Responsive robotic prey reveal how predators adapt to predictability in escape tactics

Szopa-Comley, Andrew W.; Ioannou, Christos C.

doi:10.1073/pnas.2117858119

Cited by 17 publications

(21 citation statements)

References 72 publications

(110 reference statements)

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“…The advantage of a virtual prey system allowing for precise control over prey traits and hence minimising confounding effects is, however, countered by the limited range of predators that are suitable for testing in such an artificial, laboratory-based set up. Another valuable extension of the results here would be to explore the consequence of allowing predators repeated exposure to prey that vary in their movement pattern, as recently we have shown that predators can adapt to unpredictability of fleeing prey [16]. Any such future work would ideally not only consider the choice of which prey is targeted amongst those displaying different types of motion, but also allow the prey to be captured and consumed so that attack success can be measured.…”

Section: Resultsmentioning

confidence: 99%

“…However, except for apex predators, how animals move in space also determines encounter rates with, and conspicuousness to, their own predators [10–12]. It is also generally considered that unpredictable movement by prey may hinder capture by predators [13–15, although see 16]; the lack of turns during longer step lengths may increase the short-term predictability of movement and so increase predation risk. Here we use a system of fish predators (three-spined sticklebacks, Gasterosteus aculeatus ) targeting computer-generated prey whose motion can be entirely controlled [17,18] to test the hypothesis that prey with Lévy motion are targeted preferentially relative to prey with Brownian motion, potentially revealing a cost of Lévy motion that counteracts the benefits for finding resources [4–7].…”

Section: Introductionmentioning

confidence: 99%

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Predatory fish preferentially target virtual prey with Lévy motion rather than Brownian motion

Ioannou

Carvalho

Budleigh

et al. 2022

Preprint

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Of widespread interest in animal behaviour and ecology is how animals search their environment for resources, and whether these search strategies are optimal. However, movement also affects predation risk through effects on encounter rates, the conspicuousness of prey, and the success of attacks. Here we use predatory fish attacking a simulation of virtual prey to test whether predation risk is associated with movement behaviour. Despite often being demonstrated to be a more efficient strategy for finding resources, we find that prey displaying Lévy motion are twice as likely to be targeted by predators than prey utilising Brownian motion. This result emphasises that costs of predation risk need to be considered alongside the foraging benefits when comparing different movement strategies.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Predatory fish preferentially target virtual prey with Lévy motion rather than Brownian motion

Ioannou

Carvalho

Budleigh

et al. 2022

Preprint

Self Cite

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“…The effectiveness of protean motion may also differ depending on the predators' approach to the prey. For instance, an ambush predator may be less likely to adjust and modify their trajectory and tactics rapidly, compared to a pursuit predator (Szopa-Comley & Ioannou, 2022). Furthermore, unpredictable motion may be more effective during initial attempts to escape, as the predator may adapt to the prey's path after a certain period.…”

Section: Misleading Motion Signalsmentioning

confidence: 99%

Antipredator defences in motion: animals reduce predation risks by concealing or misleading motion signals

Tan,

Zhang,

Stevens

et al. 2024

Biological Reviews

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Motion is a crucial part of the natural world, yet our understanding of how animals avoid predation whilst moving remains rather limited. Although several theories have been proposed for how antipredator defence may be facilitated during motion, there is often a lack of supporting empirical evidence, or conflicting findings. Furthermore, many studies have shown that motion often ‘breaks’ camouflage, as sudden movement can be detected even before an individual is recognised. Whilst some static camouflage strategies may conceal moving animals to a certain extent, more emphasis should be given to other modes of camouflage and related defences in the context of motion (e.g. flicker fusion camouflage, active motion camouflage, motion dazzle, and protean motion). Furthermore, when motion is involved, defence strategies are not necessarily limited to concealment. An animal can also rely on motion to mislead predators with regards to its trajectory, location, size, colour pattern, or even identity. In this review, we discuss the various underlying antipredator strategies and the mechanisms through which they may be linked to motion, conceptualising existing empirical and theoretical studies from two perspectives – concealing and misleading effects. We also highlight gaps in our understanding of these antipredator strategies, and suggest possible methodologies for experimental designs/test subjects (i.e. prey and/or predators) and future research directions.

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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). Some toothed whales are estimated to be able to detect prey up to 300 m away using echolocation (Madsen et al, 2007), and it may be possible that conspecifics eavesdrop on the echoes of their groupmates (passive information sharing).…”

Section: Searchmentioning

confidence: 99%

“…In these experiments, the precise movements of robotic prey (or predators) can be programmed to provide controls that are impossible with real animals (Bierbach et al ., 2021; Landgraf et al ., 2021). Recently, robotic fish have been used as prey to test how the predictability of the escape path affects predator pursuit behaviour (Szopa‐Comley & Ioannou, 2022), and robots have also been used to assess differences in social responsiveness between social partners (Bierbach et al ., 2018) and how movement variables such as speed drive patterns of collective movement (Jolles et al ., 2020).…”

Section: Behavioural Roles and Simulationsmentioning

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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Responsive robotic prey reveal how predators adapt to predictability in escape tactics

Cited by 17 publications

References 72 publications

Predatory fish preferentially target virtual prey with Lévy motion rather than Brownian motion

Predatory fish preferentially target virtual prey with Lévy motion rather than Brownian motion

Antipredator defences in motion: animals reduce predation risks by concealing or misleading motion signals

Mechanisms of group‐hunting in vertebrates

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