The illusion of self-motion in virtual reality environments

John Wann; Simon Rushton

doi:10.1017/S0140525X00034932

The illusion of self-motion in virtual reality environments

Published online by Cambridge University Press: 04 February 2010

John Wann and

Simon Rushton

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John Wann: Affiliation:
[email protected]; Department of Psychology, University of Edinburgh, Edinburgh EH8 9JZ, Scotland [email protected]; Department of Human Movement, University of Queensland, Australia
Simon Rushton: Affiliation:
[email protected]; Department of Psychology, University of Edinburgh, Edinburgh EH8 9JZ, Scotland

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Type: Open Peer Commentary
Information: Behavioral and Brain Sciences , Volume 17 , Issue 2 , June 1994 , pp. 338 - 340

DOI: https://doi.org/10.1017/S0140525X00034932 [Opens in a new window]
Copyright: Copyright © Cambridge University Press 1994

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References

Algom, D. & Cohen-Raz, L. (1984) Visual velocity input-output functions: The integration of distance and duration onto subjective velocity. Journal of Experimental Psychology: Human Perception and Performance 4:486–501. [aAHW]Google Scholar

Andersen, C. J. (1986) Perception of self-motion: Psychophysical and computational approaches. Psychological Bulletin 99:52–65. [GJA]CrossRef Google Scholar PubMed

Andersen, C. J. (1990) Segregation of optic flow into object and self-motion components: Foundations of a general theory. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [aAHW]Google Scholar

Andersen, G. J. & Braunstein, M. L. (1985). Induced self-motion in central vision. Journal of Experimental Psychology: Human Perception and Performance 11:122–32. [XMS]Google Scholar PubMed

Angel, R. W. & Malenka, R. C. (1982) Velocity-dependent suppression of cutaneous sensitivity during movement. Experimental Neurology 77:266–74. [aAHW]Google Scholar

Aubert, H. (1886) Die Bewegungsempfindung. Pflügers Archiv 39:347–70. [aAHW]CrossRef Google Scholar

Aubert, H. (1887) Die Bewegungsempfindung. Zweiter Mitteilung. Pflügers Archives 40:459–80. [aAHW]Google Scholar

Barthélémy, J., Xerri, L., Borel, L. & Lacour, M. (1988) Neuronal coding of linear motion in the vestibular nuclei of the alert cat. II: Response characteristics to vertical optokinetic stimulation. Experimental Brain Research 70:287–98. [aAHW]Google Scholar

Bedell, H., Klopfenstein, J. F. & Yuan, N. (1989) Extraretinal information about eye position during involuntary eye movement: Optokinetic afternystagmus. Perception & Psychophysics 46:579–86. [aAHW]CrossRef Google Scholar PubMed

Belopolsky, V. I. (1978) Stability of visual world during reduction of visual field size. In: Dvizhenie glaz i zritel'noe vospriiatie [Eye movement and visual perception], ed. Lomov, B. F., Mit'kin, A. A. & Vergiles, N. Yu.. Nauka. [VIB]Google Scholar

Belopolsky, V. I. (1985) Selective attention and eye movement control. Psichologicheskii Zhurnal [Soviet Journal of Psychology] 6(3):56–73. [VIB]Google Scholar

Benson, A. J. (1990) Sensory functions and limitations of the vestibular system. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [aAHW]Google Scholar

Berthoz, A. (1981) Intersensory interaction in motion perception. In: Attention and performance IX, ed. Long, J. & Baddeley, A.. Erlbaum. [TP]Google Scholar

Berthoz, A. & Droulez, J. (1982) Linear self-motion perception. In: Tutorials on motion perception, ed. Wertheim, A. H., Wagenaar, W. A. & Leibowitz, H. W.. Plenum Press. [aAHW]Google Scholar

Berthoz, A. & Melville-Jones, G., eds. (1985) Adaptive mechanisms in gaze control. Elsevier. [aAHW]Google Scholar

Berthoz, A., Pavard, B. & Young, L. R. (1975) Perception of linear horizontal self-motion induced by peripheral vision (linear vection): Basic characteristics and visual-vestibular interactions. Experimental Brain Research 23:471–89. [aAHW, XMS]Google Scholar

Berthoz, A., Yoshida, K. & Vidal, P. P. (1981) Horizontal eye movement signals in second-order vestibular nuclei neurons in the eat. In: Vestibular and oculomotor physiology: International meeting of the Barany Society, ed. B. Cohen. Annals of the New York Academy of Sciences 374:144–56. [aAHW]CrossRef Google Scholar

Bingham, G. P. (1987) Kinematic form and scaling: Further investigations on the visual perception of lifted weight. Journal of Experimental Psychology: Human Perception and Performance 13:155–77. [TAS]Google Scholar

Bischof, N. (1974) Optic-vestibular orientation to the vertical. In: Handbook of vestibular physiology. Vol. 6(2): Vestibular system ed. Komhuber, H. H.. Springer-Verlag. [WB]Google Scholar

Bischof, N. & Kramer, E. (1969) Untersuchungen und Überlegungen zur Richtungswahrnehmung bei willkürlichen sakkadischen Augenbewegungen [Investigations and considerations on perception of direction during voluntary saccadic eye movements]. Psychologische Forschung 32(3): 185–218. [BMV]CrossRef Google Scholar

Bles, W. (1982) Stepping around: Circular vection and coriolis effects. In: Attention and performance IX, ed. Long, J. & Baddeley, A.. Erlbaum. [JJR]Google Scholar

Bles, W., Bos, J. E., Furrer, R., De Graaf, B., Hosman, R. J. A. W., Kortschot, H. W., Krol, J. R., Kuipers, A., Marcus, J. T., Messerschmid, E., Ockels, W. J., Oosterveld, W. J., Smit, J., Wertheim, A. H. & Wientjes, C. J. E. (1989) Space Adaptation Syndrome induced by a long duration +3Gx centrifuge run. Institute for Perception Technical Report, IZF-1989–25. TNO Institute for Perception, Soesterberg, The Netherlands. [aAHW]Google Scholar

Bles, W., Jelmorini, M., Bekkering, H. & De Graaf, B. (1994) Arthrokinetie information affects linear self-motion perception (submitted). [aAHW]CrossRef Google Scholar

Blouin, J., Bridgeman, B., Teasdale, N., Bard, C. & Fleury, M. (submitted) Visual stability with goal-directed eye and arm movements toward a target displaced during saccadic suppression. [BB]Google Scholar

Bonnet, C. (1982) Thresholds of motion perception. In: Tutorials on motion perception, ed. Wertheim, A. H., Wagenaar, W. A. & Leibowitz, H. W.. Plenum Press. [aAHW]Google Scholar

Borah, J., Young, L. R. & Curry, R. E. (1988) Optimal estimator model for human spatial orientation. In: Representation of three-dimensional space in the vestibular, oculomotor, and visual systems, ed. B. Cohen & V. Henn. Annals of the New York Academy of Sciences 545. [aAHW]Google Scholar

Bötzel, K. & Grüsser, O. J. (1982) Horizontal and vertical circular vection and eye movements. Neuroscience Letters Supplement 10:86–87. [UB]Google Scholar

Brain, W. R. (1941) Visual disorientation with special reference to lesions of the right cerebral hemisphere. Brain 64:244–72. [FHP]CrossRef Google Scholar

Brandt, T., Dichgans, J. & Büchele, W. (1974) Motion habituation: Inverted self-motion perception and optokinetic after-nystagmus. Experimental Brain Research 21:337–52. [UB]CrossRef Google Scholar PubMed

Brandt, T., Dichgans, J. & Koenig, E. (1973) Differential effects of central versus peripheral vision on egocentric and exocentric motion perception. Experiment Brain Research 16:476–91. [aAHW, GJA, FHP]Google Scholar

Brandt, T., Wist, E. R. & Dichgans, J. (1975) Foreground and background in dynamic spatial orientation. Perception & Psychophysics 17:497–503. [FHP]Google Scholar

Braunstein, M. L. (1976) Depth perception through motion. Academic Press. [aAHW]Google Scholar

Bridgeman, B. & Graziano, J. A. (1989) Effect of context and efference copy on visual straight ahead. Vision Research 29(12):1729–36. [aAHW]Google Scholar

Bridgeman, B., Hendry, D. & Stark, L. (1975) Failure to detect displacement of the visual world during saccadic eye movements. Vision Research 15:719–22. [aAHW]Google Scholar

Bridgeman, B. & Stark, L. (1991) Ocular proprioception and efference copy in registering visual direction. Vision Research 31:1903–13. [BB]Google Scholar

Bruss, A. R. & Horn, B. K. P. (1983) Passive navigation. Computer Vision, Graphics and Image Processing 21:3–20. [IH, JRT]Google Scholar

Büehele, W., Degner, D. & Brandt, T. (1980) Thresholds for object motion perception raised by concurrent head movements. Pflügers Archives Supplement 384:R33. [aAHW]Google Scholar

