Abstract

Smooth pursuit eye movements (pursuit) are used to minimize the retinal motion of moving objects. During pursuit, the pattern of motion on the retina carries not only information about the object movement but also reafferent information about the eye movement itself. The latter arises from the retinal flow of the stationary world in the direction opposite to the eye movement. To extract the global direction of motion of the tracked object and stationary world, the visual system needs to integrate ambiguous local motion measurements (i.e., the aperture problem). Unlike the tracked object, the stationary world's global motion is entirely determined by the eye movement and thus can be approximately derived from motor commands sent to the eye (i.e., from an efference copy). Because retinal motion opposite to the eye movement is dominant during pursuit, different motion integration mechanisms might be used for retinal motion in the same direction and opposite to pursuit. To investigate motion integration during pursuit, we tested direction discrimination of a brief change in global object motion. The global motion stimulus was a circular array of small static apertures within which one-dimensional gratings moved. We found increased coherence thresholds and a qualitatively different reflexive ocular tracking for global motion opposite to pursuit. Both effects suggest reduced sampling of motion opposite to pursuit, which results in an impaired ability to extract coherence in motion signals in the reafferent direction. We suggest that anisotropic motion integration is an adaptation to asymmetric retinal motion patterns experienced during pursuit eye movements. NEW & NOTEWORTHY This study provides a new understanding of how the visual system achieves coherent perception of an object's motion while the eyes themselves are moving. The visual system integrates local motion measurements to create a coherent percept of object motion. An analysis of perceptual judgments and reflexive eye movements to a brief change in an object's global motion confirms that the visual and oculomotor systems pick fewer samples to extract global motion opposite to the eye movement.

Highlights

  • During tracking of a moving object, smooth pursuit eye movements are used to reduce motion blur by minimizing the object movement on the retina

  • We tested the ability to discriminate the direction of global motion depending on coherence and eye movement condition

  • The global motion stimulus in pursuit and fixation conditions are shown in Fig. 1, B and D

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Summary

Introduction

During tracking of a moving object, smooth pursuit eye movements (pursuit for short) are used to reduce motion blur by minimizing the object movement on the retina. Previous research comparing motion coherence during pursuit and fixation indicates a perceptual bias during pursuit toward attributing the eye movement-induced (reafferent) motion to a single coherent object, even when the stimulation is compatible with a two-object interpretation (Hafed and Krauzlis 2006). This bias could reflect perceptual priors about the stability of the world during eye movements (Wexler et al 2001), rather than the ability to integrate motion and solve the aperture problem during pursuit

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