| Q39731716 | A Potential VEP Biomarker for Mild Cognitive Impairment: Evidence from Selective Visual Deficit of Higher-Level Dorsal Pathway. |
| Q49371465 | A catch-up illusion arising from a distance-dependent perception bias in judging relative movement |
| Q48433342 | A cognitive process shell |
| Q48433437 | A cognitive theory without inductive learning |
| Q74640288 | A global process in motion segregation |
| Q52079114 | A model of human heading judgement in forward motion. |
| Q48008154 | A model of the combination of optic flow and extraretinal eye movement signals in primate extrastriate visual cortex. Neural model of self-motion from optic flow and extraretinal cues |
| Q79185153 | A model using MT-like motion-opponent operators explains an illusory transformation in the optic flow field |
| Q48158351 | A new book by N. A. Bernstein: "On dexterity and its development". |
| Q30612372 | A novel role for visual perspective cues in the neural computation of depth |
| Q48433427 | A psychologically implausible architecture that is always conscious, always active |
| Q41705412 | A self-organizing neural network architecture for navigation using optic flow |
| Q48244057 | A sense of direction: going with the flow |
| Q48433482 | A unified theory for psychologists? |
| Q34311915 | Active gaze control improves optic flow-based segmentation and steering. |
| Q48433456 | Active symbols, limited storage and the power of natural intelligence |
| Q36178885 | Adaptation to heading direction dissociates the roles of human MST and V6 in the processing of optic flow |
| Q35105121 | Adjacent visual representations of self-motion in different reference frames. |
| Q49032808 | Aftereffects and sense of presence in virtual environments: formulation of a research and development agenda |
| Q30383522 | Age Differences in Visual-Auditory Self-Motion Perception during a Simulated Driving Task. |
| Q34434186 | Asymmetrical masking between radial and parallel motion flow in transparent displays |
| Q48433319 | Cartesian vs. Newtonian research strategies for cognitive science |
| Q48433372 | Choosing a unifying theory for cognitive development |
| Q48433328 | Cognition and simulation |
| Q48387603 | Complex motion perception and its deficits |
| Q48127006 | Computational neuroanatomy of human stratum proprium of interparietal sulcus |
| Q35744189 | Coordinates of Human Visual and Inertial Heading Perception |
| Q45734563 | Cortical responses to optic flow and motion contrast across patterns and speeds |
| Q46924561 | Depth information and perceived self-motion during simulated gaze rotations |
| Q47774967 | Differential processing of the direction and focus of expansion of optic flow stimuli in areas MST and V3A of the human visual cortex. |
| Q30459942 | Direction specific biases in human visual and vestibular heading perception |
| Q37384361 | Displaying optic flow to simulate locomotion: Comparing heading and steering |
| Q35114752 | Dissociation of retinal and headcentric disparity signals in dorsal human cortex |
| Q47171924 | Distinct spatial coordinate of visual and vestibular heading signals in macaque FEFsem and MSTd |
| Q48433379 | Does the evolutionary perspective offer more than constraints? |
| Q48276547 | Effect of eye position during human visual-vestibular integration of heading perception |
| Q38548905 | Effects of gaze angle and extraretinal eye movement information on visual locomotion control |
| Q48835384 | Egocentric perception through interaction among many sensory systems |
| Q24289361 | Estimation of self-motion by optic flow processing in single visual interneurons |
| Q51864775 | Evidence for the use of rotational optic flow cues for locomotor steering in healthy older adults. |
| Q50481191 | Examining the Effect of Age on Visual-Vestibular Self-Motion Perception Using a Driving Paradigm. |
| Q51939865 | Factors affecting curved versus straight path heading perception. |
| Q40787634 | Four questions of time to contact: a critical examination of research on interceptive timing |
| Q48824982 | Global speed averaging is tuned for binocular disparity. |
| Q77502705 | Guidance of locomotion on foot uses perceived target location rather than optic flow |
| Q35212494 | Harbor seals (Phoca vitulina) can perceive optic flow under water |
| Q40675017 | Heading and path percepts from visual flow and eye pursuit signals |
| Q48103254 | Heading detection from optic flow. |
| Q52232533 | Heading detection using motion templates and eye velocity gain fields. |
| Q60441050 | Heading perception and the allocation of attention |
| Q48433381 | How human is SOAR? |
| Q73348689 | Human heading estimation during visually simulated curvilinear motion |