Buettner, U. W. & Büttner, U. (1979) Vestibular nuclei activity in the alert monkey during suppression of vestibular and optokinetic nystagmus. Experimental Brain Research 37:581–93. [UB]Google Scholar

Büttner, U. & Buettner, U. W. (1978) Parietal cortex (2v) neuronal activity in the alert monkey during natural vestibular and optokinetic stimulation. Brain Research 153:392–97. [aAHW, UB]Google Scholar

Büttner, U. & Henn, V. (1981) Circularvection: Psychophysics and single-unit recordings in the monkey. Annals of the New York Academy of Sciences 374:274–83. [aAHW, UB, XMS]Google Scholar

Cameron, E. L., Baker, C. L. Jr. & Boulton, J. C. (1992) Spatial frequency selective mechanisms underlying the motion aftereffect. Vision Research 32:561–68. [FHP]CrossRef Google Scholar PubMed

Cohen, B., ed. (1981) Vestibular and oculomotor physiology: International meeting of the Barany Society. Annals of the New York Academy of Sciences 374. [aAHW]Google Scholar

Cohen, B. & Henn, V., eds. (1988) Representation of three-dimensional space in the vestibular, oculomotor, and visual systems. Annals of the New York Academy of Sciences 545. [arAHW]Google Scholar

Cohen, B., Matsuo, V. & Raphan, T. (1977) Quantitative analysis of the velocity characteristics of optokinetic nystagmus and optokinetic afternystagmus. Journal of Physiology 270:321–44. [UB]Google Scholar

Cohen, R. L. (1965) Adaptation effects and aftereffects of moving patterns viewed in the periphery of the visual field. Scandinavian Journal of Psychology 6:257–64. [aAHW]Google Scholar

Collewijn, J. (1985) Integration of adaptive changes of the optokinetic reflex, pursuit and the vestibulo-ocular reflex. In: Adaptive mechanisms in gaze control, ed. Berthoz, A. & Melvill-Jones, G.. Elsevier. [AAS]Google Scholar

Collewijn, H. & Tamminga, E. P. (1984) Human smooth pursuit and saccadic eye movements during voluntary pursuit of different target motion on different background. Journal of Physiology 351:217–50. [HH]Google Scholar

Coquery, J. M. (1978) Role of active movement in control of afferent input from skin in cat and man. In: Active touch, ed. Gordon, G.. Pergamon Press. [aAHW]Google Scholar

Coquery, J. M. (1981) Changes in somaesthetic evoked potentials during movement. Brain Research 31:361–78. [aAHW]Google Scholar

Coquery, J. M. & Amblard, B. (1973) Backward and forward masking in the perception of cutaneous stimuli. Perception & Psychophysics 13(2):161–63. [aAHW]Google Scholar

Corbin, H. H. (1942) The perception of grouping and apparent movement in visual depth. Archives of Psychology 273:1–50. [BMV]Google Scholar

Cutting, J. E., Bruno, N., Brady, N. P. & Moore, C. (1992a) Selectivity, scope, and simplicity of models: A lesson from fitting judgments of perceived depth. Journal of Experimental Psychology: Ceneral 121(3):364–81. [BMV]CrossRef Google Scholar PubMed

Cutting, J. E., Springer, K., Braren, P. A. & Johnson, S. H. (1992b) Wayfinding on foot from information in retinal, not optical, flow. Journal of Experimental Psychology: Ceneral 121(1):41–72. [aAHW]Google Scholar

da Vitoria Lobo, N. (1992) Computation, egomotion, shape, and detecting independent motion from image motion. Ph.D. dissertation, Department of Computer Science, University of Toronto. [NDVL]Google Scholar

da Vitoria Lobo, N. & Tsotsos, J. K. (1991) Telling where one is heading and where things move independently. Proceedings of the Conference of the Cognitive Science Society, August, Chicago, IL. [NDVL]Google Scholar

De Graaf, B. & Wertheim, A. H. (1988) The perception of object motion during smooth pursuit eye movements: Adjacency is not a factor contributing to the Filehne illusion. Vision Research 28:497–502. [arAHW]CrossRef Google Scholar PubMed

De Graaf, B., Wertheim, A. H., Bles, W. & Kremers, J. J. M. (1990) Angular velocity and not temporal frequency determines circular vection. Vision Research 30(4):637–46. [aAHW, XMS]CrossRef Google Scholar

Delorme, A. & Martin, C. (1986) Roles of retinal periphery and depth periphery in linear vection and visual control of standing in humans. Canadian Journal of Psychology 40:176–87. [FHP]Google Scholar

Denton, G. G. (1977) Visual motion after effect induced by simulated rectilinear motion. Perception 6:711–18. [aAHW]Google Scholar

Dichgans, J. & Brandt, T. (1972) Visual-vestibular interaction and motion perception. In: Cerebral control of eye movements, ed. Dichgans, J. & Bizzi, E.. Bibliotheca Opthalmologica, vol. 82. Kargel. [aAHW]Google Scholar

Dichgans, J. & Brandt, T. (1978) Visual-vestibular interaction: Effects on self-motion perception and postural control. In: Handbook of sensory physiology. Vol. 8: Perception. ed. Held, R., Leibowitz, H. W. & Teuber, H. -L.. Springer- Verlag. [arAHW, FHP, TP]Google Scholar

Dichgans, J., Korner, F. & Voigt, K. (1969) Vergleichende Skalierung des afferenten und efferenten Bewegungssehens beim Menschen: Liuearen Funktionen mit verschiedenen Ausstiegssteilkeit. Psychologische Forschung 32:277–95. [aAHW]Google Scholar

Dichgans, J., Nauck, B. & Wolpert, E. (1973) The influence of attention, vigilance and stimulus area on optokinetic and vestibular nystagmus and voluntary saccades. In: The oculomotor system and brain function, ed. Zikmund, V.. Butterworth. [TP]Google Scholar

Dichgans, J., Schmidt, C. L. & Graf, W. (1973) Visual input improves the speedometer function of the vestibular nuclei in the goldfish. Experimental Brain Research 18:319–22. [aAHW]Google Scholar

Dichgans, J., Wist, E., Diener, H. C. & Brandt, T. (1975) The Aubert-Fleischl phenomenon: A temporal frequency effect on perceived velocity in afferent motion perception. Experimental Brain Research 23:529–33. [aAHW]Google Scholar

Diener, H. C., Wist, E. R., Dichgans, J. & Brandt, T. (1976) The spatial frequency effect on perceived velocity. Vision Research 16:169–76. [aAHW]Google Scholar

DiZio, P. A. & Lackner, J. R. (1986) Perceived orientation, motion, and configuration of the body during viewing of an off-vertical, rotating surface. Perception & Psychophysics 39:39–46. [TAS]Google Scholar

Duncker, K. (1929) Über induzierte Bewegung [On induced motion]. Psychologische Forschung 12:180–259. [aAHW, WB, AES, BMV]Google Scholar

Dyhre-Poulsen, P. (1978) Perception of tactile stimuli before ballistic and during tracking movements. In: Active touch, ed. Gordon, G.. Pergamon Press. [aAHW]Google Scholar

Dzhafarov, E. N. (1992) Visual kinematics. Journal of Mathematical Psychology 36:471–97; 498–523; 524–46. [RAMG]Google Scholar

Ehrenstein, W. H., Mateeff, S. & Hohnsbein, J. (1986a) Zeitliche Aspekte dor Ortskonstanz bei Augenfolgbewegungen. Paper presented at the 63rd annual meeting of the German Physiological Society, March, Berlin. [aAHW]Google Scholar

Ehrenstein, W. H., Mateeff, S. & Hohnsbein, J. (1986b) Temporal aspects of position constancy during ocular pursuit. Pflügers Archives 406:R15(no. 47). [aAHW]Google Scholar

Ehrenstein, W. H., Mateeff, S. & Hohnsbein, J. (1987) Influence of exposure duration on the strength of the Filehne illusion. Perception 16:A29. [aAHW, SM]Google Scholar

Einstein, A. & Infeld, L. (1938) The evolution of physics. Simon & Schuster. [TAS]Google Scholar

Elsner, W. (1971) Power laws for the perception of rotation and the oculogyral illusion. Perception & Psychophysics 9(5):418–20. [aAHW]Google Scholar

Epstein, W. (1973) The process of “taking-into-accont” in visual perception. Perception 2:267–85. [SM]Google Scholar

Erickson, R. G. & Thier, P. (1991) A neuronal correlate of spatial stability during periods of self-induced visual motion. Experimental Brain Research 86:608–16. [PT]Google Scholar

Erickson, R. G. & Thier, P. (1992) Responses of direction-selective neurons in monkey cortex to selfinduced visual motion. Annals of the New York Academy of Sciences 656:766–74. [PT]Google Scholar

Favreau, O. E. (1976) Motion after effects: Evidence for parallel processing in motion perception. Vision Research 16:181–86. [aAHW]Google Scholar

