Your search keyword '"Retinal image motion"' showing total 3 results

1. Motion deblurring during pursuit tracking improves spatial-interval acuity

Author

Harold E. Bedell, Michael J. Moulder, and Jin Qian

Subjects

Adult, Male, Deblurring, Visual acuity, genetic structures, Motion Perception, Visual Acuity, Pursuit eye movement, Motion smear, Smooth pursuit, Standard deviation, Article, Young Adult, Optics, medicine, Separation discrimination, Humans, Computer vision, Motion perception, Mathematics, Analysis of Variance, business.industry, Motion blur, Eye movement, Middle Aged, Retinal image motion, eye diseases, Pursuit, Smooth, Sensory Systems, Ophthalmology, Motion deblurring, Space Perception, Fixation (visual), Spatial-interval acuity, Female, Artificial intelligence, sense organs, medicine.symptom, business, Photic Stimulation

Abstract

The extent of perceived blur produced by a moving retinal image is less when the image motion occurs during pursuit eye movements compared to fixation. This study examined the effect of this reduced perception of motion blur during pursuit on spatial-interval acuity. Observers judged during pursuit at 4 or 8deg/s whether the horizontal separation between two stationary lines was larger or smaller than a standard. Three different line separations were tested for each pursuit velocity. Each observer performed these judgments also during fixation, for spatial-interval stimuli that moved with the same mean and standard deviation of speeds as the distribution of eye velocities during pursuit. Spatial-interval acuity was better during pursuit than fixation for small or intermediate line separations. The results indicate that a reduction of perceived motion blur during pursuit eye movements can lead to improved visual performance.

Published

2013

2. Adaptive gaze stabilization through cerebellar internal models in a humanoid robot

Author

Cecilia Laschi, Lorenzo Vannucci, Egidio Falotico, Henrik Hautop Lund, Silvia Tolu, and Paolo Dario

Subjects

0301 basic medicine, Computer science, adaptive control, gaze tracking, Internal models, Learning and adaptation, 0302 clinical medicine, Self-adjusting control systems, Stability in control theory, Computer vision, Vestibular system, human gaze stabilization, Artificial Intelligence, Biomedical Engineering, Mechanical Engineering, Brain, Computational modeling, Robotics, adaptive gaze stabilization, eye, Stabilization, Magnetic heads, Video recording, visual feedback mechanism, VOR, VCR, Robots, Visual communication, Humanoid robot, cerebellar internal models, Neurophysiology, medical robotics, neuroscientific cerebellar theories, retinal image motion, Retina, 03 medical and health sciences, Biological and medical control systems, vestibulocollic reflex, eye movement, Retinal image, Aldehydes, opto-kinetic reflex, Vestibulo-ocular reflex, business.industry, Adaptation models, Eye movement, OKR, stability, humanoid robots, Anthropomorphic robots, Visual feedback, Gaze, 030104 developmental biology, Reflex, visual axis, Righting reflex, Artificial intelligence, Vestibulo–ocular reflex, business, Head, 030217 neurology & neurosurgery

Abstract

Two main classes of reflexes relying on the vestibular system are involved in the stabilization of the human gaze: The vestibulocollic reflex (VCR), which stabilizes the head in space and the vestibulo-ocular reflex (VOR), which stabilizes the visual axis to minimize retinal image motion. The VOR works in conjunction with the opto-kinetic reflex (OKR), which is a visual feedback mechanism for moving the eye at the same speed as the observed scene. Together they keep the image stationary on the retina. In this work we present the first complete model of gaze stabilization based on the coordination of VCR and VOR and OKR. The model, inspired on neuroscientific cerebellar theories, is provided with learning and adaptation capabilities based on internal models. Tests on a simulated humanoid platform confirm the effectiveness of our approach.

Published

2016

3. Suppression of optokinesis during smooth pursuit eye movements revisited: The role of extra-retinal information

Author

Axel Lindner and Uwe J. Ilg

Subjects

genetic structures, Computer science, Motion Perception, Self-induced motion, Relative motion, Fixation, Ocular, Stimulus (physiology), Smooth pursuit, Retina, Optokinetic reflex, chemistry.chemical_compound, Reflex, medicine, Psychophysics, Efference copy, Corollary discharge, Humans, Computer vision, Communication, Blinking, business.industry, Eye movement, Retinal, Retinal image motion, eye diseases, Pursuit, Smooth, Sensory Systems, Ophthalmology, medicine.anatomical_structure, chemistry, sense organs, Artificial intelligence, business, Photic Stimulation, Psychomotor Performance

Abstract

When our eyes track objects that are moving in a richly structured environment, the retinal image of the stationary visual scene inevitably moves over the retina in a direction opposite to the eye movement. Such self-motion-induced global retinal slip usually provides an ideal stimulus for the optokinetic reflex. This reflex operates to compensate for global image flow. However, during smooth pursuit eye movements it must be shut down so that the reflex does not counteract the voluntary pursuit of moving targets. Here, we asked if retinal information is sufficient for this cancellation of the optokinetic reflex during smooth pursuit eye movements. In a series of experiments, we show that neither the eye movement-induced retinal image motion per se nor the relative motion between the pursuit target and the background are sufficient for suppression of optokinesis. We, therefore, conclude that extra-retinal information about smooth pursuit eye movements is required for the cancellation of the optokinetic reflex.

Published

2006