scholarly article | Q13442814 |
review article | Q7318358 |
P2093 | author name string | Patrick Cavanagh | |
George A Alvarez | |||
P433 | issue | 7 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | attention | Q6501338 |
P304 | page(s) | 349-354 | |
P577 | publication date | 2005-07-01 | |
P1433 | published in | Trends in Cognitive Sciences | Q7838299 |
P1476 | title | Tracking multiple targets with multifocal attention | |
P478 | volume | 9 |
Q37064713 | "It's Always the Judge's Fault": Attention, Emotion Recognition, and Expertise in Rhythmic Gymnastics Assessment |
Q41845347 | A bilateral advantage for storage in visual working memory |
Q88538924 | A common source of attention for auditory and visual tracking |
Q42326373 | A link between attentional function, effective eye movements, and driving ability. |
Q50776990 | A mixture distribution of spatial attention. |
Q36005710 | A relational structure of voluntary visual-attention abilities |
Q89497032 | ATOM: A Grammar for Unit Visualizations |
Q47422150 | All eyes on relevance: strategic allocation of attention as a result of feature-based task demands in multiple object tracking |
Q51051170 | An investigation of the spatial selectivity of the duration after-effect. |
Q35841396 | Anatomical constraints on attention: hemifield independence is a signature of multifocal spatial selection |
Q48644760 | Anticipation in Real-World Scenes: The Role of Visual Context and Visual Memory |
Q46360327 | Associations between childhood adversity and daily suppression and avoidance in response to stress in adulthood: can neurobiological sensitivity help explain this relationship? |
Q57071246 | Associations between depression, anxious arousal and manifestations of psychological inflexibility |
Q48678988 | Attending to multiple objects relies on both feature- and dimension-based control mechanisms: Evidence from human electrophysiology |
Q42541397 | Attention and visuospatial working memory share the same processing resources |
Q33986937 | Attention maps in the brain |
Q37096842 | Attention-dependent reductions in burstiness and action-potential height in macaque area V4 |
Q36727174 | Attentional costs in multiple-object tracking |
Q30481201 | Attentional demand influences strategies for encoding into visual working memory |
Q37706768 | Attentional landscapes in reaching and grasping. |
Q35181345 | Attentional modulation of firing rate varies with burstiness across putative pyramidal neurons in macaque visual area V4. |
Q47612776 | Attentional selection of multiple objects in the human visual system |
Q48741531 | Attentional-tracking acuity is modulated by illusory changes in perceived speed. |
Q43093264 | Attentive Tracking Disrupts Feature Binding in Visual Working Memory |
Q48682599 | Attentive tracking of moving objects in real 3D space |
Q34257136 | Atypical functional brain activation during a multiple object tracking task in girls with Turner syndrome: neurocorrelates of reduced spatiotemporal resolution |
Q37632275 | Auditory Stimulus Detection Partially Depends on Visuospatial Attentional Resources. |
Q35154282 | Barrier effects in non-retinotopic feature attribution |
Q35762474 | Behavioral dynamics and neural grounding of a dynamic field theory of multi-object tracking |
Q87648366 | Bilateral and two-item advantage in subitizing |
Q35082564 | Bottlenecks of motion processing during a visual glance: the leaky flask model. |
Q44412092 | Can Limitations of Visuospatial Attention Be Circumvented? A Review |
Q34883569 | Can we track holes? |
Q35121628 | Capacity limit of simultaneous temporal processing: how many concurrent 'clocks' in vision? |
Q90957158 | Changes (but not differences) in motion direction fail to capture attention |
Q58767991 | Chasing Animals With Split Attention: Are Animals Prioritized in Visual Tracking? |
Q37712599 | Cholinergic Potentiation Improves Perceptual-Cognitive Training of Healthy Young Adults in Three Dimensional Multiple Object Tracking |
Q48730638 | Close encounters of the distracting kind: identifying the cause of visual tracking errors |
Q51007437 | Consolidation of statistical information of multiple objects in working memory. |
Q33783712 | Contralateral delay activity provides a neural measure of the number of representations in visual working memory |
