| scholarly article | Q13442814 |
| P2093 | author name string | George A Alvarez | |
| Steven L Franconeri | |||
| P433 | issue | 13 | |
| P921 | main subject | attention | Q6501338 |
| P304 | page(s) | 14.1-10 | |
| P577 | publication date | 2007-10-30 | |
| P1433 | published in | Journal of Vision | Q6296043 |
| P1476 | title | How many objects can you track? Evidence for a resource-limited attentive tracking mechanism | |
| P478 | volume | 7 |
| Q55384596 | A Neurodynamic Model of Feature-Based Spatial Selection. |
| Q90100301 | A Target-Detecting Visual Neuron in the Dragonfly Locks on to Selectively Attended Targets |
| Q88538924 | A common source of attention for auditory and visual tracking |
| Q47422150 | All eyes on relevance: strategic allocation of attention as a result of feature-based task demands in multiple object tracking |
| Q50774858 | Analog Magnitudes Support Large Number Ordinal Judgments in Infancy. |
| Q46489148 | Attention Modulates Spatial Precision in Multiple-Object Tracking |
| Q30471878 | Attention and non-retinotopic feature integration |
| Q33986937 | Attention maps in the brain |
| Q36661055 | Attentional Resource Allocation in Visuotactile Processing Depends on the Task, But Optimal Visuotactile Integration Does Not Depend on Attentional Resources |
| 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 |
| Q30525384 | Audition and vision share spatial attentional resources, yet attentional load does not disrupt audiovisual integration |
| Q37632275 | Auditory Stimulus Detection Partially Depends on Visuospatial Attentional Resources. |
| Q35762474 | Behavioral dynamics and neural grounding of a dynamic field theory of multi-object tracking |
| Q35082564 | Bottlenecks of motion processing during a visual glance: the leaky flask model. |
| Q44412092 | Can Limitations of Visuospatial Attention Be Circumvented? A Review |
| Q43668149 | Changing target trajectories influences tracking performance |
| Q48517226 | Comparing eye movements during position tracking and identity tracking: No evidence for separate systems |
| Q38110283 | Competition explains limited attention and perceptual resources: implications for perceptual load and dilution theories |
| Q35188815 | Competition in visual cortex impedes attention to multiple items |
| Q36766627 | Conceptual knowledge increases infants' memory capacity |
| Q35827226 | Deconstructing Interocular Suppression: Attention and Divisive Normalization |
| 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 |
| Q34080999 | Developmental profiles for multiple object tracking and spatial memory: typically developing preschoolers and people with Williams syndrome |
| Q51042287 | Differences in Spatial Working Memory as a Function of Team Sports Expertise: The Corsi Block-Tapping Task in Sport Psychological Assessment |
| Q42094394 | Direction information in multiple object tracking is limited by a graded resource |
| 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. |
| Q37444173 | Dual-task interference in visual working memory: a limitation in storage capacity but not in encoding or retrieval |
| Q41134923 | Duration judgments over multiple elements. |
| Q38670039 | Effect of depth information on multiple-object tracking in three dimensions: A probabilistic perspective. |
| Q36606366 | Efficiency of extracting stereo-driven object motions |
| Q52532519 | Engagement of the motor system in position monitoring: reduced distractor suppression and effects of internal representation quality on motor kinematics. |
| Q33888780 | Enhanced local processing of dynamic visual information in autism: evidence from speed discrimination |
| Q40956373 | Enhancement and suppression in the visual field under perceptual load |
| Q41953203 | Enhancing multiple object tracking performance with noninvasive brain stimulation: a causal role for the anterior intraparietal sulcus |
| Q48269172 | Ensemble coding remains accurate under object and spatial visual working memory load |
| Q88215828 | Event monitoring: Can we detect more than one event at a time? |
| Q46367278 | Evidence against a speed limit in multiple-object tracking |
| Q89523119 | Examining the roles of working memory and visual attention in multiple object tracking expertise |
| Q34744268 | Failure of working memory training to enhance cognition or intelligence |
| Q38083442 | Flexible cognitive resources: competitive content maps for attention and memory |
| Q41958874 | Healthy older observers show equivalent perceptual-cognitive training benefits to young adults for multiple object tracking. |
| Q34405600 | Hemifield effects in multiple identity tracking |
| 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 |
| Q50931876 | How many motion signals can be simultaneously perceived? |
| Q92969930 | How selective attention affects the detection of motion changes with peripheral vision in MOT |
| Q36028889 | Impaired multiple object tracking in children with chromosome 22q11.2 deletion syndrome |
| Q96109664 | Individual differences in visual attention: A short, reliable, open-source, and multilingual test of multiple object tracking in PsychoPy |
| Q57067507 | Influence of sports expertise level on attention in multiple object tracking |
| Q37548502 | Interactive multiple object tracking (iMOT). |
| Q56899093 | Investigating the effects of experience on human performance in an object-tracking task: a case study of manual rendezvous and docking |
