scholarly article | Q13442814 |
P819 | ADS bibcode | 2012PNAS..109.8456W |
P356 | DOI | 10.1073/PNAS.1201858109 |
P932 | PMC publication ID | 3365158 |
P698 | PubMed publication ID | 22586101 |
P5875 | ResearchGate publication ID | 224958750 |
P50 | author | Niels Taatgen | Q42891469 |
P2093 | author name string | Sander Martens | |
Hedderik van Rijn | |||
Stefan M Wierda | |||
P2860 | cites work | Nonparametric permutation tests for functional neuroimaging: a primer with examples | Q28211607 |
Temporary suppression of visual processing in an RSVP task: an attentional blink? | Q28249105 | ||
An integrative theory of locus coeruleus-norepinephrine function: adaptive gain and optimal performance | Q29615396 | ||
Pupil diameter tracks changes in control state predicted by the adaptive gain theory of locus coeruleus function | Q30465540 | ||
The attentional blink: a review of data and theory | Q33516475 | ||
Distracting the mind improves performance: an ERP Study | Q33760880 | ||
The attentional blink: past, present, and future of a blind spot in perceptual awareness | Q33767060 | ||
Temporal attention enhances early visual processing: a review and new evidence from event-related potentials. | Q36413330 | ||
The anatomical and functional relationship between the P3 and autonomic components of the orienting response | Q37765930 | ||
Electrophysiological evidence for a postperceptual locus of suppression during the attentional blink | Q38451193 | ||
Nonparametric analysis of statistic images from functional mapping experiments. | Q40928582 | ||
Pupil dilation during visual target detection | Q42872600 | ||
Pupil diameter predicts changes in the exploration-exploitation trade-off: evidence for the adaptive gain theory | Q48109152 | ||
Event-related potential correlates of the attentional blink phenomenon | Q48302772 | ||
Cuing and stimulus probability effects on the P3 and the AB. | Q48372511 | ||
The temporal locus of the interaction between working memory consolidation and the attentional blink. | Q51054305 | ||
The attentional blink reveals serial working memory encoding: evidence from virtual and human event-related potentials. | Q51953904 | ||
The role of the locus coeruleus in mediating the attentional blink: a neurocomputational theory. | Q51965308 | ||
Pupil dilation in response preparation. | Q51970165 | ||
Neurologial interpretations and the information in the cognitive pupillary response. | Q52025918 | ||
Resource sharing in the attentional blink. | Q52028920 | ||
Quick Minds Don't Blink: Electrophysiological Correlates of Individual Differences in Attentional Selection | Q60038134 | ||
Pupillary responses on the visual backward masking task reflect general cognitive ability | Q79739704 | ||
P433 | issue | 22 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | attention | Q6501338 |
deconvolution | Q1183700 | ||
P1104 | number of pages | 5 | |
P304 | page(s) | 8456-8460 | |
P577 | publication date | 2012-05-14 | |
P1433 | published in | Proceedings of the National Academy of Sciences of the United States of America | Q1146531 |
P1476 | title | Pupil dilation deconvolution reveals the dynamics of attention at high temporal resolution | |
P478 | volume | 109 |
Q93063817 | A dual role of prestimulus spontaneous neural activity in visual object recognition |
Q34575141 | A role of eye vergence in covert attention |
Q37194085 | A solid frame for the window on cognition: Modeling event-related pupil responses |
Q28240775 | ADHD subjects fail to suppress eye blinks and microsaccades while anticipating visual stimuli but recover with medication |
Q39996580 | Adaptive gain control during human perceptual choice |
Q40831330 | Adult-like neuroelectrical response to inequity in children: Evidence from the ultimatum game |
Q62805810 | Altered cortical functional network in major depressive disorder: A resting-state electroencephalogram study |
Q36030661 | An Individual Differences Approach to Temporal Integration and Order Reversals in the Attentional Blink Task |
Q91969408 | Analyzing the Time Course of Pupillometric Data |
Q33360719 | Assessing visual attention using eye tracking sensors in intelligent cognitive therapies based on serious games |
Q26779547 | Attentional Mechanisms during the Performance of a Subsecond Timing Task |
Q59125966 | Best Practices and Advice for Using Pupillometry to Measure Listening Effort: An Introduction for Those Who Want to Get Started |
Q28074137 | Beyond eye gaze: What else can eyetracking reveal about cognition and cognitive development? |
Q44412092 | Can Limitations of Visuospatial Attention Be Circumvented? A Review |
Q27335320 | Choosing in freedom or forced to choose? Introspective blindness to psychological forcing in stage-magic |
Q36020762 | Cognitive and Ocular Factors Jointly Determine Pupil Responses under Equiluminance |
Q35653363 | Cognitive effort: A neuroeconomic approach |
Q57031826 | Conscious processing of auditory regularities induces a pupil dilation |
Q42692547 | Coordinating long-latency stretch responses across the shoulder, elbow, and wrist during goal-directed reaching |
Q64064262 | Cortical modulation of pupillary function: systematic review |
Q37571468 | Decision-related pupil dilation reflects upcoming choice and individual bias. |
Q90592567 | Dissociable mappings of tonic and phasic pupillary features onto cognitive processes involved in mental arithmetic |
