| scholarly article | Q13442814 |
| P356 | DOI | 10.1111/1467-9280.00006 |
| P5875 | ResearchGate publication ID | 242643758 |
| P2093 | author name string | Jeremy M. Wolfe | |
| P2860 | cites work | A feature-integration theory of attention | Q28281952 |
| Visual search for a conjunction of movement and form is parallel | Q34175426 | ||
| Linguistic and conceptual control of visual spatial attention | Q38463701 | ||
| Further evidence for a time-independent shift of the focus of attention | Q43671762 | ||
| Guided search: an alternative to the feature integration model for visual search | Q46405030 | ||
| Set-size effects in visual search: the effect of attention is independent of the stimulus for simple tasks | Q47373157 | ||
| Serial and parallel processing of visual feature conjunctions | Q48365624 | ||
| Vision outside the focus of attention. | Q52240820 | ||
| Visual search and stimulus similarity. | Q52245806 | ||
| Discriminability and dimensionality effects in visual search for featural conjunctions: a functional pop-out. | Q52245808 | ||
| How serial is serial processing in vision? | Q52248041 | ||
| Stimulus discriminability in visual search. | Q52371816 | ||
| Guided Search 2.0 A revised model of visual search | Q55982827 | ||
| Preattentive Object Files: Shapeless Bundles of Basic Features | Q57743041 | ||
| Just Say No: How Are Visual Searches Terminated When There Is No Target Present? | Q57743046 | ||
| “Effortless” texture segmentation and “parallel” visual search are not the same thing | Q57743063 | ||
| P433 | issue | 1 | |
| P304 | page(s) | 33-39 | |
| P577 | publication date | 1998-01-01 | |
| P1433 | published in | Psychological Science | Q7256367 |
| P1476 | title | What Can 1 Million Trials Tell Us About Visual Search? | |
| P478 | volume | 9 |
| Q52129079 | A clarification of self-terminating versus exhaustive variances in serial and parallel models. |
| Q48605558 | A computational model of fMRI activity in the intraparietal sulcus that supports visual working memory. |
| Q38028381 | A conceptual and methodological framework for measuring and modulating the attentional blink |
| Q46166469 | A dynamic model of how feature cues guide spatial attention |
| Q99365490 | Accelerating eye movement research via accurate and affordable smartphone eye tracking |
| Q37639344 | Age-Related Changes in the Ability to Switch between Temporal and Spatial Attention. |
| Q47437922 | Analysis of internal and external validity criteria for a computerized visual search task: A pilot study |
| Q35746549 | Appraising the role of visual threat in speeded detection and classification tasks |
| Q36151274 | Are Categorical Spatial Relations Encoded by Shifting Visual Attention between Objects? |
| Q33839086 | Are cortical models really bound by the "binding problem"? |
| Q41158351 | Are processing limitations of visual attention and response selection subject to the same bottleneck in dual-tasks? |
| Q52133778 | Asymmetries in visual search: an introduction. |
| Q83513723 | Attentional guidance relies on a winner-take-all mechanism |
| Q33826720 | Attentional modulation of visual motion perception |
| Q38414714 | Basic processes in reading: is visual word recognition obligatory? |
| Q47579063 | Behavioral evidence for a continuous approach to the perception of emotionally valenced stimuli |
| Q48188935 | Binocularity and visual search-Revisited. |
| Q48251270 | Brain electrical correlates of dimensional weighting: an ERP study. |
| Q38027066 | Breaking through the attentional window: capture by abrupt onsets versus color singletons |
| Q38844261 | Central attention is serial, but midlevel and peripheral attention are parallel-A hypothesis. |
| Q48911131 | Changes in search rate but not in the dynamics of exogenous attention in action videogame players |
| Q50593744 | Color is processed less efficiently than orientation in change detection but more efficiently in visual search. |
| Q51794665 | Colour and spatial cueing in low-prevalence visual search. |
| Q52081421 | Concavities as basic features in visual search: evidence from search asymmetries. |
| Q51737013 | Concurrent deployment of visual attention and response selection bottleneck in a dual-task: Electrophysiological and behavioural evidence. |
| Q37183918 | Contextual cuing by global features |
| Q47406480 | Differential performance of Chinese volleyball athletes and nonathletes on a multiple-object tracking task. |
| Q36943919 | Displaywide visual features associated with a search display's appearance can mediate attentional capture |
