Wide-area and omnidirectional optical detector arrays using modular optical elements

Asaad Kaadan; Hazem Refai; Peter LoPresti

doi:10.1364/AO.55.004791

Applied Optics
Vol. 55,
Issue 18,
pp. 4791-4800
(2016)
•https://doi.org/10.1364/AO.55.004791

Wide-area and omnidirectional optical detector arrays using modular optical elements

Asaad Kaadan, Hazem Refai, and Peter LoPresti

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Asaad Kaadan, Hazem Refai, and Peter LoPresti, "Wide-area and omnidirectional optical detector arrays using modular optical elements," Appl. Opt. 55, 4791-4800 (2016)

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Abstract

This paper presents novel, modular optical detector arrays of various shapes and configurations. Recently developed Modular Optical Wireless Elements (MOWE) architecture serves as the basis for large and complex optical detector arrays that can be constructed as geometric shells and provide wide-area even omnidirectional field-of-view (FoV). Programmable optical modules synchronously sample the environment, and then route measurements to the user through a dedicated electrical backbone. The arrays are inexpensive, easy to construct, and can be made with homogeneous/inhomogeneous optical properties. Applications include remote sensing, motion detection, optical navigation, and medical imaging, among others. We present the MOWE detector array concept with a detailed optical analysis and a suggested design methodology, as well as a number of various demonstrations. We also utilize wavelength-diversity of MOWE arrays to demodulate two overlapping signals, showing that many diversity-based algorithms can be conveniently prototyped and implemented.

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Supplementary Material (5)

Name	Description
Visualization 1: MP4 (4866 KB)	Unequalized passive detection in a flat array.
Visualization 2: MP4 (4965 KB)	Equalized passive detection in a flat array.
Visualization 3: MP4 (758 KB)	Active detection and tracking in a flat array.
Visualization 4: MP4 (1601 KB)	Detecting two light beams in a flat array.
Visualization 5: MP4 (1382 KB)	Active object rotating around a spherical array.

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Tables (4)

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Architecture	Peer-to-Peer
Streaming speed	up to 1 Mbps
MCU	32-bit ARM Cortex-M0
Optical resolution (Module center to center)	20 mm, 30 mm
Module weight	$< 2 g$
Module cost	Approx. $6
Module power consumption (without sleep mode)	40–66 mW
LED wavelength	850 nm
LED FWHM divergence angle	$\pm 10 °$
LED radiant intensity	100 mW/sr
PT wavelength	850 nm, 940 nm
PT half sensitivity angle	$\pm 60 °$
PT optical sensitivity	$\approx 5 μW / {cm}^{2}$ for $R_{L} = 620 Ω$

Configuration	Optical Resolution $d$ (mm)	Convergence Distance (mm)
Hexagonal modules	20	$d_{R} = 8.55$
( $θ = 60 °$ , $α = 138.19 °$ )	30	$d_{R} = 12.83$
Pentagonal modules	20	$d_{R} = 17.4$
( $θ = 60 °$ , $α = 116.57 °$ )	30	$d_{R} = 26.1$

Architecture	Peer-to-Peer
Streaming speed	up to 1 Mbps
MCU	32-bit ARM Cortex-M0
Optical resolution (Module center to center)	20 mm, 30 mm
Module weight	$< 2 g$
Module cost	Approx. $6
Module power consumption (without sleep mode)	40–66 mW
LED wavelength	850 nm
LED FWHM divergence angle	$\pm 10 °$
LED radiant intensity	100 mW/sr
PT wavelength	850 nm, 940 nm
PT half sensitivity angle	$\pm 60 °$
PT optical sensitivity	$\approx 5 μW / {cm}^{2}$ for $R_{L} = 620 Ω$

Configuration	Optical Resolution $d$ (mm)	Convergence Distance (mm)
Hexagonal modules	20	$d_{R} = 8.55$
( $θ = 60 °$ , $α = 138.19 °$ )	30	$d_{R} = 12.83$
Pentagonal modules	20	$d_{R} = 17.4$
( $θ = 60 °$ , $α = 116.57 °$ )	30	$d_{R} = 26.1$

Abstract

Supplementary Material (5)

Cited By

Figures (22)

Tables (4)

Equations (7)

Applied Optics