Rolling Motion Along an Incline: Visual Sensitivity to the Relation Between Acceleration and Slope

People easily intercept a ball rolling down an incline, despite its acceleration varies with the slope in a complex manner. Apparently, however, they are poor at detecting anomalies when asked to judge artificial animations of descending motion. Since the perceptual deficiencies have been reported in studies involving a limited visual context, here we tested the hypothesis that judgments of naturalness of rolling motion are consistent with physics when the visual scene incorporates sufficient cues about environmental reference and metric scale, roughly comparable to those present when intercepting a ball. Participants viewed a sphere rolling down an incline located in the median sagittal plane, presented in 3D wide-field virtual reality. In different experiments, either the slope of the plane or the sphere acceleration were changed in arbitrary combinations, resulting in a kinematics that was either consistent or inconsistent with physics. In Experiment 1 (slope adjustment), participants were asked to modify the slope angle until the resulting motion looked natural for a given ball acceleration. In Experiment 2 (acceleration adjustment), instead, they were asked to modify the acceleration until the motion on a given slope looked natural. No feedback about performance was provided. For both experiments, we found that participants were rather accurate at finding the match between slope angle and ball acceleration congruent with physics, but there was a systematic effect of the initial conditions: accuracy was higher when the participants started the exploration from the combination of slope and acceleration corresponding to the congruent conditions than when they started far away from the congruent conditions. In Experiment 3, participants modified the slope angle based on an adaptive staircase, but the target never coincided with the starting condition. Here we found a generally accurate performance, irrespective of the target slope. We suggest that, provided the visual scene includes sufficient cues about environmental reference and metric scale, joint processing of slope and acceleration may facilitate the detection of natural motion. Perception of rolling motion may rely on the kind of approximate, probabilistic simulations of Newtonian mechanics that have previously been called into play to explain complex inferences in rich visual scenes.

[1]  Mehrdad Jazayeri,et al.  Integration of speed and time for estimating time to contact , 2018, Proceedings of the National Academy of Sciences.

[2]  A. d’Avella,et al.  Intercepting virtual balls approaching under different gravity conditions: evidence for spatial prediction. , 2017, Journal of neurophysiology.

[3]  Jessica B. Hamrick,et al.  Inferring mass in complex scenes by mental simulation , 2016, Cognition.

[4]  S. C. Masin The Cognitive and Perceptual Laws of the Inclined Plane. , 2016, The American journal of psychology.

[5]  Y. Koike,et al.  Individualistic weight perception from motion on a slope , 2016, Scientific Reports.

[6]  Alexandra S. Mueller,et al.  Visual Acceleration Perception for Simple and Complex Motion Patterns , 2016, PloS one.

[7]  Francesco Lacquaniti,et al.  Hand interception of occluded motion in humans: a test of model-based vs. on-line control. , 2015, Journal of neurophysiology.

[8]  Francesco Lacquaniti,et al.  Familiar trajectories facilitate the interpretation of physical forces when intercepting a moving target , 2014, Experimental Brain Research.

[9]  Francesco Lacquaniti,et al.  Neural Extrapolation of Motion for a Ball Rolling Down an Inclined Plane , 2014, PloS one.

[10]  Heiko Hecht,et al.  Slope estimation and viewing distance of the observer , 2014, Attention, Perception, & Psychophysics.

[11]  Jessica B. Hamrick,et al.  Simulation as an engine of physical scene understanding , 2013, Proceedings of the National Academy of Sciences.

[12]  Vikash K. Mansinghka,et al.  Reconciling intuitive physics and Newtonian mechanics for colliding objects. , 2013, Psychological review.

[13]  Dirk Kerzel,et al.  Like a rolling stone: naturalistic visual kinematics facilitate tracking eye movements. , 2013, Journal of vision.

[14]  Alessandro Moscatelli,et al.  Modeling psychophysical data at the population-level: the generalized linear mixed model. , 2012, Journal of vision.

[15]  P. White,et al.  The experience of force: the role of haptic experience of forces in visual perception of object motion and interactions, mental simulation, and motion-related judgments. , 2012, Psychological bulletin.

