Adaptive blind receiving for deep VLC coverage in&#x00A0;non-uniform LED systems

Jing-Shu Xue; Tao Wang; Chao Wang; Xiao-Jing Wang; Yi-Jun Zhu

doi:10.1364/AO.475663

Applied Optics
Vol. 61,
Issue 36,
pp. 10688-10693
(2022)
•https://doi.org/10.1364/AO.475663

Adaptive blind receiving for deep VLC coverage in non-uniform LED systems

Jing-Shu Xue, Tao Wang, Chao Wang, Xiao-Jing Wang, and Yi-Jun Zhu

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Jing-Shu Xue, Tao Wang, Chao Wang, Xiao-Jing Wang, and Yi-Jun Zhu, "Adaptive blind receiving for deep VLC coverage in non-uniform LED systems," Appl. Opt. 61, 10688-10693 (2022)

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Table of Contents Category
- Fiber Optics, Fiber Sensors, and Optical Communications
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About this Article
History
- Original Manuscript: September 15, 2022
- Revised Manuscript: November 9, 2022
- Manuscript Accepted: November 18, 2022
- Published: December 12, 2022

Abstract

Recently, visible light communication (VLC) has become a promising technology for reliable communication in the industrial Internet of Things. In VLC, light sources with non-uniform parameters make uncontrollable signal blind zones and aliases. The unknown parameters also lead to the problem of channel estimation. Hence, deep coverage of VLC is challenging. In this paper, we design a dual-sensor elongated receiver. The receiver expands the signal receiving area by increasing the distance between photon detectors and realizes aliased signal recovery without channel estimation. Cooperatively, an adaptive blind receiving scheme is proposed. The scheme separates aliased signals by parameter estimation of a Gaussian mixture model without knowing transmitter parameters. It unifies the aliased and blind receiving cases by an adaptive signal combining method. Finally, the simulation results demonstrate that our scheme achieves better reliability and deeper communication coverage in the given system.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Parameter	Symbol	Value
Transmitter locations	–	(0, 0, 3) (4, 0, 3) [m]
Transmitting power	$P_{0}$	20 [W]
Half-power angle	$ψ_{h}$	–
Data rate	$R_{b}$	100 [Mbps]
Length of payload	$L_{s}$	1 [Mbit]
Detecting area	$A_{r}$	100 [ ${m m}^{2}$ ]
Responsivity	$C_{s}$	0.64 [A/W]
Equivalent noise power	–	$2.8 \times 10^{- 15}$ [ $W / {H z}^{0.5}$ ]
Number of PDs	–	$1 \times 2$ or $2 \times 1$
Location of midpoint	–	$(x, 0, 0)$
Distance between two PDs	$D_{r}$	0 or 1.5 [m]

	Method	15º	30º	45º
15º	SCR-DD	(0.4500,0.4500)	—	—
	FD	(0.4000,0.4000)
	DCR-JD-OC	(0.6250,0.6250)
30º	SCR-DD	(0.4500,0.3876)	(0.4625,0.4625)	—
	FD	(0.5250,0.4000)	(0.5250,0.5250)
	DCR-JD-OC	(0.7000,0.6000)	(0.7875,0.7875)
45º	SCR-DD	(0.5875,0.3375)	(0.4375,0.4625)	(0.4375,0.4375)
	FD	(0.4750,0.4000)	(0.4750,0.5250)	(0.4750,0.4750)
	DCR-JD-OC	(0.7125,0.6125)	(0.8000,0.8125)	(0.9000,0.9000)

Parameter	Symbol	Value
Transmitter locations	–	(0, 0, 3) (4, 0, 3) [m]
Transmitting power	$P_{0}$	20 [W]
Half-power angle	$ψ_{h}$	–
Data rate	$R_{b}$	100 [Mbps]
Length of payload	$L_{s}$	1 [Mbit]
Detecting area	$A_{r}$	100 [ ${m m}^{2}$ ]
Responsivity	$C_{s}$	0.64 [A/W]
Equivalent noise power	–	$2.8 \times 10^{- 15}$ [ $W / {H z}^{0.5}$ ]
Number of PDs	–	$1 \times 2$ or $2 \times 1$
Location of midpoint	–	$(x, 0, 0)$
Distance between two PDs	$D_{r}$	0 or 1.5 [m]

	Method	15º	30º	45º
15º	SCR-DD	(0.4500,0.4500)	—	—
	FD	(0.4000,0.4000)
	DCR-JD-OC	(0.6250,0.6250)
30º	SCR-DD	(0.4500,0.3876)	(0.4625,0.4625)	—
	FD	(0.5250,0.4000)	(0.5250,0.5250)
	DCR-JD-OC	(0.7000,0.6000)	(0.7875,0.7875)
45º	SCR-DD	(0.5875,0.3375)	(0.4375,0.4625)	(0.4375,0.4375)
	FD	(0.4750,0.4000)	(0.4750,0.5250)	(0.4750,0.4750)
	DCR-JD-OC	(0.7125,0.6125)	(0.8000,0.8125)	(0.9000,0.9000)

Abstract

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Applied Optics