scholarly article | Q13442814 |
P6179 | Dimensions Publication ID | 1009480276 |
P356 | DOI | 10.1038/370256B0 |
P2888 | exact match | https://scigraph.springernature.com/pub.10.1038/370256b0 |
P698 | PubMed publication ID | 8035873 |
P2093 | author name string | Nijhawan R | |
P2860 | cites work | Vernier acuity with stationary moving Gabors. | Q46025621 |
Perceptual Stability of a Stroboscopically Lit Visual Field containing Self-Luminous Objects | Q59089056 | ||
Motion smear | Q59099157 | ||
P433 | issue | 6487 | |
P407 | language of work or name | English | Q1860 |
P1104 | number of pages | 2 | |
P304 | page(s) | 256-257 | |
P577 | publication date | 1994-07-01 | |
P1433 | published in | Nature | Q180445 |
P1476 | title | Motion extrapolation in catching | |
P478 | volume | 370 |
Q47214363 | 'Perceiving the present' as a framework for ecological explanations of the misperception of projected angle and angular size |
Q80101729 | 3D flash lag illusion |
Q52001362 | A clockwork orange: compensation opposing momentum in memory for location. |
Q46047986 | A comparison of visual and auditory representational momentum in spatial tasks |
Q39687450 | A flash-drag effect in random motion reveals involvement of preattentive motion processing |
Q77181252 | A flash-lag effect in random motion |
Q73741396 | A model of the perceived relative positions of moving objects based upon a slow averaging process |
Q51851418 | A psychophysical and computational analysis of the spatio-temporal mechanisms underlying the flash-lag effect. |
Q41991012 | A transient auditory signal shifts the perceived offset position of a moving visual object. |
Q79507371 | Absence of flash-lag when judging global shape from local positions |
Q34934360 | Action can amplify motion-induced illusory displacement |
Q41968615 | Active inference, eye movements and oculomotor delays |
Q74419850 | Afferent delays and the mislocalization of perisaccadic stimuli |
Q48184689 | Alcohol slows interhemispheric transmission, increases the flash-lag effect, and prolongs masking: evidence for a slowing of neural processing and transmission |
Q36935743 | An empirical explanation of the flash-lag effect |
Q73341312 | Analogous mechanisms compensate for neural delays in the sensory and the motor pathways: evidence from motor flash-lag |
Q48245448 | Anticipation of moving stimuli by the retina |
Q41872703 | Apparent motion can impair and enhance target visibility: the role of shape in predicting and postdicting object continuity |
Q52925331 | Apparent position governs contour-element binding by the visual system. |
Q49277745 | Apparent shift in long-range motion trajectory by local pattern orientation. |
Q46617219 | Asymmetric mislocalization of a visual flash ahead of and behind a moving objectt. |
Q45986219 | Asymmetry in visual cortical circuits underlying motion-induced perceptual mislocalization. |
Q52097377 | Asynchronous perception of motion and luminance change. |
Q51949106 | Attention maintains mental extrapolation of target position: irrelevant distractors eliminate forward displacement after implied motion |
Q51956375 | Attention shifts and memory averaging. |
Q48947962 | Attentive tracking shifts the perceived location of a nearby flash. |
Q51895093 | Auditory temporal cues can modulate visual representational momentum. |
Q47695870 | Bioplausible multiscale filtering in retino-cortical processing as a mechanism in perceptual grouping |
Q39143981 | Catching the voltage gradient-asymmetric boost of cortical spread generates motion signals across visual cortex: a brief review with special thanks to Amiram Grinvald. |
Q73727371 | Change in feature space is not necessary for the flash-lag effect |
Q41730818 | Changing objects lead briefly flashed ones |
Q33523029 | Characteristics of motor resonance predict the pattern of flash-lag effects for biological motion |
Q55412088 | Chromatic induction in space and time. |
Q44593442 | Classification images reveal spatiotemporal contour interpolation |
Q36617014 | Combining visual and auditory information |
Q81420105 | Comparison of flashed and moving probes in the flash-lag effect: evidence for misbinding of abrupt and continuous changes |
Q81918515 | Computational neurobiology of the flash-lag effect |
Q58642033 | Confusion of Space and Time in the Flash-Lag Effect |
Q30519462 | Conscious updating is a rhythmic process. |
Q48820782 | Constancy of target velocity as a critical factor in the emergence of auditory and visual representational momentum. |
Q51925443 | Contributions of visible persistence and perceptual set to the flash-lag effect: focusing on flash onset abolishes the illusion. |
Q60629357 | Cortical processing and perceived timing |
Q46111666 | Cyclopean flash-lag illusion |
