Raking the ocean surface: new patterns of coordinated motion in seabirds

Assali, Camille; Bez, Nicolas; Tremblay, Yann

doi:10.1111/jav.02258

Cited by 8 publications

(4 citation statements)

References 63 publications

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“…This experimental device opens up the possibility for future analyses on the effects of a wide variety of ground types on the movement of ground‐dwelling arthropods. Additional video treatments or improved tracker algorithms (e.g., Assali et al, 2020) may be required in more complex environments, such as plant cover, where background noise management for trajectory extraction and individual recovery is challenging. In all cases, the spatial distribution of the cover units that could hide individuals should be set to allow the brief but regular appearance of the target species.…”

Section: Discussionmentioning

confidence: 99%

Assessing the effect of complex ground types on ground‐dwelling arthropod movements with video monitoring: Dealing with concealed movements under a layer of plant residues

Collard

Tixier

Carval

et al. 2022

Ecology and Evolution

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Understanding the effect of ground types on foraging movements of ground-dwelling arthropods is a key step to managing their spatial distribution as required for successful conservation biological control. Indeed, fine movements at the centimeter scale can strongly influence the foraging ability of pest predators. However, because radio frequency identification or harmonic tracking techniques are not yet suitable for small species and video tracking focuses on uniform and light backgrounds, foraging movements have rarely been studied in relation to ground types. We present a method to track a ground-dwelling arthropod (the earwig Euborellia caraibea) at night, walking on two contrasted ground types: bare soil and soil partly covered with a stratum of banana plant residues allowing individuals to hide periodically. The tracking of individuals within these ground types was achieved by infrared light, tagging individuals, video treatments, and semi-automatic cleaning of trajectories. We tested different procedures to obtain segments with identical durations to quantify speeds and sinuosities. These procedures were characterized by the junction time gap between trajectory fragments, the rediscretization time of trajectories, and whether or not to use interpolation to fill in missing points in the trajectories. Earwigs exhibited significantly slower and more sinuous movements on soil with banana plant residues than on bare soil. Long time gaps for trajectory junction, extended rediscretization times, and interpolation were complementary means to integrate concealed movements in the trajectories. The highest slowdown in plant residues was detected when the procedure could account for longer periods under the residues. These results suggest that earwigs spent a significant amount of time concealed by the residues. Additionally, the residues strongly decreased the earwigs' movement. Since the technical solutions presented in this study are inexpensive, easy to set up, and replicate, they represent valuable contributions to the emerging field of video monitoring.

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Section: Discussionmentioning

confidence: 99%

Assessing the effect of complex ground types on ground‐dwelling arthropod movements with video monitoring: Dealing with concealed movements under a layer of plant residues

Collard

Tixier

Carval

et al. 2022

Ecology and Evolution

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“…during searches and increase individual foraging efficiency for predators; indeed, this has been shown to be a vitalcomponent of the hunt when predators such as porpoises and seabirds search for fish schools (Norris et al, 1961;Hoffman, Heinemann & Wiens, 1981;Götmark, Winkler & Andersson, 1986;Barrett-Lennard, Ford & Heise, 1996;Benoit-Bird, Würsig & McFadden, 2004;Benoit-Bird & Au, 2009;Goodale et al, 2010;Assali, Bez & Tremblay, 2020). Flock leaders in colonies of black-billed gulls (Larus bulleri) call for flock mates to follow them during hunting outings (active information sharing; Evans, 1982) and during Cape gannet (Morus capensis) hunting trips aimed at fish schools, conspecifics act as directional cues and reduce the time to find a patch by half (passive information sharing; Thiebault et al, 2014a).…”

Section: Searchmentioning

confidence: 99%

“…density waves that can propagate across many hundreds of metres) as well as normal locomotion through the environment (Swartzman, 1997; Mackinson et al ., 1999; Gerlotto & Paramo, 2003; Makris et al ., 2006, 2009). Because of the complexity involved in spatially and temporally tracking these sorts of groups, the use of social information by predators can reduce individual error during searches and increase individual foraging efficiency for predators; indeed, this has been shown to be a vital component of the hunt when predators such as porpoises and seabirds search for fish schools (Norris et al ., 1961; Hoffman, Heinemann & Wiens, 1981; Götmark, Winkler & Andersson, 1986; Barrett‐Lennard, Ford & Heise, 1996; Benoit‐Bird, Würsig & McFadden, 2004; Benoit‐Bird & Au, 2009; Goodale et al ., 2010; Assali, Bez & Tremblay, 2020). Flock leaders in colonies of black‐billed gulls ( Larus bulleri ) call for flock mates to follow them during hunting outings (active information sharing; Evans, 1982) and during Cape gannet ( Morus capensis ) hunting trips aimed at fish schools, conspecifics act as directional cues and reduce the time to find a patch by half (passive information sharing; Thiebault et al ., 2014 a ).…”

