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DeepGCSS: a robust and explainable contour classifier providing generalized curvature scale space features | Neural Computing and Applications Skip to main content

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DeepGCSS: a robust and explainable contour classifier providing generalized curvature scale space features

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Abstract

In this paper, we build a novel, robust, and explainable deep neural network architecture for contour classification whose feature extraction layers are a deep version of the Generalized CSS (Generalized Curvature Scale Space) descriptors. For particular kernels, the proposed model behaves exactly like GCSS when extracting areas with strong curvatures. Such architecture is firstly essential to establish a comparison between the efficiency of hand-crafted kernels and the learned ones and secondly to study the ability of the classifier to map the input data into an invariant representation. Experimental results on MPEG-7 and MNIST contour datasets prove that the feature extraction block with hand-crafted kernels leads to an invariant and explainable CSS-based representation. Even though the number of parameters in the DeepGCSS model is much smaller compared to the conventional contour classifiers, the performance remains close. The robustness study was carried out using the ContourVerifier and proves that the features extraction block with hand-crafted kernels leads to a more robust GCSS-based representation model.

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Data availibility

All analyzed data during this study are available in the following Github repository: https://github.com/OueslatiRania/2D-contours-dataset. Generated models are available on request.

Notes

  1. Different applications are available in the following Github https://github.com/topics/curvature-scale-space.

  2. Available in the following Github http://yann.lecun.com/exdb/mnist/.

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Correspondence to Mallek Mziou-Sallami or Rania Khalsi.

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Mziou-Sallami, M., Khalsi, R., Smati, I. et al. DeepGCSS: a robust and explainable contour classifier providing generalized curvature scale space features. Neural Comput & Applic 35, 17689–17700 (2023). https://doi.org/10.1007/s00521-023-08639-1

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