Perceived self-motion in two visual contexts: Dissociable mechanisms underlie perception

We evaluated the influence of moving visual scenes and knowledge of spatial and physical context on visually induced self-motion perception in an immersive virtual environment. A sinusoidal, vertically oscillating visual stimulus induced perceptions of self-motion that matched changes in visual acceleration. Subjects reported peaks of perceived self-motion in synchrony with peaks of visual acceleration and opposite in direction to visual scene motion. Spatial context was manipulated by testing subjects in the environment that matched the room in the visual scene or by testing them in a separate chamber. Physical context was manipulated by testing the subject while seated in a stable, earth-fixed desk chair or in an apparatus capable of large linear motions, however, in both conditions no actual motion occurred. The compellingness of perceived self-motion was increased significantly when the spatial context matched the visual input and actual body displacement was possible, however, the latency and amplitude of perceived self-motion were unaffected by the spatial or physical context. We propose that two dissociable processes are involved in self-motion perception: one process, primarily driven by visual input, affects vection latency and path integration, the other process, receiving cognitive input, drives the compellingness of perceived self-motion.

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Vertical linear self-motion perception during visual and inertial motion: More than weighted summation of sensory inputs

Journal of Vestibular Research ◽

10.3233/ves-2005-15402 ◽

2005 ◽

Vol 15 (4) ◽

pp. 185-195 ◽

Cited By ~ 7

Author(s):

W.G. Wright ◽

P. DiZio ◽

J.R. Lackner

Keyword(s):

Motion Perception ◽

Visual Motion ◽

Test Chamber ◽

Vestibular Stimulation ◽

Visual Scene ◽

Inertial Motion ◽

Physical Test ◽

Head Mounted Display ◽

Linear Oscillation ◽

Self Motion

We evaluated visual and vestibular contributions to vertical self motion perception by exposing subjects to various combinations of 0.2 Hz vertical linear oscillation and visual scene motion. The visual stimuli presented via a head-mounted display consisted of video recordings of the test chamber from the perspective of the subject seated in the oscillator. In the dark, subjects accurately reported the amplitude of vertical linear oscillation with only a slight tendency to underestimate it. In the absence of inertial motion, even low amplitude oscillatory visual motion induced the perception of vertical self-oscillation. When visual and vestibular stimulation were combined, self-motion perception persisted in the presence of large visual-vestibular discordances. A dynamic visual input with magnitude discrepancies tended to dominate the resulting apparent self-motion, but vestibular effects were also evident. With visual and vestibular stimulation either spatially or temporally out-of-phase with one another, the input that dominated depended on their amplitudes. High amplitude visual scene motion was almost completely dominant for the levels tested. These findings are inconsistent with self-motion perception being determined by simple weighted summation of visual and vestibular inputs and constitute evidence against sensory conflict models. They indicate that when the presented visual scene is an accurate representation of the physical test environment, it dominates over vestibular inputs in determining apparent spatial position relative to external space.

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Arthrokinetic Information Affects Linear Self-Motion Perception

Journal of Vestibular Research ◽

10.3233/ves-1995-5202 ◽

1995 ◽

Vol 5 (2) ◽

pp. 109-116

Author(s):

Willem Bles ◽

Monique Jelmorini ◽

Harold Bekkering ◽

Bernd de Graaf

Keyword(s):

Motion Perception ◽

Opposite Direction ◽

Frontoparallel Plane ◽

Vestibular Information ◽

The Subject ◽

Moving Platform ◽

Self Motion ◽

Predominant Effect

A sensation of linear self-motion can be induced in a blindfolded stationary sitting subject, who keeps contact with a linearly moving platform (acceleration 0.1 m/s2) in the frontoparallel plane by means of a hand-over-hand walking action. When discordant suprathreshold vestibular information from the otoliths is added by moving the subject laterally (acceleration 0.1 m/s2) in the same direction as the platform (acceleration of the platform 0.2 m/s2, so the arthrokinetic stimulus is also an acceleration of 0.1 m/s2, but into the opposite direction), the arthrokinetic information was found to have a predominant effect on the perceived direction of self-motion.

