Synchronized Audio-Visual Transients Drive Efficient Visual Search for Motion-in-Depth

In natural audio-visual environments, a change in depth is usually correlated with a change in loudness. In the present study, we investigated whether correlating changes in disparity and loudness would provide a functional advantage in binding disparity and sound amplitude in a visual search paradigm. To test this hypothesis, we used a method similar to that used by van der Burg et al. to show that non-spatial transient (square-wave) modulations of loudness can drastically improve spatial visual search for a correlated luminance modulation. We used dynamic random-dot stereogram displays to produce pure disparity modulations. Target and distractors were small disparity-defined squares (either 6 or 10 in total). Each square moved back and forth in depth in front of the background plane at different phases. The target’s depth modulation was synchronized with an amplitude-modulated auditory tone. Visual and auditory modulations were always congruent (both sine-wave or square-wave). In a speeded search task, five observers were asked to identify the target as quickly as possible. Results show a significant improvement in visual search times in the square-wave condition compared to the sine condition, suggesting that transient auditory information can efficiently drive visual search in the disparity domain. In a second experiment, participants performed the same task in the absence of sound and showed a clear set-size effect in both modulation conditions. In a third experiment, we correlated the sound with a distractor instead of the target. This produced longer search times, indicating that the correlation is not easily ignored.

[1]  M. Schwab,et al.  Neurite growth inhibitors restrict plasticity and functional recovery following corticospinal tract lesions , 1998, Nature Neuroscience.

[2]  D H Brainard,et al.  The Psychophysics Toolbox. , 1997, Spatial vision.

[3]  A. Parker,et al.  Neuronal Computation of Disparity in V1 Limits Temporal Resolution for Detecting Disparity Modulation , 2005, Journal of Neuroscience.

[4]  Leland S Stone,et al.  Spatial scale of stereomotion speed processing. , 2006, Journal of vision.

[5]  Scott N. J. Watamaniuk,et al.  Visual search for motion-in-depth: stereomotion does not 'pop out' from disparity noise , 1998, Nature Neuroscience.

[6]  Michael T. Lippert,et al.  Improvement of visual contrast detection by a simultaneous sound , 2007, Brain Research.

[7]  D. Alais,et al.  Efficient Visual Search from Synchronized Auditory Signals Requires Transient Audiovisual Events , 2010, PLoS ONE.

[8]  Jan Theeuwes,et al.  Early multisensory interactions affect the competition among multiple visual objects , 2011, NeuroImage.

[9]  D G Pelli,et al.  The VideoToolbox software for visual psychophysics: transforming numbers into movies. , 1997, Spatial vision.

[10]  D Marr,et al.  Cooperative computation of stereo disparity. , 1976, Science.

[11]  Ken Nakayama,et al.  Serial and parallel processing of visual feature conjunctions , 1986, Nature.

[12]  M. Posner,et al.  Orienting of Attention* , 1980, The Quarterly journal of experimental psychology.

[13]  P. Mamassian,et al.  Audiovisual integration of stimulus transients , 2008, Vision Research.

[14]  Robert S. Allison,et al.  The Effect of Crosstalk on the Perceived Depth From Disparity and Monocular Occlusions , 2011, IEEE Transactions on Broadcasting.

[15]  U. Neisser VISUAL SEARCH. , 1964, Scientific American.

[16]  Ning Qian,et al.  Solving da Vinci stereopsis with depth-edge-selective V2 cells , 2007, Vision Research.

[17]  J. Driver,et al.  Sound-Induced Enhancement of Low-Intensity Vision: Multisensory Influences on Human Sensory-Specific Cortices and Thalamic Bodies Relate to Perceptual Enhancement of Visual Detection Sensitivity , 2010, The Journal of Neuroscience.

[18]  Jan Theeuwes,et al.  Pip and pop: nonspatial auditory signals improve spatial visual search. , 2008, Journal of experimental psychology. Human perception and performance.

[19]  Julie M. Harris,et al.  Binocular vision and motion-in-depth. , 2008, Spatial vision.

[20]  A. Treisman,et al.  A feature-integration theory of attention , 1980, Cognitive Psychology.