| Q77797826 | Human heading judgments and object-based motion information |
| Q52200527 | Human heading judgments in the presence of moving objects. |
| Q52216344 | Human sensitivity to temporal proximity: the role of spatial and temporal speed gradients. |
| Q41343438 | Infant-specific gaze patterns in response to radial optic flow |
| Q35832003 | Influence of Visual Motion, Suggestion, and Illusory Motion on Self-Motion Perception in the Horizontal Plane |
| Q41672291 | Influence of gaze rotation on the visual response of primate MSTd neurons |
| Q50641061 | Influence of optic flow on the control of heading and target egocentric direction during steering toward a goal. |
| Q80169355 | Interaction between complex motion patterns in the perception of shape |
| Q71301316 | Interactions between self-motion and depth perception in the processing of optic flow |
| Q48433443 | Is Unified theories of cognition good strategy? |
| Q52130721 | Is optic flow used to guide walking while wearing a displacing prism? |
| Q43841945 | Judging object motion during smooth pursuit eye movements: The role of optic flow |
| Q43424974 | Linear vestibuloocular reflex during motion along axes between nasooccipital and interaural |
| Q52217398 | Local velocity representation: evidence from motion adaptation. |
| Q42937558 | Localization of speed differences of context stimuli during fixation and smooth pursuit eye movements |
| Q52957223 | Long range interactions between object-motion and self-motion in the perception of movement in depth. |
| Q48276441 | MST neuronal responses to heading direction during pursuit eye movements |
| Q44624762 | Measurement of rate of expansion in the perception of radial motion |
| Q43772575 | Mobility of Normal Observers under Conditions of Reduced Visual Input |
| Q34043525 | Monkey steering responses reveal rapid visual-motor feedback |
| Q64923916 | Motion cues modulate responses to emotion in movies. |
| Q35016846 | Motions add, orientations don't, in the human visual system |
| Q42876723 | Multimodal representation of optic flow in area PEc of macaque monkey |
| Q48617944 | Multisensory integration in the estimation of walked distances. |
| Q34434164 | Neural analysis of visual information during locomotion |
| Q41518932 | Neural mechanisms of visual motion perception in primates |
| Q71684267 | Neural responses to velocity gradients in macaque cortical area MT |
| Q49111031 | Ocular responses to motion parallax stimuli: the role of perceptual and attentional factors |
| Q49082202 | Ocular responses to radial optic flow and single accelerated targets in humans |
| Q48433348 | On models and mechanisms |
| Q48433335 | On putting the cart before the horse: Taking perception seriously in unified theories of cognition |
| Q67760553 | On the sufficiency of the velocity field for perception of heading |
| Q43568180 | Opsoclonus-induced occipital deactivation with a region-specific distribution |
| Q73435425 | Optic flow is used to control human walking |
| Q35693177 | Optic-flow selective cortical sensory regions associated with self-reported states of vection |
| Q73312049 | Optimal spatial frequencies for discrimination of motion direction in optic flow patterns |
| Q48469065 | Optimal visual-vestibular integration under conditions of conflicting intersensory motion profiles. |
| Q43799836 | Optimizing visual motion perception during eye movements. |
| Q84443598 | Optokinetic nystagmus is elicited by curvilinear optic flow during high speed curve driving |
| Q34185665 | Path curvature discrimination: dependence on gaze direction and optical flow speed |
| Q30581748 | Path perception and Filehne illusion compared: model and data |
| Q44897680 | Path perception during rotation: influence of instructions, depth range, and dot density |
| Q46002334 | Perceived head-centric speed is affected by both extra-retinal and retinal errors. |
| Q73812972 | Perceived heading during simulated torsional eye movements |
| Q36316260 | Perceiving Collision Impacts in Alzheimer's Disease: The Effect of Retinal Eccentricity on Optic Flow Deficits |
| Q45940973 | Perceiving heading with different retinal regions and types of optic flow. |
| Q47322086 | Perceiving self-motion in depth: the role of stereoscopic motion and changing-size cues. |
| Q59092820 | Perception of heading |
| Q73221860 | Perception of heading during rotation: sufficiency of dense motion parallax and reference objects |
| Q48240002 | Perception of heading is a brain in the neck |
| Q46176526 | Perception of heading without retinal optic flow |
| Q45990789 | Perception of scene-relative object movement: Optic flow parsing and the contribution of monocular depth cues. |
