Prediction-model-assisted reinforcement learning algorithm for handover decision-making in hybrid LiFi and WiFi networks

Dayrene Frometa Fonseca; Dayrene Frometa Fonseca; Borja Genoves Guzman; Giovanni Luca Martena; Rui Bian; Harald Haas; Domenico Giustiniano

doi:10.1364/JOCN.495234

Journal of Optical Communications and Networking
Vol. 16,
Issue 2,
pp. 159-170
(2024)
•https://doi.org/10.1364/JOCN.495234

Prediction-model-assisted reinforcement learning algorithm for handover decision-making in hybrid LiFi and WiFi networks

Dayrene Frometa Fonseca, Borja Genoves Guzman, Giovanni Luca Martena, Rui Bian, Harald Haas, and Domenico Giustiniano

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Dayrene Frometa Fonseca, Borja Genoves Guzman, Giovanni Luca Martena, Rui Bian, Harald Haas, and Domenico Giustiniano, "Prediction-model-assisted reinforcement learning algorithm for handover decision-making in hybrid LiFi and WiFi networks," J. Opt. Commun. Netw. 16, 159-170 (2024)

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Abstract

The handover process in hybrid light fidelity (LiFi) and wireless fidelity (WiFi) networks (HLWNets) is very challenging due to the short area covered by LiFi access points and the coverage overlap between LiFi and WiFi networks, which introduce frequent horizontal and vertical handovers, respectively. Different handover schemes have been proposed to reduce the handover rate in HLWNets, among which handover skipping (HS) techniques stand out. However, existing solutions are still inefficient or require knowledge that is not available in practice, such as the exact user’s trajectory or the network topology. In this work, a novel machine learning-based handover scheme is proposed to overcome the limitations of previous HS works. Specifically, we have designed a classification model to predict the type of user’s trajectory and assist a reinforcement learning (RL) algorithm to make handover decisions that are automatically adapted to new network conditions. The proposed scheme is called RL-HO, and we compare its performance against the standard handover scheme of long-term evolution (STD-LTE) and the so-called smart handover (Smart HO) algorithm. We show that our proposed RL-HO scheme improves the network throughput by 146% and 59% compared to STD-LTE and Smart HO, respectively. We make our simulator code publicly available to the research community.

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Parameter	Value
Room size (length by width by height)	$10 \times 10 \times 3 m$
Physical area of each PD, $A_{p d}$	$1 {c m}^{2}$
Optical filter gain, $g_{f}$	1
Refractive index, $n$	1
FoV semi-angle of the PD, $Ψ_{max}$	$90^{\circ}$
Detector responsivity, $R_{p d}$	0.53 A/W
Half-intensity radiation angle, $Φ_{1 / 2}$	$60^{\circ}$
Modulated optical power per LiFi AP, $P_{o p t}$	3.5 W
Transmitted power of the WiFi AP, $P_{W i F i}$	15 dBm
Bandwidth per LiFi AP, $B_{L i F i}$	20 MHz
Bandwidth per WiFi AP, $B_{W i F i}$	40 MHz
PSD of noise in LiFi, $N_{L i F i}$	$10^{- 21} A^{2} / H z$ [38]
PSD of noise in WiFi, $N_{W i F i}$	$- 174 d B m / H z$ [38]

Parameter	Value
Room size (length by width by height)	$10 \times 10 \times 3 m$
Physical area of each PD, $A_{p d}$	$1 {c m}^{2}$
Optical filter gain, $g_{f}$	1
Refractive index, $n$	1
FoV semi-angle of the PD, $Ψ_{max}$	$90^{\circ}$
Detector responsivity, $R_{p d}$	0.53 A/W
Half-intensity radiation angle, $Φ_{1 / 2}$	$60^{\circ}$
Modulated optical power per LiFi AP, $P_{o p t}$	3.5 W
Transmitted power of the WiFi AP, $P_{W i F i}$	15 dBm
Bandwidth per LiFi AP, $B_{L i F i}$	20 MHz
Bandwidth per WiFi AP, $B_{W i F i}$	40 MHz
PSD of noise in LiFi, $N_{L i F i}$	$10^{- 21} A^{2} / H z$ [38]
PSD of noise in WiFi, $N_{W i F i}$	$- 174 d B m / H z$ [38]

Dayrene Frometa Fonseca	https://orcid.org/0000-0001-5447-631X
Borja Genoves Guzman	https://orcid.org/0000-0002-6969-793X

Abstract

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Equations (15)

Journal of Optical Communications and Networking