Analysis of uncertainty in different neural network structures using monte carlo dropout
Abstract
Deep learning technologies developed at an exponential rate throughout the years.
Starting from Convolutional Neural Networks (CNNs) to Involutional Neural Net works (INNs), there are several neural network (NN) architectures today, including
Vision Transformers (ViT), Graph Neural Networks (GNNs), Recurrent Neural Net works (RNNs) etc. However, uncertainty cannot be represented in these architec tures, which poses a significant difficulty for decision-making given that capturing
the uncertainties of these state-of-the-art NN structures would aid in making spe cific judgments. Dropout is one method that may be implemented within Deep
Learning (DL) networks as a technique to assess uncertainty. Dropout is applied
at the inference phase to measure the uncertainty of these neural network models.
This approach, commonly known as Monte Carlo Dropout (MCD), works well as a
low-complexity estimation to compute uncertainty. MCD is a widely used approach
to measure uncertainty in DL models, but majority of the earlier works focus on
only a particular application. Furthermore, there are many state-of-the-art (SOTA)
NNs that remain unexplored, with regards to that of uncertainty evaluation. There fore an up-to-date roadmap and benchmark is required in this field of study. Our
study revolved around a comprehensive analysis of the MCD approach for assessing
model uncertainty in neural network models with a variety of datasets. Besides,
we include SOTA NNs to explore the untouched models regarding uncertainty. In
addition, we demonstrate how the model may perform better with less uncertainty
by modifying NN topologies, which also reveals the causes of a model’s uncertainty.
Using the results of our experiments and subsequent enhancements, we also discuss
the various advantages and costs of using MCD in these NN designs. While working
with reliable and robust models we propose two novel architectures, which provide
outstanding performances in medical image diagnosis.