Image thresholding framework based on two-dimensional digital fractional integration and Legendre moments’

A. Nakib; Y. Schulze; E. Petit

Image thresholding framework based on two-dimensional digital fractional integration and Legendre moments’

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Image thresholding framework based on two-dimensional digital fractional integration and Legendre moments’

Author(s): A. Nakib ; Y. Schulze ; E. Petit
DOI: 10.1049/iet-ipr.2010.0471

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Author(s): A. Nakib ¹ ; Y. Schulze ¹ ; E. Petit ¹
- Affiliations: 1: Laboratoire Images, Signaux et Systèmes Intelligents (LISSI, E.A. 3956), Université Paris EST-Créteil, Créteil, France
Source: Volume 6, Issue 6, August 2012, p. 717 – 727
DOI: 10.1049/iet-ipr.2010.0471 , Print ISSN 1751-9659, Online ISSN 1751-9667

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In this study, the authors present a new image segmentation algorithm based on two-dimensional digital fractional integration (2D-DFI) that was inspired from the properties of the fractional integration function. Although obtaining a good segmentation result corresponds to finding the optimal 2D-DFI order, the authors propose a new alternative based on Legendre moments. This framework, called two dimensional digital fractional integration and Legendre moments’ (2D-DFILM), allows one to include contextual information such as the global object shape and exploits the properties of the 2D fractional integration. The efficiency of 2D-DFILM is shown by the comparison to other six competing methods recently published and it was tested on real-world problem.

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Image thresholding framework based on two-dimensional digital fractional integration and Legendre moments’

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