| scholarly article | Q13442814 |
| P356 | DOI | 10.1364/JOSA.65.000847 |
| P953 | full work available at URL | https://www.osapublishing.org/viewmedia.cfm?URI=josa-65-7-847&seq=0 |
| P698 | PubMed publication ID | 1142031 |
| P50 | author | Gerald Westheimer | Q5549674 |
| Suzanne P. McKee | Q56523919 | ||
| P2860 | cites work | VISUAL ACUITY. | Q35494275 |
| Visual acuity as a function of exposure duration | Q43914030 | ||
| Motions of the Retinal Image during Fixation* | Q56029116 | ||
| Eye movement responses to a horizontally moving visual stimulus | Q73676507 | ||
| Effect of retinal image motion on contrast thresholds for maintained vision | Q74568242 | ||
| The role of physiological nystagmus in monocular acuity | Q76109744 | ||
| Vision with controlled movements of the retinal image | Q78518804 | ||
| Effects of involuntary eye movements on visual acuity | Q78777617 | ||
| Quantitative relations among vernier, real depth, and stereoscopic depth acuities | Q79516012 | ||
| P433 | issue | 7 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | engineering | Q11023 |
| P304 | page(s) | 847-850 | |
| P577 | publication date | 1975-07-01 | |
| P1433 | published in | Journal of the Optical Society of America | Q6296174 |
| P1476 | title | Visual acuity in the presence of retinal-image motion | |
| Visual acuity in the presence of retinal-image motion* | |||
| P478 | volume | 65 |
| Q36568943 | A Weber-like law for perceptual learning |
| Q36729802 | A foveal target increases catch-up saccade frequency during smooth pursuit |
| Q43967132 | A retinotopic attentional trace after saccadic eye movements: evidence from event-related potentials |
| Q41832302 | Age related change of optokinetic nystagmus in healthy subjects: a study from infancy to senescence |
| Q92386599 | An automated segmentation approach to calibrating infantile nystagmus waveforms |
| Q48288566 | Analog VLSI-based modeling of the primate oculomotor system |
| Q51503863 | Angular and linear vestibulo-ocular responses in humans. |
| Q46156322 | Autorotation test of the horizontal vestibulo-ocular reflex in Menière's disease |
| Q49310256 | Bilateral oculomotor abnormalities in strabismic amblyopes: evidence for a common central mechanism |
| Q51407969 | Binocular coordination of saccades in 7 years old children in single word reading and target fixation. |
| Q36499301 | Broad bandwidth of perceptual learning in the visual system of adults with anisometropic amblyopia |
| Q58816649 | COMPUTATIONAL VISUAL SENSITIVITY MODELS — A REVIEW |
| Q34222248 | Can perceptual learning be used to treat amblyopia beyond the critical period of visual development? |
| Q54056274 | Chapter 27 Is the cerebellum sensory for motor's sake, or motor for sensory's sake: the view from the whiskers of a rat? |
| Q88396971 | Choosing a foveal goal recruits the saccadic system during smooth pursuit |
| Q73466616 | Chromatic and luminance contributions to a hyperacuity task |
| Q48440172 | Commutative saccadic generator is sufficient to control a 3-D ocular plant with pulleys |
| Q38809134 | Comparison of Naso-temporal Asymmetry During Monocular Smooth Pursuit, Optokinetic Nystagmus, and Ocular Following Response in Strabismic Monkeys |
| Q46715818 | Comparison of ganglion cell signals and psychophysical localization of moving targets can help define central motion mechanisms |
| Q73850666 | Comparison of thresholds for high-speed drifting vernier and a matched temporal phase-discrimination task |
| Q48288609 | Computing with self-excitatory cliques: A model and an application to hyperacuity-scale computation in visual cortex |
| Q48422301 | Congenital and compensated vestibular dysfunction in childhood: an overlooked entity |
| Q30417230 | Consensus paper: the role of the cerebellum in perceptual processes |
| Q48975196 | Cortical maps of separable tuning properties predict population responses to complex visual stimuli |
| Q52387569 | Detection of changes in speed and direction of motion: reaction time analysis. |
| Q71077685 | Differential motion hyperacuity under conditions of common image motion |
| Q52051303 | Direction of heading and vestibular control of binocular eye movements. |
| Q48396504 | Does the nervous system use equilibrium-point control to guide single and multiple joint movements? |
| Q38380868 | Effect of title on eye-movement exploration of cubist paintings by Fernand Léger |
