Abstract
The efficient diagnosis of COVID-19 plays a key role in preventing its spread. Recently, many artificial intelligence techniques, such as the deep neural network approach, have been implemented to help efficient diagnosis of COVID-19. However, the accurate performance of deep learning depends on the tuning of many hyperparameters and a large amount of labeled data. This COVID-19 data bottleneck also leads to insufficient human resources for data labeling, which presents a challenging obstacle. In this paper, a novel discriminative batch-mode active learning (DS3) is proposed to allow faster and more effective COVID-19 data annotation. The framework specifically designed to suit the imbalanced data phenomenon that is characteristic of COVID-19 data. Extensive experiments over four public real-world COVID-19 datasets from several countries such as Brazil, China, Israel and Mexico show that our active learning framework significantly outmatches other state-of-the-art models. Our proposed framework achieves an average G-Mean of 10% improvement for the four datasets. Finally, the results of significance testing verify the effectiveness of DS3 and its superiority over baseline active learning algorithms.
Highlights
The COVID-19 pandemic has infected over 10 million people globally with more than 4 million people deceased as of mid-June 2021
This research shows that a discriminative-based approach works best for batch-mode active learning in imbalanced data scenarios
The first potential explanation is that the ability of DS3 to select the most representative data; since data that belong to the minority class inside the cluster leads to better sample selection compared to other models
Summary
The COVID-19 pandemic has infected over 10 million people globally with more than 4 million people deceased as of mid-June 2021. This crisis has further affected billions of people on a social, economic, and medical level, leading to significant changes in social connections, health regulations, commerce, employment, and educational settings. Mathematicians and epidemiologists are creating comprehensive virus dispersion and transmission models to predict virus propagation under different mobility and social distance situations [1].
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
