2,365 research outputs found
Highlighting objects of interest in an image by integrating saliency and depth
Stereo images have been captured primarily for 3D reconstruction in the past.
However, the depth information acquired from stereo can also be used along with
saliency to highlight certain objects in a scene. This approach can be used to
make still images more interesting to look at, and highlight objects of
interest in the scene. We introduce this novel direction in this paper, and
discuss the theoretical framework behind the approach. Even though we use depth
from stereo in this work, our approach is applicable to depth data acquired
from any sensor modality. Experimental results on both indoor and outdoor
scenes demonstrate the benefits of our algorithm
Entropy-difference based stereo error detection
Stereo depth estimation is error-prone; hence, effective error detection
methods are desirable. Most such existing methods depend on characteristics of
the stereo matching cost curve, making them unduly dependent on functional
details of the matching algorithm. As a remedy, we propose a novel error
detection approach based solely on the input image and its depth map. Our
assumption is that, entropy of any point on an image will be significantly
higher than the entropy of its corresponding point on the image's depth map. In
this paper, we propose a confidence measure, Entropy-Difference (ED) for stereo
depth estimates and a binary classification method to identify incorrect
depths. Experiments on the Middlebury dataset show the effectiveness of our
method. Our proposed stereo confidence measure outperforms 17 existing measures
in all aspects except occlusion detection. Established metrics such as
precision, accuracy, recall, and area-under-curve are used to demonstrate the
effectiveness of our method
Parkinson's Disease Detection Using Ensemble Architecture from MR Images
Parkinson's Disease(PD) is one of the major nervous system disorders that
affect people over 60. PD can cause cognitive impairments. In this work, we
explore various approaches to identify Parkinson's using Magnetic Resonance
(MR) T1 images of the brain. We experiment with ensemble architectures
combining some winning Convolutional Neural Network models of ImageNet Large
Scale Visual Recognition Challenge (ILSVRC) and propose two architectures. We
find that detection accuracy increases drastically when we focus on the Gray
Matter (GM) and White Matter (WM) regions from the MR images instead of using
whole MR images. We achieved an average accuracy of 94.7\% using smoothed GM
and WM extracts and one of our proposed architectures. We also perform
occlusion analysis and determine which brain areas are relevant in the
architecture decision making process
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