Independent component analysis for enhancement of an FMCW optical ranging technique in turbid waters

David W. Illig; William D. Jemison; Linda J. Mullen

doi:10.1364/AO.55.000C25

Applied Optics
Vol. 55,
Issue 31,
pp. C25-C33
(2016)
•https://doi.org/10.1364/AO.55.000C25

Independent component analysis for enhancement of an FMCW optical ranging technique in turbid waters

David W. Illig, William D. Jemison, and Linda J. Mullen

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David W. Illig, William D. Jemison, and Linda J. Mullen, "Independent component analysis for enhancement of an FMCW optical ranging technique in turbid waters," Appl. Opt. 55, C25-C33 (2016)

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About this Article
History
- Original Manuscript: June 2, 2016
- Revised Manuscript: September 19, 2016
- Manuscript Accepted: September 19, 2016
- Published: October 14, 2016
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Abstract

Optical detection and ranging in turbid waters are challenged by the effects of absorption and scattering. In particular, backscatter creates a clutter return, which can mask the presence of weak underwater targets. This work explores the use of independent component analysis (ICA), a statistical signal processing approach, to recover weak targets from strong backscatter in turbid waters using a frequency-modulated continuous-wave optical rangefinder. ICA uses statistical differences between target and backscatter returns to suppress the backscatter return. In laboratory test tank experiments, the use of ICA is observed to improve probability of detection at various turbidities and extend target detection range by four optical attenuation lengths.

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Parameter	Value	Unit
Source-receiver separation	15.0	cm
Receiver-object distance	1.35–3.05	m
Laser wavelength	532	nm
Optical power	80	mW
Beam attenuation coefficient	1.1–6.2	$m^{- 1}$
Scattering agent	Equate
Single-scattering albedo	0.9
Receiver aperture	0.05	m
Receiver field of view	3.4	deg
Analog-digital converter bits	12	bits
Sample rate	4	GHz
Averaging window	10200	samples
Effective integration time	2.55	us
Chirp bandwidth	800	MHz
Chirp band	200–1000	MHz
Chirp duration	850	ns
Time-bandwidth product	680
Number of digital steps	1000	steps
Step duration	850	ps

$z$ (m)	$c (m^{- 1})$	$c z$	Baseline TBR (dB)	ICA TBR (dB)
1.35	1.1	1.48	$+ 70$	$+ 67$
2.05	2.1	4.31	$+ 8$	$+ 13$
2.55	3.2	8.16	−9.8	$+ 2.3$
2.65	6.2	16.43	−1.4	−0.4

Parameter	Value	Unit
Source-receiver separation	15.0	cm
Receiver-object distance	1.35–3.05	m
Laser wavelength	532	nm
Optical power	80	mW
Beam attenuation coefficient	1.1–6.2	$m^{- 1}$
Scattering agent	Equate
Single-scattering albedo	0.9
Receiver aperture	0.05	m
Receiver field of view	3.4	deg
Analog-digital converter bits	12	bits
Sample rate	4	GHz
Averaging window	10200	samples
Effective integration time	2.55	us
Chirp bandwidth	800	MHz
Chirp band	200–1000	MHz
Chirp duration	850	ns
Time-bandwidth product	680
Number of digital steps	1000	steps
Step duration	850	ps

$z$ (m)	$c (m^{- 1})$	$c z$	Baseline TBR (dB)	ICA TBR (dB)
1.35	1.1	1.48	$+ 70$	$+ 67$
2.05	2.1	4.31	$+ 8$	$+ 13$
2.55	3.2	8.16	−9.8	$+ 2.3$
2.65	6.2	16.43	−1.4	−0.4

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Equations (10)

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