Automated Underwater Object Recognition by Means of Fluorescence LIDAR

This paper focuses on automated recognition of underwater objects by means of light detection and ranging (LIDAR) systems. Differently from most works involved in underwater object recognition with LIDAR, where objects are recognized by their shape, here the interest is distinguishing objects on the basis of physical/chemical properties of object materials. To this aim, laser-induced fluorescence (LIF) spectroscopy is exploited, and an ad hoc signal processing chain is presented to effectively analyze the LIF spectra extracted at the detected object-range. Specifically, the goal is that of automatically recognizing the detected object with respect to a database (DB) of objects of interest, which have been previously spectrally characterized by means of laboratory fluorescence measurements. To this aim, suitable physics-based methodologies are proposed to compensate the signal for water-column effects. A decision-theory-based framework is developed to approach spectral recognition of the detected object with respect to the object DB. Experimental results from a laboratory test-bed show that the proposed processing chain is effective at automatically recognizing objects submerged in an artificial water column at different depths, based on a diverse DB of sample materials. The presented approach is shown to provide great potential for automated object recognition in marine and other water environments.

[1]  Steven Kay,et al.  Fundamentals Of Statistical Signal Processing , 2001 .

[2]  Nicolas Baghdadi,et al.  Wa-LiD: A New LiDAR Simulator for Waters , 2012, IEEE Geoscience and Remote Sensing Letters.

[3]  Ove Steinvall,et al.  Range accuracy and resolution for laser radars , 2005, SPIE Security + Defence.

[4]  Nail Cadalli,et al.  Bistatic receiver model for airborne lidar returns incident on an imaging array from underwater objects. , 2002, Applied optics.

[5]  R. Reuter,et al.  Submarine lidar for seafloor inspection , 1999 .

[6]  P. Coble Characterization of marine and terrestrial DOM in seawater using excitation-emission matrix spectroscopy , 1996 .

[7]  T. Dolenko,et al.  Fluorescence diagnostics of oil pollution in coastal marine waters by use of artificial neural networks. , 2002, Applied optics.

[8]  Donald J. Berndt,et al.  Using Dynamic Time Warping to Find Patterns in Time Series , 1994, KDD Workshop.

[9]  Fanglin Gu,et al.  Learning optimal warping window size of DTW for time series classification , 2012, 2012 11th International Conference on Information Science, Signal Processing and their Applications (ISSPA).

[10]  Andy Adler,et al.  Imaging of Compact Objects Buried in Underwater Sediments Using Electrical Impedance Tomography , 2014, IEEE Transactions on Geoscience and Remote Sensing.

[11]  J. Bryan Blair,et al.  Decomposition of laser altimeter waveforms , 2000, IEEE Trans. Geosci. Remote. Sens..

[12]  Jie Ma,et al.  A Gravity Gradient Differential Ratio Method for Underwater Object Detection , 2014, IEEE Geoscience and Remote Sensing Letters.

[13]  Andreas Antoniou,et al.  Characterization and decomposition of waveforms for Larsen 500 airborne system , 1991, IEEE Trans. Geosci. Remote. Sens..

[14]  John E. McFee,et al.  Standoff sensing of bioaerosols using intensified range-gated spectral analysis of laser-induced fluorescence , 2004, IEEE Transactions on Geoscience and Remote Sensing.

[15]  Peter Tian‐Yuan Shih,et al.  Historic Shipwreck Study in Dongsha Atoll with Bathymetric LiDAR , 2014 .

[16]  Jean Verdebout,et al.  Determination of aquatic parameters by a time-resolved laser fluorosensor operating from a helicopter , 1992, Other Conferences.

[17]  Andrew C. Singer,et al.  Three-dimensional tomographic imaging of ocean mines from real and simulated lidar returns , 2002, Optics + Photonics.

[18]  Fredrik Gustafsson,et al.  Influence of laser radar sensor parameters on range-measurement and shape-fitting uncertainties , 2007 .

[19]  Giovanna Cecchi,et al.  Remote sensing of chlorophyll a fluorescence of vegetation canopies: 1. Near and far field measurement techniques , 1994 .

[20]  Khaled Mohamed Almhdi,et al.  CLASSIFICATION WITH ARTIFICIAL NEURAL NETWORKS AND SUPPORT VECTOR MACHINES: APPLICATION TO OIL FLUORESCENCE SPECTRA , 2007 .

[21]  Abdelhak M. Zoubir,et al.  Unified Design of a Feature-Based ADAC System for Mine Hunting Using Synthetic Aperture Sonar , 2014, IEEE Transactions on Geoscience and Remote Sensing.

[22]  J. McLean,et al.  Lidar equations for turbid media with pulse stretching. , 1999, Applied optics.

[23]  Andrew C. Singer,et al.  3-D tomographic imaging of ocean mines from real and simulated lidar returns , 2001 .

[24]  Satarupa Banerjee,et al.  Lidar detection of underwater objects using a neuro-SVM-based architecture , 2006, IEEE Transactions on Neural Networks.

[25]  Vladimir Vapnik,et al.  An overview of statistical learning theory , 1999, IEEE Trans. Neural Networks.

[26]  Mireille Guillaume,et al.  Underwater Target Detection With Hyperspectral Data: Solutions for Both Known and Unknown Water Quality , 2012, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[27]  Tristan Cossio,et al.  Predicting Small Target Detection Performance of Low-SNR Airborne Lidar , 2010, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[28]  R. Gagosian,et al.  Characterization of dissolved organic matter in the Black Sea by fluorescence spectroscopy , 1990, Nature.

[29]  K. C. Slatton,et al.  Predicting Topographic and Bathymetric Measurement Performance for Low-SNR Airborne Lidar , 2009, IEEE Transactions on Geoscience and Remote Sensing.

[30]  R. Bro,et al.  Tracing dissolved organic matter in aquatic environments using a new approach to fluorescence spectroscopy , 2003 .

[31]  Eamonn J. Keogh,et al.  Experimental comparison of representation methods and distance measures for time series data , 2010, Data Mining and Knowledge Discovery.

[32]  M.D. DeVore,et al.  Analysis of data and model accuracy requirements for target classification using ladar data , 2008, IEEE Transactions on Aerospace and Electronic Systems.

[33]  F. Meer The effectiveness of spectral similarity measures for the analysis of hyperspectral imagery , 2006 .