Harbor-border inspection for unmanned aerial vehicle based on visible
light source tracking

Renhai Feng; Zhaolin Zhang; Zhimao Lai; Sheng Xie; Xurui Mao

doi:10.1364/AO.431149

Applied Optics
Vol. 60,
Issue 31,
pp. 9659-9667
(2021)
•https://doi.org/10.1364/AO.431149

Harbor-border inspection for unmanned aerial vehicle based on visible light source tracking

Renhai Feng, Zhaolin Zhang, Zhimao Lai, Sheng Xie, and Xurui Mao

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Renhai Feng, Zhaolin Zhang, Zhimao Lai, Sheng Xie, and Xurui Mao, "Harbor-border inspection for unmanned aerial vehicle based on visible light source tracking," Appl. Opt. 60, 9659-9667 (2021)

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Abstract

The unmanned aerial vehicle (UAV) offers unique advantages of autonomous flight capability and small coefficient of risk, and is increasingly being used in harbor-border inspection to ensure security and orderly operation of harbors. In response to the influence of external factors such as electromagnetic interference in harbor-border inspection, this paper utilizes UAV and visible light communication (VLC) to build an efficient system to track maritime targets near the harbor reliably. In a VLC scenario, a geometrical equation for transmitter positioning is first proposed based on the received signal strength of the optical signal emitted by the target. On this basis, linear iterative positioning (LIP) using first-order Taylor expansion is proposed to realize online beam tracking. Furthermore, quadratic approximative iterative positioning (QAIP), a more precise approximation of the geometrical equation, is proposed based on second-order Taylor expansion. Simulation results show that the proposed algorithms can track targets effectively, and QAIP can achieve higher accuracy with no noise or high signal-to-noise ratio. In addition, compared with the geometrical solution, LIP and QAIP have faster computing speeds and fixed overheads.

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Data Availability

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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Equations (19)

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$i$	Position Vector $m_{i}$	Unit Normal Vector $n_{i}$
$A$	(0,0,0)	(0,0,1)
$B$	$(- \frac{3}{2}, 0, \frac{\tan (\frac{π}{2} - F O V)}{2})$	$(\sin (\frac{π}{2} - F O V), 0, \cos (\frac{π}{2} - F O V))$
$C$	$(0, - \frac{3}{2}, \frac{\tan (\frac{π}{2} - F O V)}{2})$	$(0, \sin (\frac{π}{2} - F O V), \cos (\frac{π}{2} - F O V))$

Parameter	Unit of Parameter	Initial Value
$P_{T}$	W	100
$r$	A/W	0.8
$g$		6
$A_{i}$	${c m}^{2}$	1
$α$	rad	0.9
FOV of $A$	rad	$π / 3$
FOV of $B$ , $C$	rad	$π / 2 - α$
$ϕ_{1 / 2}$	rad	$π / 3$

Scenario	SNR in Daytime (dB)	SNR in Nighttime (dB)
Scenario 1	36.8415	47.5292
Scenario 3	38.1079	47.7260

$i$	Position Vector $m_{i}$	Unit Normal Vector $n_{i}$
$A$	(0,0,0)	(0,0,1)
$B$	$(- \frac{3}{2}, 0, \frac{\tan (\frac{π}{2} - F O V)}{2})$	$(\sin (\frac{π}{2} - F O V), 0, \cos (\frac{π}{2} - F O V))$
$C$	$(0, - \frac{3}{2}, \frac{\tan (\frac{π}{2} - F O V)}{2})$	$(0, \sin (\frac{π}{2} - F O V), \cos (\frac{π}{2} - F O V))$

Parameter	Unit of Parameter	Initial Value
$P_{T}$	W	100
$r$	A/W	0.8
$g$		6
$A_{i}$	${c m}^{2}$	1
$α$	rad	0.9
FOV of $A$	rad	$π / 3$
FOV of $B$ , $C$	rad	$π / 2 - α$
$ϕ_{1 / 2}$	rad	$π / 3$

Abstract

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Figures (13)

Tables (4)

Equations (19)

Applied Optics