• DocumentCode
    3185565
  • Title

    lambda-Connectedness Determination for Image Segmentation

  • Author

    Chen, Li

  • Author_Institution
    Univ. of the District of Columbia, Washington
  • fYear
    2007
  • fDate
    10-12 Oct. 2007
  • Firstpage
    71
  • Lastpage
    79
  • Abstract
    Image segmentation is to separate an image into distinct homogeneous regions belonging to different objects. It is an essential step in image analysis and computer vision. This paper compares some segmentation technologies and attempts to find an automated way to better determine the parameters for image segmentation, especially the connectivity value of lambda in lambda-connected segmentation. Based on the theories on the maximum entropy method and Otsu´s minimum variance method, we propose:(1)maximum entropy connectedness determination: a method that uses maximum entropy to determine the best lambda value in lambda-connected segmentation, and (2) minimum variance connectedness determination: a method that uses the principle of minimum variance to determine lambda value. Applying these optimization techniques in real images, the experimental results have shown great promise in the development of the new methods. In the end, we extend the above method to more general case in order to compare it with the famous Mumford-Shah method that uses variational principle and geometric measure.
  • Keywords
    computer vision; image segmentation; maximum entropy methods; Mumford-Shah method; Otsu minimum variance; computer vision; image analysis; image segmentation; lambda-connectedness determination; maximum entropy connectedness determination; Computer science; Computer vision; Data mining; Entropy; Fuzzy sets; Image edge detection; Image segmentation; Information technology; Optimization methods; Pattern recognition;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Applied Imagery Pattern Recognition Workshop, 2007. AIPR 2007. 36th IEEE
  • Conference_Location
    Washington, DC
  • ISSN
    1550-5219
  • Print_ISBN
    978-0-7695-3066-6
  • Type

    conf

  • DOI
    10.1109/AIPR.2007.8
  • Filename
    4476126