Q38618463 | Driver's Mental Workload Prediction Model Based on Physiological Indices |
Q38907541 | Emotional arousal predicts intertemporal choice |
Q90145587 | Eye pupil signals information gain |
Q51110913 | Eye tracking and pupillometry are indicators of dissociable latent decision processes. |
Q60310164 | How pupil responses track value-based decision-making during and after reinforcement learning |
Q35867626 | Individual Differences in Temporal Selective Attention as Reflected in Pupil Dilation |
Q90570752 | Intranasal Oxytocin Increases Perceptual Salience of Faces in the Absence of Awareness |
Q30585062 | Mapping the origins of time: scalar errors in infant time estimation |
Q35878457 | Metacognitive processes in executive control development: the case of reactive and proactive control. |
Q89048376 | Mind over motor mapping: Driver response to changing vehicle dynamics |
Q90123087 | Modeling pupil responses to rapid sequential events |
Q57739579 | Modulation of stimulus contrast on the human pupil orienting response |
Q92187611 | Multiple-Time-Scale Analysis of Attention as Revealed by EEG, NIRS, and Pupil Diameter Signals During a Free Recall Task: A Multimodal Measurement Approach |
Q30565506 | Musical minds: attentional blink reveals modality-specific restrictions |
Q38617976 | Neural, physiological, and behavioral correlates of visuomotor cognitive load |
Q92483457 | No modulation of pupil size and event-related pupil response by transcutaneous auricular vagus nerve stimulation (taVNS) |
Q57758884 | Predicting Driver’s Work Performance in Driving Simulator Based on Physiological Indices |
Q90089871 | Pupil Dilation Reflects Task Relevance Prior to Search |
Q36225160 | Pupil Sizes Scale with Attentional Load and Task Experience in a Multiple Object Tracking Task |
Q35913082 | Pupil diameter reflects uncertainty in attentional selection during visual search |
Q58769329 | Pupil dilation but not microsaccade rate robustly reveals decision formation |
Q36448538 | Pupil dilation co-varies with memory strength of individual traces in a delayed response paired-associate task |
Q34097077 | Pupil dilation dynamics track attention to high-level information |
Q52647840 | Pupil dilation tracks the dynamics of mnemonic interference resolution. |
Q42260772 | Pupil dilation: a fingerprint of temporal selection during the "attentional blink". |
Q30620109 | Pupil fluctuations track fast switching of cortical states during quiet wakefulness |
Q37408620 | Pupil fluctuations track rapid changes in adrenergic and cholinergic activity in cortex. |
Q92730054 | Pupil response to noxious corneal stimulation |
Q21129354 | Pupil size and social vigilance in rhesus macaques |
Q47397632 | Pupil size reveals preparatory processes in the generation of pro-saccades and anti-saccades. |
Q47401300 | Pupil size tracks perceptual content and surprise. |
Q34081380 | Pupil size variations correlate with physical effort perception |
Q30445220 | Pupil size varies with word listening and response selection difficulty in older adults with hearing loss. |
Q38574233 | Pupillometry |
Q47378778 | Pupillometry reveals increased pupil size during indirect request comprehension |
Q38808472 | Pupillometry shows the effort of auditory attention switching |
Q91604733 | Rapid serial blinks: An index of temporally increased cognitive load |
Q35581830 | Relating Pupil Dilation and Metacognitive Confidence during Auditory Decision-Making |
Q30442033 | Second language experience modulates word retrieval effort in bilinguals: evidence from pupillometry |
Q30402130 | Speech-perception training for older adults with hearing loss impacts word recognition and effort. |
Q47098294 | Task relevance modulates the behavioural and neural effects of sensory predictions |
Q30358520 | Temporal alignment of pupillary response with stimulus events via deconvolution |
Q50655084 | Temporal cues and the attentional blink: a further examination of the role of expectancy in sequential object perception. |
Q42772029 | The eyes and ears are visual indicators of attention in domestic horses |
Q47563813 | The locus coeruleus-norepinephrine system as pacemaker of attention - a developmental mechanism of derailed attentional function in autism spectrum disorder |
Q21559547 | The pupillary light response reveals the focus of covert visual attention |
Q30818658 | Time to see the bigger picture: Individual differences in the attentional blink |
Q37612405 | Time-domain analysis for extracting fast-paced pupil responses |
Q42825639 | Tracking the allocation of attention using human pupillary oscillations |
Q46183243 | Transient pupil response is modulated by contrast-based saliency. |
Q50642968 | Two visual targets for the price of one? Pupil dilation shows reduced mental effort through temporal integration. |
Q37365580 | Unexpected arousal modulates the influence of sensory noise on confidence |
Q28080669 | Waking State: Rapid Variations Modulate Neural and Behavioral Responses |
Q48703713 | What You See Is What You Remember: Visual Chunking by Temporal Integration Enhances Working Memory. |
Q47397372 | Willing to Think Hard? The Subjective Value of Cognitive Effort in Children |
Q31137541 | Word frequency and the attentional blink: the effects of target difficulty on retrieval and consolidation processes |