Your search keyword '"Brett J. Graham"' showing total 2 results

1. A self-calibrating, camera-based eye tracker for the recording of rodent eye movements

Author

Davide Zoccolan, Brett J Graham, and David D Cox

Subjects

Calibration, Cornea, Pupil, rat, Vision, rodent, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Much of neurophysiology and vision science relies on careful measurement of a human or animal subject’s gaze direction. Video-based eye trackers have emerged as an especially popular option for gaze tracking, because they are easy to use and are completely non-invasive. However, video eye trackers typically require a calibration procedure in which the subject must look at a series of points at known gaze angles. While it is possible to rely on innate orienting behaviors for calibration in some nonhuman species, other species, such as rodents, do not reliably saccade to visual targets, making this form of calibration impossible. To overcome this problem, we developed a fully-automated infrared video eye-tracking system that is able to quickly and accurately calibrate itself without requiring cooperation from the subject. This technique relies on the optical geometry of the cornea and uses computer controlled motorized stages to rapidly estimate the geometry of the eye relative to the camera. The accuracy and precision of our system was carefully measured using an artificial eye, and its capability to monitor the gaze of rodents was verified by tracking spontaneous saccades and evoked oculomotor reflexes in head-fixed rats (in both cases, we obtained measurements that are consistent with those found in the literature). Overall, given its fully-automated nature and its intrinsic robustness against operator errors, we believe that our eye-tracking system enhances the utility of existing approaches to gaze-tracking in rodents and represents a valid tool for rodent vision studies.

Published

2010

2. A Self-Calibrating, Camera-Based Eye Tracker for the Recording of Rodent Eye Movements

Author

David D. Cox, Davide Zoccolan, and Brett J. Graham

Subjects

vision, genetic structures, BitTorrent tracker, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, lcsh:RC321-571, Cornea, InformationSystems_MODELSANDPRINCIPLES, Robustness (computer science), Methods Article, rat, Computer vision, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, eye-tracking, Eye tracking on the ISS, rodent, calibration, business.industry, General Neuroscience, Eye movement, Pupil, Gaze, eye diseases, Vision science, Settore M-PSI/02 - Psicobiologia e Psicologia Fisiologica, Saccade, Eye tracking, Artificial intelligence, business, Neuroscience

Abstract

Much of neurophysiology and vision science relies on careful measurement of a human or animal subject's gaze direction. Video-based eye trackers have emerged as an especially popular option for gaze tracking, because they are easy to use and are completely non-invasive. However, video eye trackers typically require a calibration procedure in which the subject must look at a series of points at known gaze angles. While it is possible to rely on innate orienting behaviors for calibration in some non-human species, other species, such as rodents, do not reliably saccade to visual targets, making this form of calibration impossible. To overcome this problem, we developed a fully automated infrared video eye-tracking system that is able to quickly and accurately calibrate itself without requiring co-operation from the subject. This technique relies on the optical geometry of the cornea and uses computer-controlled motorized stages to rapidly estimate the geometry of the eye relative to the camera. The accuracy and precision of our system was carefully measured using an artificial eye, and its capability to monitor the gaze of rodents was verified by tracking spontaneous saccades and evoked oculomotor reflexes in head-fixed rats (in both cases, we obtained measurements that are consistent with those found in the literature). Overall, given its fully automated nature and its intrinsic robustness against operator errors, we believe that our eye-tracking system enhances the utility of existing approaches to gaze-tracking in rodents and represents a valid tool for rodent vision studies.

Published

2010