| Q37172591 | Distractor Dwelling, Skipping, and Revisiting Determine Target Absent Performance in Difficult Visual Search. |
| Q57742963 | Do Intersections Serve as Basic Features in Visual Search? |
| Q36127176 | Do People "Pop Out"? |
| Q52106279 | Does partial difficult search help difficult search? |
| Q36091771 | Dynamics of saccade target selection: race model analysis of double step and search step saccade production in human and macaque. |
| Q38537621 | EPS Mid-Career Award 2014. The control of attention in visual search: Cognitive and neural mechanisms |
| Q51640156 | Early computation of part structure: evidence from visual search. |
| Q73918251 | Effect of stimulus contrast on performance and eye movements in visual search |
| Q59070140 | Electrophysiological measurement of rapid shifts of attention during visual search |
| Q50636995 | Emotional triangles: a test of emotion-based attentional capture by simple geometric shapes. |
| Q74327398 | Eye movements in the visual search of word lists |
| Q33764625 | Familiarity facilitates feature-based face processing |
| Q52120596 | Fast responses to neglected targets in visual search reflect pre-attentive processes: an exploration of response times in visual neglect. |
| Q77875722 | Focal attention in visual search |
| Q42028254 | For whom the bell tolls: periodic reactivation of sensory cortex in the gamma band as a substrate of visual working memory maintenance |
| Q50619777 | From shunting inhibition to dynamic normalization: Attentional selection and decision-making in brief visual displays. |
| Q38538860 | Functional MRI mapping of visual function and selective attention for performance assessment and presurgical planning using conjunctive visual search |
| Q47433057 | Ground-plane influences on size estimation in early visual processing |
| Q41479949 | Guided search for triple conjunctions |
| Q35691085 | Haptic pop-out of movable stimuli |
| Q34598691 | Hemifield asymmetries differentiate VSTM for single- and multiple-feature objects |
| Q51940612 | Hemispatial neglect and visual search: a large scale analysis. |
| Q43839206 | Higher set sizes in pop-out search displays do not eliminate priming or enhance target selection |
| Q51970239 | How does the purpose of inspection influence the potency of visual salience in scene perception? |
| Q36094189 | How the speed of motor-response decisions, but not focal-attentional selection, differs as a function of task set and target prevalence |
| Q52137389 | How to produce an absent-advantage in visual search. |
| Q36583527 | Hybrid foraging search: Searching for multiple instances of multiple types of target |
| Q47726940 | Icon flickering, flicker rate, and color combinations of an icon's symbol/background in visual search performance |
| Q43790949 | Impact of the motion and visual complexity of the background on players' performance in video game-like displays. |
| Q44405135 | Inefficient conjunction search made efficient by concurrent spoken delivery of target identity |
| Q52166579 | Inhibition of return and visual search: how many separate loci are inhibited? |
| Q51843695 | Inhibitory guidance in visual search: the case of movement-form conjunctions. |
| Q41832372 | Introduction to the special issue on visual working memory |
| Q80232790 | Investigating a space-variant weighted salience account of visual selection |
| Q64259273 | Investigating the Effect of the Environment on Prey Detection Ability in Humans |
| Q49035131 | Linguistically mediated visual search |
| Q51991916 | Localized attentional interference affects object individuation, not feature detection. |
| Q51028995 | Location and identity memory of saccade targets. |
| Q46933215 | Looking, seeing and believing in autism: Eye movements reveal how subtle cognitive processing differences impact in the social domain |
| Q36973685 | Measuring the Performance of Attention Networks with the Dalhousie Computerized Attention Battery (DalCAB): Methodology and Reliability in Healthy Adults |
| Q57742970 | Memory for rejected distractors in visual search? |
| Q51015925 | Memory load affects visual search processes without influencing search efficiency. |
| Q50959866 | Modeling visual search using three-parameter probability functions in a hierarchical Bayesian framework. |
| Q36167040 | Modulation of spatial attention by goals, statistical learning, and monetary reward |
| Q50060277 | More insight into the interplay of response selection and visual attention in dual-tasks: masked visual search and response selection are performed in parallel |
