Convoluational Transformer With Adaptive Position Embedding For Covid-19 Detection From Cough Sounds

authored by
Tianhao Yan, Hao Meng, Shuo Liu, Emilia Parada-Cabaleiro, Zhao Ren, Björn W. Schuller
Abstract

Covid-19 has caused a huge health crisis worldwide in the past two years. Although an early detection of the virus through nucleic acid screening can considerably reduce its spread, the efficiency of this diagnostic process is limited by its complexity and costs. Hence, an effective and inexpensive way to early detect Covid-19 is still needed. Considering that the cough of an infected person contains a large amount of information, we propose an algorithm for the automatic recognition of Covid-19 from cough signals. Our approach generates static log-Mel spectrograms with deltas and delta-deltas from the cough signal and subsequently extracts feature maps through a Convolutional Neural Network (CNN). Following the advances on transformers in the realm of deep learning, our proposed architecture exploits a novel adaptive position embedding structure which can learn the position information of the features from the CNN output. This make the transformer structure rapidly lock the attention feature location by overlaying with the CNN output, which yields better classification. The efficiency of the proposed architecture is shown by the improvement, w. r. t. the baseline, of our experimental results on the INTERPSEECH 2021 Computational Paralinguistics Challenge CCS (Coughing Sub Challenge) database, which reached 72.6 % UAR (Unweighted Average Recall).

Organisation(s)
L3S Research Centre
External Organisation(s)
Harbin Engineering University
University of Augsburg
Johannes Kepler University of Linz (JKU)
Imperial College London
Type
Conference contribution
Pages
9092-9096
No. of pages
5
Publication date
2022
Publication status
Published
Peer reviewed
Yes
ASJC Scopus subject areas
Software, Signal Processing, Electrical and Electronic Engineering
Electronic version(s)
https://doi.org/10.1109/icassp43922.2022.9747513 (Access: Closed)