An edge-based segmentation technique for 2D still-image with cellular neural networks

When strong CPU power consumption constraints must be met, and high computation speed is mandatory (real-time processing), it can be preferable to adopt custom hardware for some computationally intensive image processing tasks. An alternative approach to the conventional ones is provided by the cellular neural network (CNN) paradigm. CNNs have been extensively used in image processing applications: in the past, we developed a still image segmentation technique based on an active contour obtained via single-layer CNNs. This technique suffered from sensitivity to noise as most of edge-based methods: noise may create meaningless false edges or determine "edge fragmentation". The aim of this paper is to reformulate the algorithm previously proposed in order to step-over the cited weakness. The new formulation is introduced and motivated and experimental results are presented. Finally, a competition-based approach for a parameterless version of the presented algorithm is proposed and discussed as an ongoing work

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