Estimating Uncertainty and Interpretability in Deep Learning for
Coronavirus (COVID-19) Detection
- URL: http://arxiv.org/abs/2003.10769v2
- Date: Fri, 27 Mar 2020 16:48:13 GMT
- Title: Estimating Uncertainty and Interpretability in Deep Learning for
Coronavirus (COVID-19) Detection
- Authors: Biraja Ghoshal, Allan Tucker
- Abstract summary: Knowing how much confidence there is in a computer-based medical diagnosis is essential for gaining clinicians trust in the technology.
In this paper, we investigate how drop-weights based Bayesian Convolutional Neural Networks (BCNN) can estimate uncertainty in Deep Learning solution.
We believe that the availability of uncertainty-aware deep learning solution will enable a wider adoption of Artificial Intelligence (AI) in a clinical setting.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Deep Learning has achieved state of the art performance in medical imaging.
However, these methods for disease detection focus exclusively on improving the
accuracy of classification or predictions without quantifying uncertainty in a
decision. Knowing how much confidence there is in a computer-based medical
diagnosis is essential for gaining clinicians trust in the technology and
therefore improve treatment. Today, the 2019 Coronavirus (SARS-CoV-2)
infections are a major healthcare challenge around the world. Detecting
COVID-19 in X-ray images is crucial for diagnosis, assessment and treatment.
However, diagnostic uncertainty in the report is a challenging and yet
inevitable task for radiologist. In this paper, we investigate how drop-weights
based Bayesian Convolutional Neural Networks (BCNN) can estimate uncertainty in
Deep Learning solution to improve the diagnostic performance of the
human-machine team using publicly available COVID-19 chest X-ray dataset and
show that the uncertainty in prediction is highly correlates with accuracy of
prediction. We believe that the availability of uncertainty-aware deep learning
solution will enable a wider adoption of Artificial Intelligence (AI) in a
clinical setting.
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