Does Perceptual-Motor Calibration Generalize across Two Different Forms of Locomotion? Investigations of Walking and Wheelchairs

The relationship between biomechanical action and perception of self-motion during walking is typically consistent and well-learned but also adaptable. This perceptual-motor coupling can be recalibrated by creating a mismatch between the visual information for self-motion and walking speed. Perceptual-motor recalibration of locomotion has been demonstrated through effects on subsequent walking without vision, showing that learned perceptual-motor coupling influences a dynamic representation of one's spatial position during walking. Our present studies test whether recalibration of wheelchair locomotion, a novel form of locomotion for typically walking individuals, similarly influences subsequent wheelchair locomotion. Furthermore, we test whether adaptation to the pairing of visual information for self-motion during one form of locomotion transfers to a different locomotion modality. We find strong effects of perceptual-motor recalibration for matched locomotion modalities – walking/walking and wheeling/wheeling. Transfer across incongruent locomotion modalities showed weak recalibration effects. The results have implications both for theories of perceptual-motor calibration mechanisms and their effects on spatial orientation, as well as for practical applications in training and rehabilitation.

[1]  William B. Thompson,et al.  Recalibration of rotational locomotion in immersive virtual environments , 2008, TAP.

[2]  Anne E. Garing,et al.  Calibration of human locomotion and models of perceptual-motor organization. , 1995, Journal of experimental psychology. Human perception and performance.

[3]  R. J. van Beers,et al.  Integration of proprioceptive and visual position-information: An experimentally supported model. , 1999, Journal of neurophysiology.

[4]  David Waller,et al.  Correcting distance estimates by interacting with immersive virtual environments: effects of task and available sensory information. , 2008, Journal of experimental psychology. Applied.

[5]  T F Shipley,et al.  Prism adaptation to dynamic events , 1999, Perception & psychophysics.

[6]  Betty J. Mohler,et al.  Calibration of locomotion resulting from visual motion in a treadmill-based virtual environment , 2007, TAP.

[7]  G. Courtine,et al.  Asymmetrical after-effects of prism adaptation during goal oriented locomotion , 2008, Experimental Brain Research.

[8]  Frank H. Durgin,et al.  Not Letting the Left Leg Know What the Right Leg is Doing , 2003, Psychological science.

[9]  Timothy P. McNamara,et al.  Updating orientation in large virtual environments using scaled translational gain , 2006, APGV '06.

[10]  D. Wolpert,et al.  When Feeling Is More Important Than Seeing in Sensorimotor Adaptation , 2002, Current Biology.

[11]  Brett R. Fajen,et al.  Affordance-Based Control of Visually Guided Action , 2007 .

[12]  Anthony M. Avolio,et al.  Walking infants adapt locomotion to changing body dimensions. , 2000, Journal of experimental psychology. Human perception and performance.

[13]  M. Ernst,et al.  The statistical determinants of adaptation rate in human reaching. , 2008, Journal of vision.

[14]  Moira B. Flanagan,et al.  Movement in the Perception of an Affordance for Wheelchair Locomotion , 2009 .

[15]  Brett R. Fajen,et al.  Rapid recalibration based on optic flow in visually guided action , 2007, Experimental Brain Research.

[16]  Adar Pelah,et al.  Visuomotor adaptation without vision? , 1999, Experimental Brain Research.

[17]  G J Savelsbergh,et al.  Locomoting through apertures of different width: a study of children with cerebral palsy. , 1998, Pediatric rehabilitation.

[18]  Betty J. Mohler,et al.  The influence of feedback on egocentric distance judgments in real and virtual environments , 2006, APGV '06.

[19]  Takahiro Higuchi,et al.  Visual estimation of spatial requirements for locomotion in novice wheelchair users. , 2004, Journal of experimental psychology. Applied.

[20]  Jack M. Loomis,et al.  Measuring Spatial Perception with Spatial Updating and Action , 2008 .

[21]  Betty J. Mohler,et al.  The effect of feedback within a virtual environment on human distance perception and adaptation , 2007 .

[22]  Sarah H. Creem-Regehr,et al.  Evidence for motor simulation in imagined locomotion. , 2009, Journal of experimental psychology. Human perception and performance.

[23]  A. Yuille,et al.  Opinion TRENDS in Cognitive Sciences Vol.10 No.7 July 2006 Special Issue: Probabilistic models of cognition Vision as Bayesian inference: analysis by synthesis? , 2022 .

[24]  Paul R. Schrater,et al.  How Optimal Depth Cue Integration Depends on the Task , 2000, International Journal of Computer Vision.

[25]  William H Warren,et al.  The Direction of Walking—but Not Throwing or Kicking—Is Adapted by Optic Flow , 2010, Psychological science.

[26]  S. M. Morton,et al.  Prism adaptation during walking generalizes to reaching and requires the cerebellum. , 2004, Journal of neurophysiology.

[27]  Betty J. Mohler,et al.  Visual motion influences locomotion in a treadmill virtual environment , 2004, APGV '04.

[28]  M. Landy,et al.  Measurement and modeling of depth cue combination: in defense of weak fusion , 1995, Vision Research.

[29]  L. Kaufman,et al.  Handbook of perception and human performance , 1986 .

[30]  Laura F. Fox,et al.  Self-motion perception during locomotor recalibration: more than meets the eye. , 2005, Journal of experimental psychology. Human perception and performance.

[31]  John J. Rieser,et al.  The recalibration of rotational locomotion , 1999 .

[32]  Victoria Interrante,et al.  Seven League Boots: A New Metaphor for Augmented Locomotion through Moderately Large Scale Immersive Virtual Environments , 2007, 2007 IEEE Symposium on 3D User Interfaces.

[33]  M. Ernst,et al.  Humans integrate visual and haptic information in a statistically optimal fashion , 2002, Nature.

[34]  Gordon M. Redding,et al.  Applications of prism adaptation: a tutorial in theory and method , 2005, Neuroscience & Biobehavioral Reviews.

[35]  William B. Thompson,et al.  HMD calibration and its effects on distance judgments , 2008, APGV '08.

[36]  David Waller,et al.  Interaction With an Immersive Virtual Environment Corrects Users' Distance Estimates , 2007, Hum. Factors.

[37]  J. Philbeck,et al.  Progressive locomotor recalibration during blind walking , 2008, Perception & psychophysics.

[38]  W. T. Thach,et al.  Throwing while looking through prisms. II. Specificity and storage of multiple gaze-throw calibrations. , 1996, Brain : a journal of neurology.

[39]  Konrad Paul Kording,et al.  Bayesian integration in sensorimotor learning , 2004, Nature.

[40]  Rob Withagen,et al.  The Calibration of Walking Transfers to Crawling: Are Action Systems Calibrated? , 2002 .

[41]  Daniel M Wolpert,et al.  Adaptation to a visuomotor shift depends on the starting posture. , 2002, Journal of neurophysiology.

[42]  J. Loomis,et al.  Visual space perception and visually directed action. , 1992, Journal of experimental psychology. Human perception and performance.

[43]  Ajitkumar P. Mulavara,et al.  Locomotor function after long-duration space flight: effects and motor learning during recovery , 2010, Experimental Brain Research.