Photogrammetry as a tool to improve ecosystem restoration

Ferrari, Renata; Lachs, Liam; Pygas, Daniel; Humanes, Adriana; Sommer, Brigitte; Figueira, Will F.; Edwards, Alasdair J.; Bythell, John C.; Guest, James R.

doi:10.1016/j.tree.2021.07.004

Cited by 25 publications

(28 citation statements)

References 59 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…With the rise in remote sensing technologies (Section ‘ On the rise of remote‐sensing technologies in ecology ’), the idea of translating some metric of habitat complexity (e.g. obtained from scanning diverse or pristine natural environments) into real‐world solutions is tantalising (Calders et al, 2020 ; Ferrari et al, 2021 ). These solutions range from replanting or introducing trees and habitat‐forming species to adding physical elements to manipulate habitat structure in both natural and urban environments (Morris et al, 2019 ; Palmer et al, 2010 ).…”

Section: Applied Significancementioning

confidence: 99%

“…Complexity metrics are also being used as success indicators for restoration programs. It has been suggested that techniques such as photogrammetry will improve restoration success by enabling the measurement of complexity with ‘unprecedented accuracy’ (Ferrari et al, 2021 ). Again, this premise is built on the assumption that we already have reliable, accurate metrics of complexity; but, unfortunately, we do not.…”

Section: Applied Significancementioning

confidence: 99%

See 1 more Smart Citation

Measuring habitat complexity and spatial heterogeneity in ecology

Loke

Chisholm

2022

Ecology Letters

View full text Add to dashboard Cite

Habitat complexity has been considered a key driver of biodiversity and other ecological phenomena for nearly a century. However, there is still no consensus over the definition of complexity or how to measure it. Up-to-date and clear guidance on measuring complexity is urgently needed, particularly given the rise of remote sensing and advent of technologies that allow environments to be scanned at unprecedented spatial extents and resolutions. Here we review how complexity is measured in ecology. We provide a framework for metrics of habitat complexity, and for the related concept of spatial heterogeneity. We focus on the two most commonly used complexity metrics in ecology: fractal dimension and rugosity.We discuss the pros and cons of these metrics using practical examples from our own empirical data and from simulations. Fractal dimension is particularly widely used, and we provide a critical examination of it drawing on research from other scientific fields. We also discuss informational metrics of complexity and their potential benefits. We chart a path forward for research on measuring habitat complexity by presenting, as a guide, sets of essential and desirable criteria that a metric of complexity should possess. Lastly, we discuss the applied significance of our review.

show abstract

Section: Applied Significancementioning

confidence: 99%

Section: Applied Significancementioning

confidence: 99%

Measuring habitat complexity and spatial heterogeneity in ecology

Loke

Chisholm

2022

Ecology Letters

View full text Add to dashboard Cite

show abstract

“…0.25 m 2 quadrats (Ohara et al 2021), with a restricted range of metrics collected. However, the development of underwater imaging tools such as 'structure from motion' (SfM) photogrammetry now enables researchers to track millimetre-scale changes in reef environments over large areas (> ~ 500 m 2 ) within a single dive (Bayley and Mogg 2020;Ferrari et al 2021). Survey locations can then be repeatedly returned to once marked, using photogrammetry to track various changes at the frequency of choice-be it days or years (Magel et al 2019;Bongaerts et al 2020;Cresswell et al 2020).…”

Section: Supplementary Informationmentioning

confidence: 99%

Mushroom to manoeuvre? Using photogrammetry to track the movement and survival of free-living corals

Bayley

Mogg²

2022

Coral Reefs

View full text Add to dashboard Cite

Mushroom corals can play an important role in tropical reef ecosystems by providing habitat and performing important ecological functions. Unlike most stony corals, free-living mushroom corals can move, both passively and actively, and can use this ability to escape competition or harmful environments. However, as their movement is typically slow, occurs over relatively small scales, and is traditionally hard to measure, their movement ecology is little researched. Nevertheless, quantitative geospatial data on species’ movement, distribution, survival, and interaction can improve mechanistic modelling of community dynamics in various environments. We use ‘structure from motion’ photogrammetry to track 51 individual corals’ 3D movement and survival over one year within an isolated and enclosed lagoon. This technique essentially provides a large-scale quantitative community time-lapse and allows detailed individual level life-history data to be collected over spatial and temporal scales that were previously impractical.

show abstract

“…Traditionally, 3D growth forms in corals have been measured, including destructive computed tomography (CT; Foster et al, 2016) or non‐destructive ‘structure from motion’ (SfM; Friedman et al, 2012; Young et al, 2017). This latter work has included 3D reconstruction of individual colonies that are precise to the mm range (Ferrari et al, 2021; Lange & Perry, 2020; Million et al, 2021) or 3D scanning of the benthos over large areas (e.g. the ReefCloud program), including field photogrammetry of reefscapes.…”

Section: Introductionmentioning

confidence: 99%

A fast, precise, in‐vivo method for micron‐level 3D models of corals using dental scanners

Quigley

2022

Methods Ecol Evol

View full text Add to dashboard Cite

Several sampling and measurement strategies have been developed to assess biological forms in three dimensions, including corals. However, the effectiveness (in speed and precision) of current three‐dimensional (3D) methods in scanning and model construction are challenging at small scales (μm–mm). In this paper, a practical 3D scanning and model construction tool using an intra‐oral dental scanner was assessed to measure the surface area and volume of coral juveniles across multiple species. Intra‐oral scanners using confocal imaging are fast, precise to the μm scale and safe to use with live tissue, thereby eliminating the need to harm or kill the animals. The trial was conducted at the National Sea Simulator at the Australian Institute of Marine Science. High‐quality 3D scans of individual coral juveniles were successfully generated and integrated automatically into high‐resolution (μm) mesh from point clouds. The attained average scanning efficiency was <2 min/individual, without a significant difference in speed given coral complexity or between live colonies or dead coral skeletons. Overall, this fast and precise system could become a promising tool for marine environmental surveys and restoration initiatives. This tool also removes the need to sacrifice animals for measurement analysis, thereby increasing conservation and animal welfare.

show abstract

Photogrammetry as a tool to improve ecosystem restoration

Cited by 25 publications

References 59 publications

Measuring habitat complexity and spatial heterogeneity in ecology

Measuring habitat complexity and spatial heterogeneity in ecology

Mushroom to manoeuvre? Using photogrammetry to track the movement and survival of free-living corals

A fast, precise, in‐vivo method for micron‐level 3D models of corals using dental scanners

Contact Info

Product

Resources

About