Diverted by dazzle: perceived movement direction is biased by target pattern orientation

Hughes, Anna E.; Jones, Christian; Joshi, Kaustuv; Tolhurst, David J.

doi:10.1098/rspb.2017.0015

Cited by 16 publications

(13 citation statements)

References 55 publications

(85 reference statements)

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“…Secondly, the fact that Hughes et al . 42 employed continuously-moving stimuli may have weakened the effects relative to those in the present study. It is widely known that continuous (or “short-range”) motion is detected by early motion energy detectors whereas long-range motion (produced by our stimuli with discrete-jumps and blank ISIs) is processed by higher-order motion detectors 43 , 44 .…”

Section: Discussioncontrasting

confidence: 68%

“…It is sensible that orientation information should also assist higher-order motion processing if it can contribute to more accurate estimates of motion direction. The orientation-induced shift in perceived motion direction is increased by shorter motion trajectories as well as by faster motion (<15 deg/sec) 42 . Note that we found a subtle proportional increment of the maximum shift when apparent motion became faster up to about 15 deg/sec (Experiment 1) and speed will be another factor of the directional shift or even it might be a by-product of speed modulated by orientation information 54 .…”

Section: Discussionmentioning

confidence: 97%

“…Recently, Hughes et al . 42 had observers localize apparent position as extrapolated from the motion trajectory of grating stimuli and revealed that directional shifts in motion trajectory depend on the grating orientation. The directional shift found in our study (~6 deg) is much larger than that reported in the Hughes et al .…”

Section: Discussionmentioning

confidence: 99%

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Apparent shift in long-range motion trajectory by local pattern orientation

Nakayama

Harada

Kamachi

et al. 2018

Sci Rep

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The present study shows that the apparent direction of a moving pattern is systematically affected by its orientation. We found that the perceived direction of motion of a single Gabor grating changing position in discrete steps interleaved by blank inter-stimulus interval (ISI) is biased toward the orientation of the grating. This orientation-induced motion shift peaks for grating orientations ~±15 deg away from the physical motion trajectory and was profound for relatively short distances. Orientation adaptation revealed that the directional shift is determined by the apparent –not the physical –orientation of the grating, and a subsequent experiment demonstrated that directional shift is also influenced by the orientation of the contrast-defined stimulus envelope. Results provide further evidence that the apparent trajectory of a motion stimulus is determined by interactions between motion and pattern information at relatively high levels of visual processing.

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Section: Discussioncontrasting

confidence: 68%

Section: Discussionmentioning

confidence: 97%

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Apparent shift in long-range motion trajectory by local pattern orientation

Nakayama

Harada

Kamachi

et al. 2018

Sci Rep

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“…fish (Kjernsmo & Merilaita, ); mammals (Powell, ); lizards (Cooper & Vitt, ); insects (Prudic et al ., )), such markings can protect the prey from predation. Another type of striking prey coloration, which have been termed motion dazzle patterns, includes stripes, bands and zigzags and are thought to protect moving prey by hampering the attacking predator's perception of speed or trajectory (Stevens et al ., ; Scott‐Samuel et al ., ; Murali & Kodandaramaiah, ; Hughes et al ., ), an idea initially proposed by Thayer ().…”

Section: Introductionmentioning

confidence: 99%

Grab my tail: evolution of dazzle stripes and colourful tails in lizards

Murali

Merilaita

Kodandaramaiah

2018

J of Evolutionary Biology

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Understanding the functions of animal coloration has been a long-standing question in evolutionary biology. For example, the widespread occurrence of striking longitudinal stripes and colourful tails in lizards begs for an explanation. Experiments have suggested that colourful tails can deflect attacks towards the tail (the 'deflection' hypothesis), which is sacrificable in most lizards, thereby increasing the chance of escape. Studies also suggest that in moving lizards, longitudinal body stripes can redirect predators' strikes towards the tail through the 'motion dazzle' effect. Despite these experimental studies, the ecological factors associated with the evolution of such striking colorations remain unexplored. Here, we investigated whether predictions from motion dazzle and attack deflection could explain the widespread occurrence of these striking marks using comparative methods and information on eco-physiological variables (caudal autotomy, diel activity, microhabitat and body temperature) potentially linked to their functioning. We found both longitudinal stripes and colourful tails are associated with diurnal activity and with the ability to lose the tail. Compared to stripeless species, striped species are more likely to be ground-dwelling and have higher body temperature, emphasizing the connection of stripes to mobility and rapid escape strategy. Colourful tails and stripes have evolved multiple times in a correlated fashion, suggesting that their functions may be linked. Overall, our results together with previous experimental studies support the notion that stripes and colourful tails in lizards may have protective functions based on deflective and motion dazzle effects.

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“…False cues of direction or speed can introduce error via so-called dazzle coloration [39,40,[44][45][46][47]. Here, high contrast, repetitive patterns induce contradictory or biased motion cues [48], influencing estimations of speed [46,49] and/or direction [44]. Interference with optic flow cues may be why biting flies are deterred from landing on zebras [50].…”

Section: Increasing the Noisementioning

confidence: 99%

Camouflage in a dynamic world

Cuthill

Matchette

Scott‐Samuel

2019

Current Opinion in Behavioral Sciences

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We review how animals conceal themselves in the face of the need to move, and how this is modulated by the dynamic components and rapidly varying illumination of natural backgrounds. We do so in a framework of minimising the viewer's signal-tonoise ratio. Motion can match that of the observer such that there is no relative motion cue, or mimic that of background objects (e.g. swaying leaves). For group-living animals, matched motion and coloration is a special case of the latter 'motion masquerade', where each animal is a potential signal against the noise of other individuals. Recent research shows that dynamic illumination, such as underwater caustics or dappled forest shade, greatly impedes detection of moving targets, so may change the balance of predator-prey interactions.

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Diverted by dazzle: perceived movement direction is biased by target pattern orientation

Cited by 16 publications

References 55 publications

Apparent shift in long-range motion trajectory by local pattern orientation

Apparent shift in long-range motion trajectory by local pattern orientation

Grab my tail: evolution of dazzle stripes and colourful tails in lizards

Camouflage in a dynamic world

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