[16]  Francesco Lacquaniti,et al.  Coherence of structural visual cues and pictorial gravity paves the way for interceptive actions. , 2011, Journal of vision.

[17]  Frank H Durgin,et al.  Perceptual scale expansion: an efficient angular coding strategy for locomotor space , 2011, Attention, perception & psychophysics.

[18]  F. Lacquaniti,et al.  The weight of time: gravitational force enhances discrimination of visual motion duration. , 2011, Journal of vision.

[19]  Frank H Durgin,et al.  Perceived slant of binocularly viewed large-scale surfaces: a common model from explicit and implicit measures. , 2010, Journal of vision.

[20]  Massimo Bergamasco,et al.  A Flexible Framework for WideSpectrum VR Development , 2010, PRESENCE: Teleoperators and Virtual Environments.

[21]  Vincenzo Maffei,et al.  Extrapolation of vertical target motion through a brief visual occlusion , 2010, Experimental Brain Research.

[22]  B. Gillam,et al.  Stereoscopic discrimination of the layout of ground surfaces. , 2009, Journal of vision.

[23]  D. Proffitt Affordances matter in geographical slant perception , 2009, Psychonomic bulletin & review.

[24]  M. Begg An introduction to categorical data analysis (2nd edn). Alan Agresti, John Wiley & Sons, Inc., Hoboken, New Jersey, 2007. No. of Pages: 400. Price: $100.95. ISBN: 978‐0‐471‐22618‐5 , 2009 .

[25]  Florence Rosey,et al.  Precocity of Fine Motor Control and Task Context: Hitting a Ball While Stepping , 2008, Journal of motor behavior.

[26]  F. Lacquaniti,et al.  Internal models and prediction of visual gravitational motion , 2008, Vision Research.

[27]  Bruce Bridgeman,et al.  Processing Spatial Layout by Perception and Sensorimotor Interaction , 2008, Quarterly journal of experimental psychology.

[28]  Vincenzo Maffei,et al.  Vestibular nuclei and cerebellum put visual gravitational motion in context. , 2008, Journal of neurophysiology.

[29]  Maggie Shiffrar,et al.  Rolling Perception without Rolling Motion , 2008, Perception.

[30]  F. Lacquaniti,et al.  Cognitive, perceptual and action-oriented representations of falling objects , 2005, Neuropsychologia.

[31]  Francesco Lacquaniti,et al.  Anticipating the effects of gravity when intercepting moving objects: differentiating up and down based on nonvisual cues. , 2005, Journal of neurophysiology.

[32]  F. Lacquaniti,et al.  Fast adaptation of the internal model of gravity for manual interceptions: evidence for event-dependent learning. , 2005, Journal of neurophysiology.

[33]  Randolph Blake,et al.  Physics embedded in visual perception of three-dimensional shape from motion , 2004, Nature Neuroscience.

[34]  M. Bar Visual objects in context , 2004, Nature Reviews Neuroscience.

[35]  F. Lacquaniti,et al.  Internal models of target motion: expected dynamics overrides measured kinematics in timing manual interceptions. , 2004, Journal of neurophysiology.

[36]  Stephen J Heinen,et al.  Perceptual and oculomotor evidence of limitations on processing accelerating motion. , 2003, Journal of vision.

[37]  D. Rohrer The natural appearance of unnatural incline speed , 2003, Memory & cognition.

[38]  D. Rohrer Misconceptions about incline speed for nonlinear slopes. , 2002, Journal of experimental psychology. Human perception and performance.

[39]  Anne-Marie Brouwer,et al.  Perception of acceleration with short presentation times: Can acceleration be used in interception? , 2001, Perception & psychophysics.

[40]  F. Lacquaniti,et al.  Does the brain model Newton's laws? , 2001, Nature Neuroscience.

[41]  C. Michaels,et al.  Information and action in punching a falling ball , 2001, The Quarterly journal of experimental psychology. A, Human experimental psychology.

[42]  D. Proffitt,et al.  Visual-motor recalibration in geographical slant perception. , 1999, Journal of experimental psychology. Human perception and performance.