Q36798964 | Default perception of high-speed motion |
Q58642022 | Detection of colour changes in a moving object |
Q55649810 | Determinants of asynchronous processing in vision. |
Q55880654 | Die Hermann-Gitter-Täuschung: Lehrbucherklärung widerlegt |
Q58787958 | Differences in the Magnitude of Representational Momentum Between School-Aged Children and Adults as a Function of Experimental Task |
Q44926466 | Differential latencies and the dynamics of the position computation process for moving targets, assessed with the flash-lag effect. |
Q64054775 | Distinct mechanisms of temporal binding in generalized and cross-modal flash-lag effects |
Q81733008 | Distinct position assignment mechanisms revealed by cross-order motion |
Q47851372 | Disturbance in hitting accuracy by professional and collegiate baseball players due to intentional change of target position |
Q79437643 | Dividing attention in the flash-lag illusion |
Q40956275 | Do the flash-lag effect and representational momentum involve similar extrapolations? |
Q35171640 | Does Area V3A Predict Positions of Moving Objects? |
Q61445649 | Dynamic colour change and the confusion effect against predation |
Q46933408 | Dynamic shifts in the owl's auditory space map predict moving sound location |
Q79283418 | Dynamics of shape interaction in human vision |
Q58595256 | Ebbinghaus illusion depends more on the retinal than perceived size of surrounding stimuli |
Q46366936 | Effect of motion smoothness on the flash-lag illusion |
Q36362009 | Effect of speed overestimation on flash-lag effect at low luminance |
Q41154156 | Effects of consciousness and consistency in manual control of visual stimulus on reduction of the flash-lag effect for luminance change |
Q37119234 | Egocentric and allocentric localization during induced motion |
Q39751511 | Errors in judging "offside" in association football: test of the optical error versus the perceptual flash-lag hypothesis. |
Q91938836 | Examining motion speed processing in schizophrenia using the flash lag illusion |
Q41714681 | Extrapolating movement without retinal motion |
Q59074653 | Extrapolation or attention shift? |
Q52023055 | Eye movements and visible persistence explain the mislocalization of the final position of a moving target. |
Q48023798 | Eye-hand coordination during flexible manual interception of an abruptly appearing, moving target |
Q91586865 | Familiarity with visual stimuli boosts recency bias in macaques |
Q58560962 | Faster processing of moving compared with flashed bars in awake macaque V1 provides a neural correlate of the flash lag illusion |
Q36382882 | Feature binding of a continuously changing object |
Q90950161 | Feature integration within discrete time windows |
Q82516642 | Flash lag in depth |
Q38484997 | Flash-lag chimeras: the role of perceived alignment in the composite face effect |
Q48961923 | Flash-lag effect: complicating motion extrapolation of the moving reference-stimulus paradoxically augments the effect. |
Q45956779 | Flash-lag effects in biological motion interact with body orientation and action familiarity. |
Q45192936 | Flashes are localised as if they were moving with the eyes. |
Q48074575 | Fluctuation-response relation unifies dynamical behaviors in neural fields. |
Q41580277 | Forward Prediction in the Posterior Parietal Cortex and Dynamic Brain-Machine Interface |
Q79256684 | Forward displacements of fading objects in motion: the role of transient signals in perceiving position |
Q36031690 | Forward to the past |
Q86109351 | Fourier decomposition of spatial localization errors reveals an idiotropic dominance of an internal model of gravity |
Q39558069 | Gaze position lagging behind scene content in multiple object tracking: Evidence from forward and backward presentations. |
Q59210753 | Gross Misperceptions in the Perceived Trajectories of Moving Dots |
Q85795891 | High temporal frequency adaptation compresses time in the Flash-Lag illusion |
Q30354049 | History of experimental psychology from an Estonian perspective. |
Q35933984 | How Fast Do Objects Fall in Visual Memory? Uncovering the Temporal and Spatial Features of Representational Gravity |
Q91494482 | How can we play together? Temporal inconsistencies in neural coding of music |
Q30443855 | How long did it last? You would better ask a human |
Q83160440 | How well can people judge when something happened? |
Q30538969 | Illusory motion and mislocalization of temporally offset target in apparent motion display |
Q83949910 | Illusory position shift induced by cyclopean motion |
Q84573248 | Illusory position shift induced by plaid motion |
Q73741382 | Illusory spatial offset of a flash relative to a moving stimulus is caused by differential latencies for moving and flashed stimuli |
