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References (53)
-
V. Marlinsky (1999)
Vestibular and vestibulo-proprioceptive perception of motion in the horizontal plane in blindfolded man—II. Estimations of rotations about the earth-vertical axisNeuroscience, 90
-
L. Stone, F. Miles, M. Banks (2003)
Linking eye movements and perceptionJournal of Vision, 3
-
R. Allison, L. Harris, M. Jenkin, U. Jasiobedzka, J. Zacher (2001)
Tolerance of temporal delay in virtual environmentsProceedings IEEE Virtual Reality 2001
-
J. Blouin, Nicolas Amade, J. Vercher, G. Gauthier (1999)
Opposing Resistance to the Head Movement Does not Affect Space Perception During Head Rotations -
L. Harris, L. Lott (1995)
Sensitivity to full-field visual movement compatible with head rotation: Variations among axes of rotationVisual Neuroscience, 12
-
P. Jaekl, Michael Jenkin, Laurence Harris (2003)
Perceptual stability during active head movements orthogonal and parallel to gravity.Journal of vestibular research : equilibrium & orientation, 13 4-6
-
V. Marlinsky (1999)
Vestibular and vestibulo-proprioceptive perception of motion in the horizontal plane in blindfolded man. Estimations of linear displacementNeuroscience, 90
-
Alain Viguier, Gilles Clément, Y. Trotter (2001)
Distance Perception within near Visual SpacePerception, 30
-
Chris Johnson, R. Scobey (1982)
Effects of reference lines on displacement thresholds at various durations of movementVision Research, 22
-
J. Golding, A. Benson (1993)
Perceptual scaling of whole-body low frequency linear oscillatory motion.Aviation, space, and environmental medicine, 64 7
-
F. Redlick, M. Jenkin, L. Harris (2001)
Humans can use optic flow to estimate distance of travelVision Research, 41
-
B. Choudhury, A. Crossey (1981)
Slow-movement sensitivity in the human field of visionPhysiology & Behavior, 26
-
R. Melzack, P. Wall (1965)
Pain mechanisms: a new theory.Science, 150 3699
-
H. Wallach (1985)
Perceiving a Stable EnvironmentScientific American, 252
-
D. Angelaki (1992)
Detection of rotating gravity signalsBiological Cybernetics, 67
-
H. Aubert (2005)
Die BewegungsempfindungArchiv für die gesamte Physiologie des Menschen und der Tiere, 39
-
(1994)
Visual motion caused by movements of the eye, head and body -
I. Israël, N. Chapuis, S. Glasauer, O. Charade, A. Berthoz (1993)
Estimation of passive horizontal linear whole-body displacement in humans.Journal of neurophysiology, 70 3
-
C. Darlot, Pierre Denise, J. Droulez, Bernard Cohen, A. Berthoz (2004)
Eye movements induced by off-vertical axis rotation (OVAR) at small angles of tiltExperimental Brain Research, 73
-
Mesland Bs, Wertheim Ah (1995)
Visual and nonvisual contributions to perceived ego-motion studied with a new psychophysical method.Journal of Vestibular Research-equilibrium & Orientation, 5
-
L. Harris, M. Jenkin, D. Zikovitz (2000)
Visual and non-visual cues in the perception of linear self motionExperimental Brain Research, 135
-
(2002)
The role of visual and vestibular cues in determining stability during head movement -
L. Harris, K. Beykirch, Michael Fetter (2001)
The visual consequences of deviations in the orientation of the axis of rotation of the human vestibulo-ocular reflexVision Research, 41
-
Laurence Harris, Michael Morgan, A. Still (1981)
Moving and the motion after-effectNature, 293
-
R. Tomlinson, G. Saunders, D. Schwarz (1980)
Analysis of human vestibulo-ocular reflex during active head movements.Acta oto-laryngologica, 90 3-4
-
H. Wallach (1987)
Perceiving a stable environment when one moves.Annual review of psychology, 38
-
R. Allison, I. Howard, J. Zacher (1999)
Effect of Field Size, Head Motion, and Rotational Velocity on Roll Vection and Illusory Self-Tilt in a Tumbling RoomPerception, 28
-
V. Henn, L. Young, C. Finley (1974)
Vestibular nucleus units in alert monkeys are also influenced by moving visual fields.Brain research, 71 1
-
J. Morrison, T. Whiteside (1984)
Binocular Cues in the Perception of Distance of a Point Source of LightPerception, 13
-
C. Busettini, G. Masson, F. Miles (1997)
Radial optic flow induces vergence eye movements with ultra-short latenciesNature, 390
-
A. Wertheim, P. Gelder (1990)
An Acceleration Illusion Caused by Underestimation of Stimulus Velocity during Pursuit Eye Movements: Aubert–Fleischl RevisitedPerception, 19
-
A. Graybiel, D. Hupp (1946)
The oculo-gyral illusion; a form of apparent motion which may be observed following stimulation of the semicircular canals.The Journal of aviation medicine, 17
-
P. Jaekl, R. Allison, L. Harris, U. Jasiobedzka, H. Jenkin, M. Jenkin, J. Zacher, D. Zikovitz (2002)
Perceptual stability during head movement in virtual realityProceedings IEEE Virtual Reality 2002
-
A. Johnston, M. Wright (1985)
