Visual Neuroscience



Motion direction signals in the primary visual cortex of cat and monkey


WILSON S.  GEISLER a1c1, DUANE G.  ALBRECHT a1, ALISON M.  CRANE a1 and LAWRENCE  STERN a1
a1 Department of Psychology and Center for Vision and Image Sciences, University of Texas, Austin

Abstract

When an image feature moves with sufficient speed it should become smeared across space, due to temporal integration in the visual system, effectively creating a spatial motion pattern that is oriented in the direction of the motion. Recent psychophysical evidence shows that such “motion streak signals” exist in the human visual system. In this study, we report neurophysiological evidence that these motion streak signals also exist in the primary visual cortex of cat and monkey. Single neuron responses were recorded for two kinds of moving stimuli: single spots presented at different velocities and drifting plaid patterns presented at different spatial and temporal frequencies. Measurements were made for motion perpendicular to the spatial orientation of the receptive field (“perpendicular motion”) and for motion parallel to the spatial orientation of the receptive field (“parallel motion”). For moving spot stimuli, as the speed increases, the ratio of the responses to parallel versus perpendicular motion increases, and above some critical speed, the response to parallel motion exceeds the response to perpendicular motion. For moving plaid patterns, the average temporal tuning function is approximately the same for both parallel motion and perpendicular motion; in contrast, the spatial tuning function is quite different for parallel motion and perpendicular motion (band pass for the former and low pass for the latter). In general, the responses to spots and plaids are consistent with the conventional model of cortical neurons with one rather surprising exception: Many cortical neurons appear to be direction selective for parallel motion. We propose a simple explanation for “parallel motion direction selectivity” and discuss its implications for the motion streak hypothesis. Taken as a whole, we find that the measured response properties of cortical neurons to moving spot and plaid patterns agree with the recent psychophysics and support the hypothesis that motion streak signals are present in V1.

(Received July 27 2000)
(Accepted March 28 2001)


Key Words: Visual cortex; Receptive fields; Motion; Direction Selectivity.

Correspondence:
c1 Address correspondence and reprint requests to: Wilson S. Geisler, Department of Psychology, Center for Vision and Image Sciences, University of Texas, Austin, TX 78712.