Accuracy and Precision of Habitat Structural Complexity Metrics Derived from Underwater Photogrammetry

In tropical reef ecosystems corals are the key habitat builders providing most ecosystem structure, which influences coral reef biodiversity and resilience. Remote sensing applications have progressed significantly and photogrammetry together with application of structure from motion software is emerging as a leading technique to create three-dimensional (3D) models of corals and reefs from which biophysical properties of structural complexity can be quantified. This enables the addressing of a range of important marine research questions, such as what the role of habitat complexity is in driving key ecological processes (i.e., foraging). Yet, it is essential to assess the accuracy and precision of photogrammetric measurements to support their application in mapping, monitoring and quantifying coral reef form and structure. This study evaluated the precision (by repeated modeling) and accuracy (by comparison with laser reference models) of geometry and structural complexity metrics derived from photogrammetric 3D models of marine benthic habitat at two ecologically relevant spatial extents; individual coral colonies of a range of common morphologies and patches of reef area of 100s of square metres. Surface rugosity measurements were generally precise across all morphologies and spatial extents with average differences in the geometry of replicate models of 1–6 mm for coral colonies and 25 mm for the reef area. Precision decreased with complexity of the coral morphology, with metrics for small massive corals being the most precise (1% coefficient of variation (CV) in surface rugosity) and metrics for bottlebrush corals being the least precise (10% CV in surface rugosity). There was no indication however that precision was related to complexity for the patch-scale modelling. The 3D geometry of coral models differed by only 1–3 mm from laser reference models. However, high spatial variation in these differences around the model led to a consistent underestimation of surface rugosity values for all morphs of between 8% and 37%. This study highlights the utility of several off-the-shelf photogrammetry tools for the measurement of structural complexity across a range of scales relevant to ecologist and managers. It also provides important information on the accuracy and precision of these systems which should allow for their targeted use by non-experts in computer vision within these contexts.

[1]  Thomas A. Schlacher,et al.  New metric of microhabitat complexity predicts species richness on a rocky shore , 2013 .

[2]  Michael W. Beck,et al.  Comparison of the measurement and effects of habitat structure on gastropods in rocky intertidal and mangrove habitats , 1998 .

[3]  Michael J. Risk,et al.  Fish Diversity on a Coral Reef in the Virgin Islands , 1972 .

[4]  Jonathan Benjamin,et al.  Multi-image Photogrammetry for Underwater Archaeological Site Recording: An Accessible, Diver-Based Approach , 2014, Journal of Maritime Archaeology.

[5]  N. Graham,et al.  The importance of structural complexity in coral reef ecosystems , 2012, Coral Reefs.

[6]  Danielle M. Warfe,et al.  Habitat complexity: approaches and future directions , 2011, Hydrobiologia.

[7]  Vikram Pakrashi,et al.  A Comparison of Image Based 3D Recovery Methods for Underwater Inspections , 2014 .

[8]  Ross A. Coleman,et al.  Habitat identity influences species−area relationships in heterogeneous habitats , 2011 .

[9]  Morgan S. Pratchett,et al.  Climate change and the future for coral reef fishes , 2008 .

[10]  Cherisse Du Preez,et al.  A new arc–chord ratio (ACR) rugosity index for quantifying three-dimensional landscape structural complexity , 2015 .

[11]  C. D'Helft,et al.  Simple methods for interactive 3D modeling, measurements, and digital databases of coral skeletons , 2015 .

[12]  O. Pizarro,et al.  Large Area 3-D Reconstructions From Underwater Optical Surveys , 2009, IEEE Journal of Oceanic Engineering.

[13]  Benjamin P. Neal,et al.  A quick, easy and non‐intrusive method for underwater volume and surface area evaluation of benthic organisms by 3D computer modelling , 2015 .

[14]  Glenn De'ath,et al.  Declining Coral Calcification on the Great Barrier Reef , 2009, Science.

[15]  Alan M. Friedlander,et al.  Using bathymetric lidar to define nearshore benthic habitat complexity: Implications for management of reef fish assemblages in Hawaii , 2008 .

[16]  Oscar Pizarro,et al.  The Catlin Seaview Survey – kilometre‐scale seascape assessment, and monitoring of coral reef ecosystems , 2014 .

