In pure symmetrical vergence eye movements, a fusion initiating component quickly brings the eyes close to the desired position. A small error usually remains after this response which must be corrected to attain the small final vergence error (i.e., fixation disparity). Error correction will usually involve both version and version movements so possible mechanisms include: small saccades, smooth pursuit, symmetrical vergence, or some combination. Alternatively, an asymmetrical vergence or uniocular slow eye movement could be used to achieve the highly precise final position. Saccade-free late fusion sustaining components during the steady state to a symmetrical vergence step stimulus are analyzed using independent component analysis. Resul...
The neural origin of the steady-state vergence eye movement error, called binocular fixation dispari...
AbstractMonkeys generated disjunctive smooth pursuit eye movements when they tracked visual targets ...
AbstractSeveral categories of torsional eye movements obey Listing’s law; however, systematic deviat...
In pure symmetrical vergence eye movements, a fusion initiating component quickly brings the eyes cl...
Purely symmetrical vergence stimuli aligned along the midline (cyclopean axis) require only a pure v...
If two targets are carefully aligned so that they fall along the cyclopean axis, the required eye mo...
AbstractWe examined the velocity dependence of the vergence and version eye movements elicited by mo...
AbstractWhen a visual stimulus changes direction and distance simultaneously, Hering's Law argues th...
AbstractWhen a target travels slowly and smoothly along the line of sight of one eye, the eye that i...
The stereotypical vergence response to a step stimulus consists of two dynamic components: a high ve...
AbstractIn a natural environment, saccade and vergence eye movements shift gaze in different directi...
When we track an object moving in depth, our eyes rotate in opposite directions. This type of "disju...
Introduction: Previous studies have shown that the slow, or fusion sustaining, component of di...
AbstractIn the context of Hering's equal-innervation law, this paper discusses the problem of how th...
Disparity vergence eye movements were analyzed to determine if the early component of this response ...
The neural origin of the steady-state vergence eye movement error, called binocular fixation dispari...
AbstractMonkeys generated disjunctive smooth pursuit eye movements when they tracked visual targets ...
AbstractSeveral categories of torsional eye movements obey Listing’s law; however, systematic deviat...
In pure symmetrical vergence eye movements, a fusion initiating component quickly brings the eyes cl...
Purely symmetrical vergence stimuli aligned along the midline (cyclopean axis) require only a pure v...
If two targets are carefully aligned so that they fall along the cyclopean axis, the required eye mo...
AbstractWe examined the velocity dependence of the vergence and version eye movements elicited by mo...
AbstractWhen a visual stimulus changes direction and distance simultaneously, Hering's Law argues th...
AbstractWhen a target travels slowly and smoothly along the line of sight of one eye, the eye that i...
The stereotypical vergence response to a step stimulus consists of two dynamic components: a high ve...
AbstractIn a natural environment, saccade and vergence eye movements shift gaze in different directi...
When we track an object moving in depth, our eyes rotate in opposite directions. This type of "disju...
Introduction: Previous studies have shown that the slow, or fusion sustaining, component of di...
AbstractIn the context of Hering's equal-innervation law, this paper discusses the problem of how th...
Disparity vergence eye movements were analyzed to determine if the early component of this response ...
The neural origin of the steady-state vergence eye movement error, called binocular fixation dispari...
AbstractMonkeys generated disjunctive smooth pursuit eye movements when they tracked visual targets ...
AbstractSeveral categories of torsional eye movements obey Listing’s law; however, systematic deviat...