Q47560157 | Impact of anticipation in dynamical systems |
Q81484576 | Inference of complex human motion requires internal models of action: behavioral evidence |
Q48273404 | Influence of motion signals on the perceived position of spatial pattern. |
Q33284528 | Integrated mechanisms of anticipation and rate-of-change computations in cortical circuits |
Q48823210 | Integrating perception and action through cognitive neuropsychology (broadly conceived). |
Q30356496 | Intercepting a sound without vision. |
Q60046848 | Interpolation and extrapolation on the path of apparent motion |
Q39993007 | Interpretation and application of the offside law by expert assistant referees: perception of spatial positions in complex dynamic events on and off the field. |
Q74494318 | Intrasaccadic perception |
Q46898921 | Knowledge-based correction of flash-lag illusion |
Q50485287 | Lag normalization in an electrically coupled neural network. |
Q48447178 | Latency correction explains the classical geometrical illusions. |
Q77299462 | Latency difference, not spatial extrapolation |
Q73573408 | Latency differences and the flash-lag effect |
Q64263468 | Linking Pathological Oscillations With Altered Temporal Processing in Parkinsons Disease: Neurophysiological Mechanisms and Implications for Neuromodulation |
Q50454439 | Localization of moving sound. |
Q39819796 | Location estimation of approaching objects is modulated by the observer's inherent and momentary action capabilities |
Q42590966 | Looking ahead: the perceived direction of gaze shifts before the eyes move |
Q34634286 | Macaque monkeys perceive the flash lag illusion |
Q34600025 | Manipulating the experienced onset of intention after action execution |
Q51264111 | Manual control of the visual stimulus reduces the flash-lag effect. |
Q37539797 | Memory-prediction errors and their consequences in schizophrenia |
Q51946372 | Mental extrapolation of target position is strongest with weak motion signals and motor responses |
Q52689233 | Meridian Interference reveals Neural Locus of Motion-induced Position Shifts. |
Q41618389 | Microsaccadic sampling of moving image information provides Drosophila hyperacute vision. |
Q30480548 | Minding time in an amodal representational space |
Q34277297 | Misperceptions in the trajectories of objects undergoing curvilinear motion |
Q59210750 | Misperceptions of Trajectories of Dots Moving through the Blind Spot |
Q51407952 | Modulation of perceived contrast in the brightness comparison of asynchronous stimuli. |
Q48507124 | Modulation of the perception of temporal order by attentional and pre-attentional factors. |
Q60046824 | Motion Extrapolation for Eye Movements Predicts Perceived Motion-Induced Position Shifts |
Q52241653 | Motion detection on flashed, stationary pedestal gratings: evidence for an opponent-motion mechanism. |
Q52952497 | Motion distorts perceived depth. |
Q74246543 | Motion distorts visual space: shifting the perceived position of remote stationary objects |
Q27306517 | Motion extrapolation in the central fovea |
Q46201295 | Motion extrapolation into the blind spot. |
Q73800782 | Motion extrapolation is not responsible for the flash-lag effect |
Q38583769 | Motion in depth from interocular velocity differences revealed by differential motion aftereffect |
Q51942822 | Motion misperception caused by feedback connections: a neural model simulating the Fröhlich effect. |
Q37842844 | Motion psychophysics: 1985-2010. |
Q42123273 | Motion signals bias localization judgments: a unified explanation for the flash-lag, flash-drag, flash-jump, and Frohlich illusions |
Q85102516 | Motion signals deflect relative positions of moving objects |
Q35995978 | Motion-Dependent Filling-In of Spatiotemporal Information at the Blind Spot |
Q37733793 | Motion-Induced Position Shifts Activate Early Visual Cortex |
Q73203909 | Motion-based mechanisms of illusory contour synthesis |
Q36845265 | Motion-dependent representation of space in area MT+ |
Q81127451 | Motion-induced illusory displacement reexamined: differences between perception and action? |
Q48276241 | Motion-induced position shifts are influenced by global motion, but dominated by component motion. |
Q35175536 | Motor expertise modulates the unconscious processing of human body postures. |
Q45999383 | Moving Backgrounds Massively Change the Apparent Size, Shape and Orientation of Flashed Test Squares. |
Q53909631 | Moving ahead through differential visual latency. |
Q74675434 | Neural delays, visual motion and the flash-lag effect |
Q60213645 | Neural latencies do not explain the auditory and audio-visual flash-lag effect |
Q42139460 | Neurobiological mechanisms behind the spatiotemporal illusions of awareness used for advocating prediction or postdiction |
