motion perception
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2022 ◽  
Vol 193 ◽  
pp. 107977
Author(s):  
Julien Audiffren ◽  
Jean-Luc Bloechle ◽  
Jean-Pierre Bresciani

2022 ◽  
Vol 15 ◽  
Author(s):  
Chengcheng Han ◽  
Guanghua Xu ◽  
Xiaowei Zheng ◽  
Peiyuan Tian ◽  
Kai Zhang ◽  
...  

The refresh rate is one of the important parameters of visual presentation devices, and assessing the effect of the refresh rate of a device on motion perception has always been an important direction in the field of visual research. This study examined the effect of the refresh rate of a device on the motion perception response at different stimulation frequencies and provided an objective visual electrophysiological assessment method for the correct selection of display parameters in a visual perception experiment. In this study, a flicker-free steady-state motion visual stimulation with continuous scanning frequency and different forms (sinusoidal or triangular) was presented on a low-latency LCD monitor at different refresh rates. Seventeen participants were asked to observe the visual stimulation without head movement or eye movement, and the effect of the refresh rate was assessed by analyzing the changes in the intensity of their visual evoked potentials. The results demonstrated that an increased refresh rate significantly improved the intensity of motion visual evoked potentials at stimulation frequency ranges of 7–28 Hz, and there was a significant interaction between the refresh rate and motion frequency. Furthermore, the increased refresh rate also had the potential to enhance the ability to perceive similar motion. Therefore, we recommended using a refresh rate of at least 120 Hz in motion visual perception experiments to ensure a better stimulation effect. If the motion frequency or velocity is high, a refresh rate of≥240 Hz is also recommended.


2022 ◽  
Vol 12 ◽  
Author(s):  
Stefano Mastandrea ◽  
John M. Kennedy

Usain Bolt’s Lightning Bolt pose, one arm highly extended to one side, suggests action. Likewise, static pictures of animals, legs extended, show animation. We tested a new cue for motion perception—extension—and in particular extension of dancer’s legs. An experiment with pictures of a dancer finds larger angles between the legs suggest greater movement, especially with in-air poses and in lateral views. Leg positions graded from simply standing to very difficult front and side splits. Liking ratings (a small range) were more related to Difficulty ratings (a large range) than Movement ratings (a moderate range).


Cortex ◽  
2022 ◽  
Author(s):  
Shir Shalom-Sperber ◽  
Aihua Chen ◽  
Adam Zaidel

2021 ◽  
Author(s):  
Zaeem Hadi ◽  
Yuscah Pondeca ◽  
Elena Calzolari ◽  
Mariya Chepisheva ◽  
Rebecca M Smith ◽  
...  

AbstractActivation of the peripheral vestibular apparatus simultaneously elicits a reflex vestibular nystagmus and the vestibular perception of self-motion (vestibular-motion perception) or vertigo. In a newly characterised condition called Vestibular Agnosia found in conditions with disrupted brain network connectivity, e.g. traumatic brain injury (TBI) or neurodegeneration (Parkinson’s Disease), the link between vestibular reflex and perception is uncoupled, such that, peripheral vestibular activation elicits a vestibular ocular reflex nystagmus but without vertigo. Using structural brain imaging in acute traumatic brain injury, we recently linked vestibular agnosia to postural imbalance via disrupted right temporal white-matter circuits (inferior longitudinal fasciculus), however no white-matter tracts were specifically linked to vestibular agnosia. Given the relative difficulty in localizing the neuroanatomical correlates of vestibular-motion perception, and compatible with current theories of human consciousness (viz. the Global Neuronal Workspace Theory), we postulate that vestibular-motion perception (vertigo) is mediated by the coordinated interplay between fronto-parietal circuits linked to whole-brain broadcasting of the vestibular signal of self-motion. We thus used resting state functional MRI (rsfMRI) to map functional brain networks and hence test our postulate of an anterior-posterior cortical network mediating vestibular agnosia. Whole-brain rsfMRI was acquired from 39 prospectively recruited acute TBI patients (and 37 matched controls) with preserved peripheral and reflex vestibular function, along with self-motion perceptual thresholds during passive yaw rotations in the dark, and posturography. Following quality control of the brain imaging, 25 TBI patients’ images were analyzed. We classified 11 TBI patients with vestibular agnosia and 14 without vestibular agnosia based on laboratory testing of self-motion perception. Using independent component analysis, we found altered functional connectivity within posterior (right superior longitudinal fasciculus) and anterior networks (left rostral prefrontal cortex) in vestibular agnosia. Regions of interest analyses showed both inter-hemispheric and intra-hemispheric (left anterior-posterior) network disruption in vestibular agnosia. Assessing the brain regions linked via right inferior longitudinal fasciculus, a tract linked to vestibular agnosia in unbalanced patients (but now controlled for postural imbalance), seed-based analyses showed altered connectivity between higher order visual cortices involved in motion perception and mid-temporal regions. In conclusion, vestibular agnosia in our patient group is mediated by multiple brain network dysfunction, involving primarily left frontal and bilateral posterior networks. Understanding the brain mechanisms of vestibular agnosia provide both an insight into the physiological mechanisms of vestibular perception as well as an opportunity to diagnose and monitor vestibular cognitive deficits in brain disease such as TBI and neurodegeneration linked to imbalance and spatial disorientation.


