Load balancing with shadowing effects handover in Li-Fi and RF hybrid network

Light Fidelity (LiFi) uses light emitting diodes (LEOs) for high speed wireless communications. a hybrid network combining light fidelity (Li-Fi) with a radio frequency (RF) wireless fidelity (Wi-Fi) network is considered. An additional tier of very small Li-Fi attocells which utilise the visible...

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Main Author: Al-Bayati, Sallar Salam Murad
Format: Thesis
Language:English
Published: 2018
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Online Access:http://psasir.upm.edu.my/id/eprint/91302/1/FSKTM%202018%2044%20-%20IR.pdf
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spelling my-upm-ir.913022021-11-12T01:55:06Z Load balancing with shadowing effects handover in Li-Fi and RF hybrid network 2018-01 Al-Bayati, Sallar Salam Murad Light Fidelity (LiFi) uses light emitting diodes (LEOs) for high speed wireless communications. a hybrid network combining light fidelity (Li-Fi) with a radio frequency (RF) wireless fidelity (Wi-Fi) network is considered. An additional tier of very small Li-Fi attocells which utilise the visible light spectrum offers a significant increase in wireless data throughput in an indoor environment while at the same time providing room illumination. Importantly, there is no interference between Li-Fi and Wi-Fi. A Li-Fi attocell covers a significantly smaller area than a Wi- Fi access point (AP). This means that even with moderate user movement a large number of handover between Li-Fi attocells can occur, and this compromises the system throughput. Dynamic load balancing (LB) can mitigate this issue so that quasi-static users are served by Li-Fi attocells while moving users are served by a Wi-Fi AP. However, due to user movement, local overload situations may occur which prevent handover, leading to a lower throughput. LiFi can significantly alleviate the traffic bottlenecks in high density RF scenarios, typically present in an indoor environment. Hence, a combination of LiFi and RF networks becomes a promising candidate for future indoor wireless communications. In a practical indoor scenario, the optical interference from neighbouring LiFi access points (APs) and the blockages of line-of-sight (LoS) optical channels induced by people and objects are the main factors that cause significant optical channel variations. This research studies LB in a hybrid Li-Fi/Wi-Fi network by taking into account user mobility and handover signalling overheadsl, and also Inthis study, the effect of these two factors on the system throughput of a hybrid LiFilRF network is investigated. Furthermore, a dynamic LB scheme is proposed, where the utility function considers system throughput and fairness. In order to better understand the hand over effect on the LB, the service areas of different APs are studied, and the throughput of each AP by employing the proposed LB scheme is analysed. In order to offer a fair comparison, area data rate, which is defined as the system throughput in a unit area, is used for performance evaluation. The simulation shows that there is an optimal distance between two neighbouring LiFi APs to achieve the highest area data rate. In addition, the area data rate increases with the density of blockages when the blockage density is below a certain threshold. Wireless communication systems 2018-01 Thesis http://psasir.upm.edu.my/id/eprint/91302/ http://psasir.upm.edu.my/id/eprint/91302/1/FSKTM%202018%2044%20-%20IR.pdf text en public masters Universiti Putra Malaysia Wireless communication systems Kweh, Yeah Lun
institution Universiti Putra Malaysia
collection PSAS Institutional Repository
language English
advisor Kweh, Yeah Lun
topic Wireless communication systems


spellingShingle Wireless communication systems


Al-Bayati, Sallar Salam Murad
Load balancing with shadowing effects handover in Li-Fi and RF hybrid network
description Light Fidelity (LiFi) uses light emitting diodes (LEOs) for high speed wireless communications. a hybrid network combining light fidelity (Li-Fi) with a radio frequency (RF) wireless fidelity (Wi-Fi) network is considered. An additional tier of very small Li-Fi attocells which utilise the visible light spectrum offers a significant increase in wireless data throughput in an indoor environment while at the same time providing room illumination. Importantly, there is no interference between Li-Fi and Wi-Fi. A Li-Fi attocell covers a significantly smaller area than a Wi- Fi access point (AP). This means that even with moderate user movement a large number of handover between Li-Fi attocells can occur, and this compromises the system throughput. Dynamic load balancing (LB) can mitigate this issue so that quasi-static users are served by Li-Fi attocells while moving users are served by a Wi-Fi AP. However, due to user movement, local overload situations may occur which prevent handover, leading to a lower throughput. LiFi can significantly alleviate the traffic bottlenecks in high density RF scenarios, typically present in an indoor environment. Hence, a combination of LiFi and RF networks becomes a promising candidate for future indoor wireless communications. In a practical indoor scenario, the optical interference from neighbouring LiFi access points (APs) and the blockages of line-of-sight (LoS) optical channels induced by people and objects are the main factors that cause significant optical channel variations. This research studies LB in a hybrid Li-Fi/Wi-Fi network by taking into account user mobility and handover signalling overheadsl, and also Inthis study, the effect of these two factors on the system throughput of a hybrid LiFilRF network is investigated. Furthermore, a dynamic LB scheme is proposed, where the utility function considers system throughput and fairness. In order to better understand the hand over effect on the LB, the service areas of different APs are studied, and the throughput of each AP by employing the proposed LB scheme is analysed. In order to offer a fair comparison, area data rate, which is defined as the system throughput in a unit area, is used for performance evaluation. The simulation shows that there is an optimal distance between two neighbouring LiFi APs to achieve the highest area data rate. In addition, the area data rate increases with the density of blockages when the blockage density is below a certain threshold.
format Thesis
qualification_level Master's degree
author Al-Bayati, Sallar Salam Murad
author_facet Al-Bayati, Sallar Salam Murad
author_sort Al-Bayati, Sallar Salam Murad
title Load balancing with shadowing effects handover in Li-Fi and RF hybrid network
title_short Load balancing with shadowing effects handover in Li-Fi and RF hybrid network
title_full Load balancing with shadowing effects handover in Li-Fi and RF hybrid network
title_fullStr Load balancing with shadowing effects handover in Li-Fi and RF hybrid network
title_full_unstemmed Load balancing with shadowing effects handover in Li-Fi and RF hybrid network
title_sort load balancing with shadowing effects handover in li-fi and rf hybrid network
granting_institution Universiti Putra Malaysia
publishDate 2018
url http://psasir.upm.edu.my/id/eprint/91302/1/FSKTM%202018%2044%20-%20IR.pdf
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