Limit cycle oscillations of the human eye
- 1 October 1984
- journal article
- research article
- Published by Springer Nature in Biological Cybernetics
- Vol. 51 (1) , 33-44
- https://doi.org/10.1007/bf00336185
Abstract
The altered feedback technique is very suited to display nonlinearities of the human smooth pursuit system. In fact, when the gain of the retinal feedback path is raised, for the horizontal channel, above its normal unitary negative value, a threshold is met beyond which sustained horizontal self-excited smooth oscillations of the eye can be observed, which point out the existence of a stable limit cycle. Furthermore, the characterizing features of both the transient and steady state show a well defined dependence on the total feedback factor K. In particular, the analytical dependence on K of the amplitude and frequency of limit cycle oscillations can be derived. Implications of the experiment with respect to the mathematical modelling of the system are discussed.Keywords
This publication has 62 references indexed in Scilit:
- Hans Gertz Revisited: The Different Effects of Invisibility and Darkness on Pursuit Eye MovementsPerception, 1979
- Pursuing Stationary Dots: Smooth Eye Movements and Apparent MovementPerception, 1973
- A New Experimental Paradigm for the Investigation of the Secondary System of Human Visual Motion PerceptionPerception, 1973
- EYE MOVEMENT AMPLITUDES IN IMAGINED PURSUIT OF A PENDULUM WITH EYES CLOSEDPsychophysiology, 1970
- Eye tracking of self-moved targets: The role of efference.Journal of Experimental Psychology, 1969
- Eye Tracking of Observer-Generated Target MovementsScience, 1968
- Learning behavior of the eye fixation control systemIEEE Transactions on Automatic Control, 1963
- Visual Effects of Varying the Extent of Compensation for Eye Movements*Journal of the Optical Society of America, 1959
- Nystagmus Induced by Visual FeedbackJournal of the Optical Society of America, 1959
- Involuntary Eyeball Motion During Anesthesia and Sleep Relationship to Cortical Rhythmic Potentials.*Anesthesia & Analgesia, 1941