Filehne, W. (1922) Über das optische Wahrnehmen von Bewegungen. Zeitschrift für Sinnephysiologie 53:134–45. [aAHW, AES]Google Scholar

Fleischl, von E. (1882) Physiologisch-optische Notizen, 2. Mitteilung. Sitzung Wiener Bereich der Akademie der Wissenschaften 3(86):7–25. [aAHW]Google Scholar

Fletcher, W. A., Haiti, T. C. & Zee, D. S. (1990) Optokinetic nystagmus and afternystagmus in human beings: Relationship to nonlinear processing of information about retinal slip. Experimental Brain Research 81:46–52. [aAHW]Google Scholar

Fuchs, A. F. & Kim, J. (1975) Unit activity in vestibular nucleus of the alert monkey during horizontal angular acceleration and eye movement. Journal of Neurophysiology 38:1140–61. [aAHW]Google Scholar

Gibson, E. J. (1991) An odyssey in learning and perception. MIT Press. [GER]Google Scholar

Gibson, J. J. (1950) The perception of the visual world. Houghton-Mifflin. [AES]Google Scholar

Gibson, J. J. (1954) The visual perception of objective motion and subjective movement. Psychological Review 61(5):304–14. [AES]Google Scholar

Gibson, J. J. (1966) The senses considered as perceptual systems. Houghton-Mifflin. [aAHW, N-GK, GER, WLS, JW, LY]Google Scholar

Gibson, J. J. (1968) What gives rise to the perception of motion? Psychological Review 75:335–45. [aAHW]Google Scholar

Gibson, J. J. (1973) Direct visual perception: A reply to Gyr. Psychological Bulletin 79(6):396–97. [aAHW]Google Scholar

Gibson, J. J. (1979) The ecological approach to visual perception. Houghton Mifflin. [aAHW, VIB, N-GK, GER, BMV, JW, LY]Google Scholar

Gibson, J. J., Olum, P. & Rosenblatt, F. (1955) Parallax and perspective during aircraft landings. American Journal of Psychology 68:372–85. [JRT]Google Scholar

Gibson, J. J., Smit, O. W., Steinschneider, A. & Johnson, C. W. (1957) The relative accuracy of visual perception of motion during fixation and pursuit. American Journal of Psychology 70:64–68. [aAHW]Google Scholar

Gogel, W. C. (1981) Perceived depth is a necessary factor in apparent motion concomitant with head motion: A reply to Shebilske and Proffitt. Perception & Psychophysics 29:173–77. [rAHW]Google Scholar

Gogel, W. C. (1982) Analysis of the perception of retinal motion concomitant with a lateral motion of the head. Perception & Psychophysics 32:241–50. [MS]Google Scholar

Gogel, W. C. (1990) A theory of phenomenal geometry and its applications. Perception & Psychophysics 48:105–23. [rAHW, MS]Google Scholar

Gogel, W. C., Loomis, J. M., Newman, N. J. & Sharkey, T. J. (1985) Agreement between indirect measures of perceived distance. Perception & Psychophysics 37:17–27. [MS]Google Scholar

Gogel, W. C. & Sharkey, T. J. (1989) Measuring attention using induced motion. Perception 18:303–20. [SM]Google Scholar

Gogel, W. C. & Tietz, J. D. (1992) Determinants of the perception of sagittal motion. Perception & Psychophysics 52:75–96. [MS]Google Scholar

Goodale, M. A. (1988) Modularity in visuomotor control: From input to output. In: Computational processes in human vision: An interdisciplinary perspective, ed. Pylyshyn, Z. W.. Ablex. [WLS]Google Scholar

Goodale, M. A. & Milner, A. D. (1992) Separate visual pathways for perception and action. Trends in Neurosciences 15:20–25. [XMS]CrossRef Google Scholar PubMed

Grant, W. & Best, W. (1987) Otolith-organ mechanics: Lumped parameter model and dynamic response. Aviation Space and Environmental Medicine 58:970–76. [aAHW]Google Scholar

Graybiel, A. (1952) Oculogravic illusion. Archives of Ophthalmology 48:605. [TAS]Google Scholar

Graybiel, A. & Brown, R. H. (1951) The delay in visual reorientation following exposure to a change in direction of resultant force on a human centrifuge. Journal of General Psychology 45:143–50. [HER]Google Scholar

Graybiel, A. & Hupp, E. D. (1946) The oculogyral illusion: A form of apparent motion which may be observed following stimulation of the semi-circular canals. Journal of Aviation Medicine 17:3–27. [aAHW]Google Scholar

Graybiel, A. & Niven, J. (1951) The effect of a change in direction of resultant force on sound localization: The audiogravic illusion. Journal of Experimental Psychology 42:227–30. [TAS]Google Scholar

Gregory, R. L. (1958) Eye movements and the stability of the visual world. Nature 182:1214–16. [HER, AES]Google Scholar

Grüsser, O. -J. (1983) Multimodal structure of the extrapersonal space. In: Spatially oriented behavior, ed. Hein, A. & Jeannerod, M.. Springer-Verlag. [FHP]Google Scholar

Grüsser, O. -J., Pause, M. & Schreiter, U. (1990a) Localization and responses of neurons in the parieto-insular vestibular cortex of awake monkeys (Macaca fascicularis). Journal of Physiology 430:537–57. [UB]Google Scholar

Grüsser, O. -J., Pause, M. & Schreiter, U. (1990b) Vestibular neurons in the parieto-insular cortex of monkeys (Macaca fascicularis): Visual and neck receptor responses. Journal of Physiology 430:559–83. [UB]Google Scholar

Guedry, F. E. (1974) Psychophysics of vestibular sensation. In: Handbook of sensory physiology, vol. 6/2, ed. Kornhuber, H. H.. Springer. [rAHW]Google Scholar

Guldin, W. O., Akbarian, S. & Grüsser, O. J. (1992) Cortico-cortical connections and cytoarchitectonics of the primate vestibular cortex: A study in squirrel monkeys (Saimiri sciureus). Journal of Comparative Neurology 326:375–401. [UB]Google Scholar

Guldin, W., Mirring, S. & Grüsser, O. J. (1992) Monosynaptic input from the cerebral cortex to the vestibular brainstem nuclei in the rat. Society of Neuroscience Abstracts 18:510. [UB]Google Scholar

Gyr, J. W. (1972) Is a theory of direct visual perception adequate? Psychological Bulletin 77:246–61. [aAHW]Google Scholar

Hadani, I., Ishai, G., Frisch, H. I. & Kononov, A. (1993) Two metric solutions to 3-D reconstruction for an eye in pure rotations. Journal of the Optical Society of America (in press). [IH]Google Scholar

Hadani, I., Ishai, G. & Gur, M. (1980) Visual stability and space perception in monocular vision: Mathematical model. Journal of the Optical Society of America 1:60–65. [IH]Google Scholar

Hadani, I. & Kononov, A. (1993) Passive navigation for an eye in six degrees of freedom. Science (in preparation). [IH]Google Scholar

Hansen, R. H. (1979) Spatial localization during pursuit eye movements. Vision Research 19:1213–21. [rAHW, AAS]Google Scholar

Hansen, R. H. & Skavenski, A. A. (1985) Accuracy of spatial localizations near the time of saccadic eye movements. Vision Research 25:1077–82. [rAHW, AAS]Google Scholar

Heekmann, T. & Howard, I. P. (1991) Induced motion: Isolation and dissociation of egocentric and vection-entrained components. Perception 20:285–305. [FHP]Google Scholar

Heckmann, T. & Post, R. B. (1988) Induced motion and optokinetic afternystagmus: Parallel response dynamics with prolonged stimulation. Vision Research 28:681–94. [FHP]Google Scholar

Helmholtz, H. (1910) Handbuch der physiologischen Optik, Vol. 3. Voss. [aAHW]Google Scholar

Henderson, D. C. (1971) The relationship among time, distance, and intensity as determinants of motion discrimination. Perception & Psychophysics 10:310–20. [aAHW]Google Scholar

Henn, V., Cohen, B. & Young, L. R. (1980) Visual-vestibular interaction in motion perception and the generation of nystagmus. Neurosciences Research Program Bulletin 18 (4). MIT Press. [arAHW, TP]Google Scholar

Henn, V., Young, L. R. & Finley, C. (1974) Vestibular nucleus units in alert monkeys are also influenced by moving visual fields. Brain Research 71:144–49. [aAHW]Google Scholar

Hofstadter, D. R. (1980) Gödel, Escher Bach: An eternal golden braid. Vintage Press. [aAHW]Google Scholar

Hofstetter-Degen, K. (1988) Eine psychophysische Untersuchung zur visuell-vistibulären Interaktion. Beeinflussung der Objektbewegungswahrnehmung durch gleichzeitige Eigenbewegung. Ph.D. dissertation, University of Mainz. (Author's transl.: A psychophysical investigation of visual-vestibular interaction. Influence of object-motion perception by simultaneous self-motion.) [TP]Google Scholar

