The map from eye to brain in vertebrates is topographic, i.e. neighbouring points in the eye map to neighbouring points in the brain. In addition, when two eyes innervate the same target structure, the two sets of ®bres segregate to form ocular dominance stripes. Experimental evidence from the frog and gold®sh suggests that these two phenomena may be subserved by the same mechanisms. We present a computational model that addresses the formation of both topography and ocular dominance. The model is based on a form of competitive learning with subtractive enforcement of a weight normalization rule. Inputs to the model are distributed patterns of activity presented simultaneously in both eyes. An important aspect of this model is that ocular d...
Dataset and code used for data analysis featured in "A Role for Ocular Dominance in Binocular Integr...
Piepenbrock C, Ritter H, Obermayer K. The joint development of orientation and ocular dominance: Rol...
Piepenbrock C, Ritter H, Obermayer K. Why it is hard to generate orientation and ocular dominance wi...
The map from eye to brain in vertebrates is topographic, i.e. neighbouring points in the eye map to ...
A new computational model that addresses the formation of both topography and ocular dominance is pr...
iAbstract There is strong biological evidence that the same mechanisms underly the formation of both...
The author describes a novel activity-based model which uses a simple competitive mechanism to form ...
Neural development leads to the establishment of precise connectivity in the nervous system. By cont...
We present two related computational models of ocular dominance column formation. Both address nervo...
We present a Hebbian model for the development of cortical maps in the striate cortex that includes ...
The primary visual area (V1) of the mammalian brain is a thin sheet of neurons, Because each neuron ...
The elastic net [Durbin & Willshaw 1987] can account for the development of both topography and ...
The elastic net (Durbin and Willshaw 1987) can account for the development of both topography and oc...
Introduction The formation of ocular dominance (OD) columns is an often investigated example for ac...
Several factors may interact to determine the periodicity of ocular dominance stripes in cat and mon...
Dataset and code used for data analysis featured in "A Role for Ocular Dominance in Binocular Integr...
Piepenbrock C, Ritter H, Obermayer K. The joint development of orientation and ocular dominance: Rol...
Piepenbrock C, Ritter H, Obermayer K. Why it is hard to generate orientation and ocular dominance wi...
The map from eye to brain in vertebrates is topographic, i.e. neighbouring points in the eye map to ...
A new computational model that addresses the formation of both topography and ocular dominance is pr...
iAbstract There is strong biological evidence that the same mechanisms underly the formation of both...
The author describes a novel activity-based model which uses a simple competitive mechanism to form ...
Neural development leads to the establishment of precise connectivity in the nervous system. By cont...
We present two related computational models of ocular dominance column formation. Both address nervo...
We present a Hebbian model for the development of cortical maps in the striate cortex that includes ...
The primary visual area (V1) of the mammalian brain is a thin sheet of neurons, Because each neuron ...
The elastic net [Durbin & Willshaw 1987] can account for the development of both topography and ...
The elastic net (Durbin and Willshaw 1987) can account for the development of both topography and oc...
Introduction The formation of ocular dominance (OD) columns is an often investigated example for ac...
Several factors may interact to determine the periodicity of ocular dominance stripes in cat and mon...
Dataset and code used for data analysis featured in "A Role for Ocular Dominance in Binocular Integr...
Piepenbrock C, Ritter H, Obermayer K. The joint development of orientation and ocular dominance: Rol...
Piepenbrock C, Ritter H, Obermayer K. Why it is hard to generate orientation and ocular dominance wi...