Abstract
Coral reef habitat structural complexity influences key ecological processes, ecosystem biodiversity, and resilience. Measuring structural complexity underwater is not trivial and researchers have been searching for accurate and cost-effective methods that can be applied across spatial extents for over 50 years. This study integrated a set of existing multi-view, image-processing algorithms, to accurately compute metrics of structural complexity (e.g., ratio of surface to planar area) underwater solely from images. This framework resulted in accurate, high-speed 3D habitat reconstructions at scales ranging from small corals to reef-scapes (10s km2). Structural complexity was accurately quantified from both contemporary and historical image datasets across three spatial scales: (i) branching coral colony (Acropora spp.); (ii) reef area (400 m2); and (iii) reef transect (2 km). At small scales, our method delivered models with <1 mm error over 90% of the surface area, while the accuracy at transect scale was 85.3% ± 6% (CI). Advantages are: no need for an a priori requirement for image size or resolution, no invasive techniques, cost-effectiveness, and utilization of existing imagery taken from off-the-shelf cameras (both monocular or stereo). This remote sensing method can be integrated to reef monitoring and improve our knowledge of key aspects of coral reef dynamics, from reef accretion to habitat provisioning and productivity, by measuring and up-scaling estimates of structural complexity.
Highlights
Structural complexity is a key habitat feature that influences ecological processes by providing a suite of primary and secondary resources to organisms, such as shelter from predators and availability of food [1,2,3,4]
3D model, our accuracy applies to the entire surface area of the coral
We were able to flip this piece of coral over to obtain images of all surfaces; our accuracy applies to the entire surface area of the coral
Summary
Structural complexity is a key habitat feature that influences ecological processes by providing a suite of primary and secondary resources to organisms, such as shelter from predators and availability of food [1,2,3,4]. Our current knowledge of underwater ecosystems and their trajectory is impaired by the lack of understanding of how structural complexity directly and indirectly influences important ecological processes [9]. Three-dimensional habitat structural complexity is a key driver of ecosystem diversity, function, and resilience in many ecosystems [11], yet the field of marine ecology lacks the tools to effectively quantify 3D features from underwater environments. Researchers employ a range of techniques to estimate habitat structural complexity, and related metrics, such as surface area and volume [14,16]
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