| Q34176947 | Moving towards solutions to some enduring controversies in visual search |
| Q33839076 | Neuronal synchrony: a versatile code for the definition of relations? |
| Q50449910 | Numerosity estimates for attended and unattended items in visual search |
| Q41457786 | On computational modeling of visual saliency: Examining what's right, and what's left |
| Q42042289 | On the Factors Causing Processing Difficulty of Multiple-Scene Displays. |
| Q47727343 | On the brink: The demise of the item in visual search moves closer |
| Q45047731 | Optimal random search for a single hidden target |
| Q58175179 | Outstanding Data sets: A new category of articles that promotes modelling published in the Quantitative Methods for Psychology |
| Q35648507 | Parametric modeling of visual search efficiency in real scenes |
| Q50605691 | Part-whole information assists in topological × topological but not in orientation × orientation conjunction searches. |
| Q48358897 | Perceptual basis of redundancy gains in visual pop-out search |
| Q50626468 | Person perception informs understanding of cognition during visual search. |
| Q39355376 | Prior Knowledge of Object Associations Shapes Attentional Templates and Information Acquisition |
| Q30010642 | Production and perception rules underlying visual patterns: effects of symmetry and hierarchy |
| Q48285760 | Psychophysics in a Web browser? Comparing response times collected with JavaScript and Psychophysics Toolbox in a visual search task. |
| Q51989124 | Rapid resumption of interrupted visual search. New insights on the interaction between vision and memory. |
| Q33937234 | Reaction time distributions constrain models of visual search |
| Q27345555 | Reading between eye saccades |
| Q28598214 | Reconsidering Visual Search |
| Q37407045 | Reduced comparison speed during visual search in late life depression |
| Q47298978 | Reference Production as Search: The Impact of Domain Size on the Production of Distinguishing Descriptions |
| Q36532999 | Response variability of frontal eye field neurons modulates with sensory input and saccade preparation but not visual search salience |
| Q58705202 | Saccadic inhibition interrupts ongoing oculomotor activity to enable the rapid deployment of alternate movement plans |
| Q47558216 | Scanning movements during haptic search: similarity with fixations during visual search |
| Q50660303 | Search asymmetry and eye movements in infants and adults. |
| Q48333569 | Searching for a salient target involves frontal regions |
| Q29041508 | Searching for faces in scrambled scenes |
| Q35222551 | Searching for flavor labels in food products: the influence of color-flavor congruence and association strength. |
| Q52176443 | Searching for impossible objects: processing form and attributes in early vision. |
| Q48555413 | Searching for inefficiency in visual search |
| Q48139122 | Searching night and day: a dissociation of effects of circadian phase and time awake on visual selective attention and vigilance |
| Q52008916 | Segmentation of objects from backgrounds in visual search tasks. |
| Q57408844 | Selective Visual Attention and Visual Search: Behavioral and Neural Mechanisms |
| Q48128747 | Selective visual attention, visual search and visual awareness |
| Q38935511 | Serial vs. parallel models of attention in visual search: accounting for benchmark RT-distributions |
| Q47858761 | Set size slope still does not distinguish parallel from serial search. |
| Q73454020 | Solutions to the binding problem: progress through controversy and convergence |
| Q33336417 | Spatial and temporal dynamics of attentional guidance during inefficient visual search. |
| Q52024936 | Spatial context learning in visual search and change detection. |
| Q33839082 | Specialized representations in visual cortex: a role for binding? |
| Q30997328 | Stimulus saliency modulates pre-attentive processing speed in human visual cortex |
| Q38387395 | Stuck on semantics: Processing of irrelevant object-scene inconsistencies modulates ongoing gaze behavior |
| Q28144831 | Synchrony unbound: a critical evaluation of the temporal binding hypothesis |
| Q41904052 | TAM: Explaining off-object fixations and central fixation tendencies as effects of population averaging during search |
| Q48534417 | Target objects defined by a conjunction of colour and shape can be selected independently and in parallel. |
| Q42676829 | Task specificity of attention training: the case of probability cuing |
| Q37685954 | The Mechanisms Underlying the ASD Advantage in Visual Search |