[43]  F Lacquaniti,et al.  Virtual reality: a tutorial. , 1998, Electroencephalography and clinical neurophysiology.

[44]  Hartwig K. Distler,et al.  Velocity Constancy in a Virtual Reality Environment , 1997, Perception.

[45]  P Viviani,et al.  The Relationship between Curvature and Velocity in Two-Dimensional Smooth Pursuit Eye Movements , 1997, The Journal of Neuroscience.

[46]  Rich Gossweiler,et al.  Perceiving geographical slant , 1995, Psychonomic bulletin & review.

[47]  M. Arbib,et al.  Grasping objects: the cortical mechanisms of visuomotor transformation , 1995, Trends in Neurosciences.

[48]  H. Hecht Judging Rolling Wheels: Dynamic and Kinematic Aspects of Rotation – Translation Coupling , 1993, Perception.

[49]  P. Werkhoven,et al.  Visual processing of optic acceleration , 1992, Vision Research.

[50]  M. Goodale,et al.  Separate visual pathways for perception and action , 1992, Trends in Neurosciences.

[51]  P R DeLucia,et al.  Pictorial and motion-based information for depth perception. , 1991, Journal of experimental psychology. Human perception and performance.

[52]  D. Proffitt,et al.  Understanding wheel dynamics , 1990, Cognitive Psychology.

[53]  P Bressan,et al.  Wheels: A New Illusion in the Perception of Rolling Objects , 1990, Perception.

[54]  D. Proffitt,et al.  Understanding natural dynamics. , 1989, Journal of experimental psychology. Human perception and performance.

[55]  F. Lacquaniti,et al.  The role of preparation in tuning anticipatory and reflex responses during catching , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[56]  David N. Lee,et al.  Visual Timing in Hitting An Accelerating Ball , 1983, The Quarterly journal of experimental psychology. A, Human experimental psychology.

[57]  Richard Kammann,et al.  The overestimation of vertical distance and slope and its role in the moon illusion , 1967 .

[58]  M. M. Taylor,et al.  PEST: Efficient Estimates on Probability Functions , 1967 .

[59]  R. Gottsdanker,et al.  Identifying the acceleration of visual targets. , 1961, British journal of psychology.

[60]  G. Hirt,et al.  Rolling , 2019, CIRP Encyclopedia of Production Engineering.

[61]  Jessika Weiss,et al.  Vision Science Photons To Phenomenology , 2016 .

[62]  F. Lacquaniti,et al.  Gravity in the Brain as a Reference for Space and Time Perception. , 2015, Multisensory research.

[63]  Mary Hayhoe,et al.  Saccades to future ball location reveal memory-based prediction in a virtual-reality interception task. , 2013, Journal of vision.

[64]  Marius Usher,et al.  Disentangling decision models: from independence to competition. , 2013, Psychological review.

[65]  D. Vercelli,et al.  A Flexible Framework for Wide-Spectrum VR Development , 2010 .

[66]  A. Mizuno,et al.  A change of the leading player in flow Visualization technique , 2006, J. Vis..

[67]  T. Albright,et al.  Contextual influences on visual processing. , 2002, Annual review of neuroscience.

[68]  J. Tresilian,et al.  Perceptual and cognitive processes in time-to-contact estimation: Analysis of prediction-motion and relative judgment tasks , 1995, Perception & psychophysics.

[69]  A. Agresti An introduction to categorical data analysis , 1997 .

[70]  M K Kaiser,et al.  Visual acceleration detection: Effect of sign and motion orientation , 1989, Perception & psychophysics.

[71]  M. McCloskey,et al.  Naive physics: the curvilinear impetus principle and its role in interactions with moving objects. , 1983, Journal of experimental psychology. Learning, memory, and cognition.

[72]  J. Gibson The Ecological Approach to Visual Perception , 1979 .

[73]  J. Tresilian,et al.  a moving target: effects of temporal precision constraints and movement amplitude , 2022 .

[74]  E. Keshner,et al.  Journal of Neuroengineering and Rehabilitation Virtual Reality and Physical Rehabilitation: a New Toy or a New Research and Rehabilitation Tool? Prevalence of Virtual Reality Technology , 2022 .