Q34219257 | Correction of refractive errors in rhesus macaques (Macaca mulatta) involved in visual research |
Q48408050 | Cortical Circuit for Binding Object Identity and Location During Multiple-Object Tracking. |
Q48240238 | Cross-Modal Attention Effects in the Vestibular Cortex during Attentive Tracking of Moving Objects. |
Q37373648 | Demand-based dynamic distribution of attention and monitoring of velocities during multiple-object tracking |
Q48625376 | Detecting single-target changes in multiple object tracking: The case of peripheral vision |
Q37592065 | Differing effects of attention in single-units and populations are well predicted by heterogeneous tuning and the normalization model of attention. |
Q42094394 | Direction information in multiple object tracking is limited by a graded resource |
Q48763518 | Discrete object representation, attention switching, and task difficulty in the parietal lobe |
Q60949687 | Disentangling Neural Synchronization and Sustained Neural Activity in the Processing of Auditory Temporal Patterns |
Q41784301 | Distinguishing between parallel and serial accounts of multiple object tracking |
Q48344888 | Distracting tracking: Interactions between negative emotion and attentional load in multiple-object tracking. |
Q48679330 | Distractor Locations Influence Multiple Object Tracking Beyond Interobject Spacing: Evidence From Equidistant Distractor Displacements |
Q37802008 | Do we track what we see? Common versus independent processing for motion perception and smooth pursuit eye movements: A review |
Q41134923 | Duration judgments over multiple elements. |
Q61445649 | Dynamic colour change and the confusion effect against predation |
Q38051627 | Dynamically partitionable autoassociative networks as a solution to the neural binding problem |
Q33983343 | EEG correlates of attentional load during multiple object tracking |
Q38537621 | EPS Mid-Career Award 2014. The control of attention in visual search: Cognitive and neural mechanisms |
Q99637126 | Effect of bilingualism on visual tracking attention and resistance to distraction |
Q26766003 | Electrophysiological Advances on Multiple Object Processing in Aging |
Q52656911 | Emotional cues and social anxiety resolve ambiguous perception of biological motion. |
Q36867921 | Endogenous spatial attention: evidence for intact functioning in adults with autism |
Q48394475 | Enhancing Cognitive Function Using Perceptual-Cognitive Training |
Q41953203 | Enhancing multiple object tracking performance with noninvasive brain stimulation: a causal role for the anterior intraparietal sulcus |
Q88215828 | Event monitoring: Can we detect more than one event at a time? |
Q46367278 | Evidence against a speed limit in multiple-object tracking |
Q50672045 | Evidence for a shared mechanism used in multiple-object tracking and subitizing. |
Q89523119 | Examining the roles of working memory and visual attention in multiple object tracking expertise |
Q48818990 | Expansion of MT neurons excitatory receptive fields during covert attentive tracking. |
Q48673702 | Extrapolation occurs in multiple object tracking when eye movements are controlled |
Q41106114 | Eye fixation during multiple object attention is based on a representation of discrete spatial foci |
Q36727165 | Eye movements during multiple object tracking: where do participants look? |
Q48235306 | Fear Spreading Across Senses: Visual Emotional Events Alter Cortical Responses to Touch, Audition, and Vision |
Q41971564 | Feature binding in attentive tracking of distinct objects |
Q34775874 | Fixation strategy influences the ability to focus attention on two spatially separate objects |
Q30504545 | Gaze fixation improves the stability of expert juggling |
Q41958874 | Healthy older observers show equivalent perceptual-cognitive training benefits to young adults for multiple object tracking. |
Q34405600 | Hemifield effects in multiple identity tracking |
Q99557105 | Hierarchical structure is employed by humans during visual motion perception |
Q40073514 | High-capacity, transient retention of direction-of-motion information for multiple moving objects. |
Q38576282 | How Many Objects are You Worth? Quantification of the Self-Motion Load on Multiple Object Tracking |
Q47858618 | How functional are functional viewing fields? |
