Joining the dots: reconstructing 3D environments and movement paths using animal-borne devices

McClune, David W.

doi:10.1186/s40317-018-0150-6

Cited by 6 publications

(5 citation statements)

References 83 publications

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“…Technological advances allow for increasingly accurate and detailed mapping of complex canopy habitat structure. Light Detection and Ranging (LiDAR) systems can map the threedimensional architecture of forests (Davies and Asner, 2014;Rodríguez-Ronderos et al, 2016;McClune, 2018;Moorthy et al, 2019), and when mounted on a drone or a plane, offer promising opportunities for balancing fine-scale and landscapelevel measurements of tree and forest structure, canopy height, and vegetation density (Asner et al, 2008). Satellite-borne LiDAR systems can also measure vertical canopy structure at larger spatial scales, although with coarser resolution (e.g., Global Ecosystem Dynamics Investigation, GEDI) (Dubayah et al, 2020;Lang et al, 2021).…”

Section: A Virtual Window Into a 25d Worldmentioning

confidence: 99%

Life in 2.5D: Animal Movement in the Trees

et al. 2022

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The complex, interconnected, and non-contiguous nature of canopy environments present unique cognitive, locomotor, and sensory challenges to their animal inhabitants. Animal movement through forest canopies is constrained; unlike most aquatic or aerial habitats, the three-dimensional space of a forest canopy is not fully realized or available to the animals within it. Determining how the unique constraints of arboreal habitats shape the ecology and evolution of canopy-dwelling animals is key to fully understanding forest ecosystems. With emerging technologies, there is now the opportunity to quantify and map tree connectivity, and to embed the fine-scale horizontal and vertical position of moving animals into these networks of branching pathways. Integrating detailed multi-dimensional habitat structure and animal movement data will enable us to see the world from the perspective of an arboreal animal. This synthesis will shed light on fundamental aspects of arboreal animals’ cognition and ecology, including how they navigate landscapes of risk and reward and weigh energetic trade-offs, as well as how their environment shapes their spatial cognition and their social dynamics.

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Section: A Virtual Window Into a 25d Worldmentioning

confidence: 99%

Life in 2.5D: Animal Movement in the Trees

et al. 2022

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“…In both of these studies, the environments mapped were , but there is currently growing interest in reconstructing an animal’s experience of its environment at much larger scales, relevant to ecology and conservation (Tuia et al, 2022 ). This interest has led to demonstrations of animal-borne 3D mapping sensors (McClune, 2018 ), and a mobile-camera method for embedding an animal’s track in an aerial view of its environment (Haalck et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Through Hawks’ Eyes: Synthetically Reconstructing the Visual Field of a Bird in Flight

et al. 2023

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Birds of prey rely on vision to execute flight manoeuvres that are key to their survival, such as intercepting fast-moving targets or navigating through clutter. A better understanding of the role played by vision during these manoeuvres is not only relevant within the field of animal behaviour, but could also have applications for autonomous drones. In this paper, we present a novel method that uses computer vision tools to analyse the role of active vision in bird flight, and demonstrate its use to answer behavioural questions. Combining motion capture data from Harris’ hawks with a hybrid 3D model of the environment, we render RGB images, semantic maps, depth information and optic flow outputs that characterise the visual experience of the bird in flight. In contrast with previous approaches, our method allows us to consider different camera models and alternative gaze strategies for the purposes of hypothesis testing, allows us to consider visual input over the complete visual field of the bird, and is not limited by the technical specifications and performance of a head-mounted camera light enough to attach to a bird’s head in flight. We present pilot data from three sample flights: a pursuit flight, in which a hawk intercepts a moving target, and two obstacle avoidance flights. With this approach, we provide a reproducible method that facilitates the collection of large volumes of data across many individuals, opening up new avenues for data-driven models of animal behaviour.

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“…Reconstructing animal movement paths is an important tool in ecology, providing insights into animal space-use, behaviour and habitat selection [1][2][3]. However, accurate estimation of paths at fine temporal scales has proved a persistent challenge [4,5].…”

Section: Introductionmentioning

confidence: 99%

Dead-reckoning animal movements in R: a reappraisal using Gundog.Tracks

et al. 2021

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Background Fine-scale data on animal position are increasingly enabling us to understand the details of animal movement ecology and dead-reckoning, a technique integrating motion sensor-derived information on heading and speed, can be used to reconstruct fine-scale movement paths at sub-second resolution, irrespective of the environment. On its own however, the dead-reckoning process is prone to cumulative errors, so that position estimates quickly become uncoupled from true location. Periodic ground-truthing with aligned location data (e.g., from global positioning technology) can correct for this drift between Verified Positions (VPs). We present step-by-step instructions for implementing Verified Position Correction (VPC) dead-reckoning in R using the tilt-compensated compass method, accompanied by the mathematical protocols underlying the code and improvements and extensions of this technique to reduce the trade-off between VPC rate and dead-reckoning accuracy. These protocols are all built into a user-friendly, fully annotated VPC dead-reckoning R function; Gundog.Tracks, with multi-functionality to reconstruct animal movement paths across terrestrial, aquatic, and aerial systems, provided within the Additional file 4 as well as online (GitHub). Results The Gundog.Tracks function is demonstrated on three contrasting model species (the African lion Panthera leo, the Magellanic penguin Spheniscus magellanicus, and the Imperial cormorant Leucocarbo atriceps) moving on land, in water and in air. We show the effect of uncorrected errors in speed estimations, heading inaccuracies and infrequent VPC rate and demonstrate how these issues can be addressed. Conclusions The function provided will allow anyone familiar with R to dead-reckon animal tracks readily and accurately, as the key complex issues are dealt with by Gundog.Tracks. This will help the community to consider and implement a valuable, but often overlooked method of reconstructing high-resolution animal movement paths across diverse species and systems without requiring a bespoke application.

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Joining the dots: reconstructing 3D environments and movement paths using animal-borne devices

Cited by 6 publications

References 83 publications

Life in 2.5D: Animal Movement in the Trees

Life in 2.5D: Animal Movement in the Trees

Through Hawks’ Eyes: Synthetically Reconstructing the Visual Field of a Bird in Flight

Dead-reckoning animal movements in R: a reappraisal using Gundog.Tracks

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