scholarly article | Q13442814 |
P2093 | author name string | Michael A Riley | |
Benoît G Bardy | |||
Thomas A Stoffregen | |||
Cédrick T Bonnet | |||
Elise Faugloire | |||
P2860 | cites work | Postural instability and motion sickness in a fixed-based flight simulator | Q33145995 |
The Claustrophobia Questionnaire | Q34085224 | ||
Motion sickness and anxiety | Q39615811 | ||
A heuristic mathematical model for the dynamics of sensory conflict and motion sickness | Q41556085 | ||
Postural instability precedes motion sickness | Q41610595 | ||
Off-vertical rotation: a convenient precise means of exposing the passive human subject to a rotating linear acceleration vector. | Q43948440 | ||
Relationship between postural control and motion sickness in healthy subjects | Q48272620 | ||
Evaluating sensory conflict and postural instability. Theories of motion sickness | Q48272631 | ||
Visually induced motion sickness predicted by postural instability | Q49009597 | ||
Airsickness and anxiety | Q51343169 | ||
The possible role of nystagmus in motion sickness: a hypothesis. | Q51621482 | ||
"Conflicting" motion cues to the visual and vestibular self-motion systems around 0.06 Hz evoke simulator sickness. | Q51673324 | ||
Frequency effect of 0.35-1.0 Hz horizontal translational oscillation on motion sickness and the somatogravic illusion. | Q52266480 | ||
Effect of seating, vision and direction of horizontal oscillation on motion sickness. | Q53902764 | ||
Motion sickness adaptation: a neural mismatch model | Q55502496 | ||
Motion sickness and motion characteristics of vessels at sea | Q67999949 | ||
Altered sensorimotor control of the body as an etiological factor in space motion sickness | Q68027927 | ||
Motion sickness incidence as a function of the frequency and acceleration of vertical sinusoidal motion | Q69750574 | ||
Motion sickness | Q69896441 | ||
Flow structure versus retinal location in the optical control of stance | Q69977679 | ||
Stimulus required to produce motion sickness; restriction of head movement as a preventive of airsickness; field studies on airborne troops | Q73334067 | ||
Effects of image scale and system time delay on simulator sickness within head-coupled virtual environments | Q74271671 | ||
Some experiments on the relative effectiveness of various types of accelerations on motion sickness | Q79124832 | ||
Motion sickness preceded by unstable displacements of the center of pressure | Q83364096 | ||
P433 | issue | 4 | |
P921 | main subject | motion sickness | Q309067 |
P304 | page(s) | 520-532 | |
P577 | publication date | 2006-10-05 | |
P1433 | published in | Experimental Brain Research | Q13358841 |
P1476 | title | Motion sickness, body movement, and claustrophobia during passive restraint | |
P478 | volume | 177 |
Q48720548 | Console video games, postural activity, and motion sickness during passive restraint |
Q84009855 | Differential integration of visual and kinaesthetic signals to upright stance |
Q45008971 | Isolating the effects of vection and optokinetic nystagmus on optokinetic rotation-induced motion sickness. |
Q87247463 | Motion control, motion sickness, and the postural dynamics of mobile devices |
Q45079281 | Motion sickness and postural sway in console video games |
Q33647750 | Postural instability and motion sickness in a virtual moving room |
Q48708888 | Postural sway in men and women during nauseogenic motion of the illuminated environment |
Q52626374 | Postural time-to-contact as a precursor of visually induced motion sickness. |
Q47947154 | Predicting vection and visually induced motion sickness based on spontaneous postural activity. |
Q35866378 | Relationship between Spectral Characteristics of Spontaneous Postural Sway and Motion Sickness Susceptibility |
Q36336219 | Vection is the main contributor to motion sickness induced by visual yaw rotation: Implications for conflict and eye movement theories. |
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