Q92969930 | How selective attention affects the detection of motion changes with peripheral vision in MOT |
Q47916910 | Hue distinctiveness overrides category in determining performance in multiple object tracking |
Q37379722 | Human attention filters for single colors |
Q57090186 | Impaired spatial and binocular summation for motion direction discrimination in strabismic amblyopia |
Q57067507 | Influence of sports expertise level on attention in multiple object tracking |
Q34749175 | Investigating the status of biological stimuli as objects of attention in multiple object tracking |
Q34555998 | Is Attentional Resource Allocation Across Sensory Modalities Task-Dependent? |
Q56515884 | It is not good to talk: conversation has a fixed interference cost on attention regardless of difficulty |
Q46062268 | It is time to integrate: the temporal dynamics of object motion and texture motion integration in multiple object tracking. |
Q37689518 | Long-term memory guidance of visuospatial attention in a change-detection paradigm. |
Q34114904 | Looking at the center of the targets helps multiple object tracking |
Q95286195 | Mechanisms of competitive selection: A canonical neural circuit framework |
Q52689233 | Meridian Interference reveals Neural Locus of Motion-induced Position Shifts. |
Q35113911 | Modulation of early cortical processing during divided attention to non-contiguous locations |
Q37717625 | Motion integration for ocular pursuit does not hinder perceptual segregation of moving objects |
Q35588074 | Moving in groups: how density and unpredictable motion affect predation risk. |
Q54382139 | Multiple event monitoring. |
Q48249602 | Multiple object individuation and exact enumeration |
Q36636643 | Multiple object tracking in autism spectrum disorders |
Q91762008 | Multiple-target tracking in human and machine vision |
Q50687327 | Neural Mechanisms Underlying Visual Short-Term Memory Gain for Temporally Distinct Objects. |
Q48807109 | Neural correlates of the multiple-object tracking deficit in amblyopia |
Q36669424 | Neural dynamics of object-based multifocal visual spatial attention and priming: object cueing, useful-field-of-view, and crowding |
Q36943543 | Neural measures of individual differences in selecting and tracking multiple moving objects |
Q38873947 | Neural mechanisms of selective attention in the somatosensory system |
Q35090913 | Neural substrates of cognitive capacity limitations. |
Q33784782 | Nicotinic receptor gene CHRNA4 interacts with processing load in attention |
Q44481199 | Normal aging delays and compromises early multifocal visual attention during object tracking |
Q46001864 | Object-based integration of motion information during attentive tracking. |
Q40139646 | Objects or Locations in Vision for Action? Evidence from the MILO task |
Q36314894 | Overt orienting of spatial attention and corticospinal excitability during action observation are unrelated |
Q41835451 | Patients with schizophrenia do not preserve automatic grouping when mentally re-grouping figures: shedding light on an ignored difficulty. |
Q41688624 | Position Affects Performance in Multiple-Object Tracking in Rugby Union Players |
Q46495993 | Preparatory Encoding of the Fine Scale of Human Spatial Attention |
Q51877722 | Processing spatial relations with different apertures of attention. |
Q44543011 | Processing statistics: an examination of focused and distributed attention using event related potentials |
Q36576258 | Professional athletes have extraordinary skills for rapidly learning complex and neutral dynamic visual scenes |
Q36225160 | Pupil Sizes Scale with Attentional Load and Task Experience in a Multiple Object Tracking Task |
Q42137481 | Remapping attention in multiple object tracking |
Q48738924 | Resource demands of object tracking and differential allocation of the resource. |
Q50585010 | Retrieval-Induced Inhibition in Short-Term Memory. |
Q37005394 | Risk perception, road behavior, and pedestrian injury among adolescent students in Kathmandu, Nepal |
Q34958726 | Selecting and perceiving multiple visual objects |
Q41013684 | Sequential sampling of visual objects during sustained attention |
Q30491126 | Spatial attention decorrelates intrinsic activity fluctuations in macaque area V4. |
Q34969491 | Spatial attention modulates center-surround interactions in macaque visual area v4 |