| Q41746355 | Effects of vestibular and cerebellar deficits on gaze and torso stability during ambulation |
| Q37020163 | Efference copy failure during smooth pursuit eye movements in schizophrenia |
| Q37257198 | Efficient sensory cortical coding optimizes pursuit eye movements |
| Q35027851 | Evaluation of vestibular function in young children |
| Q42453582 | Expression of calcium-binding proteins in cerebellar- and inferior olivary-projecting neurons in the nucleus lentiformis mesencephali of pigeons |
| Q33462268 | Extending the eXpanded Nystagmus Acuity Function for vertical and multiplanar data |
| Q61803874 | Eye Movement Compensation and Spatial Updating in Visual Prosthetics: Mechanisms, Limitations and Future Directions |
| Q46531950 | Eye movement instabilities and nystagmus can be predicted by a nonlinear dynamics model of the saccadic system |
| Q30466293 | Eye movements: the past 25 years |
| Q30505236 | Feature integration across space, time, and orientation |
| Q34054234 | Features and the 'primal sketch'. |
| Q30571476 | Flexibility of foveal attention during ocular pursuit |
| Q90049773 | Glissades Are Altered by Lesions to the Oculomotor Vermis but Not by Saccadic Adaptation |
| Q64267752 | Habitual higher order aberrations affect Landolt but not Vernier acuity |
| Q30704093 | Head-Eye Coordination at a Microscopic Scale. |
| Q33403756 | Identification of retinal ganglion cells and their projections involved in central transmission of information about upward and downward image motion |
| Q45814899 | Illusory motion reveals velocity matching, not foveation, drives smooth pursuit of large objects |
| Q48147347 | Impaired analysis of moving objects due to deficient smooth pursuit eye movements |
| Q44160472 | Improvement in vernier acuity with practice |
| Q42606301 | Increased drift in amblyopic eyes |
| Q34545535 | Influence of motion smear on visual acuity in simulated infantile nystagmus |
| Q40069692 | Integration regions for visual hyperacuity |
| Q34064772 | Is the cerebellum sensory for motor's sake, or motor for sensory's sake: the view from the whiskers of a rat? |
| Q46803091 | Line-separation discrimination curve in the human fovea: smooth or segmented? |
| Q38130378 | Linking minds and brains |
| Q80858548 | Local and non-local deficits in amblyopia: acuity and spatial interactions |
| Q48267365 | Modulation of saccadic intrusions by exogenous and endogenous attention |
| Q48362042 | Motion deblurring in a neural network model of retino-cortical dynamics. |
| Q55431012 | Motion deblurring in human vision. |
| Q48389858 | Motion of the eye immediately after a saccade |
| Q59099157 | Motion smear |
| Q46039923 | Motion-based super-resolution in the peripheral visual field. |
| Q58998263 | Motion-deblurring in human vision |
| Q73887642 | Moving vernier in amblyopic and peripheral vision: greater tolerance to motion blur |
| Q48348940 | Neural control of rotational kinematics within realistic vestibuloocular coordinate systems |
| Q37102600 | Neural models and physiological reality |
| Q74486980 | New, sensitive window on abnormal spatial vision: rarebit probing |
| Q48518720 | Nonlinear time series analysis of jerk congenital nystagmus |
| Q36071035 | Nystagmus Does Not Limit Reading Ability in Albinism |
| Q30493809 | Oculopalatal tremor explained by a model of inferior olivary hypertrophy and cerebellar plasticity |
| Q35318697 | Optokinetic nystagmus in patients with central scotomas in age related macular degeneration |
| Q38937196 | Orientation-dependent biases in length judgments of isolated stimuli |
| Q34181745 | Origins of superior dynamic visual acuity in baseball players: superior eye movements or superior image processing |
| Q30495661 | Oscillopsia: visual function during motion in the absence of vestibulo-ocular reflex |
| Q71527190 | Pattern perception at high velocities |
| Q24651081 | Perceptual learning as a potential treatment for amblyopia: a mini-review |
| Q45017043 | Predicting the duration of ocular pursuit in humans. |
| Q52168630 | Progress and paradigm shifts in spatial vision over the 20 years of ECVP. |
| Q42676842 | Psychophysical and physiological evidence contradicts a model of dynamic image stabilization |
| Q70892042 | Psychophysical isolation of movement sensitivity by removal of familiar position cues |
| Q67003716 | Quality of retinal image stabilization during small natural and artificial body rotations in man |
| Q61805801 | Rapid and specific processing of person-related information in human anterior temporal lobe |
