Your search keyword '"Burg E"' showing total 8 results

1. Where and when to look: Sequential effects at the millisecond level.

Author

Marques-Carneiro JE, Polgári P, Koning E, Seyller E, Martin B, Van der Burg E, and Giersch A

Subjects

Attention, Humans, Reaction Time, Vision, Ocular, Consciousness, Time Perception, Visual Perception

Abstract

Learning and imitating a complex motor action requires to visually follow complex movements, but conscious perception seems too slow for such tasks. Recent findings suggest that visual perception has a higher temporal resolution at an unconscious than at a conscious level. Here we investigate whether high-temporal resolution in visual perception relies on prediction mechanisms and attention shifts based on recently experienced sequences of visual information. To that aim we explore sequential effects during four different simultaneity/asynchrony discrimination tasks. Two stimuli are displayed on each trial with varying stimulus onset asynchronies (SOA). Subjects decide whether the stimuli are simultaneous or asynchronous and give manual responses. The main finding is an advantage for different-order over same-order trials, when subjects decided that stimuli had been simultaneous on Trial t - 1 , and when Trial t is with an SOA slightly larger than Trial t - 1, or equivalent. The advantage for different-order trials disappears when the stimuli change eccentricity but not direction between trials (Experiment 2), and persists with stimuli displayed in the centre and unlikely to elicit a sense of direction (Experiment 4). It is still observed when asynchronies on Trial t - 1 are small and undetected (Experiment 3). The findings can be explained by an attention shift that is precisely planned in time and space and that incidentally allows subjects to detect an isolated stimulus on the screen, thus helping them to detect an asynchrony.

Published

2020

2. Learned prioritization yields attentional biases through selection history.

Author

Munneke J, E Corbett J, and van der Burg E

Subjects

Attention, Humans, Reaction Time, Reward, Attentional Bias, Learning

Abstract

While numerous studies have provided evidence for selection history as a robust influence on attentional allocation, it is unclear precisely which behavioral factors can result in this form of attentional bias. In the current study, we focus on "learned prioritization" as an underlying mechanism of selection history and its effects on selective attention. We conducted two experiments, each starting with a training phase to ensure that participants learned different stimulus priorities. This was accomplished via a visual search task in which a specific color was consistently more relevant when presented together with another given color. In Experiment 1, one color was always prioritized over another color and inferior to a third color, such that each color had an equal overall priority by the end of the training session. In Experiment 2, the three different colors had unequal priorities at the end of the training session. A subsequent testing phase in which participants had to search for a shape-defined target showed that only stimuli with unequal overall priorities (Experiment 2) affected attentional selection, with increased reaction times when a distractor was presented in a previously high-priority compared with a low-priority color. These results demonstrate that adopting an attentional set where certain stimuli are prioritized over others can result in a lingering attentional bias and further suggest that selection history does not equally operate on all previously selected stimuli. Finally, we propose that findings in value-driven attention studies where high-value and low-value signaling stimuli differentially capture attention may be a result of learned prioritization rather than reward.

Published

2020

3. Dynamic distractor environments reveal classic visual field anisotropies for judgments of temporal order.

Author

Cass J and Van der Burg E

Subjects

Adult, Anisotropy, Female, Humans, Male, Photic Stimulation, Time Factors, Young Adult, Judgment, Visual Fields, Visual Perception

Abstract

Numerous studies have shown that visual performance critically depends on the stimulus' projected retinal location. For example, performance tends to be better along the horizontal relative to the vertical meridian (lateral anisotropy). Another case is the so-called upper-lower anisotropy, whereby performance is better in the upper relative to the lower hemifield. This study investigates whether temporal order judgments (TOJs) are subject to these visual field constraints. In Experiments 1 and 2, subjects reported the temporal order of two disks located along the horizontal or vertical meridians. Each target disk was surrounded by 10 black and white distractor disks, whose polarity remained unchanged (static condition) or reversed throughout the trial (dynamic condition). Results indicate that the mere presence of dynamic distractors elevated thresholds by more than a factor of four and that this elevation was particularly pronounced along the vertical meridian, evidencing the lateral anisotropy. In Experiment 3, thresholds were compared in upper, lower, left, and right visual hemifields. Results show that the threshold elevation caused by dynamic distractors was greatest in the upper visual field, demonstrating an upper-lower anisotropy. Critically, these anisotropies were evident exclusively in dynamic distractor conditions suggesting that distinct processes govern TOJ performance under these different contextual conditions. We propose that whereas standard TOJs are processed by fast low-order motion mechanisms, the presence of dynamic distractors mask these low-order motion signals, forcing observers to rely more heavily on more sluggish higher order motion processes.

Published

2019

4. Rapid recalibration to audiovisual asynchrony follows the physical-not the perceived-temporal order.

Author

Van der Burg E, Alais D, and Cass J

Subjects

Adolescent, Adult, Female, Humans, Male, Middle Aged, Young Adult, Auditory Perception physiology, Awareness physiology, Time Perception physiology, Visual Perception physiology

Abstract

In natural scenes, audiovisual events deriving from the same source are synchronized at their origin. However, from the perspective of the observer, there are likely to be significant multisensory delays due to physical and neural latencies. Fortunately, our brain appears to compensate for the resulting latency differences by rapidly adapting to asynchronous audiovisual events by shifting the point of subjective synchrony (PSS) in the direction of the leading modality of the most recent event. Here we examined whether it is the perceived modality order of this prior lag or its physical order that determines the direction of the subsequent rapid recalibration. On each experimental trial, a brief tone pip and flash were presented across a range of stimulus onset asynchronies (SOAs). The participants' task alternated over trials: On adaptor trials, audition either led or lagged vision with fixed SOAs, and participants judged the order of the audiovisual event; on test trials, the SOA as well as the modality order varied randomly, and participants judged whether or not the event was synchronized. For test trials, we showed that the PSS shifted in the direction of the physical rather than the perceived (reported) modality order of the preceding adaptor trial. These results suggest that rapid temporal recalibration is determined by the physical timing of the preceding events, not by one's prior perceptual decisions.