Honda, H. (1990) The extraretinal signal from the pursuit-eye-movement system: Its role in the perceptual and the egocentric localization systems. Perception & Psychophysics 48:509–15. [HH]Google Scholar

Howard, I. P. (1982) Human visual orientation. Wiley. [aAHW, VIB, DC]Google Scholar

Howard, I. P. & Heckmann, T. (1989) Circular vection as a function of the relative sizes, distances, and positions of two competing visual displays. Perception 18:657–65. [XMS]Google Scholar

Howard, I. P. & Marton, C. (1992) Visual pursuit over textured backgrounds in different depth planes. Experimental Brain Research 90:625–29. [FHP]Google Scholar

Howard, I. P. & Templeton, W. B. (1966) Human spatial orientation. Wiley. [aAHW]Google Scholar

Hunzelmann, N. & Spillmann, L. (1984) Movement adaptation in the peripheral retina. Vision Research 24(12): 1765–69. [aAHW]Google Scholar

Ilg, U. & Thier, P. (1993) Inability of visual area VI of the awake rhesus monkey to discriminate between self-induced and externally-induced retinal image slip. Society for Neuroscience Abstracts 19:629. [PT]Google Scholar

Ioannou, P. A. & Kokotovic, P. V. (1983) Adaptive systems with reduced models. Lecture notes in control and information sciences 47. Springer-Verlag. [RAMG]Google Scholar

Ito, M. (1982) Cerebellar control of the vestibulo-ocular reflex: Around the flocculus hypothesis. Annual Review of Neuroscience 5:275–96. [aAHW]Google Scholar

Ito, M. (1987) Oculomotor system, mechanisms. In: Encyclopedia of neuroscience, vol. 2, ed. Adelman, G.. Birkhäuser. [TP]Google Scholar

Jeannerod, M., Kennedy, H. & Magnin, M. (1979) Corollary discharge: Its possible implications in visual and oculomotor interactions. Neuropsychologic 17:241–58. [aAHW]Google Scholar

Johansson, G. (1982) Visual space perception through motion. In: Tutorials on motion perception, ed. Wertheim, A. H., Wagenaar, W. A. & Leibowitz, H. W.. Plenum Press. [AES]Google Scholar

Johnson, C. A. & Leibowitz, H. W. (1976) Velocity-time reciprocity in the perception of motion: Foveal and peripheral determinations. Vision Research 16:177–80. [aAHW]Google Scholar

Johnstone, J. R. & Mark, R. F. (1970) Two classes of eye movement and their perceptual consequences. Proceedings of the Australian Physiological and Pharmacological Society 1(2):46–47. [aAHW]Google Scholar

Johnstone, J. R. & Mark, R. F. (1971) The efference copy neurone. Journal of Experimental Biology 54:403–14. [aAHW]Google Scholar

Johnstone, J. R. & Mark, R. F. (1973) Corollary discharge. Vision Research 13:1621. [aAHW]Google Scholar

Jung, R. (1972) Neurophysiological and psychophysical correlates in visual research. In: Brain and human behavior, ed. Karczmar, A. G. & Eccles, J. C.. Springer. [VIB]Google Scholar

Kano, C. (1970) Changes of threshold of continuous visual movement by variation of phenomenal size with invariant retinal size. Psychological Research 33(3):242–53. [BMV]Google Scholar

Kaufman, L. (1974) Sight and mind: An introduction to visual perception. Oxford University Press. [BMV]Google Scholar

Kinchla, R. A. (1971) Visual movement perception: A comparison between absolute and relative movement discrimination. Perception & Psychophysics 9(2A):165–71. [aAHW]Google Scholar

Koenderink, J. J. (1990) Some theoretical aspects of optic flow. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [aAHW]Google Scholar

Koenderink, J. J. & van Doorn, A. J. (1976) Local structure of movement parallax of the plane. Journal of the Optical Society of America 66:717–23. [GJA]Google Scholar

Koenderink, J. J. & van Doorn, A. J. (1981) Exterospecific component of the motion parallax field. Journal of the Optical Society of America 71:953–57. [JRT]Google Scholar

Koenderink, J. J. & van Doorn, A. J. (1987) Facts on optic flow. Biological Cybernetics 56:247–54. [aAHW, JRT]Google Scholar

Koenderink, J. J. & van Doorn, A. J. (1991) Affine structure from motion. Journal of the Optical Society of America 8(2):377–85. [IH]CrossRef Google Scholar PubMed

Köhler, W. (1947) Cestalt psychology: An introduction to new concepts in modern psychology. Liveright. [BMV]Google Scholar

Kornhuber, H. H. (1974) Nystagmus and related phenomena in man: An outline of otoneurology. In: Handbook of sensory physiology. Vol. 6/2, Vestibular system, part 2, psychophysics. Applied aspects and general interpretations. Springer Verlag. [aAHW]Google Scholar

Lackner, J. R. (1992) Spatial orientation in weightless environments. Perception 21:803–12. [FHP]Google Scholar

Lackner, J. & DiZio, P. (1984) Some efferent and somatosensory influences on body orientation and oculomotor control. In: Sensory experience, adaptation and perception: Festschrift for Ivo Kohler, ed. Spillman, L. & Wooten, B.. Erlbaum. [JJR]Google Scholar

Lackner, J. R. & Teixeira, R. A. (1977) Optokinetic motion sickness: Continuous head movements attenuate the visual induction of apparent self-rotation and symptoms of motion sickness. Aviation, Space and Environmental Medicine 48:248–53. [LY]Google Scholar

Lang, W., Büttner-Ennever, J. A. & Büttner, U. (1979) Vestibular projections to the monkey thalamus: An autoradiographic study. Brain Research 177:3–17. [UB]Google Scholar

Larsen, A., Farrell, J. E. & Bundesen, C. (1983) Short- and long-range processes in visual apparent movement. Psychological Research 45:11–18. [BMV]Google Scholar

Lee, D. & Aronson, E. (1974) Visual proprioceptive control of standing in human infants. Perception & Psychophysics 15:529–32. [JJR]Google Scholar

Lee, D. N. (1974) Visual information during locomotion. In: Perception: Essays in honour of James J. Cibson, ed. McLeod, R. B. & Pick, H.. Cornell University Press. [JRT]Google Scholar

Lee, D. N. (1990) Getting around with light and sound. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [rAHW]Google Scholar

Leibowitz, H. W., Post, R. B., Brandt, T. & Dichgans, J. (1982) Implications of recent developments in dynamic spatial orientation and visual resolution for vehicle guidance. In: Tutorials on motion perception, ed. Wertheim, A. H., Wagenaar, W. A. & Leibowitz, H. W.. Plenum Press. [aAHW]Google Scholar

Lisberger, S. G. & Fuchs, A. F. (1978a) Role of primate flocculus during rapid behavioral modification of vestibulo-ocular reflex I. Purkinje cell activity during visually guided horizontal smooth pursuit eye movements and passive head rotation. Journal of Neurophysiology 41(3):733–63. [aAHW]Google Scholar

Lisberger, S. G. & Fuchs, A. F. (1978b) Role of primate flocculus during rapid behavioral modification of vestibulo-ocular reflex II. Mossy fiber firing patterns during horizontal head rotation and eye movement. Journal of Neurophysiology 41(3):764–77. [aAHW]Google Scholar

Lishman, J. R. & Lee, D. N. (1973) The autonomy of visual kinaesthesis. Perception 2:287–94. [N-GK, JW]Google Scholar

Lombardo, T. J. (1987) The reciprocity of perceiver and environment: The evolution of J. J. Gibson's ecological psychology. Erlbaum. [aAHW]Google Scholar

Longuet-Higgins, H. C. & Prazdny, K. (1980) The interpretation of a moving retinal image. Proceedings of the Royal Society of London (B) 208:385–97. [GJA, JRT]Google Scholar

Mack, A. (1978) Three modes of visual perception. In: Models of perceiving and processing information, ed. Pick, H. L. & Saltzman, E.. Erlbaum. [aAHW, AES]Google Scholar

Mack, A. (1986) Perceptual aspects of motion in the frontal plane. In: Handbook of perception and human performance. Vol. I: Sensory processes and perception, ed. Boff, K. R., Kaufman, L. & Thomas, J. P.. Wiley. [aAHW]Google Scholar

Mack, A. & Herman, E. (1972) A new illusion: The underestimation of distance during smooth pursuit eye movements. Perception of Psychophysics 12(6):471–73. [aAHW, HH]Google Scholar

Mack, A. & Herman, E. (1973) Position constancy during pursuit eye movement: An investigation of the Filehne illusion. Quarterly Journal of Experimental Psychology 25:71–84. [aAHW]Google Scholar

Mack, A. & Herman, E. (1978) The loss of position constancy during pursuit eye movements. Vision Research 18:55–62. [aAHW]Google Scholar

MacKay, D. M. (1972) Voluntary eye movements as questions. In: Cerebral control of eye movements, ed. Dichgans, J. & Bizzi, E.. Bibliotheca Opthalmologica, vol. 82. Kargel. [aAHW]Google Scholar

