Abstract
We examine the structure of the visual motion projected on the retina during natural locomotion in real world environments. Bipedal gait generates a complex, rhythmic pattern of head translation and rotation in space, so without gaze stabilization mechanisms such as the vestibular-ocular-reflex (VOR) a walker's visually specified heading would vary dramatically throughout the gait cycle. The act of fixation on stable points in the environment nulls image motion at the fovea, resulting in stable patterns of outflow on the retinae centered on the point of fixation. These outflowing patterns retain a higher order structure that is informative about the stabilized trajectory of the eye through space. We measure this structure by applying the curl and divergence operations on the retinal flow velocity vector fields and found features that may be valuable for the control of locomotion. In particular, the sign and magnitude of foveal curl in retinal flow specifies the body's trajectory relative to the gaze point, while the point of maximum divergence in the retinal flow field specifies the walker's instantaneous overground velocity/momentum vector in retinotopic coordinates. Assuming that walkers can determine the body position relative to gaze direction, these time-varying retinotopic cues for the body's momentum could provide a visual control signal for locomotion over complex terrain. In contrast, the temporal variation of the eye-movement-free, head-centered flow fields is large enough to be problematic for use in steering towards a goal. Consideration of optic flow in the context of real-world locomotion therefore suggests a re-evaluation of the role of optic flow in the control of action during natural behavior.
Highlights
IntroductionAccurate vision is predicated on fixation [1]. Vertebrate photoreceptors are relatively slow, with cones taking up to 20 ms to respond to changes in light intensity [2]
Sighted animals must stabilize their eyes relative to the external world to resolve an image that may be used for the control of action. This may be the reason that most vertebrates utilize a “saccade and fixate” strategy whereby gaze is rapidly moved to a new location and kept stable by way of a gaze stabilization reflexes such as the vestibular ocular reflex (VOR) e.g. [3]
We show that the the point of maximum divergence is a reliable feature of fixation-mediated retinal optic flow that appears to encode behaviorally relevant information that could be valuable for the control of locomotion
Summary
Accurate vision is predicated on fixation [1]. Vertebrate photoreceptors are relatively slow, with cones taking up to 20 ms to respond to changes in light intensity [2]. Sighted animals must stabilize their eyes relative to the external world to resolve an image that may be used for the control of action This may be the reason that most vertebrates utilize a “saccade and fixate” strategy whereby gaze is rapidly moved to a new location and kept stable by way of a gaze stabilization reflexes such as the vestibular ocular reflex (VOR) e.g. These gaze stabilization mechanisms are phylogenically ancient, with evidence for compensatory eye movements stretching back to the origin of bony fish approximately 450 million years ago [1, 4] This oculomotor strategy, along with the highly foveated nature of the primate visual system, suggests that the input to the visual system is structured by our ability to rapidly direct gaze to points of interest in the world and fixate that point as we move our bodies through the world
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