| Q73110516 | Relationships among visual acuity demands, convergence, and nystagmus in patients with manifest/latent nystagmus |
| Q48529712 | Resolution of static and dynamic stimuli in the peripheral visual field. |
| Q42462506 | Retinal projection to the pretectal nucleus lentiformis mesencephali in pigeons (Columba livia). |
| Q24594991 | Shifter circuits: a computational strategy for dynamic aspects of visual processing |
| Q43483342 | Simulation of a phosphene-based visual field: visual acuity in a pixelized vision system |
| Q35023153 | Slow fluctuations in eye position and resting-state functional magnetic resonance imaging brain activity during visual fixation |
| Q51835360 | Spatial attention and reaction times during smooth pursuit eye movement. |
| Q53938943 | Spatial integration in human smooth pursuit. |
| Q58786142 | Spatial summation in the human fovea: Do normal optical aberrations and fixational eye movements have an effect? |
| Q36094888 | Spatial-bisection acuity in infantile nystagmus |
| Q51986696 | Spatiotemporal tuning of optic flow inputs to the vestibulocerebellum in pigeons: differences between mossy and climbing fiber pathways. |
| Q75363610 | Spontaneous eye movements in goldfish: oculomotor integrator performance, plasticity, and dependence on visual feedback |
| Q43051593 | Stimulus dependence of the flash-lag effect |
| Q42479260 | Telencephalic projections to the nucleus of the basal optic root and pretectal nucleus lentiformis mesencephali in pigeons |
| Q35785903 | Temporal dynamics of ocular position dependence of the initial human vestibulo-ocular reflex |
| Q34088602 | Temporal facilitation for moving stimuli is independent of changes in direction |
| Q39569737 | The behavior of human gaze in three dimensions |
| Q44235705 | The detectability of geometric structure in rapidly changing optical patterns |
| Q49791178 | The effect of locomotion on early visual contrast processing in humans. |
| Q43617981 | The flash-lag phenomenon: object motion and eye movements |
| Q58698858 | The gaze stability of 4- to 10-week-old human infants |
| Q92770035 | The impact of retinal motion on stereoacuity for physical targets |
| Q30491397 | The main sequence of saccades optimizes speed-accuracy trade-off |
| Q53537076 | The relationship of nystagmus waveform on the VEP response in infantile nystagmus syndrome: a small case series. |
| Q50924396 | The representation of complex images in spatial frequency domains of primary visual cortex. |
| Q48396495 | The representation of egocentric space in the posterior parietal cortex |
| Q47555089 | The retinal projection to the nucleus lentiformis mesencephali in zebra finch (Taeniopygia guttata) and Anna's hummingbird (Calypte anna). |
| Q36868009 | The temporal impulse response function in infantile nystagmus |
| Q38781096 | The vestibulo-ocular reflex: an outdated concept? |
| Q71715937 | Topographical reproducibility of small scotoma using computerised dynamic fixation target |
| Q49150974 | Tracking of small objects in front of a textured background by insects and vertebrates: phenomena and neuronal basis |
| Q39135174 | Treated amblyopes remain deficient in spatial vision: a contrast sensitivity and external noise study |
| Q38571556 | Unilateral vestibular deafferentation causes permanent impairment of the human vertical vestibulo-ocular reflex in the pitch plane |
| Q73043735 | Velocity dependence of Vernier and letter acuity for band-pass filtered moving stimuli |
| Q70991747 | Vernier acuity and stereopsis with discontinuously moving stimuli |
| Q52207319 | Vernier acuity during image rotation and translation: Visual performance limits |
| Q77496001 | Vernier and letter acuities for low-pass filtered moving stimuli |
| Q44457823 | Vestibular contributions to gaze stability during transient forward and backward motion |
| Q64063296 | Vestibulo-Ocular Responses and Dynamic Visual Acuity During Horizontal Rotation and Translation |
| Q35004778 | Visual acuity of simulated thalamic visual prostheses in normally sighted humans |
| Q21133643 | Visual function and cortical organization in carriers of blue cone monochromacy |
| Q72518398 | Visual hyperacuity: spatiotemporal interpolation in human vision |
| Q47953872 | Visual search tasks: measurement of dynamic visual lobe and relationship with display movement velocity. |
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