MacKay, D. M. (1973) Visual stability and voluntary eye movements. In: Handbook of sensory physiology, vol. 7 (3A), ed. Jung, R.. Springer. [aAHW, VIB]Google Scholar

MacKay, D. M. (1982) Anomalous perception of extrafoveal motion. Perception 11:359–60. [aAHW]Google Scholar

Maioli, M. G., Squatrito, S. & Domeniconi, R. (1989) Projections from visual cortical areas of the superior temporal sulcus to the lateral terminal nucleus of the accessory optic system in macaque monkeys. Brain Research 498:389–92. [XMS]Google Scholar

Marcus, J. T. (1992) Vestibulo-ocular responses in man to gravito-inertial forces. Ph. D. dissertation. TNO Institute for Perception, Soesterberg. [aAHW]Google Scholar

Marendaz, C., Stivalet, P., Barraclough, L. & Walkowiac, P. (1993) Effect of gravitational cues on visual search for orientation. Journal of Experimental Psychology: Human Perception and Performance 19(6): 1266–77. [LY]Google Scholar

Mark, L. M. (1987) Eye-height-scaled information about affordanees: A study of sitting and stair-climbing, Journal of Experimental Psychology: Human Perception and Performance 13:683–783. [TAS]Google Scholar

Massaro, D. & Cohen, M. M. (1993) The paradigm and the fuzzy logical model of perception are alive and well. Journal of Experimental Psychology: General 122(1): 115–24. [BMV]Google Scholar

Mateeff, S. (1980) Visual perception of movement patterns during smooth eye tracking. Acta Physiologica et Pharmacologica Bulgarica 6:82–89. [SM]Google Scholar

Mateeff, S., Ehrenstein, W. H. & Hohnsbein, J. (1987) Constancy of visual direction requires time to develop. Perception 16:A29. [SM]Google Scholar

Mateeff, S., Yakimoff, N., Hohnsbein, J. & Ehrenstein, W. H. (1991) Perceptual constancy during ocular pursuit: A quantitative estimation procedure. Perception & Psychophysics 49(4):390–92. [aAHW]Google Scholar

Matin, L. (1982) Visual localization and eye movements. In: Tutorials on motion perception, ed. Wertheim, A. H., Wagenaar, W. A. & Leibowitz, H. W.. Plenum Press. [arAHW]Google Scholar

Matin, L. (1986) Visual localization and eye movements. In: Handbook of perception and human performance. Vol. I: Sensory processes and perception, ed. Boff, K. R., Kaufman, L. & Thomas, J. P.. Wiley. [arAHW]Google Scholar

Matin, L., Matin, E. & Pearce, D. (1969) Visual perception of direction when voluntary saccades occur. I. Relation of visual direction of a fixation target extinguished before a saccade to a subsequent test flash presented during the saccade. Perception & Psychophysics 5:65–80. [arAHW, AAS]Google Scholar

McConkie, A. B. & Farber, J. M. (1979) Relation between perceived depth and perceived motion in uniform flow fields. Journal of Experimental Psychology: Human Perception and Performance 5:501–8. [GJA]Google Scholar

McCrea, R. A., Yoshida, K., Evinger, C. & Berthoz, A. (1981) The location, axonal arborization and termination sites of eye movement-related secondary vestibular neurons demonstrated by intra-axonal HRP injection in the alert cat. In: Progress in oculomotor research, ed. Fuchs, A. F. & Becker, W.. Elsevier North-Holland. [aAHW]Google Scholar

Mergner, T. & Becker, W. (1990) Perception of horizontal self-rotation: Multisensory and cognitive aspects. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [arAHW, WB, N-GK, SM, FHP]Google Scholar

Mergner, T., Rottler, G., Kimmig, H. & Becker, W. (1992) Role of vestibular and neck inputs for the perception of object motion in space. Experimental Brain Research 89:655–68. [WB]Google Scholar

Mergner, T., Siebold, C., Schweigart, G. & Becker, W. (1991) Human perception of horizontal head and trunk rotation in space during vestibular and neck stimulation. Experimental Brain Research 85:389–404. [WB]Google Scholar

Metzger, W. (1941) Psychologie [Psychology]. Steinkopf. [BMV]Google Scholar

Miller, J. (1980) Information used by the perceptual and oculomotor systems regarding the amplitude of saccadic and pursuit eye movements. Vision Research 20:59–68. [HH]Google Scholar

Mittelstaedt, H. (1983) A new solution to the problem of the subjective vertical. Naturwissenschaften 70:272–81. [LY]Google Scholar

Mittelstaedt, H. (1990) Basic solutions to the problem of head-centric visual localization. In: Perception and control of self-motion, ed. R. Warren & A. H. Wertheim. [aAHW]Google Scholar

Moulden, B. (1975) Eye movements and the movement after effect. Vision Research 15:1169–70. [aAHW]Google Scholar

Murphy, B. J. (1978) Pattern thresholds for moving and stationary gratings during smooth pursuit eye movement. Vision Research 18:521–30. [aAHW]Google Scholar

Nagao, S. (1988) Behavior of floccular Purkinje cells correlated with adaptation of horizontal optokinetic eye movement response in pigmented rabbits. Experimental Brain Research 73:489–97. [aAHW]Google Scholar

Nakayama, K. (1981) Differential motion hyperacuity under conditions of common image motion. Vision Research 21:1475–82. [aAHW]Google Scholar

Neisser, U. (1976) Cognition and reality. W. H. Freeman. [GER]Google Scholar

Noda, H. (1986) Mossy fibers sending retinal-slip, eye, and head velocity signals to the flocculus of the monkey. Journal of Physiology 379:39–60. [aAHW]Google Scholar

Ockels, W. J., Furrer, R. & Messerschmid, E. (1989) Space sickness on earth. Nature 340(August):681–82. [aAHW]Google Scholar

Ockels, W. J., Furrer, R. & Messerschmid, E. (1990) Space sickness on earth. Experimental Brain Research 79(3):661–63. [aAHW]Google Scholar

Ohmi, M., Howard, I. P. & Landolt, J. P. (1987) Circular vection as a function of foreground-background relationships. Perception 16:17–22. [N-CK, FHP, LY]Google Scholar

Oman, C. M. (1988) The role of static visual orientation cues in the etiology of space motion sickness. In: Proceedings of the Symposium on Vestibular Organs and Altered Force Environment, ed. Igarashi, M. & Nute, K. G.. National Aeronautics and Space Administration. [FHP]Google Scholar

Ono, M. E., Rivest, J. & Ono, H. (1986) Depth perception as a function of motion parallax and absolute-distance information. Journal of Experimental Psychology: Human Perception & Performance 12:331–37. [MS]Google Scholar

Owen, D. H. (1990) Perception and control of changes in self-motion: A functional approach to the study of information and skill. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [aAHW]Google Scholar

Paillard, J., Brouchon-Viton, M. & Jordan, P. (1978) Differential encoding of location cues by active and passive touch. In: Active touch, ed. Gordon, G.. Pergamon Press. [aAHW]Google Scholar

Pavard, B. & Berthoz, A. (1977) Linear acceleration modifies the perception of a moving visual scene. Perception 6:529–40. [aAHW]Google Scholar

Post, R. B. & Leibowitz, H. W. (1985) A revised analysis of the role of efference in motion perception. Perception 14:631–43. [arAHW, SM, AAS]Google Scholar

Post, R. B., Leibowitz, H. W. & Shoehy, J. B. (1986) Efference, perceived movement, and illusory displacement. Acta Psychologica 63(1–3):23–34. [BMV]Google Scholar

Precht, W. (1982) Anatomical and functional organization of optokinetic pathways. In: Functional basis of ocular motility disorders, ed. Lennestrand, G., Lee, D. S. & Keller, E. L.. Pergamon Press. [aAHW]Google Scholar

Previc, F. H. & Donnelly, M. (1993) The effects of visual depth and eccentricity on manual bias, induced motion, and vection. Perception 22. [FHP]Google Scholar

Previc, F. H., Varner, D. C. & Gillingham, K. K. (1992) Visual scene effects on the somatogravic illusion. Aviation, Space, and Environmental Medicine 63:1060–64. [FHP]Google Scholar

Probst, T. (1983) Beeinflussung der Objektbewegungswahrnehmung durch gleichzeitige Eigenbewegungsempfindung. Psychophysische Grundlagen und angewandte Aspekte bei der Fahrzeugsteuerung. Ph.D. dissertation, University of Essen. (Author's transl.: Influence of object-motion detection by concurrent self-motion perception. Basic psychophysics and applied aspects for vehicle guidance.) [TP]Google Scholar

Probst, T. (1991) Intersensorische Interaktion beim Menschen. Psychophysikalische und elektrophysiologische Untersuchungen. Waxmann Münster. (Author's transl.: Intersensory interaction in humans. Psychophysical and electrophysiological investigations.) [TP]Google Scholar

