• DocumentCode
    3404962
  • Title

    Boundary Learning by Optimization with Topological Constraints

  • Author

    Jain, Viren ; Bollmann, Benjamin ; Richardson, Mark ; Berger, Daniel R. ; Helmstaedter, Moritz N. ; Briggman, Kevin L. ; Denk, Winfried ; Bowden, Jared B. ; Mendenhall, John M. ; Abraham, Wickliffe C. ; Harris, Kristen M. ; Kasthuri, Narayanan ; Hayworth,

  • Author_Institution
    Brain & Cognitive Sci., Massachusetts Inst. of Technol., Cambridge, MA, USA
  • fYear
    2010
  • fDate
    13-18 June 2010
  • Firstpage
    2488
  • Lastpage
    2495
  • Abstract
    Recent studies have shown that machine learning can improve the accuracy of detecting object boundaries in images. In the standard approach, a boundary detector is trained by minimizing its pixel-level disagreement with human boundary tracings. This naive metric is problematic because it is overly sensitive to boundary locations. This problem is solved by metrics provided with the Berkeley Segmentation Dataset, but these can be insensitive to topological differences, such as gaps in boundaries. Furthermore, the Berkeley metrics have not been useful as cost functions for supervised learning. Using concepts from digital topology, we propose a new metric called the warping error that tolerates disagreements over boundary location, penalizes topological disagreements, and can be used directly as a cost function for learning boundary detection, in a method that we call Boundary Learning by Optimization with Topological Constraints (BLOTC). We trained boundary detectors on electron microscopic images of neurons, using both BLOTC and standard training. BLOTC produced substantially better performance on a 1.2 million pixel test set, as measured by both the warping error and the Rand index evaluated on segmentations generated from the boundary labelings. We also find our approach yields significantly better segmentation performance than either gPb-OWT-UCM or multiscale normalized cut, as well as Boosted Edge Learning trained directly on our data.
  • Keywords
    image resolution; image segmentation; learning (artificial intelligence); object detection; optimisation; BLOTC; Berkeley metrics; Berkeley segmentation dataset; boundary labelings; boundary learning by optimization with topological constraints; cost function; human boundary tracings; learning boundary detection; machine learning; object boundary detection; pixel-level disagreement; supervised learning; Constraint optimization; Cost function; Detectors; Electrons; Humans; Image segmentation; Machine learning; Object detection; Supervised learning; Topology;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Computer Vision and Pattern Recognition (CVPR), 2010 IEEE Conference on
  • Conference_Location
    San Francisco, CA
  • ISSN
    1063-6919
  • Print_ISBN
    978-1-4244-6984-0
  • Type

    conf

  • DOI
    10.1109/CVPR.2010.5539950
  • Filename
    5539950