| Q52147712 | The Speed of Serial Attention Shifts in Visual Search: Evidence from the N2pc Component. |
| Q73453997 | The binding problem |
| Q51934971 | The contents of perceptual hypotheses: evidence from rapid resumption of interrupted visual search. |
| Q47957272 | The contribution of stimulus-driven and goal-driven mechanisms to feature-based selection in patients with spatial attention deficits |
| Q34080505 | The distinct modes of vision offered by feedforward and recurrent processing |
| Q36761659 | The downside of choice: Having a choice benefits enjoyment, but at a cost to efficiency and time in visual search |
| Q42016615 | The effect of feature saliency on haptic subitizing |
| Q35049092 | The effect of visual representation style in problem-solving: a perspective from cognitive processes |
| Q51906522 | The effects of age and exogenous support on visual search performance. |
| Q49142583 | The impending demise of the item in visual search |
| Q45252310 | The influence of cast shadows on visual search |
| Q40516253 | The multi-item localization (MILO) task: measuring the spatiotemporal context of vision for action |
| Q34021901 | The perceptual reality of synesthetic colors |
| Q33839059 | The psychophysical evidence for a binding problem in human vision |
| Q48390692 | The reconfiguration of task set has no effect on the efficiency of feature search |
| Q33839065 | The role of neural mechanisms of attention in solving the binding problem |
| Q33495578 | The spatial and temporal deployment of voluntary attention across the visual field |
| Q46268428 | The spatio-temporal dynamics of visual letter recognition |
| Q53112593 | The speed of free will. |
| Q33839069 | The temporal correlation hypothesis of visual feature integration: still alive and well |
| Q33864728 | The time-course of pop-out search |
| Q38090589 | The visual detection of threat: a cautionary tale |
| Q33839091 | The what and why of binding: the modeler's perspective |
| Q51895103 | Timing divided attention. |
| Q35224268 | Toddlers with Autism Spectrum Disorder are more successful at visual search than typically developing toddlers. |
| Q40964658 | Towards the quantitative evaluation of visual attention models. |
| Q36361916 | Trail Making Test performance contributes to subjective judgment of visual efficiency in older adults |
| Q53517121 | Understanding visual attention in childhood: Insights from a new visual foraging task. |
| Q53517125 | Use-inspired basic research in medical image perception. |
| Q73399990 | Utilisation of spatial frequency information in face search |
| Q36675480 | Viewing the dynamics and control of visual attention through the lens of electrophysiology |
| Q36035311 | Visual Features: Featural Strength and Visual Strength Are Two Dissociable Dimensions. |
| Q41896381 | Visual Search Revived: The Slopes Are Not That Slippery: A Reply to Kristjansson (2015). |
| Q50935963 | Visual routines are associated with specific graph interpretations. |
| Q38573192 | Visual search |
| Q29037229 | Visual search and selective attention |
| Q42022023 | Visual search for arbitrary objects in real scenes |
| Q92985774 | Visual search for complex objects: Set-size effects for faces, words and cars |
| Q52037961 | Visual search has no memory. |
| Q47292343 | Visual search in children and adults: top-down and bottom-up mechanisms |
| Q43987301 | Visual search in divided areas: dividers initially interfere with and later facilitate visual search |
| Q44454264 | Visual search is facilitated by scene and sequence familiarity in rhesus monkeys |
| Q50468052 | Visual search performance on an lcd monitor: effects of color combination of figure and icon background, shape of icon, and line width of icon border |
| Q52046309 | Visual search: efficiency continuum or distinct processes? |
| Q48713800 | Visual working memory capacity increases between ages 3 and 8 years, controlling for gains in attention, perception, and executive control |
| Q35777648 | What attributes guide the deployment of visual attention and how do they do it? |
| Q51886576 | What eye fixation patterns tell us about subitizing. |
| Q39756227 | When is it time to move to the next map? Optimal foraging in guided visual search |
| Q37694782 | When memory is not enough: electrophysiological evidence for goal-dependent use of working memory representations in guiding visual attention |
| Q57743031 | Which end is up? Two representations of orientation in visual search |
| Q34422453 | Words, shape, visual search and visual working memory in 3-year-old children |
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