Lower thresholds of motion for gratings as a function of eccentricity and contrastVision Research, 25
-
F. Steen (1998)
An earth-stationary perceived visual scene during roll and yaw motions in a flight simulator.Journal of Vestibular Research-equilibrium & Orientation, 8
-
L. Vaina, S. Beardsley, S. Rushton (2004)
Optic Flow and Beyond -
J. Foley, R. Held (1972)
Visually directed pointing as a function of target distance, direction, and available cuesPerception & Psychophysics, 12
-
R. Snowden (1992)
Sensitivity to Relative and Absolute MotionPerception, 21
-
H. Veen, Hartwig Distler, Stephan Braun, H. Bülthoff (1998)
Navigating through a virtual city: Using virtual reality technology to study human action and perceptionFuture Gener. Comput. Syst., 14
-
I. Howard, A. Howard (1994)
Vection: The Contributions of Absolute and Relative Visual MotionPerception, 23
-
M. Lappe, F. Bremmer, A. Berg (1999)
Perception of self-motion from visual flowTrends in Cognitive Sciences, 3
-
(1985)
The orientation of vestibular nystagmus is modified by head tilt -
B. Bridgeman (1999)
Neither strong nor weak space constancy is coded in striate cortexPsychological Research, 62
-
(2001)
Overestimation of linearvection induced by optic flow: contributions of size of field and stereopsis -
A. Wertheim (1994)
Fixations or smooth eye movements?Behavioral and Brain Sciences, 17
-
L. Zupan, D. Merfeld, C. Darlot (2002)
Using sensory weighting to model the influence of canal, otolith and visual cues on spatial orientation and eye movementsBiological Cybernetics, 86
-
M. Walker, M. Shelhamer, D. Zee (2004)
Eye-position dependence of torsional velocity during interaural translation, horizontal pursuit, and yaw-axis rotation in humansVision Research, 44
-
(1985)
Extracting self-created retinal motion The orientation of vestibular nystagmus is modified by head tilt The vestibular system: neurophysiologic and clinical research -
Otto-Joachim Grüsser (1986)
Interaction of efferent and afferent signals in visual perception. A history of ideas and experimental paradigms.Acta psychologica, 63 1-3
-
C. Lathan, C. Wall, L. Harris (2004)
Human eye movement response to z-axis linear acceleration: the effect of varying the phase relationships between visual and vestibular inputsExperimental Brain Research, 103
-
Pierre Denise, C. Darlot, J. Droulez, Bernard Cohen, A. Berthoz (2004)
Motion perceptions induced by off-vertical axis rotation (OVAR) at small angles of tiltExperimental Brain Research, 73
-
R. Carpenter (1980)
Mammalian vestibular physiologyNature, 284
-
(1982)
The vestibular sensory system The senses
- Publisher
- Springer Journals
- Copyright
- Copyright © 2005 by Springer-Verlag
- Subject
- Biomedicine; Neurosciences; Neurology
- ISSN
- 0014-4819
- eISSN
- 1432-1106
- DOI
- 10.1007/s00221-004-2191-8
- pmid
- 15856212
- Publisher site
- See Article on Publisher Site
Abstract
When a person moves through the world, the associated visual displacement of the environment in the opposite direction is not usually seen as external movement but rather as a changing view of a stable world. We measured the amount of visual motion that can be tolerated as compatible with the perception of moving within a stable world during active, sinusoidal, translational and rotational head movement. Head movements were monitored by means of a low-latency, mechanical head tracker and the information was used to update a helmet-mounted visual display. A variable gain was introduced between the head tracker and the display. Ten subjects adjusted this gain until the visual display appeared stable during sinusoidal yaw, pitch and roll head rotations and naso-occipital, inter-aural and dorso-ventral translations at 0.5 Hz. Each head movement was tested with movement either orthogonal to or parallel with gravity. A wide spread of gains was accepted as stable (0.8 to 1.4 for rotation and 1.1 to 1.8 for translation). The gain most likely to be perceived as stable was greater than that required by the geometry (1.2 for rotation; 1.4 for translation). For rotational motion, the mean gains were the same for all axes. For translation there was no effect of whether the movement was inter-aural (mean gain 1.6) or dorso-ventral (mean gain 1.5) and no effect of the relative orientation of the translation direction relative to gravity. However translation in the naso-occipital direction was associated with more closely veridical settings (mean gain 1.1) and narrower standard deviations than in other directions. These findings are discussed in terms of visual and non-visual contributions to the perception of an earth-stable environment during active head movement.
Journal
Experimental Brain Research – Springer Journals
Published: Jun 1, 2005