Probst, T., Brandt, T. & Degner, D. (1986) Object-motion detection affected by concurrent self-motion perception: Psychophysics of a new phenomenon. Behavioural Brain Research 22:1–11. [aAHW, TP]Google Scholar

Probst, T., Degner, D. & Brandt, T. (1980) Object motion perception affected by concurrent self-motion. Paper presented at the third European Conference on Visual Perception. August, Brighton, UK. [aAHW]Google Scholar

Probst, T., Krafezyk, S., Brandt, T. & Wist, E. R. (1984) Interaction between perceived self-motion and object-motion impairs vehicle guidance. Science 225:536–38. [aAHW]Google Scholar

Probst, T., Straube, A. & Bles, W. (1985) Differential effects of ambient visual-vestibular-somatosensory stimulation on the perception of self-motion. Behavioural Brain Research 16:71–79. [aAHW]Google Scholar

Puckett, J. W. & Steinman, R. M. (1969) Tracking eye movements with and without saccadie correction. Vision Research 9:695–703. [HH]Google Scholar

Rapban, T., Cohen, D. & Matsuo, V. (1977) A velocity storage mechanism responsible for OKN, OKAN and vestibular nystagmus. In: Control of gaze by brainstem neurons. Developments in neuroscience, vol. I, ed. Baker, R. & Berthoz, A.. Elsevier North Holland, Biomedical Press. [aAHW]Google Scholar

Ranch, R., Angel, R. W. & Boylls, C. C. (1985) Velocity-dependent suppression of somatosensory evoked potentials during movement. Encephalography and Clinical Neurophysiology 62:421–25. [aAHW]Google Scholar

Raymond, J. W., Shapiro, K. L. & Rose, D. J. (1984) Optokinetic backgrounds affect perceived velocity during ocular tracking. Perception & Psychophysics 36(3):221–24. [aAHW]Google Scholar

Reinhardt-Rutland, A. H. (1992) Does the type of eye motion determine whether induced motion is diminished or enhanced? Perceptual and Motor Skills 74:882. [aAHW]Google Scholar

Riccio, G. E. (1993a) Information in movement variability about the qualitative dynamics of posture and orientation. In: Variability and motor control, ed. Newell, K. M. & Corcos, D. M.. Human Kinetics. [GER]Google Scholar

Riccio, G. E. (1993b) Multimodal perception and multicriterion control of nested systems: Self-motion in real and virtual environments (UIUC-BI-HPP-93-02). Beckman Institute for Advanced Science and Technology, University of Illinois. [GER]Google Scholar

Riccio, G. E., Martin, E. J. & Stoffregen, T. A. (1992) The role of balance dynamics in the active perception of orientation. Journal of Experimental Psychology: Human Perception & Performance 18:624–44. [TAS]Google Scholar

Riccio, G. E. & Stoffregen, T. A. (1990) Gravitoinertial force versus the direction of balance in the perception and control of orientation. Psychological Review 97:135–37. [TAS]Google Scholar

Rieser, J. J., Ashmead, D. A., Talor, C. & Youngquist, G. (1991) Visual perception and the guidance of locomotion without vision to previously seen targets. Perception 19:675–89. [JJR]Google Scholar

Rieser, J., Garing, A. & Young, M. (1994) Imagery, action and young children's spatial orientation: It's not being there that counts, it's what one has in mind. Child Development (in press). [JJR]Google Scholar

Rieser, J., Pick, H., Ashmead, D. & Garing, A. (submitted) The calibration of human locomotion and models of perceptual-motor organization. [JJR]Google Scholar

Rock, I. (1977) In defense of unconscious inference. In: Stability and constancy in visual perception: Mechanisms and processes, ed. Epstein, W.. Wiley. [SM, AES]Google Scholar

Rock, I. (1983) The logic of perception. MIT Press. [SM]Google Scholar

Rogers, B. & Graham, M. (1979) Motion parallax as an independent cue for depth perception. Perception 8:125–34. [MS]Google Scholar

Rosengren, K. S., Pick, H. & von Hofsten, C. (1988) The role of visual information in ball catching. Journal of Motor Behaviour 20:150–64. [JRT]Google Scholar

Ross, H. E. (1974) Behaviour and perception in strange environments. Allen & Unwin. [aAHW, HER]Google Scholar

Ross, H. E. (1976) The direction of apparent movement during transient pressure vertigo. Undersea Biomedical Research 3:403–10. [HER]Google Scholar

Ross, H. E. (1990) Orientation and movement in divers. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [HER]Google Scholar

Ross, H. E. & Lennie, P. (1968) Visual stability during bodily movement underwater. Underwater Association Report 3:55–57. [HER]Google Scholar

Runeson, S. (1988) The distorted room illusion, equivalent configurations, and the specificity of static optic arrays. Journal of Experimental Psychology: Human Perception and Performance 14:295–304. [LY]Google Scholar

Sauvan, X. M. & Bonnet, C. (1988) Thresholds and variations of the forward rectilinear and curvilinear vections in man. In: Proceedings of the European Brain and Behaviour Society Workshop “Visual processing of form and motion,” March, Tübingen, Germany. [XMS]Google Scholar

Sauvan, X. M. & Bonnet, C. (1989) Les sensations de déplacement curvilinéaire générées visuellement. Psychologie Française 34:19–24. [XMS]Google Scholar

Sauvan, X. M. & Bonnet, C. (1993) Properties of curvilinear vection. Perception & Psychophysics 53:429–35. [TAS, XMS]Google Scholar

Schöne, H. (1984) Spatial orientation: The spatial control of behavior in animals and man (trans. Strausfeld, C.). Princeton University Press. [TAS]Google Scholar

Schoppmann, A. (1981) Projections from areas 17 and 18 of the visual cortex to the nucleus of the optic tract. Brain Research 223:1–17. [TP]Google Scholar

Sekuler, A. B. (1990) Motion segregation from speed differences: Evidence for nonlinear processing. Vision Research 30(5):785–95. [aAHW]Google Scholar

Sekuler, R. R., Ball, K., Tynan, P. & Machamer, J. (1982) Psychophysics of motion perception. In: Tutorials on motion perception, ed. Wertheim, A. H., Wagenaar, W. A. & Leibowitz, H. W.. Plenum Press. [aAHW]Google Scholar

Shaffer, O. & Wallach, H. (1966) Extent-of-motion thresholds under subject-relative and object-relative conditions. Perception & Psychophysics 1:447–51. [aAHW]Google Scholar

Shaw, R. E., Kadar, E., Sim, M. & Repperger, D. W. (1992) The intentional spring: A strategy for modeling systems that learn to perform intentional acts. Motor Behavior 24:3–28. [GER]Google Scholar

Shebilske, W. L. (1977) Visuomotor coordination in visual direction and position constancies. In: Stability and constancy in visual perception: Mechanisms and processes, ed. Epstein, W.. Wiley. [WLS]Google Scholar

Shebilske, W. L. (1984) Efferent factors in cognition and perception. In: Cognition and motor processes, ed. Prinz, W. & Sanders, A. F.. Plenum Press. [WLS]Google Scholar

Shebilske, W. L. (1987a) An ecological efference mediation theory of natural event perception. In: Perspectives on perception and action, ed. W. Prinz & A. F. Sanders. Erlbaum. [WLS]Google Scholar

Shebilske, W. L. (1987b) Baseball batters support an ecological efference mediation theory of natural event perception. In: Sensorimotor interactions in space perception and action, ed. Bouwhuis, D. G., Bridgeman, B., Owens, D. A., Shebilske, W. L. & Wolff, P.. North Holland. [WLS]Google Scholar

Shebilske, W. L. (1990) Visuomotor modularity, ontogeny, and training high-performance skills with spatial display instruments. In: Spatial displays and spatial instruments, ed. Ellis, S. R. & Kaiser, M. K.. Erlbaum. [WLS]Google Scholar

Shebilske, W. L. & Peters, P. (in press) Perception, action, and constancy. In: Handbook of perception, ed. W. Prinz & B. Bridgeman. Springer-Verlag. [WLS]Google Scholar

Shebilske, W. L., Proffitt, D. R. & Fisher, S. K. (1984) Efferent factors in natural event perception can be rationalized and verified: A reply to Turvey and Solomon. Journal of Experimental Psychology: Human Perception and Performance 10:455–60. [WLS]Google Scholar

Shulman, P. H. (1979) Eye movements do not cause induced motion. Perception & Psychophysics 26:381–83. [aAHW]Google Scholar

Simpson, J. & Graf, W. (1985) The selection of reference frames by nature and its investigators. In: Adaptive mechanisms in gaze control, ed. Berthoz, A. & Melvill-Jones, G.. Elsevier. [AAS]Google Scholar

Skavenski, A. A. (1972) Inflow as a source of extraretinal eye position information. Vision Research 12:221–29. [aAHW]Google Scholar

Skavenski, A. A. (1990) Eye movement and visual localization of objects in space. In: Eye movements and their role in visual and cognitive processes, ed. Kowler, E.. Elsevier. [rAHW, AAS]Google Scholar

