| scholarly article | Q13442814 |
| P50 | author | Fernando Vargas-Martín | Q41174190 |
| Eli Peli | Q55446038 | ||
| P2093 | author name string | Gang Luo | |
| P2860 | cites work | The roles of vision and eye movements in the control of activities of daily living | Q73647479 |
| Gaze-shift dynamics in two kinds of sequential looking tasks | Q73887672 | ||
| Intrasaccadic perception | Q74494318 | ||
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| Spatiotopic transfer of visual-form adaptation across saccadic eye movements | Q81328728 | ||
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| Velocity characteristics of normal human saccades. | Q34052925 | ||
| Motion perception of saccade-induced retinal translation | Q34381646 | ||
| Eye movements in natural behavior | Q36088630 | ||
| What can saliency models predict about eye movements? Spatial and sequential aspects of fixations during encoding and recognition | Q38391785 | ||
| Use of an augmented-vision device for visual search by patients with tunnel vision | Q38394076 | ||
| Quantitative measurement of saccade amplitude, duration, and velocity | Q39225068 | ||
| Predictive remapping of visual features precedes saccadic eye movements | Q40200980 | ||
| A saliency-based search mechanism for overt and covert shifts of visual attention | Q41733083 | ||
| Comparison of the main sequence of reflexive saccades and the quick phases of optokinetic nystagmus | Q42198298 | ||
| Eye movements of patients with tunnel vision while walking | Q42604322 | ||
| Illusory localization of stimuli flashed in the dark before saccades | Q46073607 | ||
| Task and context determine where you look | Q47569007 | ||
| Influence of the thalamus on spatial visual processing in frontal cortex. | Q48375321 | ||
| The updating of the representation of visual space in parietal cortex by intended eye movements | Q48550550 | ||
| Optimal eye movement strategies in visual search | Q48964127 | ||
| Transsaccadic integration of visual features in a line intersection task. | Q51957575 | ||
| Visual stability across saccades while viewing complex pictures. | Q52047945 | ||
| Changing your mind: on the contributions of top-down and bottom-up guidance in visual search for feature singletons. | Q52105170 | ||
| Peripheral and parafoveal cueing and masking effects on saccadic selectivity in a gaze-contingent window paradigm. | Q52128859 | ||
| Integration of Form across Saccadic Eye Movements | Q52239070 | ||
| The influence of artificial scotomas on eye movements during visual search. | Q52971535 | ||
| Motion perception during saccadic eye movements | Q55969405 | ||
| Guided Search 2.0 A revised model of visual search | Q55982827 | ||
| Human gaze control during real-world scene perception | Q56698469 | ||
| The role of the saccade target object in the perception of a visually stable world | Q63253014 | ||
| Most naturally occurring human saccades have magnitudes of 15 degrees or less | Q66934255 | ||
| Saccadic eye movements and the perception of visual direction | Q69763270 | ||
| Postsaccadic target blanking prevents saccadic suppression of image displacement | Q71336716 | ||
| Saccadic eye movement parameters in normal subjects | Q72067681 | ||
| P433 | issue | 14 | |
| P304 | page(s) | 25.1-8 | |
| P577 | publication date | 2008-12-22 | |
| P1433 | published in | Journal of Vision | Q6296043 |
| P1476 | title | The role of peripheral vision in saccade planning: learning from people with tunnel vision | |
| P478 | volume | 8 |
| Q38884084 | Adaptive Gaze Strategies for Locomotion with Constricted Visual Field |
| Q37244742 | Association between rates of binocular visual field loss and vision-related quality of life in patients with glaucoma |
| Q37149418 | Considering Apical Scotomas, Confusion, and Diplopia When Prescribing Prisms for Homonymous Hemianopia |
| Q42649629 | Driving with Hemianopia V: Do Individuals with Hemianopia Spontaneously Adapt Their Gaze Scanning to Differing Hazard Detection Demands? |
| Q30567424 | Driving with hemianopia: III. Detection of stationary and approaching pedestrians in a simulator |
| Q37637442 | Driving with hemianopia: IV. Head scanning and detection at intersections in a simulator |
| Q38930281 | Driving with homonymous visual field loss: a review of the literature |
| Q42250718 | Dynamic peripheral visual performance relates to alpha activity in soccer players |
| Q30528392 | Effects of peripheral visual field loss on eye movements during visual search. |
| Q33839216 | Extended wearing trial of Trifield lens device for 'tunnel vision' |
| Q36063088 | Eye Movement Training and Suggested Gaze Strategies in Tunnel Vision - A Randomized and Controlled Pilot Study |
| Q47299030 | Gaze Compensation as a Technique for Improving Hand–Eye Coordination in Prosthetic Vision. |
| Q37540133 | Impact of high power and angle of incidence on prism corrections for visual field loss |
| Q58765081 | Measuring Pedestrian Collision Detection With Peripheral Field Loss and the Impact of Peripheral Prisms |
| Q47902425 | Multiplexing Prisms for Field Expansion |
| Q45780258 | Peripheral visual performance enhancement by neurofeedback training. |
| Q53076635 | Spatial judgments in patients with retinitis pigmentosa. |
| Q38385064 | The Role of Extrafoveal Vision in Source Code Comprehension. |
| Q37482087 | The risk of pedestrian collisions with peripheral visual field loss |
| Q50696012 | The role of central and peripheral vision in expert decision making. |
| Q38562533 | Visual Contrast Processing is Largely Unaltered during Saccades |
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