| Abstract: | Investigated temporal factors in vision in relation to the delay of the retinal feedback of ocular movements in eye tracking. A hybrid real-time computer system and dynamic programing methods were used to calibrate photoelectric eye-movement transducers in viewing visual targets, to yoke these targets to eye motion, to introduce feedback delays in eye-movement-retinal interaction, and to measure error in eye tracking. Results indicate that feedback delay affected the accuracy of both the compensatory and the pursuit tracking in a significant way, with a somewhat greater effect being found for pursuit movements. Since delay reduced smooth pursuit motions to saccadic reactions that varied in size with the delay interval, it is suggested that ocular dynamics and guidance in space perception are governed by time-specific neuron mechanisms of the central visual system. Findings negate classical theory of ocular dynamics and perception of direction by proving that directional guidance of the eyes is determined by directional specificity and temporal specificity of the feedback processes of pursuit and saccadic movements of the eyes and is not caused primarily by learned temporal association between visual and tactual sensory processes. It is concluded that major disabilities and distortions in vision, which are not reducible to traditionally defined optometric and ophthalmologic factors, may be produced by built-in developmental perturbations of ocular feedback timing. Findings emphasize dynamic optometric measurements in understanding common and elusive distortions of visual perception. (19 ref.) (PsycINFO Database Record (c) 2010 APA, all rights reserved) |