| Q47879901 | Persistent perceptual delay for active head movement onset relative to sound onset with and without vision. |
| Q48433364 | Problem spaces, language and connectionism: Issues for cognition |
| Q48433505 | Précis of Unified theories of cognition |
| Q43679789 | Pursuit affects precision of perceived heading for small viewing apertures |
| Q44211135 | Pursuit speed compensation in cortical area MSTd |
| Q59052691 | Radial optic flow induces vergence eye movements with ultra-short latencies |
| Q48433462 | Re-membering cognition |
| Q48433490 | Reframing the problem of intelligent behavior |
| Q44130305 | Retinal flow is sufficient for steering during observer rotation |
| Q35111517 | Role of visual and non-visual cues in constructing a rotation-invariant representation of heading in parietal cortex |
| Q46258029 | SOAR as a world view, not a theory |
| Q57090192 | Second-order optic flow processing |
| Q36337911 | Self-motion-induced eye movements: effects on visual acuity and navigation |
| Q33979620 | Sensitivity of human visual and vestibular cortical regions to egomotion-compatible visual stimulation |
| Q41689501 | Spatial knowledge acquisition from maps and from navigation in real and virtual environments |
| Q24289018 | Spiral motion selective neurons in area MSTd contribute to judgments of heading |
| Q74029131 | Steering with or without the flow: is the retrieval of heading necessary? |
| Q40892353 | Testing the Perrone and Stone (1994) model of heading estimation |
| Q36167736 | The Effects of Restricted Peripheral Field-of-View on Spatial Learning while Navigating |
| Q87886439 | The coupling of vision with locomotion in cortical blindness |
| Q51712380 | The detection of moving objects by moving observers. |
| Q52055524 | The discrimination of dynamic orientation changes in gratings. |
| Q73820035 | The effect of 3D structure on motion segmentation |
| Q50506762 | The effect of monocular depth cues on the detection of moving objects by moving observers. |
| Q74005815 | The mechanism of interaction between visual flow and eye velocity signals for heading perception |
| Q37328284 | The motion/pursuit law for visual depth perception from motion parallax |
| Q28601785 | The need for speed: global optic flow speed influences steering |
| Q46016341 | The perception of heading during eye movements. |
| Q43690295 | The perception of visually presented yaw and pitch turns: assessing the contribution of motion, static, and cognitive cues. |
| Q48859762 | The role of disparity-sensitive cortical neurons in signalling the direction of self-motion |
| Q48348616 | The role of vision in maintaining heading direction: effects of changing gaze and optic flow on human gait |
| Q36597943 | The temporal dynamics of heading perception in the presence of moving objects. |
| Q48433473 | Toward unified cognitive theory: The path is well worn and the trenches are deep |
| Q59070286 | Two stages of visual processing for radial and circular motion |
| Q33966021 | Understanding the Pathophysiology of Alzheimer's Disease and Mild Cognitive Impairment: A Mini Review on fMRI and ERP Studies |
| Q48433404 | Unified cognition misses language |
| Q48433450 | Unified cognitive theory is not comprehensive |
| Q48433419 | Unified cognitive theory: Having one's apple pie and eating it. |
| Q48433498 | Unified cognitive theory: You can't get there from here |
| Q47283725 | Unified psychobiological theory |
| Q48433354 | Unified theories and theories that mimic each other's predictions |
| Q48433395 | Unified theories must explain the codependencies among perception, cognition and action |
| Q48433411 | Unifying congnition: Has it all been put together? |
| Q51405378 | Use of speed cues in the detection of moving objects by moving observers. |
| Q34982325 | Virtual reality in behavioral neuroscience and beyond |
| Q48859773 | Vision. Knowing where you're going |
| Q51704909 | Visual and postural control of an arbitrary posture: the handstand. |
| Q46272977 | Visual control of steering without course information |
| Q48604858 | Visual selectivity for heading in the macaque ventral intraparietal area |
| Q30497783 | Visually guided navigation: head-mounted eye-tracking of natural locomotion in children and adults |
| Q48718937 | Visually perceived eye level and horizontal midline of the body trunk influenced by optic flow |
| Q74226450 | Weighting to go with the flow? |
| Q48131692 | Where are you heading? Flexible integration of retinal and extra-retinal cues during self-motion perception |
| Q60077239 | Why two eyes are better than one for judgements of heading |
| Q60441051 | Why you should look where you are going |