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A Comparison of the Latencies of Visually Induced Postural Change and Self-Motion Perception

Journal of Vestibular Research ◽

10.3233/ves-1991-1310 ◽

1991 ◽

Vol 1 (3) ◽

pp. 317-323 ◽

Cited By ~ 1

Author(s):

Fred H. Previc ◽

Thomas J. Mullen

Keyword(s):

Motion Perception ◽

Opposite Direction ◽

Postural Instability ◽

Postural Change ◽

The Subject ◽

Self Motion ◽

Visual Conditions

This study compared the latencies of visually induced postural change and self-motion perception under identical visual conditions. The results showed that a visual roll stimulus elicits postural tilt in the direction of scene motion and an increase in postural instability several seconds before the subject begins to perceive illusory self-motion (vection) in the opposite direction. Postural and vection latencies correlate highly with one another, but bear little relationship with the magnitude of either sway or vection.

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EXPRESS: Cue Combination in Goal-Oriented Navigation

Quarterly Journal of Experimental Psychology ◽

10.1177/17470218211015796 ◽

2021 ◽

pp. 174702182110157

Author(s):

Yafei Qi ◽

Weimin Mou ◽

Xuehui Lei

Keyword(s):

Path Integration ◽

Turning Point ◽

Length Ratio ◽

Cue Combination ◽

Goal Location ◽

Immersive Virtual Environment ◽

Medium Length ◽

Large Length ◽

Self Motion ◽

Location Estimate

This study examined cue combination of self-motion and landmark cues in goal-localization. In an immersive virtual environment, before walking a two-leg path, participants learned the locations of three goal objects (one at the path origin, i.e., home) and landmarks. After walking the path without seeing landmarks or goals, participants indicated the locations of the home and non-home goals in four conditions: 1) path integration only, 2) landmarks only, 3) both path integration and the landmarks, and 4) path integration and rotated landmarks. The ratio of the length between the testing position (P) and the turning point (T) over the length between the T and the three goals (G) (i.e., PT/TG) was manipulated. The results showed the cue combination consistently for participants’ heading estimates but not for goal-localization. In Experiments 1-2 (using distal landmarks), the cue combination for goal estimates appeared in a small length ratio (PT/TG=0.5) but disappeared in a large length ratio (PT/TG=2). In Experiments 3-4 (using proximal landmarks), while the cue combination disappeared for the home with a medium length ratio (PT/TG=1), it appeared for the non-home goal with a large length ratio (PT/TG=2) and only disappeared with a very large length ratio (PT/TG=3). These findings are explained by a model stipulating that cue combination occurs in self-localization (e.g., heading estimates), which leads to one estimate of the goal location; proximal landmarks produce another goal location estimate; these two goal estimates are then combined, which may only occur for non-home goals.

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Activity Strength within Optic Flow-Sensitive Cortical Regions Is Associated with Visual Path Integration Accuracy in Aged Adults

Brain Sciences ◽

10.3390/brainsci11020245 ◽

2021 ◽

Vol 11 (2) ◽

pp. 245

Author(s):

Lauren Zajac ◽

Ronald Killiany

Keyword(s):

Motion Perception ◽

Optic Flow ◽

Path Integration ◽

Visual Motion ◽

Spatial Navigation ◽

Motion Processing ◽

Global Pattern ◽

Age Related ◽

Cortical Regions ◽

Self Motion

Spatial navigation is a cognitive skill fundamental to successful interaction with our environment, and aging is associated with weaknesses in this skill. Identifying mechanisms underlying individual differences in navigation ability in aged adults is important to understanding these age-related weaknesses. One understudied factor involved in spatial navigation is self-motion perception. Important to self-motion perception is optic flow–the global pattern of visual motion experienced while moving through our environment. A set of optic flow-sensitive (OF-sensitive) cortical regions was defined in a group of young (n = 29) and aged (n = 22) adults. Brain activity was measured in this set of OF-sensitive regions and control regions using functional magnetic resonance imaging while participants performed visual path integration (VPI) and turn counting (TC) tasks. Aged adults had stronger activity in RMT+ during both tasks compared to young adults. Stronger activity in the OF-sensitive regions LMT+ and RpVIP during VPI, not TC, was associated with greater VPI accuracy in aged adults. The activity strength in these two OF-sensitive regions measured during VPI explained 42% of the variance in VPI task performance in aged adults. The results of this study provide novel support for global motion processing as a mechanism underlying visual path integration in normal aging.

