A Fast Image Segmentation Algorithm Based on Saliency Map and Neutrosophic Set Theory

Sensen Song, Zhenhong Jia, Jie Yang, Nikola Kasabov

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Abstract

Due to more or less deviations in the imaging system, there will be noise in
the image, which makes the image segmentation inaccurate. To divide a natural image into a more accurate binary image, the target and background of the image are effectively separated to achieve a more effective segmentation result. Therefore, this paper proposes an image segmentation algorithm combining a saliency map and neutrosophic set (NS) theory. First, to overcome the problem of weak edges in the image, we highlight the details and use the guided filter to filter the various channels of the natural image. Then, the initial saliency map is generated. After the weighted superposition of the initial saliency map, the local entropy map and the gray scale map, the final saliency map can be generated
using the nonlinear function, and it can effectively highlight the foreground information of the image. Second, the saliency map is transformed to the NS domain and interpreted by three subsets: true (T), indeterminate (I), and false (F). According to NS theory, the indeterminacy is reduced, and the segmentation results are finally obtained by using the method of threshold. Various experiments were done and compared with other state-of-the art
approaches. These experiments demonstrate the effect of the proposed work, which is fast and effective for de-noising.
Original languageEnglish
Article number3901016
Pages (from-to)1-16
Number of pages16
JournalIEEE Photonics journal
Volume12
Issue number5
Early online date28 Sep 2020
DOIs
Publication statusPublished - 16 Oct 2020

Keywords

  • imaging system
  • image segmentaion
  • neurtrosophic set theory
  • saliency map
  • the method of threshold

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