Object Detection and Geometric Profiling through Dirty Water Media Using Asymmetry Properties of Backscattered Signals

TL;DR

This paper introduces a novel underwater object detection and profiling method using backscattering asymmetry of continuous wave laser beams, enabling geometric shape reconstruction in turbid water environments.

Contribution

The paper proposes a new asymmetry-based approach for underwater object detection and shape profiling using dual CW laser beams, improving imaging through turbid media.

Findings

Backscattering asymmetry indicates object tilt and position.

Method achieves geometric shape reconstruction of objects.

Resolution and range limits are experimentally characterized.

Abstract

The scattering of light observed through the turbid underwater channel is often regarded as the leading challenge when designing underwater electro-optical imaging systems. There have been many approaches to address the effects of scattering such as using pulsed laser sources to reject scattered light temporally, or using intensity modulated waveforms and matched filters to remove the scattered light spectrally. In this paper, a new method is proposed which primarily uses the backscattering asymmetry property for object detection and geometric profiling. In our approach, two parallel and identical continuous wave (CW) laser beams with narrow beam widths (~2mm) are used as active illumination sources. The two beams also have controllable spacing and aiming angle, as well as initial phase difference for convenience of scanning and profiling a target. Through theory and experimental results, it will be shown that when an object leans or tilts towards one of the beam's central trajectory, the asymmetry in the backscattered signals can be used to indicate the location or slope of the target's surface, respectively. By varying the spacing or aiming angle of the two beams, a number of surface samples can be collected to reconstruct the object's shape geometrically. The resolution and range limit of our approach are also measured and reported in this work. In application, our proposed method provides an economic solution to perform imaging through turbid underwater environments. Additionally, the idea can be combined with the pulsed or modulated laser signals for enhanced imaging results.