Cortical dynamics of three-dimensional surface perception: binocular and half-occluded scenic images
Transactions of the Society for Computer Simulation International - Special issue: simulation methodology in transportation systems
Recurrent Long-Range Interactions in Early Vision
Emergent Neural Computational Architectures Based on Neuroscience - Towards Neuroscience-Inspired Computing
Neural Computation
Towards Novel Neuroscience-Inspired Computing
Emergent Neural Computational Architectures Based on Neuroscience - Towards Neuroscience-Inspired Computing
A Biologically Motivated Scheme for Robust Junction Detection
BMCV '02 Proceedings of the Second International Workshop on Biologically Motivated Computer Vision
How the Spatial Filters of Area V1 Can Be Used for a Nearly Ideal Edge Detection
BMCV '02 Proceedings of the Second International Workshop on Biologically Motivated Computer Vision
Brightness perception, dynamic range and noise: a unifying model for adaptive image sensors
CVPR'04 Proceedings of the 2004 IEEE computer society conference on Computer vision and pattern recognition
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Contours and surfaces are basic qualities which are processed by the visual system to aid the successful behavior of autonomous beings within the environment. There is increasing evidence that the two modalities of contours and surfaces are processed in separate, but interacting visual streams or sub-systems. Neurons at early stages in the visual system show strong responses only at locations of high contrast, such as edges, but only weak responses within homogeneous regions. Thus, for the processing and representation of surfaces, the visual system has to integrate sparse local measurements into a dense, coherent representation. We suggest a mechanism of confidence-based filling-in, where a confidence measure ensures a robust selection of sparse contrast signals. The new mechanism supports the generation of surface representations which are invariant against size and shape transformation. The filling-in process is controlled by contour or boundary signals which stop the filling-in of contrast signals at region boundaries. Localized responses to contours are most often noisy and fragmented. We suggest a recurrent processing scheme for the extraction of contours that incorporates long-range connections. The recurrent long-range processing enhances coaligned activity which is consistent within a more global context, while inconsistent noisy activity is suppressed. The capability of the model is shown for noisy synthesized and natural stimuli.