[17]  Peter J. Mumby,et al.  Predicting structural complexity of reefs and fish abundance using acoustic remote sensing (RoxAnn) , 2011 .

[18]  Matthijs C. Dorst Distinctive Image Features from Scale-Invariant Keypoints , 2011 .

[19]  Lael Parrott,et al.  Measuring ecological complexity , 2010 .

[20]  Stefan B. Williams,et al.  Multi-Scale Measures of Rugosity, Slope and Aspect from Benthic Stereo Image Reconstructions , 2012, PloS one.

[21]  David Scaradozzi,et al.  Innovative study methods for the Mediterranean coralligenous habitats , 2016 .

[22]  D. Delparte,et al.  Distributed under Creative Commons Cc-by 4.0 Integrating Structure-from-motion Photogrammetry with Geospatial Software as a Novel Technique for Quantifying 3d Ecological Characteristics of Coral Reefs , 2022 .

[23]  Bridgette K. Gunn,et al.  Predation Risk, Resource Quality, and Reef Structural Complexity Shape Territoriality in a Coral Reef Herbivore , 2015, PloS one.

[24]  Peter J Mumby,et al.  The dynamics of architectural complexity on coral reefs under climate change , 2015, Global change biology.

[25]  K. Moffett,et al.  Remote Sens , 2015 .

[26]  Ben Upcroft,et al.  Measuring reef complexity and rugosity from monocular video bathymetric reconstruction , 2012 .

[27]  Emma V. Kennedy,et al.  Biotic and multi-scale abiotic controls of habitat quality: their effect on coral-reef fishes , 2011 .

[28]  J. Blanchard,et al.  Vulnerability of Coral Reef Fisheries to a Loss of Structural Complexity , 2014, Current Biology.

[29]  Ben Upcroft,et al.  Towards automated and in-situ, near-real time 3-D reconstruction of coral reef environments , 2011, OCEANS'11 MTS/IEEE KONA.

[30]  F. Torre 3-D reconstruction of biological objects using underwater video technique and image processing , 2003 .

[31]  Renata Ferrari,et al.  The effectiveness of different meso-scale rugosity metrics for predicting intra-habitat variation in coral-reef fish assemblages , 2011, Environmental Biology of Fishes.

[32]  J. Bythell,et al.  Three-dimensional morphometric measurements of reef corals using underwater photogrammetry techniques , 2001, Coral Reefs.

[33]  S. Phinn,et al.  Measuring coral reef terrain roughness using 'Structure-from-Motion' close-range photogrammetry , 2015 .

[34]  M. Favalli,et al.  Multiview 3D reconstruction in geosciences , 2012, Comput. Geosci..

[35]  Larry B. Crowder,et al.  Small-scale demographic variability of the biocolor damselfish, Stegastes partitus, in the Florida Keys USA , 2008, Environmental Biology of Fishes.

[36]  C. Wild,et al.  A precise and non-destructive method to calculate the surface area in living scleractinian corals using X-ray computed tomography and 3D modeling , 2008, Coral Reefs.

[37]  Shahriar Negahdaripour,et al.  On Feature Matching and Image Registration for Two-dimensional Forward-scan Sonar Imaging , 2013, J. Field Robotics.

[38]  Stuart R. Phinn,et al.  Mapping Coral Reef Resilience Indicators Using Field and Remotely Sensed Data , 2013, Remote. Sens..

[39]  Shahriar Negahdaripour,et al.  On 3-D Motion Estimation From Feature Tracks in 2-D FS Sonar Video , 2013, IEEE Transactions on Robotics.

[40]  Jan Warnken,et al.  Investigating three‐dimensional mesoscale habitat complexity and its ecological implications using low‐cost RGB‐D sensor technology , 2014 .

[41]  Michael M. Kazhdan,et al.  Screened poisson surface reconstruction , 2013, TOGS.

[42]  Stefan B. Williams,et al.  Generation and visualization of large‐scale three‐dimensional reconstructions from underwater robotic surveys , 2010, J. Field Robotics.

[43]  E. Harvey,et al.  The application of predicted habitat models to investigate the spatial ecology of demersal fish assemblages , 2010 .

[44]  Sandy Raimondo,et al.  Estimating 3-dimensional colony surface area of field corals , 2007 .