Life in 2.5D: Animal Movement in the Trees

Harel, Roi; Alavi, Shauhin E.; Ashbury, Alison M.; Aurisano, Jillian; Berger-Wolf, Tanya Y.; Davis, Grace H.; Hirsch, Ben T.; Kalbitzer, Urs; Kays, Roland; McLean, Kevin A.; Núñez, Chase L.; Vining, Alexander Q.; Walton, Zea; Havmøller, Rasmus Worsøe; Crofoot, Margaret C.

doi:10.3389/fevo.2022.801850

Cited by 7 publications

(5 citation statements)

References 66 publications

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“…There could also be significant differences in travel costs between the four species. We assume that coati terrestrial locomotion expends less energy than arboreal movements of capuchins, which include substantial vertical leaping and climbing [59], although arboreal species can reduce locomotor costs in hilly areas by traveling at consistent altitudes within the canopy [60]. How these differences in locomotor costs affect foraging efficiency is not known.…”

Section: Discussionmentioning

confidence: 99%

Smarter foragers do not forage smarter: a test of the diet hypothesis for brain expansion

Hirsch,

Kays,

Alavi

et al. 2024

Proc. R. Soc. B.

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A leading hypothesis for the evolution of large brains in humans and other species is that a feedback loop exists whereby intelligent animals forage more efficiently, which results in increased energy intake that fuels the growth and maintenance of large brains. We test this hypothesis for the first time with high-resolution tracking data from four sympatric, frugivorous rainforest mammal species (42 individuals) and drone-based maps of their predominant feeding trees. We found no evidence that larger-brained primates had more efficient foraging paths than smaller brained procyonids. This refutes a key assumption of the fruit-diet hypothesis for brain evolution, suggesting that other factors such as temporal cognition, extractive foraging or sociality have been more important for brain evolution.

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Section: Discussionmentioning

confidence: 99%

Smarter foragers do not forage smarter: a test of the diet hypothesis for brain expansion

Hirsch,

Kays,

Alavi

et al. 2024

Proc. R. Soc. B.

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“…This suggests that the unique sensory and locomotor adaptations of these species were not different enough to result in consistently large differences in these most basic components of movement: step lengths or turning angles. However, step-level metrics are the most likely to be affected by sampling rate GPS error, and potentially even vertical movement (which we didn’t study, but see [ 20 ]), which could have obscured species differences. Other studies comparing step metrics across species have found differences in step length associated with phylogeny, ecology, and human disturbance for terrestrial species, but fewer differences across marine taxa [ 44 , 47 , 48 ].…”

Section: Discussionmentioning

confidence: 99%

Multi-scale movement syndromes for comparative analyses of animal movement patterns

Kays,

Hirsch,

Caillaud

et al. 2023

Mov Ecol

Self Cite

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Background Animal movement is a behavioral trait shaped by the need to find food and suitable habitat, avoid predators, and reproduce. Using high-resolution tracking data, it is possible to describe movement in greater detail than ever before, which has led to many discoveries about the behavioral strategies of particular species. Recently, enough data been become available to enable a comparative approach, which has the potential to uncover general causes and consequences of variation in movement patterns, but which must be scale specific. Methods Here we introduce a new multi-scale movement syndrome (MSMS) framework for describing and comparing animal movements and use it to explore the behavior of four sympatric mammals. MSMS incorporates four hierarchical scales of animal movement: (1) fine-scale movement steps which accumulate into (2) daily paths which then, over weeks or months, form a (3) life-history phase. Finally, (4) the lifetime track of an individual consists of multiple life-history phases connected by dispersal or migration events. We suggest a series of metrics to describe patterns of movement at each of these scales and use the first three scales of this framework to compare the movement of 46 animals from four frugivorous mammal species. Results While subtle differences exist between the four species in their step-level movements, they cluster into three distinct movement syndromes in both path- and life-history phase level analyses. Differences in feeding ecology were a better predictor of movement patterns than a species’ locomotory or sensory adaptations. Conclusions Given the role these species play as seed dispersers, these movement syndromes could have important ecosystem implications by affecting the pattern of seed deposition. This multiscale approach provides a hierarchical framework for comparing animal movement for addressing ecological and evolutionary questions. It parallels scales of analyses for resource selection functions, offering the potential to connect movement process with emergent patterns of space use.

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“…• Investigation of movement and movement patterns on different levels of scale [53][54][55] and individual or collective movement [24], such as home-range, territorial behavior, and swarm movement • Interaction between individuals or groups [56,57], e.g., in movement, predation, and decision making [58] • Impact of environmental conditions, e.g., on decision making, social dynamics, or survival [18,19,59, 60] • Differences in species and groups, e.g., based on phenotypic variation [61] or related to evolutionary relation • Cognitive processes underlying behavioral patterns, e.g., foraging or mate choice [62] • Prediction and modeling of behavior [13,63] The available information on animal behavior and movement is usually collected by sensors, imaging, and subsequent processing of the results. Analysis methods need to exhibit a certain level of robustness toward incomplete and noisy data and be capable of coping with the uncertainty associated with it.…”

Section: Challenges From Animal Ecologymentioning

confidence: 99%

“…In a holistic approach, the enriched recreation of the environment and information on animal behavior can be combined with access to analysis methods and pipelines, supporting an immersive interactive experience and analysis. For example, Harel et al [59] discussed the representation of arboreal animal movements and decision making in VR. They mapped the 2.5D setting of canopy environments into a S3D environment for detailed analysis.…”

Section: Potential For Synergies and Researchmentioning

confidence: 99%

“…They mapped the 2.5D setting of canopy environments into a S3D environment for detailed analysis. As the ability to precisely measure movement and position is improving, more fine-grained options for representation are becoming available, which may support a better understanding of animal decisionmaking, for example, regarding the trade-off between risk and reward [59]. However, as Harel et al mention, current technologies used to collect data, such as sensor collars or drones, may still have an impact on the available decision options of the animal and the decisions taken.…”

Section: Potential For Synergies and Researchmentioning

confidence: 99%

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Beyond the horizon: immersive developments for animal ecology research

Zhang

Klein

Schreiber

et al. 2023

Vis. Comput. Ind. Biomed. Art

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More diverse data on animal ecology are now available. This “data deluge” presents challenges for both biologists and computer scientists; however, it also creates opportunities to improve analysis and answer more holistic research questions. We aim to increase awareness of the current opportunity for interdisciplinary research between animal ecology researchers and computer scientists. Immersive analytics (IA) is an emerging research field in which investigations are performed into how immersive technologies, such as large display walls and virtual reality and augmented reality devices, can be used to improve data analysis, outcomes, and communication. These investigations have the potential to reduce the analysis effort and widen the range of questions that can be addressed. We propose that biologists and computer scientists combine their efforts to lay the foundation for IA in animal ecology research. We discuss the potential and the challenges and outline a path toward a structured approach. We imagine that a joint effort would combine the strengths and expertise of both communities, leading to a well-defined research agenda and design space, practical guidelines, robust and reusable software frameworks, reduced analysis effort, and better comparability of results.

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Life in 2.5D: Animal Movement in the Trees

Cited by 7 publications

References 66 publications

Smarter foragers do not forage smarter: a test of the diet hypothesis for brain expansion

Smarter foragers do not forage smarter: a test of the diet hypothesis for brain expansion

Multi-scale movement syndromes for comparative analyses of animal movement patterns

Beyond the horizon: immersive developments for animal ecology research

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