a minimum gap of 0.4 b/s/Hz during rush hour and in a clear weather condition. We also show that the average capacity bounds of V2V-VLC are less affected by atmospheric turbulence and fog, and that the capacity during rush hours is higher by 0.7 b/s/Hz than during late hours.

Published

2024