Object discrimination based on depth-from-occlusion
Neural Computation
Pre-attentive segmentation in the primary visual cortex
Pre-attentive segmentation in the primary visual cortex
Towards novel neuroscience-inspired computing
Emergent neural computational architectures based on neuroscience
Neural mechanisms for representing surface and contour features
Emergent neural computational architectures based on neuroscience
Neural mechanisms for the robust representation of junctions
Neural Computation
Iterated tensor voting and curvature improvement
Signal Processing
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A general principle of cortical architecture is the bidirectional flow of information along feedforward and feedback connections. In the feedforward path, converging connections mainly define the feature detection characteristics of cells. The computational role of feedback connections, on the contrary, is largely unknown. Based on empirical findings we suggest that top-down feedback projections modulate activity of target cells in a context dependent manner. The context is represented by the spatial extension and direction of long-range connections. In this scheme, bottom-up activity which is consistent in a more global context is enhanced, inconsistent activity is suppressed. We present two instantiations of this general scheme having complementary functionality, namely a model of cortico-cortical V1-V2 interactions and a model of recurrent intracortical V1 interactions. The models both have long-range interactions for the representation of contour shapes and modulating feedback in common. They differ in their response properties to illusory contours and corners, and in the details of computing the bipole filter which models the long-range connections. We demonstrate that the models are capable of basic processing tasks in vision, such as, e.g., contour enhancement, noise suppression and corner detection. Also, a variety of perceptual phenomena such as grouping of fragmented shape outline and interpolation of illusory contours can be explained.