Sperry, R. W. (1950) Neural basis of the spontaneous optokinetic response produced by visual inversion. Journal of Comparative and Physiological Psychology 43:482–89. [aAHW]Google Scholar

Stark, L. & Bridgeman, B. (1983) Role of corollary discharge in space constancy. Perception & Psychophysics 34(4):371–80. [aAHW]Google Scholar

Steinbach, M. J. (1987) Proprioceptive knowledge of eye position. Vision Research 27(10): 1737–44. [aAHW]Google Scholar

Stern, L. D. & Emelity, D. (1978) Evidence for frames of reference based on pursuit eye movements. Perception & Psychophysics 24:521–28. [rAHW, SM, AS]Google Scholar

Stoffregen, T. A. (1985) Flow structure versus retinal location in the optical control of stance. Journal of Experimental Psychology: Human Perception and Performance 11:554–65. [TAS]Google Scholar

Stoffregen, T. A. (1986) The role of optical velocity in the control of stance. Perception & Psychophysics 39:355–60. [TAS]Google Scholar

Stoffregen, T. A. (1990) Multiple sources of information: For what? Newsletter of the International Society for Ecological Psychology 4:5–8. [TAS]Google Scholar

Stoffregen, T. A. & Riccio, G. E. (1988) An ecological theory of orientation and the vestibular system. Psychological Review 95:3–14. [aAHW, TAS, LY]Google Scholar

Stoffregen, T. A. & Riccio, G. E. (1990) Responses to optical looming in the retinal center and periphery. Ecological Psychology 2:251–74. [TAS]Google Scholar

Stoffregen, T. A. & Riccio, G. E. (1991) An ecological critique of the sensory conflict theory of motion sickness. Ecological Psychology 3:159–94. [TAS]Google Scholar

Stone, L. S. & Lisberger, S. G. (1990a) Visual responses of Purkinje cells in the cerebellar flocculus during smooth pursuit eye movements in monkeys. I: Simple spikes; II: Complex spikes. Journal of Neurophysiology 63(5):1241–75. [aAHW]Google Scholar

Stone, L. S. & Lisberger, S. G. (1990b) Synergistic action of complex and simple spikes in the monkey flocculus in the control of smooth pursuit eye movement. Experimental Brain Research 17: 299–312. [aAHW]Google Scholar

Stoper, A. (1967) Vision during ptirsuit eye movement: The role of oculomotor information. Ph.D. dissertation, Brandeis University. University Microfilms, No. 67–16, 579. [AES]Google Scholar

Stoper, A. (1973) Apparent motion of stimuli presented stroboscopically during pursuit movement of the eye. Perception & Psychophysics 23:201–11. [AES]Google Scholar

Straube, A. & Brandt, T. (1987) Importance of the visual and vestibular cortex for self-motion perception in man (circularvection). Human Neurobiology 6:211–18. [aAHW, UB, TP]Google Scholar

Straube, A., Paulus, W. & Brandt, T. (1990) Influence of visual blue on object-motion detection, self-motion detection and postural balance. Behavioural Brain Research 40:1–6. [UB]Google Scholar

Suzuki, D. A. & Keller, E. L. (1988) The role of the posterior vermis of monkey cerebellum in smooth pursuit eye movement control. II. Target velocity-related Purkinje cell activity. Journal of Neurophysiology 59:19–40. [UB]Google Scholar

Swanston, M. T. & Wade, N. J. (1988) The perception of visual motion during movements of the eyes and of the head. Perception & Psychophysics 43:559–66. [aAHW, MS]Google Scholar

Swanston, M. T. & Wade, N. J. (1992a) The interaction of perceived distance with the perceived direction of visual motion during movements of the eyes and of the head. Perception & Psychophysics 52:705–13. [MS]Google Scholar

Swanston, M. T. & Wade, N. J. (1992b) Motion over the retina and the motion aftereffect. Perception 21:569–82. [MS]Google Scholar

Swanston, M. T., Wade, N. J. & Day, R. H. (1987) The representation of uniform motion in vision. Perception 16:143–60. [aAHW, MS]Google Scholar

Swanston, M. T., Wade, N. J. & Ono, H. (1990) The binocular representation of uniform motion. Perception 19:29–34. [MS]Google Scholar

Tanaka, K., Hikosaka, K., Saito, H. -A., Yukie, M., Fukada, Y. & Iwai, E. (1986) Analysis of local and wide-field movements in the superior temporal visual areas of the macaque monkey. Journal of Neuroscience 6:134–44. [FT]Google Scholar

Telford, L., Spratley, J. & Frost, B. J. (1992) Linear vection in the central visual field facilitated by kinetic depth cues. Perception 21:337–49. [XMS]Google Scholar

Thompson, S. P. (1879) Some new optical illusions. Journal of Science 9:373–74. [HER]Google Scholar

Tsai, R. Y. & Huang, T. S. (1985) Uniqueness and estimation of 3-D motion parameters and surface structures of rigid objects. In: Image understanding, ed. Richards, W. & Ullman, S.. Albex. [IH]Google Scholar

Turvey, M. T. (1992) Affordances and prospective control: An outline of the ontology. Ecological Psychology 4:173–88. [GER]Google Scholar

Tyler, C. W. & Foley, J. M. (1974) Stereomovement suppression for transient disparity changes. Perception 3(3):287–96. [BMV]Google Scholar

Ullman, S. (1980) Against direct perception. Behavioral and Brain Sciences 3:373–415. [arAHW, JRT]Google Scholar

Van de Grind, W. A., Koenderink, J. J. & van Doorn, A. J. (1992) Viewing-distance invariance of movement detection. Experimental Brain Research 91:135–50. [rAHW]Google Scholar

Velichkovsky, B. M. (1971) Autokincticheskaja illusia i intermodalnije otnoshenija v zritel'nom vosprijatii dvizhenija [Autokinetic illusion and intermodal relationships in visual perception of motion]. Ergonomika 2:182–96. [BMV]Google Scholar

Velichkovsky, B. M. (1973) O roll prostranstveimykh system otscheta v vosprijatii sobstvennugo i objectnogo dvizhenija [On the role of spatial frames of reference in perception of self-motion and object's motion]. Voprosy Psykhologii 18(2):15–26. [BMV]Google Scholar

Velichkovsky, B. M. (1982) Funktional'naja struktura perceptivnikh processov [Functional structure of perceptual processes]. In: Osnovy psykhologii: Poznavatel'nije processy, ed. Smirnov, A. A.. Pedagogika. [BMV]Google Scholar

Von Holst, E. (1954) Relations between the central nervous system and peripheral organs. British Journal of Animal Behaviour 2:89–94. [aAHW]Google Scholar

Von Holst, E. & Mittelstaedt, H. (1950) Das Reafferenzprinzip (Wechselwirkungen zwischen Zentralnervensystem und Peripherie). Naturwissenschaften 37:464–76. [aAHW, TP]Google Scholar

Von Kries, J. (1910/1962) Notes on the perception of depth. In: H. von Helmholtz, Treatise on physiological optics, vol. 3, ed. and trans., J. P. C. Southall. Dover. (Original work published in German, 1867; in English, 1925.) [GJA]Google Scholar

Wade, N. J. & Swanston, M. T. (1987) The representation of non-uniform motion: Induced movement. Perception 16:143–60. [MS]Google Scholar

Waespe, W., Büttner, U. & Henn, V. (1981) Visual-vestibular interaction in the flocculus of the alert monkey I. Input activity. Experimental Brain Research 43:336–48. [aAHW]Google Scholar

Waespe, W. & Henn, V. (1979) The velocity response of vestibular nucleus neurons during vestibular, visual and combined angular acceleration. Experimental Brain Research 37:337–47. [aAHW]Google Scholar

Waespe, W. & Henn, V. (1981) Visual-vestibular interaction in the flocculus of the alert monkey II. Purkinje cell activity. Experimental Brain Research 43:349–60. [aAHW]Google Scholar

Waespe, W. & Henn, V. (1987) Gaze stabilization in the primate. The interaction of the vestibulo-ocular reflex, optokinetic nystagmus, and smooth pursuit. Review of Physiology, Biochemistry and Pharmacology 106:37–125. [UB]Google Scholar

Wallach, H. (1959) The perception of motion. Scientific American 201:56–60. [arAHW]Google Scholar

Wallach, H. (1982) Eye movement and motion perception. In: Tutorials on motion perception, ed. Wertheim, A. H., Wagenaar, W. A. & Leibowitz, H. W.. Plenum Press. [aAHW]Google Scholar

Wallach, H. (1985) Perceiving a stable environment. Scientific American 252(4):92–98. [aAHW]Google Scholar

Wallach, H. (1987) Perceiving a stable environment when one moves. Annual Review of Psychology 38:1–27. [aAHW]Google Scholar

Wallach, H., Becklen, R. & Nitzberg, D. (1985) The perception of motion during collinear eye movements. Perception & Psychophysics 38:18–22. [aAHW]Google Scholar