Q37870257 | Spatial attention, feature-based attention, and saccades: three sides of one coin? |
Q30487131 | Spatial ensemble statistics are efficient codes that can be represented with reduced attention |
Q50666074 | Spatial reference in multiple object tracking. |
Q48822174 | Spatial updating of dynamic scenes: tracking multiple invisible objects across viewpoint changes |
Q48715402 | Spatio-temporal patterns of brain activity distinguish strategies of multiple-object tracking. |
Q48766351 | Speed has an effect on multiple-object tracking independently of the number of close encounters between targets and distractors |
Q39353592 | Studying visual attention using the multiple object tracking paradigm: A tutorial review |
Q45815082 | Sustained multifocal attentional enhancement of stimulus processing in early visual areas predicts tracking performance. |
Q41843095 | Swapping or dropping? Electrophysiological measures of difficulty during multiple object tracking |
Q48534417 | Target objects defined by a conjunction of colour and shape can be selected independently and in parallel. |
Q38385718 | Telephone conversation impairs sustained visual attention via a central bottleneck |
Q33840992 | Temporal brain dynamics of multiple object processing: the flexibility of individuation |
Q36838422 | Temporal dynamics of divided spatial attention |
Q48506370 | Temporal estimation with two moving objects: overt and covert pursuit. |
Q48695561 | The Identity-Location Binding Problem |
Q51953904 | The attentional blink reveals serial working memory encoding: evidence from virtual and human event-related potentials. |
Q30480884 | The blinking spotlight of attention. |
Q35765648 | The capacity of audiovisual integration is limited to one item |
Q48824438 | The contribution of working memory to divided attention. |
Q48550503 | The contributions of visual and central attention to visual working memory |
Q34401709 | The coordinate systems used in visual tracking |
Q34342057 | The effect of spatial organization of targets and distractors on the capacity to selectively memorize objects in visual short-term memory |
Q42321287 | The effect of visual distinctiveness on multiple object tracking performance |
Q42269657 | The effects of sequential attention shifts within visual working memory |
Q41939967 | The more often you see an object, the easier it becomes to track it |
Q37382989 | The normalization model of attention |
Q33854759 | The number of attentional foci and their precision are dissociated in the posterior parietal cortex |
Q37929576 | The psychophysics of brain rhythms |
Q41649020 | The representation of simple ensemble visual features outside the focus of attention |
Q27302235 | The role of attention in ambiguous reversals of structure-from-motion |
Q34081022 | The role of visual attention in multiple object tracking: Evidence from ERPs |
Q30460579 | The sound of a mobile phone ringing affects the complex reaction time of its owner. |
Q50686205 | The what-where trade-off in multiple-identity tracking. |
Q51895103 | Timing divided attention. |
Q34395553 | Tracking moving identities: after attending the right location, the identity does not come for free |
Q39727293 | Tracking objects that move where they are headed |
Q34114922 | Tracking planets and moons: mechanisms of object tracking revealed with a new paradigm |
Q48909216 | Tracking unique objects |
Q33627926 | Two Trackers Are Better than One: Information about the Co-actor's Actions and Performance Scores Contribute to the Collective Benefit in a Joint Visuospatial Task |
Q61448900 | Unilateral neglect post stroke: Eye movement frequencies indicate directional hypokinesia while fixation distributions suggest compensational mechanism |
Q33642150 | Using fMRI to distinguish components of the multiple object tracking task |
Q35772770 | Vagal flexibility: A physiological predictor of social sensitivity |
Q38406598 | Visual Working Memory in Human Cortex |
Q37844208 | Visual cognition |
Q46006533 | Visually tracking and localizing expanding and contracting objects. |
Q48782545 | We see more than we can report: "cost free" color phenomenality outside focal attention |
Q42943790 | Why do people appear not to extrapolate trajectories during multiple object tracking? A computational investigation |
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