Q34253255 | Neuronal latencies and the position of moving objects |
Q47737353 | New twists for an old turning illusion |
Q47247469 | Non-veridical size perception of expanding and contracting objects |
Q47382376 | Nonretinotopic processing is related to postdictive size modulation in apparent motion |
Q43783947 | Object motion continuity and the flash-lag effect. |
Q52561372 | Object updating and the flash-lag effect. |
Q80177121 | Object-based anisotropic mislocalization by retinotopic motion signals |
Q51812580 | Observer's control of the moving stimulus increases the flash-lag effect. |
Q30412723 | On the cyclic nature of perception in vision versus audition |
Q77753030 | On the perceived location of global motion |
Q89876486 | On the relation between anticipatory ocular torsion and anticipatory smooth pursuit |
Q40704617 | Optimal smoothing in visual motion perception |
Q58642049 | Perceived onset time and position of a moving stimulus |
Q53044901 | Perceived spatial displacement of motion-defined contours in peripheral vision. |
Q37365543 | Perceived temporal asynchrony between sinusoidally modulated luminance and depth |
Q37740858 | Perception of intersensory synchrony: a tutorial review. |
Q48303207 | Perceptual acceleration of objects in stream: evidence from flash-lag displays |
Q52007370 | Perceptual compression of space through position integration. |
Q42397005 | Perceptual shrinkage of a one-way motion path with high-speed motion |
Q37397683 | Perceptual suppression of predicted natural images |
Q46368647 | Perceptual-binding and persistent surface segregation |
Q45195419 | Perisaccadic perception of continuous flickers |
Q37419929 | Phenomenology and neurophysiological correlations: two approaches to perception research |
Q39728238 | Position representations lag behind targets in multiple object tracking. |
Q37689419 | Postdiction: its implications on visual awareness, hindsight, and sense of agency |
Q28731629 | Postdictive modulation of visual orientation |
Q52054877 | Predictability and the dynamics of position processing in the flash-lag effect. |
Q60086680 | Predicting the present |
Q73620271 | Predicting the present direction of heading |
Q90370926 | Predictions drive neural representations of visual events ahead of incoming sensory information |
Q64065398 | Predictive Coding with Neural Transmission Delays: A Real-Time Temporal Alignment Hypothesis |
Q39670972 | Preferential Inspection of Recent Real-World Events Over Future Events: Evidence from Eye Tracking during Spoken Sentence Comprehension |
Q39614605 | Priming of future states in complex motor skills. |
Q36779506 | Prospective coding in event representation |
Q51909286 | Reduction of the flash-lag effect in terms of active observation. |
Q33976574 | Representational momentum for the human body: awkwardness matters, experience does not |
Q59589580 | Representational momentum: New findings, new directions |
Q36906505 | Saccades and pursuit: two outcomes of a single sensorimotor process |
Q43607850 | Sensorimotor integration compensates for visual localization errors during smooth pursuit eye movements |
Q56889766 | Sensory cortex is optimized for prediction of future input |
Q40832990 | Shifts in perceived position following adaptation to visual motion |
Q51640289 | Shifts in perceived position of flashed stimuli by illusory object motion. |
Q52959616 | Shorter latencies for motion trajectories than for flashes in population responses of cat primary visual cortex. |
Q43670708 | Smooth eye movements and spatial localisation. |
Q35739885 | Soccer Offside Judgments in Laypersons with Different Types of Static Displays |
Q58545394 | Spatial Distortions in Visual Short-term Memory: Interplay of Intrinsic and Extrinsic Reference Systems |
Q44215770 | Spatial but not temporal cueing influences the mislocalisation of a target flashed during smooth pursuit. |
Q52958119 | Spatial distortions and processing latencies in the onset repulsion and Fröhlich effects. |
Q80185569 | Spatial facilitation is involved in flash-lag effect |
Q41871407 | Spatially localized time shifts of the perceptual stream |
Q43051593 | Stimulus dependence of the flash-lag effect |
Q52040816 | Stopping motion and the flash-lag effect. |
Q45052154 | Stopping the motion and sleuthing the flash-lag effect: spatial uncertainty is the key to perceptual mislocalization |
Q48155441 | Strikingly rapid neural basis of motion-induced position shifts revealed by high temporal-resolution EEG pattern classification |
Q37497935 | Temporal binding of interval markers |
Q46169890 | Temporal coherence in visual rotation |
Q44683014 | Temporal dependence of local motion induced shifts in perceived position. |
Q34088602 | Temporal facilitation for moving stimuli is independent of changes in direction |
