Estimation of optimal wavelengths for atmospheric non-line-of-sight optical communication in the UV range of the spectrum in daytime and at night for baseline distances from 50 m to 50 km

Mikhail V. Tarasenkov; Vladimir V. Belov; Egor S. Poznakharev

doi:10.1364/JOSAA.440875

Journal of the Optical Society of America A
Vol. 39,
Issue 2,
pp. 177-188
(2022)
•https://doi.org/10.1364/JOSAA.440875

Estimation of optimal wavelengths for atmospheric non-line-of-sight optical communication in the UV range of the spectrum in daytime and at night for baseline distances from 50 m to 50 km

Mikhail V. Tarasenkov, Vladimir V. Belov, and Egor S. Poznakharev

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Mikhail V. Tarasenkov, Vladimir V. Belov, and Egor S. Poznakharev, "Estimation of optimal wavelengths for atmospheric non-line-of-sight optical communication in the UV range of the spectrum in daytime and at night for baseline distances from 50 m to 50 km," J. Opt. Soc. Am. A 39, 177-188 (2022)

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Abstract

For implementation of non-line-of-sight optical communication, the wavelength from the range 200–400 nm at which the signal-to-noise ratio reaches a maximum depending on the baseline distance is estimated. The estimates are performed in the daytime, at moonlit night, and without background radiation. The results obtained allow us to recommend $\lambda = 290 \;{\rm{nm}}$ for the implementation of the long-range communication in the daytime and $\lambda = 350 \;{\rm{nm}}$ at night. For impulse response that provides the basis for estimating the communication channel quality, four algorithms of the Monte Carlo method are considered. The algorithm with modified double local estimate provides the least error for the same number of photon trajectories. UV radiation is potentially dangerous to humans, and therefore, the illuminance of the Earth’s surface is estimated under the optical axis of the source for baseline distances of 2, 10, and 100 m together with the time period of a continuous communication session safe for operators.

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Supplementary Material (1)

Name	Description
Dataset 1	Dataset containing the results of calculations of the impulse responses (IPR) and of the signal-to-noise ratios (SNR) and the models of the atmosphere for the UV wavelength range that were used in the paper.

Data Availability

Data underlying the results presented in this paper are available in Dataset 1, Ref. [35].

35. M. Tarasenkov and V. Belov, “Estimation of optimal wavelengths for atmospheric non-line-of-sight optical communication in the UV range of the spectrum in the daytime and at night for baseline distances from 50 m to 50 km,” IEEE Dataport, 2020, https://doi.org/10.21227/ak0a-5r69.

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Figures (11)

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Tables (3)

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Equations (26)

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$λ, n m$	$Σ_{K}, m A / W$	$λ, n m$	$Σ_{K}, m A / W$
200	30	300	52
210	36	310	50
220	45	320	49
230	51	330	48
240	53	340	47
250	54	350	42
260	54	360	25
270	54	370	7
280	53	380	3
290	53	390	1

Algorithm	$η_{msc}$ , dB	$A η_{msc}$ , dB	$δ h_{msc}$ , %
Atmospheric model 1; $Y_{N} = 0.1 km$
Local estimate	116.1	0.32	14.29
Double local estimate	116.2	0.11	1.67
Combined estimate	115.9	0.28	3.56
Modified double local estimate	116.1	0.03	0.53
From Ref. [15]	115.9	—	—
Atmospheric model 2c; $Y_{N} = 0.1 km$
Modified double local estimate	116.8	0.06	0.67
Atmospheric model 2c; $Y_{N} = 10 km$
Local estimate	174.0	1.01	24.5
Double local estimate	176.5	0.25	8.98
Combined estimate	176.6	0.33	6.86
Modified double local estimate	176.3	0.11	4.06

$Y_{N}, m$	Model 2a	Model 2b	Model 2c	Model 2d
2	14 min	1 h 57 min	3 h 36 min	5 h 57 min
10	1 h 14 min	9 h 47 min	18 h 9 min	30 h 5 min
100	21 h 52 min	111 h	201 h	329 h

$λ, n m$	$Σ_{K}, m A / W$	$λ, n m$	$Σ_{K}, m A / W$
200	30	300	52
210	36	310	50
220	45	320	49
230	51	330	48
240	53	340	47
250	54	350	42
260	54	360	25
270	54	370	7
280	53	380	3
290	53	390	1

Algorithm	$η_{msc}$ , dB	$A η_{msc}$ , dB	$δ h_{msc}$ , %
Atmospheric model 1; $Y_{N} = 0.1 km$
Local estimate	116.1	0.32	14.29
Double local estimate	116.2	0.11	1.67
Combined estimate	115.9	0.28	3.56
Modified double local estimate	116.1	0.03	0.53
From Ref. [15]	115.9	—	—
Atmospheric model 2c; $Y_{N} = 0.1 km$
Modified double local estimate	116.8	0.06	0.67
Atmospheric model 2c; $Y_{N} = 10 km$
Local estimate	174.0	1.01	24.5
Double local estimate	176.5	0.25	8.98
Combined estimate	176.6	0.33	6.86
Modified double local estimate	176.3	0.11	4.06

$λ, n m$	$Σ_{K}, m A / W$	$λ, n m$	$Σ_{K}, m A / W$
200	30	300	52
210	36	310	50
220	45	320	49
230	51	330	48
240	53	340	47
250	54	350	42
260	54	360	25
270	54	370	7
280	53	380	3
290	53	390	1

$λ, n m$	$Σ_{K}, m A / W$	$λ, n m$	$Σ_{K}, m A / W$
200	30	300	52
210	36	310	50
220	45	320	49
230	51	330	48
240	53	340	47
250	54	350	42
260	54	360	25
270	54	370	7
280	53	380	3
290	53	390	1

$λ, n m$	$Σ_{K}, m A / W$	$λ, n m$	$Σ_{K}, m A / W$
200	30	300	52
210	36	310	50
220	45	320	49
230	51	330	48
240	53	340	47
250	54	350	42
260	54	360	25
270	54	370	7
280	53	380	3
290	53	390	1

$λ, n m$	$Σ_{K}, m A / W$	$λ, n m$	$Σ_{K}, m A / W$
200	30	300	52
210	36	310	50
220	45	320	49
230	51	330	48
240	53	340	47
250	54	350	42
260	54	360	25
270	54	370	7
280	53	380	3
290	53	390	1

Abstract

References

Supplementary Material (1)

Data Availability

Cited By

Figures (11)

Tables (3)

Equations (26)

Metrics

Journal of the Optical Society of America A

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$λ, n m$	$Σ_{K}, m A / W$	$λ, n m$	$Σ_{K}, m A / W$
200	30	300	52
210	36	310	50
220	45	320	49
230	51	330	48
240	53	340	47
250	54	350	42
260	54	360	25
270	54	370	7
280	53	380	3
290	53	390	1

$λ, n m$	$Σ_{K}, m A / W$	$λ, n m$	$Σ_{K}, m A / W$
200	30	300	52
210	36	310	50
220	45	320	49
230	51	330	48
240	53	340	47
250	54	350	42
260	54	360	25
270	54	370	7
280	53	380	3
290	53	390	1