Published

2018

5. Orientation categories used in guidance of attention in visual search can differ in strength.

Author

Kong G, Alais D, and Van der Burg E

Subjects

Female, Humans, Male, Psychophysics, Reaction Time, Young Adult, Attention, Orientation, Pattern Recognition, Visual, Photic Stimulation methods, Task Performance and Analysis

Abstract

We investigated orientation categories in the guidance of attention in visual search. In the first two experiments, participants had a limited amount of time to find a target line among distractors lines. We systematically varied the orientation of the target and the angular difference between the target and distractors. We find vertical, horizontal, and 45° targets require the least target/distractor angular difference to be found reliably and that the rate at which increases in target/distractor difference decrease search difficulty to be independent of target identity. Unexpectedly, even when the angular difference between the target and distractors was large, search performance was never optimal when the target orientation was 45°. A third experiment investigates this unexpected finding by correlating target/distractor difference and error rate with performance on tasks that measure a specific perceptual or cognitive ability. We find that the elevated error rate is correlated with performance on stimulus recognition and identification tasks, while the amount of target/distractor difference needed to detect the target reliably is correlated with performance on a stimulus reproduction task. We conclude that the target/distractor difference reveals the number of orientation categories in visual search, and, accordingly, that there are four such categories: two strong ones centred on 0° and 90° and two weak ones centred on 45° and 135°.

Published

2017

6. Auditory frequency perception adapts rapidly to the immediate past.

Author

Alais D, Orchard-Mills E, and Van der Burg E

Subjects

Acoustic Stimulation, Adaptation, Physiological, Adult, Analysis of Variance, Female, Humans, Male, Psychophysics, Reaction Time physiology, Reference Values, Sound, Young Adult, Auditory Perception physiology, Hearing physiology

Abstract

Frequency modulation is critical to human speech. Evidence from psychophysics, neurophysiology, and neuroimaging suggests that there are neuronal populations tuned to this property of speech. Consistent with this, extended exposure to frequency change produces direction specific aftereffects in frequency change detection. We show that this aftereffect occurs extremely rapidly, requiring only a single trial of just 100-ms duration. We demonstrate this using a long, randomized series of frequency sweeps (both upward and downward, by varying amounts) and analyzing intertrial adaptation effects. We show the point of constant frequency is shifted systematically towards the previous trial's sweep direction (i.e., a frequency sweep aftereffect). Furthermore, the perception of glide direction is also independently influenced by the glide presented two trials previously. The aftereffect is frequency tuned, as exposure to a frequency sweep from a set centered on 1,000 Hz does not influence a subsequent trial drawn from a set centered on 400 Hz. More generally, the rapidity of adaptation suggests the auditory system is constantly adapting and "tuning" itself to the most recent environmental conditions.

Published

2015

7. Cross-modal associations between vision, touch, and audition influence visual search through top-down attention, not bottom-up capture.

Author

Orchard-Mills E, Alais D, and Van der Burg E

Subjects

Adolescent, Adult, Female, Humans, Male, Young Adult, Attention physiology, Auditory Perception physiology, Cues, Pattern Recognition, Visual, Touch physiology, Visual Perception physiology

Abstract

Recently, Guzman-Martinez, Ortega, Grabowecky, Mossbridge, and Suzuki (Current Biology : CB, 22(5), 383-388, 2012) reported that observers could systematically match auditory amplitude modulations and tactile amplitude modulations to visual spatial frequencies, proposing that these cross-modal matches produced automatic attentional effects. Using a series of visual search tasks, we investigated whether informative auditory, tactile, or bimodal cues can guide attention toward a visual Gabor of matched spatial frequency (among others with different spatial frequencies). These cues improved visual search for some but not all frequencies. Auditory cues improved search only for the lowest and highest spatial frequencies, whereas tactile cues were more effective and frequency specific, although less effective than visual cues. Importantly, although tactile cues could produce efficient search when informative, they had no effect when uninformative. This suggests that cross-modal frequency matching occurs at a cognitive rather than sensory level and, therefore, influences visual search through voluntary, goal-directed behavior, rather than automatic attentional capture.

Published

2013

8. On the limits of top-down control of visual selection.

Author

Theeuwes J and Van der Burg E

Subjects

Adolescent, Adult, Female, Humans, Male, Orientation, Reaction Time, Young Adult, Attention, Color Perception, Cues, Pattern Recognition, Visual

Abstract

In the present study, observers viewed displays in which two equally salient color singletons were simultaneously present. Before each trial, observers received a word cue (e.g., the word red, or green) or a symbolic cue (a circle colored red or green) telling them which color singleton to select on the upcoming trial. Even though many theories of visual search predict that observers should be able to selectively attend the target color singleton, the results of the present study show that observers could not select the target singleton without interference from the irrelevant color singleton. The results indicate that the irrelevant color singleton captured attention. Only when the color of the target singleton remained the same from one trial to the next was selection perfect--an effect that is thought to be the result of passive automatic intertrial priming. The results of the present study demonstrate the limits of top-down attentional control.

Published

2011