Q73008851 | Temporal recruitment along the trajectory of moving objects and the perception of position |
Q35044484 | The "Flash-Lag" effect occurs in audition and cross-modally |
Q36260905 | The Flash-Lag Effect as a Motion-Based Predictive Shift |
Q52169539 | The Fröhlich effect: a consequence of the interaction of visual focal attention and metacontrast. |
Q38940866 | The Role of Motion Extrapolation in Amphibian Prey Capture |
Q48691071 | The buzz-lag effect. |
Q47568535 | The common rate control account of prediction motion |
Q47843741 | The edge of awareness: Mask spatial density, but not color, determines optimal temporal frequency for continuous flash suppression |
Q34308883 | The effect of visual apparent motion on audiovisual simultaneity |
Q59030759 | The eyes have it! |
Q27303047 | The flash grab effect |
Q52029035 | The flash-lag effect is reduced when the flash is perceived as a sensory consequence of our action. |
Q43617981 | The flash-lag phenomenon: object motion and eye movements |
Q48316298 | The haptic and the visual flash-lag effect and the role of flash characteristics. |
Q52116958 | The impact of spatiotemporal sampling on time-to-contact judgments. |
Q48458238 | The infinite regress illusion reveals faulty integration of local and global motion signals. |
Q46428543 | The influence of motion signals in hand movements |
Q83821596 | The influence of visual motion on interceptive actions and perception |
Q42671979 | The influence of visual motion on perceived position |
Q52088711 | The modulation of the flash-lag effect by voluntary attention. |
Q80322527 | The motion-induced position shift depends on the perceived direction of bistable quartet motion |
Q37361225 | The motion-induced shift in the perceived location of a grating also shifts its aftereffect. |
Q81373696 | The perceived position of a moving object is not the result of position integration |
Q30528914 | The perceived position of moving objects: transcranial magnetic stimulation of area MT+ reduces the flash-lag effect |
Q47308763 | The perceived position shift of a pattern that contains internal motion is accompanied by a change in the pattern's apparent size and shape. |
Q31881685 | The persistence of position |
Q81193409 | The predictive power of trajectory motion |
Q48099669 | The relative contributions of colour and luminance signals towards the visuomotor localisation of targets in human peripheral vision |
Q46452418 | The role of attention in motion extrapolation: are moving objects 'corrected' or flashed objects attentionally delayed? |
Q41906664 | The role of differential delays in integrating transient visual and proprioceptive information |
Q84562556 | The tilt aftereffect occurs independently of the flash-lag effect |
Q48375860 | The time of perception and the other way around. |
Q30391408 | The timing of the conscious intention to move |
Q34627255 | Through the eye, slowly: delays and localization errors in the visual system |
Q30385305 | Time Slices: What Is the Duration of a Percept? |
Q49063153 | Tracking the apparent location of targets in interpolated motion. |
Q44688924 | Turning the corner with the flash-lag illusion. |
Q30504513 | Understanding vision in wholly empirical terms |
Q50667043 | Unpredictable visual changes cause temporal memory averaging. |
Q36576290 | Velocity of motion across the skin influences perception of tactile location |
Q49130100 | Vestibular signals can distort the perceived spatial relationship of retinal stimuli. |
Q50489438 | Vestibular stimulation interferes with the dynamics of an internal representation of gravity. |
Q35856782 | Visual Benefits in Apparent Motion Displays: Automatically Driven Spatial and Temporal Anticipation Are Partially Dissociated |
Q30362879 | Visual cortex responses reflect temporal structure of continuous quasi-rhythmic sensory stimulation |
Q52574354 | Visual crowding is unaffected by adaptation-induced spatial compression. |
Q60087202 | Visual decomposition of colour through motion extrapolation |
Q46386499 | Visual illusions and neurobiology |
Q39130481 | Visual information about past, current and future properties of irregular target paths in isometric force tracking |
Q39757841 | Visual motion induces a forward prediction of spatial pattern |
Q41854996 | Visual motion modulates pattern sensitivity ahead, behind, and beside motion. |
Q34071205 | Visual motion shifts saccade targets |
Q37163576 | Visual prediction: psychophysics and neurophysiology of compensation for time delays |
Q41771081 | Voluntary attention modulates motion-induced mislocalization |
Q51982234 | Why eye movements and perceptual factors have to be controlled in studies on "representational momentum". |
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