51,744 research outputs found
Distance Guided Channel Weighting for Semantic Segmentation
Recent works have achieved great success in improving the performance of
multiple computer vision tasks by capturing features with a high channel number
utilizing deep neural networks. However, many channels of extracted features
are not discriminative and contain a lot of redundant information. In this
paper, we address above issue by introducing the Distance Guided Channel
Weighting (DGCW) Module. The DGCW module is constructed in a pixel-wise context
extraction manner, which enhances the discriminativeness of features by
weighting different channels of each pixel's feature vector when modeling its
relationship with other pixels. It can make full use of the high-discriminative
information while ignore the low-discriminative information containing in
feature maps, as well as capture the long-range dependencies. Furthermore, by
incorporating the DGCW module with a baseline segmentation network, we propose
the Distance Guided Channel Weighting Network (DGCWNet). We conduct extensive
experiments to demonstrate the effectiveness of DGCWNet. In particular, it
achieves 81.6% mIoU on Cityscapes with only fine annotated data for training,
and also gains satisfactory performance on another two semantic segmentation
datasets, i.e. Pascal Context and ADE20K. Code will be available soon at
https://github.com/LanyunZhu/DGCWNet
Recurrent Fully Convolutional Neural Networks for Multi-slice MRI Cardiac Segmentation
In cardiac magnetic resonance imaging, fully-automatic segmentation of the
heart enables precise structural and functional measurements to be taken, e.g.
from short-axis MR images of the left-ventricle. In this work we propose a
recurrent fully-convolutional network (RFCN) that learns image representations
from the full stack of 2D slices and has the ability to leverage inter-slice
spatial dependences through internal memory units. RFCN combines anatomical
detection and segmentation into a single architecture that is trained
end-to-end thus significantly reducing computational time, simplifying the
segmentation pipeline, and potentially enabling real-time applications. We
report on an investigation of RFCN using two datasets, including the publicly
available MICCAI 2009 Challenge dataset. Comparisons have been carried out
between fully convolutional networks and deep restricted Boltzmann machines,
including a recurrent version that leverages inter-slice spatial correlation.
Our studies suggest that RFCN produces state-of-the-art results and can
substantially improve the delineation of contours near the apex of the heart.Comment: MICCAI Workshop RAMBO 201
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