Publication
Structured learning of assignment models for neuron reconstruction to minimize topological errors
Conference Article
Conference
IEEE International Symposium on Biomedical Imaging (ISBI)
Edition
13th
Pages
607-611
Doc link
http://dx.doi.org/10.1109/ISBI.2016.7493341
File
Authors
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Funke, Jan
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Klein, Jonas
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Moreno Noguer, Francesc
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Cardona, Albert
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Cook, Matthew
Projects associated
Abstract
Structured learning provides a powerful framework for empirical risk minimization on the predictions of structured models. It allows end-to-end learning of model parameters to minimize an application specific loss function. This framework is particularly well suited for discrete optimization models that are used for neuron reconstruction from anisotropic electron microscopy (EM) volumes. However, current methods are still learning unary potentials by training a classifier that is agnostic about the model it is used in. We believe the reason for that lies in the difficulties of (1) finding a representative training sample, and (2) designing an application specific loss function that captures the quality of a proposed solution. In this paper, we show how to find a representative training sample from human generated ground truth, and propose a loss function that is suitable to minimize topological errors in the reconstruction. We compare different training methods on two challenging EM-datasets. Our structured learning approach shows consistently higher reconstruction accuracy than other current learning methods.
Categories
computer vision, object detection.
Author keywords
connectomics, structured learning, electron microscopy
Scientific reference
J. Funke, J. Klein, F. Moreno-Noguer, A. Cardona and M. Cook. Structured learning of assignment models for neuron reconstruction to minimize topological errors, 13th IEEE International Symposium on Biomedical Imaging, 2016, Prague, pp. 607-611.
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