Section: Mechanisms Within Hunt Stagesmentioning

confidence: 99%

Mechanisms of group‐hunting in vertebrates

et al. 2023

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Group‐hunting is ubiquitous across animal taxa and has received considerable attention in the context of its functions. By contrast much less is known about the mechanisms by which grouping predators hunt their prey. This is primarily due to a lack of experimental manipulation alongside logistical difficulties quantifying the behaviour of multiple predators at high spatiotemporal resolution as they search, select, and capture wild prey. However, the use of new remote‐sensing technologies and a broadening of the focal taxa beyond apex predators provides researchers with a great opportunity to discern accurately how multiple predators hunt together and not just whether doing so provides hunters with a per capita benefit. We incorporate many ideas from collective behaviour and locomotion throughout this review to make testable predictions for future researchers and pay particular attention to the role that computer simulation can play in a feedback loop with empirical data collection. Our review of the literature showed that the breadth of predator:prey size ratios among the taxa that can be considered to hunt as a group is very large (<100 to >102). We therefore synthesised the literature with respect to these predator:prey ratios and found that they promoted different hunting mechanisms. Additionally, these different hunting mechanisms are also related to particular stages of the hunt (search, selection, capture) and thus we structure our review in accordance with these two factors (stage of the hunt and predator:prey size ratio). We identify several novel group‐hunting mechanisms which are largely untested, particularly under field conditions, and we also highlight a range of potential study organisms that are amenable to experimental testing of these mechanisms in connection with tracking technology. We believe that a combination of new hypotheses, study systems and methodological approaches should help push the field of group‐hunting in new directions.

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“…In this paper, “network foraging” will mean that birds match velocities and maintain a preferred spacing with each other while searching for food, i.e., flocking or schooling behavior (Suzuki and Sakai 1973, Okubo 1986, Parrish and Hamner 1997). The behavior I call network foraging has in fact been recently documented in the wild, in the kilometer‐scale “rake” patterns of seabirds observed on radar by Assali et al (2020). “Local enhancement,” in contrast, will refer only to the local phenomenon of birds joining compact flocks that are already feeding.…”

Section: Introductionmentioning

confidence: 97%

Visual trail following in colonial seabirds: theory, simulation, and remote observations

Urmy

2020

Ecological Monographs

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Seabirds have long been thought to exploit social information when searching for their prey, the distribution of which is often patchy and variable. The fact that most seabirds breed colonially has led to speculation that colonies serve as “information centers,” allowing their inhabitants to learn about the distribution of food by observing or following other successful foragers, though this hypothesis is controversial and the evidence for it is mixed. However, several recent studies have documented behaviors that suggest some seabirds do exploit social orientation cues at or near their colonies in order to orient toward food. In this paper, I explore in‐depth one such social orientation behavior, which I call “visual trail following.” I derived a simple model of information transfer and showed that trail following should be favored over other commonly hypothesized foraging behaviors. An individual‐based simulation model was then used to test this theoretical prediction against several other foraging strategies while varying prey patchiness and colony size. The model's results showed that trail following was the optimal strategy across a wide range of conditions. Finally, I used radar data recorded at a tern colony in coastal New York to demonstrate evidence for trail following in the movements of wild seabirds. These results show that trail following and similar behaviors are effective foraging strategies that are likely important for seabirds and other colonial animals.

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Raking the ocean surface: new patterns of coordinated motion in seabirds

Cited by 8 publications

References 63 publications

Assessing the effect of complex ground types on ground‐dwelling arthropod movements with video monitoring: Dealing with concealed movements under a layer of plant residues

Assessing the effect of complex ground types on ground‐dwelling arthropod movements with video monitoring: Dealing with concealed movements under a layer of plant residues

Mechanisms of group‐hunting in vertebrates

Visual trail following in colonial seabirds: theory, simulation, and remote observations

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