| scholarly article | Q13442814 |
| P2093 | author name string | Emily A Keshner | |
| Kalpana Dokka | |||
| Robert V Kenyon | |||
| P2860 | cites work | The influence of sensory information on two-component coordination during quiet stance. | Q36091897 |
| Strategies for the prevention and management of osteoarthritis of the hip and knee | Q36756739 | ||
| Optimal estimator model for human spatial orientation | Q39569792 | ||
| Postural readjustments induced by linear motion of visual scenes | Q41882085 | ||
| Using sensory weighting to model the influence of canal, otolith and visual cues on spatial orientation and eye movements | Q44030855 | ||
| Vection increases the magnitude and accuracy of visually evoked postural responses | Q44224150 | ||
| Perceiving self-motion in depth: the role of stereoscopic motion and changing-size cues. | Q47322086 | ||
| Postural adjustments induced by simulated motion of differently structured environments | Q48145322 | ||
| Perception of linear horizontal self-motion induced by peripheral vision (linearvection) basic characteristics and visual-vestibular interactions | Q48430386 | ||
| Postural coordination in looking and tracking tasks. | Q49015053 | ||
| Effects of the spatio-temporal structure of optical flow on postural readjustments in man. | Q52211844 | ||
| The contribution of motion, the visual frame, and visual polarity to sensations of body tilt | Q72520642 | ||
| Variability and interrelationships of surface EMG parameters during local muscle fatigue | Q72833404 | ||
| Frequency dependence of the action-perception cycle for postural control in a moving visual environment: relative phase dynamics | Q72905483 | ||
| The influence of an immersive virtual environment on the segmental organization of postural stabilizing responses | Q73884067 | ||
| Effects of characteristics of image quality in an immersive environment | Q74804468 | ||
| The influence of dynamic visual environments on postural sway in the elderly | Q78095928 | ||
| The influence of knee rigidity on balance corrections: a comparison with responses of cerebellar ataxia patients | Q80635283 | ||
| Field of view and base of support width influence postural responses to visual stimuli during quiet stance | Q82495368 | ||
| P433 | issue | 2 | |
| P1104 | number of pages | 6 | |
| P304 | page(s) | 211-216 | |
| P577 | publication date | 2009-06-07 | |
| P1433 | published in | Gait and Posture | Q15751476 |
| P1476 | title | Influence of visual scene velocity on segmental kinematics during stance | |
| P478 | volume | 30 |
| Q30374511 | Calibration of the Leg Muscle Responses Elicited by Predictable Perturbations of Stance and the Effect of Vision. |
| Q37122857 | Compensatory Postural Adjustments in an Oculus Virtual Reality Environment and the Risk of Falling in Alzheimer's Disease |
| Q33784541 | Contribution of vision to postural behaviors during continuous support-surface translations |
| Q34693204 | Differential contributions of vision, touch and muscle proprioception to the coding of hand movements |
| Q84009855 | Differential integration of visual and kinaesthetic signals to upright stance |
| Q43909733 | Identifying the control of physically and perceptually evoked sway responses with coincident visual scene velocities and tilt of the base of support |
| Q33533285 | Self versus environment motion in postural control |
| Q38733648 | The quest to apply VR technology to rehabilitation: tribulations and treasures |
| Q36151301 | The uncertainty associated with visual flow fields and their influence on postural sway: Weber's law suffices to explain the nonlinearity of vection. |
| Q37029025 | Visually induced postural reactivity is velocity-dependent at low temporal frequencies and frequency-dependent at high temporal frequencies. |
Search more.