2021 ◽  
Author(s):  
Joshua J Corbett

How do we perceive the location of moving objects? The position and motion literature is currently divided. Predictive accounts of object tracking propose that the position of moving objects is anticipated ahead of sensory signals, whilst non-predictive accounts claim that an anticipatory mechanism is not necessary. A novel illusion called the twinkle goes effect, describing a forward shift in the perceived final location of a moving object in the presence of dynamic noise, presents a novel opportunity to disambiguate these accounts. Across three experiments, we compared the predictions of predictive and non-predictive theories of object tracking by combining the twinkle goes paradigm with a multiple object tracking task. Specifically, we tested whether the size of the twinkle goes illusion would be smaller with greater attentional load (as entailed by the non-predictive, tracking continuation theory) or whether it would not be affected by attentional load (as entailed by predictive extrapolation theory). Our results failed to align with either of these theories of object localisation and tracking. Instead, we found evidence that the twinkle goes effect may be stronger with greater attentional load. We discuss whether this result may be a consequence of an essential, but previously unexplored relationship between the twinkle goes effect and representational momentum. In addition, this study was the first to reveal critical individual differences in the experience of the twinkle goes effect, and in the mislocalisation of moving objects. Together, our results continue to demonstrate the complexity of position and motion perception.


2021 ◽  
Author(s):  
Gi-Yeul Bae ◽  
Steven J Luck

Computational models for motion perception suggest a possibility that read-out of motion signal can yield the perception of opposite direction of the true stimulus motion direction. However, this possibility was not obvious in a standard 2AFC motion discrimination (e.g., leftward vs.rightward). By allowing the motion direction to vary over 360° in typical random-dot kinematograms (RDKs) displays, and by asking observers to estimate the exact direction of motion, we were able to detect the presence of opposite-direction motion perception in RDKs.This opposite-direction motion perception was replicable across multiple display types andfeedback conditions, and participants had greater confidence in their opposite-direction responses than in true guess responses. When we fed RDKs into a computational model of motion processing, we found that the model estimated substantial motion activity in the direction opposite to the coherent stimulus direction, even though no such motion was objectively present in the stimuli, suggesting that the opposite-direction motion perception may be a consequenceof the properties of motion-selective neurons in visual cortex. Together, these results demonstrate that the perception of opposite-direction motion in RDKs is consistent with the known properties of the visual system.


Author(s):  
Victoria Foglia ◽  
Hasan Siddiqui ◽  
Zainab Khan ◽  
Stephanie Liang ◽  
M. D. Rutherford

AbstractIf neurotypical people rely on specialized perceptual mechanisms when perceiving biological motion, then one would not expect an association between task performance and IQ. However, if those with ASD recruit higher order cognitive skills when solving biological motion tasks, performance may be predicted by IQ. In a meta-analysis that included 19 articles, we found an association between biological motion perception and IQ among observers with ASD but no significant relationship among typical observers. If the task required emotion perception, then there was an even stronger association with IQ in the ASD group.


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