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Color effects on self-motion perception

PsycEXTRA Dataset ◽

10.1037/e527352012-031 ◽

2006 ◽

Author(s):

Frederick Bonato ◽

Andrea Bubka

Keyword(s):

Motion Perception ◽

Self Motion

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Disruption of self-motion perception without vestibular reflex alteration in ménière’s disease

Journal of Vestibular Research ◽

10.3233/ves-201520 ◽

2021 ◽

pp. 1-11

Author(s):

Mario Faralli ◽

Michele Ori ◽

Giampietro Ricci ◽

Mauro Roscini ◽

Roberto Panichi ◽

...

Keyword(s):

Motion Perception ◽

Meniere’S Disease ◽

Menière’S Disease ◽

Whole Body ◽

Meniere's Disease ◽

Ménière’S Disease ◽

Menière's Disease ◽

Ocular Reflex ◽

Ménière's Disease ◽

Self Motion

BACKGROUND: Self-motion misperception has been observed in vestibular patients during asymmetric body oscillations. This misperception is correlated with the patient’s vestibular discomfort. OBJECTIVE: To investigate whether or not self-motion misperception persists in post-ictal patients with Ménière’s disease (MD). METHODS: Twenty-eight MD patients were investigated while in the post-ictal interval. Self-motion perception was studied by examining the displacement of a memorized visual target after sequences of opposite directed fast-slow asymmetric whole body rotations in the dark. The difference in target representation was analyzed and correlated with the Dizziness Handicap Inventory (DHI) score. The vestibulo-ocular reflex (VOR) and clinical tests for ocular reflex were also evaluated. RESULTS: All MD patients showed a noticeable difference in target representation after asymmetric rotation depending on the direction of the fast/slow rotations. This side difference suggests disruption of motion perception. The DHI score was correlated with the amount of motion misperception. In contrast, VOR and clinical trials were altered in only half of these patients. CONCLUSIONS: Asymmetric rotation reveals disruption of self-motion perception in MD patients during the post-ictal interval, even in the absence of ocular reflex impairment. Motion misperception may cause persistent vestibular discomfort in these patients.

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Sensorimotor impairment from a new analog of spaceflight-altered neurovestibular cues

Journal of Neurophysiology ◽

10.1152/jn.00156.2019 ◽

2020 ◽

Vol 123 (1) ◽

pp. 209-223

Author(s):

Jordan B. Dixon ◽

Torin K. Clark

Keyword(s):

Head Tilt ◽

Semicircular Canals ◽

Control Groups ◽

Head Restraint ◽

The Subject ◽

Sensorimotor Impairment ◽

Self Motion ◽

Future Work ◽

Extended Exposure ◽

Sensorimotor Performance

Exposure to microgravity during spaceflight causes central reinterpretations of orientation sensory cues in astronauts, leading to sensorimotor impairment upon return to Earth. Currently there is no ground-based analog for the neurovestibular system relevant to spaceflight. We propose such an analog, which we term the “wheelchair head-immobilization paradigm” (WHIP). Subjects lie on their side on a bed fixed to a modified electric wheelchair, with their head restrained by a custom facemask. WHIP prevents any head tilt relative to gravity, which normally produces coupled stimulation to the otoliths and semicircular canals, but does not occur in microgravity. Decoupled stimulation is produced through translation and rotation on the wheelchair by the subject using a joystick. Following 12 h of WHIP exposure, subjects systematically felt illusory sensations of self-motion when making head tilts and had significant decrements in balance and locomotion function using tasks similar to those assessed in astronauts postspaceflight. These effects were not observed in our control groups without head restraint, suggesting the altered neurovestibular stimulation patterns experienced in WHIP lead to relevant central reinterpretations. We conclude by discussing the findings in light of postspaceflight sensorimotor impairment, WHIP’s uses beyond a spaceflight analog, limitations, and future work. NEW & NOTEWORTHY We propose, implement, and demonstrate the feasibility of a new analog for spaceflight-altered neurovestibular stimulation. Following extended exposure to the analog, we found subjects reported illusory self-motion perception. Furthermore, they demonstrated decrements in balance and locomotion, using tasks similar to those used to assess astronaut sensorimotor performance postspaceflight.

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