Wallach, H. & Kravitz, J. H. (1965) The measurement of the constancy of visual direction and of its adaptation. Psychonomic Science 2:217–18. [aAHW]Google Scholar

Wallach, H. & Lewis, C. (1965) The effect of abnormal displacements of the retinal image during eye movements. Perception & Psychophysics 1:25–29. [AES]Google Scholar

Wallach, H. & O'Connell, D. N. (1953) The kinetic depth effect. Journal of Experimental Psychology 45:205–17. [aAHW]Google Scholar

Wallach, H., O'Leary, A. & McMahon, M. L. (1982) Three stimuli for visual motion perception compared. Perception & Psychophysics 32(1):1–6. [aAHW]Google Scholar

Walter, E. (1982) Identifiability of state space models. Lecture Notes in Biomathematics 46. Springer-Verlag. [RAMG]Google Scholar

Warren, R. (1990) Preliminary questions for the study of ego-motion. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [aAHW]Google Scholar

Warren, R. & Wertheim, A. H., eds. (1990) Perception and control of self-motion. Erlbaum. [TP]Google Scholar

Warren, W. H., Blackwell, A. W., Kurtz, K. J., Hatsopoulos, N. G. & Kalish, M. L. (1991) On the sufficiency of the velocity field for perception of heading. Biological Cybernetics 65:311–20. [N-GK]Google Scholar

Warren, W. H. & Hannon, D. J. (1988) Direction of self-motion is perceived from optical flow. Nature 336:162–63. [N-GK]Google Scholar

Warren, W. H. Jr., & Kurtz, K. J. (1992) The role of central and peripheral vision in perceiving the direction of self-motion. Perception & Psychophysics 51:443–54. [TAS]Google Scholar

Watanabe, E. (1984) Neuronal events correlated with long-term adaptation of the horizontal vestibulo-ocular reflex in the primate flocculus. Brain Research 297:169–74. [aAHW]Google Scholar

Weleh, R. B. (1986) Adaptation of space perception. In: Handbook of perception and human performance. Vol. 1: Sensory processes and perception, ed. Boff, K., Kaufman, L. & Thomas, J.. Wiley. [RH]Google Scholar

Wertheim, A. H. (1981) On the relativity of perceived motion. Acta Psychologica 48 (special volume on the perception of motion): 97–110. [aAHW]Google Scholar

Wertheim, A. H. (1985) How extraretinal is extraretinal? Perception 14(1):A8. [aAHW]Google Scholar

Wertheim, A. H. (1987) Retinal and extraretinal information in movement perception: How to invert the Filehne illusion. Perception 16(3):277–414. [arAHW, HH]Google Scholar

Wertheim, A. H. (1990) Visual, vestibular, and oculomotor interactions in the perception of object motion during ogomotion. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [TP]Google Scholar

Wertheim, A. H. (1992a) A psychophysical method to assess the gain of the otolith response. Paper presented at the satellite symposium of the 17th meeting of the Barany Society: “Vestibular-proprioceptive interaction for body orientation in space,” June, Smolenice, Czechoslovakia. [aAHW]Google Scholar

Wertheim, A. H. (1992b) Motion perception during ego-motion: Measuring the otolith response. Perception 21(supp. 2):49–50. [aAHW]Google Scholar

Wertheim, A. H. (1993) Pilot studies on object motion perception during linear self-motion after long duration centrifugation of human subjects. Institute for Perception Technical Report IZF-1993-B-3. TNO Institute for Perception, Soesterberg, The Netherlands. [aAHW]Google Scholar

Wertheim, A. H. & Bekkering, H. (1991) The Filehne illusion is age dependent. Perception 20(1):85–86. [aAHW]Google Scholar

Wertheim, A. H. & Bekkering, H. (1992) Motion thresholds of briefly visible stimuli increase asymmetrically with age. Vision Research 32(12):2379–84. [aAHW]Google Scholar

Wertheim, A. H. & Bles, W. (1984) A reevaluation of cancellation theory: Visual, vestibular and oculomotor contributions to perceived object motion. Institute for Perception Technical Report IZF-1984–8. TNO Institute for Perception, Soesterberg, The Netherlands. [aAHW, HH]Google Scholar

Wertheim, A. H., Hosman, R. J. A. W., de Graaf, B., Bles, W. & Krol, J. R. (1989) Visual motion perception during simulated space sickness on earth. Proceedings of the 15th annual meeting of the European Undersea Biomedical Society, Eilat, Israel. [aAHW]Google Scholar

Wertheim, A. H. & Mesland, B. (1993) Motion perception during linear ego-motion. Institute for Perception Technical Report 1ZF-1993–3. TNO Institute for Perception, Soesterberg, The Netherlands. [aAHW]Google Scholar

Wertheim, A. H. & Niessen, M. W. (1986) The perception of relative motion between objects during pursuit eye movements. Perception 15(1):49. [aAHW]Google Scholar

Wertheim, A. H. & Van Gelder, P. (1990) An acceleration illusion caused by underestimation of stimulus velocity during pursuit eye movements: The Aubert-Fleischl phenomenon revisited. Perception 19(4):471–82 (erratum in: Perception 19(5):700. [aAHW]Google Scholar

Wertheim, A. H., Van Gelder, P., Lautin, A., Peselow, E. & Cohen, N. (1985) High thresholds for motion perception in schizophrenia may indicate extraneous noise levels of central vestibular activity. Biological Psychiatry 20:1197–1210. [arAHW]Google Scholar

Whiteside, T. C. D., Graybiel, A. & Niven, J. I. (1965) Visual illusions of movement. Brain 88:13–210. [aAHW]Google Scholar

Wist, E. R., Diener, H. C. & Dichgans, J. (1976) Motion constancy dependent upon perceived distance and spatial frequency of the stimulus pattern. Perception & Psychophysics 19(6):485–91. [rAHW]Google Scholar

Wist, E. R., Diener, H. C., Dichgans, J. & Brandt, T. (1975) Perceived distance and the perceived speed of self-motion: Linear versus angular velocity? Perception & Psychophysics 17:545–54. [UB]Google Scholar

Wolpert, L. (1990) Field-of-view information for self-motion perception. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [aAHW]Google Scholar

Wong, S. C. P. & Frost, B. F. (1978) Subjective motion and acceleration induced by the movement of the observer's entire visual field. Perception & Psychophysics 24(2):115–20. [aAHW]Google Scholar

Wurtz, R. H. (1969) Comparison of effects of eye movements and stimulus movements on striate cortex neurons of the monkey. Journal of Neurophysiology 32:987–94. [PT]Google Scholar

Wurtz, R. H. & Duffy, C. J. (1992) Neuronal correlates of optic flow stimulation. Annals of the New York Academy of Sciences 656:205–19. [XMS]Google Scholar

Xerri, C., Barthélémy, F., Borel, L. & Lacour, M. (1988) Neuronal coding of linear motion in the vestibular nuclei of the alert cat. III: Dynamic characteristics of visual-otolith interactions. Experimental Brain Research 70:299–309. [aAHW]Google Scholar

Xerri, C., Barthélémy, F., Harlay, F., Borel, L. & Lacour, M. (1987) Neuronal coding of linear motion in the vestibular nuclei of the alert cat. I: Response characteristics to vertical otolith stimulation. Experimental Brain Research 65:569–81. [aAHW]Google Scholar

Yardley, L. (1992) Motion sickness and perception: A reappraisal of the sensory conflict approach. British Journal of Psychology 83:449–71. [LY]Google Scholar

Yoshida, K., Berthoz, A., Vidal, P. P. & McCrea, R. (1981) Eye movement-related activity of identified second order vestibular neurons in the cat. In: Progress in oculomotor research, ed. Fuchs, A. F. & Becker, W.. Elsevier, North-Holland. [aAHW]Google Scholar

Young, L. (1985) Adaptation to modified otolith input. In: Adaptive mechanisms in gaze control, ed. Berthoz, A. & Melvill-Jones, G.. Elsevier. [AAS]Google Scholar

Young, L. R. & Shelhamer, M. (1990) Weightlessness enhances the relative contribution of visually-induced self-motion. In: Perception and control of self-motion, ed. Warren, R. & Wertheim, A. H.. Erlbaum. [HER]Google Scholar

Zacharias, G. L. & Young, L. R. (1981) Influence of combined visual and vestibular cues on human perception and control of horizontal rotation. Experimental Brain Research 41:159–71. [WB]Google Scholar

Zeppenfeldt, P. (1991) Bepaling van de drempelwaarden voor het waarnemen van verschillen tussen visuele en vestibulaire stimulatie tijdens eigenbeweging [Determination of thresholds for the detection of differences between visual and vestibular stimulation]. Thesis, Technical University of Delft, The Netherlands. [aAHW]Google Scholar

Zinchenko, V. P. & Vergiles, N. Yu. (1972) Formation of visual images: Studies of stabilized images. Consultants Bureau, Plenum Press. [VIB]Google Scholar

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The illusion of self-motion in virtual reality environments

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