| scholarly article | Q13442814 |
| P50 | author | David Aagten-Murphy | Q52280018 |
| P2093 | author name string | Paul M Bays | |
| P2860 | cites work | Computational modelling of visual attention | Q28205343 |
| Endogenous and exogenous control of visual selection | Q28242695 | ||
| Saccade target selection and object recognition: evidence for a common attentional mechanism | Q28287057 | ||
| The role of visual attention in saccadic eye movements | Q28296056 | ||
| Attentional and oculomotor capture by onset, luminance and color singletons | Q33180260 | ||
| A backward progression of attentional effects in the ventral stream | Q33591593 | ||
| Microsaccades are triggered by low retinal image slip | Q34598718 | ||
| A global effect of capture saccades | Q34705569 | ||
| View from the top: hierarchies and reverse hierarchies in the visual system | Q35017703 | ||
| Selective visual attention and perceptual coherence | Q36327326 | ||
| Physiology and pathology of eye-head coordination | Q36840312 | ||
| Exploring the superior colliculus in vitro | Q37422271 | ||
| Involuntary covert orienting is contingent on attentional control settings | Q38472121 | ||
| Revisiting the global effect and inhibition of return. | Q41105912 | ||
| Role of monkey superior colliculus in saccade averaging | Q41193455 | ||
| The role of location probability in the programming of saccades: implications for "center-of-gravity" tendencies | Q41254920 | ||
| The microscopic anatomy and physiology of the mammalian saccadic system | Q41277004 | ||
| Reorienting attention across the horizontal and vertical meridians: evidence in favor of a premotor theory of attention | Q41456100 | ||
| Reducing the influence of non-target stimuli on saccade accuracy: predictability and latency effects | Q41456336 | ||
| Linking express saccade occurance to stimulus properties and sensorimotor integration in the superior colliculus | Q41966421 | ||
| Dependence on target configuration of express saccade-related activity in the primate superior colliculus | Q46246413 | ||
| The global effect for antisaccades | Q46284655 | ||
| Properties of Saccadic Responses in Monkey When Multiple Competing Visual Stimuli Are Present | Q46301527 | ||
| Averaging is not everything: the saccade global effect weakens with increasing stimulus size. | Q47314516 | ||
| Onsets do not override top-down goals, but they are responded to more quickly | Q47793173 | ||
| Competitive integration of visual and preparatory signals in the superior colliculus during saccadic programming. | Q48171896 | ||
| Role of primate superior colliculus in preparation and execution of anti-saccades and pro-saccades. | Q48257316 | ||
| A competitive integration model of exogenous and endogenous eye movements | Q48304034 | ||
| Eye movements are primed toward the center of multiple stimuli even when the interstimulus distances are too large to generate saccade averaging | Q48309796 | ||
| Representation of averaging saccades in the superior colliculus of the monkey | Q48381511 | ||
| Stimulus-salience and the time-course of saccade trajectory deviations | Q48398328 | ||
| Differential effect of a distractor on primary saccades and perceptual localization | Q48427523 | ||
| The role of stimulus-driven and goal-driven control in saccadic visual selection | Q48529423 | ||
| An in vitro study of horizontal connections in the intermediate layer of the superior colliculus. | Q48556493 | ||
| Goal-driven modulation of oculomotor capture. | Q48564596 | ||
| Eye cannot see it: the interference of subliminal distractors on saccade metrics | Q48584588 | ||
| Programming of endogenous and exogenous saccades: evidence for a competitive integration model | Q48615477 | ||
| Relation between saccade trajectories and spatial distractor locations | Q48792123 | ||
| Spatial interactions in the superior colliculus predict saccade behavior in a neural field model | Q48882241 | ||
| Saccadic inhibition reveals the timing of automatic and voluntary signals in the human brain. | Q48924452 | ||
| A model of saccade initiation based on the competitive integration of exogenous and endogenous signals in the superior colliculus | Q48956849 | ||
| Express averaging saccades in monkeys | Q49080656 | ||
| Latency dependence of colour-based target vs nontarget discrimination by the saccadic system | Q49172313 | ||
| The time course of top-down control on saccade averaging. | Q50457664 | ||
| How memory mechanisms are a key component in the guidance of our eye movements: evidence from the global effect. | Q50724260 | ||
| Global visual processing for saccadic eye movements. | Q50848430 | ||
| Searching for stimulus-driven shifts of attention. | Q52056703 | ||
| The temporal dynamics of the distractor in the global effect. | Q52139596 | ||
| Overriding stimulus-driven attentional capture. | Q52217016 | ||
| The structure of attentional control: contingent attentional capture by apparent motion, abrupt onset, and color. | Q52217310 | ||
| Oculomotor capture by transient events: a comparison of abrupt onsets, offsets, motion, and flicker. | Q52591441 | ||
| How global is the global effect? The spatial characteristics of saccade averaging | Q60036650 | ||
| Spatial attention-determined modifications in saccade trajectories | Q60184027 | ||
| Scrutinization, spatial attention, and the spatial programming of saccadic eye movements | Q67990078 | ||
| Uniqueness of abrupt visual onset in capturing attention | Q68334916 | ||
| On localization and saccade programming | Q68698361 | ||
| The relationship between eye movements and spatial attention | Q69628162 | ||
| Effect of Non-Target Stimuli upon Length of Voluntary Saccades | Q70456860 | ||
| Metrics of saccade responses to visual double stimuli: two different modes | Q70746999 | ||
| Stimulus-driven attentional capture and attentional control settings | Q72831307 | ||
| The spatial signal for saccadic eye movements emphasizes visual boundaries | Q72834192 | ||
| Influence of attentional capture on oculomotor control | Q73369597 | ||
| Intermodal selective attention in monkeys. I: distribution and timing of effects across visual areas | Q73685430 | ||
| Effect of remote distractors on saccade programming: evidence for an extended fixation zone | Q73721867 | ||
| Saccadic and psychophysical discrimination of double targets | Q73952891 | ||
| Selectivity in distraction by irrelevant featural singletons: evidence for two forms of attentional capture | Q74650318 | ||
| Saccade target selection in visual search: accuracy improves when more distractors are present | Q75430785 | ||
| Characteristics of covert and overt visual orienting: Evidence from attentional and oculomotor capture | Q79222119 | ||
| Influence of foveal distractors on saccadic eye movements: a dead zone for the global effect | Q79269691 | ||
| Limited flexibility in the filter underlying saccadic targeting | Q79312375 | ||
| Oculomotor consequences of abrupt object onsets and offsets: onsets dominate oculomotor capture | Q81586154 | ||
| Saccade target selection: Do distractors affect saccade accuracy? | Q81763436 | ||
| There is no attentional global effect: Attentional shifts are independent of the saccade endpoint | Q86802088 | ||
| P433 | issue | 2 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | automation | Q184199 |
| P304 | page(s) | 1105-1122 | |
| P577 | publication date | 2017-05-24 | |
| P1433 | published in | Journal of Neurophysiology | Q1709863 |
| P1476 | title | Automatic and intentional influences on saccade landing | |
| P478 | volume | 118 |
| Q91747383 | Increased preparation time reduces, but does not abolish, action history bias of saccadic eye movements |
| Q92567076 | The temporal and spatial constraints of saccade planning to double-step target displacements |
| Q99720228 | Visual attention and eye movement control during oculomotor competition |
| Q89233732 | Visual attention is not deployed at the endpoint of averaging saccades |
| Q83231062 | Voluntary and involuntary contributions to perceptually guided saccadic choices resolved with millisecond precision |
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