Add to ORKG& Significant advances in cognitive neuroscience can be achieved by combining techniques used to measure behavior and brain activity with neural modeling. Here we apply this approach to the initiation of rapid eye movements (saccades), which are used to redirect the visual axis to targets of interest. It is well known that the superior colliculus (SC) in the midbrain plays a major role in generating saccadic eye movements, and physiological studies have provided impor-tant knowledge of the activity pattern of neurons in this structure. Based on the observation that the SC receives localized sensory (exogenous) and voluntary (endogenous) inputs, our model assumes that this information is integrated by dynamic competition across local col...
We are immersed in an environment full of sensory information, and without much thought or effort we...
We are immersed in an environment full of sensory information, and without much thought or effort we...
During active vision, we convert information about visual objects in our periphery into goal-directe...
We present a model of the eye movement system in which the programming of an eye movement is the res...
We present a model of the eye movement system in which the programming of an eye movement is the res...
In the antisaccade paradigm subjects are instructed to perform eye movements in the opposite directi...
ABSTRACT: How does the brain tell the eye where to go? Classical models of rapid eye movements are l...
The mechanisms that underlie the integration of visual and goal-related signals for the production o...
A new, distributed model of the primate oculomotor system is presented. This model generates saccade...
We investigate the role that superior colliculus (SC) and cerebellum (CBLM) might play in controllin...
How does the saccadic movement system select a target when visual, auditory, and planned movement co...
The subcortical saccade-generating system consists of the retina, superior colliculus, cerebellum an...
The midbrain superior colliculus (SC) generates a rapid saccadic eye movement to a sensory stimulus ...
During natural viewing, the trajectories of saccadic eye movements often deviate dramatically from a...
The distributed nature of information processing in the brain creates a complex variety of decision ...
We are immersed in an environment full of sensory information, and without much thought or effort we...
We are immersed in an environment full of sensory information, and without much thought or effort we...
During active vision, we convert information about visual objects in our periphery into goal-directe...
We present a model of the eye movement system in which the programming of an eye movement is the res...
We present a model of the eye movement system in which the programming of an eye movement is the res...
In the antisaccade paradigm subjects are instructed to perform eye movements in the opposite directi...
ABSTRACT: How does the brain tell the eye where to go? Classical models of rapid eye movements are l...
The mechanisms that underlie the integration of visual and goal-related signals for the production o...
A new, distributed model of the primate oculomotor system is presented. This model generates saccade...
We investigate the role that superior colliculus (SC) and cerebellum (CBLM) might play in controllin...
How does the saccadic movement system select a target when visual, auditory, and planned movement co...
The subcortical saccade-generating system consists of the retina, superior colliculus, cerebellum an...
The midbrain superior colliculus (SC) generates a rapid saccadic eye movement to a sensory stimulus ...
During natural viewing, the trajectories of saccadic eye movements often deviate dramatically from a...
The distributed nature of information processing in the brain creates a complex variety of decision ...
We are immersed in an environment full of sensory information, and without much thought or effort we...
We are immersed in an environment full of sensory information, and without much thought or effort we...
During active vision, we convert information about visual objects in our periphery into goal-directe...