| 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 |
| Q37689518 | Long-term memory guidance of visuospatial attention in a change-detection paradigm. |
| Q38863629 | Longitudinal Motion Assessment of the Carotid Artery Using Speckle Tracking and Scale-Invariant Feature Transform |
| Q34114904 | Looking at the center of the targets helps multiple object tracking |
| Q39330455 | Looking for trouble: a description of oculomotor search strategies during live CCTV operation |
| Q46310778 | Loss of positional information when tracking multiple moving dots: the role of visual memory |
| Q57279863 | Media multitasking is associated with altered processing of incidental, irrelevant cues during person perception |
| Q51598607 | Memory for multiple visual ensembles in infancy. |
| Q37717625 | Motion integration for ocular pursuit does not hinder perceptual segregation of moving objects |
| Q54382139 | Multiple event monitoring. |
| Q48824187 | Multiple-object tracking: enhanced visuospatial representations as a result of experience |
| 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 |
| Q33784782 | Nicotinic receptor gene CHRNA4 interacts with processing load in attention |
| Q51873247 | No need for inhibitory tagging of locations in visual search. |
| Q40139646 | Objects or Locations in Vision for Action? Evidence from the MILO task |
| Q33612914 | Occlusion is hard: Comparing predictive reaching for visible and hidden objects in infants and adults |
| Q39728238 | Position representations lag behind targets in multiple object tracking. |
| Q36099533 | PowerPoint(®) Presentation Flaws and Failures: A Psychological Analysis |
| Q37403702 | Prediction processes during multiple object tracking (MOT): involvement of dorsal and ventral premotor cortices |
| Q51877722 | Processing spatial relations with different apertures of attention. |
| Q36611247 | Prosimian primates show ratio dependence in spontaneous quantity discriminations |
| Q46931294 | Representation of different exact numbers of prey by a spider-eating predator. |
| Q48738924 | Resource demands of object tracking and differential allocation of the resource. |
| Q34958726 | Selecting and perceiving multiple visual objects |
| Q38564469 | Selecting and tracking multiple objects |
| Q89397153 | Set similarity modulates object tracking in dynamic environments |
| Q42906848 | Similarity-Based Interference and the Acquisition of Adjunct Control |
| Q42720557 | Small Subitizing Range in People with Williams syndrome |
| Q30388818 | Sound segregation via embedded repetition is robust to inattention |
| Q30487131 | Spatial ensemble statistics are efficient codes that can be represented with reduced attention |
| Q30474089 | Spatially uninformative sounds increase sensitivity for visual motion change. |
| Q39673863 | Studying cognitive adaptations in the field of sport: broad or narrow transfer? A comment on Allen, Fioratou, and McGeorge (2011). |
| Q39353592 | Studying visual attention using the multiple object tracking paradigm: A tutorial review |
| Q48557913 | Sustained attention to objects' motion sharpens position representations: Attention to changing position and attention to motion are distinct |
| Q41843095 | Swapping or dropping? Electrophysiological measures of difficulty during multiple object tracking |
| Q51037457 | Task-Dependent Representation of Moving Objects Within Working Memory in Obstacle Avoidance |
| Q64088725 | The Relationship Between Cognitive Functions and Sport-Specific Motor Skills in Elite Youth Soccer Players |
| Q29038889 | The Role of the Parietal Lobe in Visual Extinction Studied with Transcranial Magnetic Stimulation |
| Q48550503 | The contributions of visual and central attention to visual working memory |
| Q34401709 | The coordinate systems used in visual tracking |
| Q36718124 | The development of individuation in autism |
| Q42321287 | The effect of visual distinctiveness on multiple object tracking performance |
| Q48773909 | The effects of distractors in multiple object tracking are modulated by the similarity of distractor and target features |
| Q37147906 | The impact of a sports vision training program in youth field hockey players |
| Q41939967 | The more often you see an object, the easier it becomes to track it |
| Q39182780 | The number and quality of representations in working memory |
| Q33854759 | The number of attentional foci and their precision are dissociated in the posterior parietal cortex |
| Q35144054 | The role of spatial configuration in multiple identity tracking |
| Q34081022 | The role of visual attention in multiple object tracking: Evidence from ERPs |
| Q34114922 | Tracking planets and moons: mechanisms of object tracking revealed with a new paradigm |
| Q46688128 | Tracking the changing features of multiple objects: progressively poorer perceptual precision and progressively greater perceptual lag. |
| 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 |
| Q37844208 | Visual cognition |
| Q38281291 | Visual learning in multiple-object tracking |
| Q47953872 | Visual search tasks: measurement of dynamic visual lobe and relationship with display movement velocity. |
| Q46006533 | Visually tracking and localizing expanding and contracting objects. |
| Q42943790 | Why do people appear not to extrapolate trajectories during multiple object tracking? A computational investigation |
Search more.