UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms

Syed Salman Badshah; Umer Saeed; Asadullah Momand; Syed Yaseen Shah; Syed Ikram Shah; Jawad Ahmad; Qammer H. Abbasi; Syed Aziz Shah

doi:10.1109/SMARTTECH54121.2022.00040

UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms

Syed Salman Badshah
, Umer Saeed
, Asadullah Momand
, Syed Yaseen Shah
, Syed Ikram Shah
, Jawad Ahmad
, Qammer H. Abbasi
, Syed Aziz Shah

Xidian University
Coventry University
University of the West of Scotland
Glasgow Caledonian University
National University of Sciences and Technology Pakistan
Edinburgh Napier University
University of Glasgow

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

9 Scopus citations

Abstract

Regarding the health-related applications in infectious respiratory/breathing diseases including COVID-19, wireless (or non-invasive) technology plays a vital role in the monitoring of breathing abnormalities. Wireless techniques are particularly important during the COVID-19 pandemic since they require the minimum level of interaction between infected individuals and medical staff. Based on recent medical research studies, COVID-19 infected individuals with the novel COVID-19-Delta variant went through rapid respiratory rate due to widespread disease in the lungs. These unpleasant circumstances necessitate instantaneous monitoring of respiratory patterns. The XeThru X4M200 ultra-wideband radar sensor is used in this study to extract vital breathing patterns. This radar sensor functions in the high and low-frequency ranges (6.0-8.5 GHz and 7.25-10.20 GHz). By performing eupnea (regular/normal) and tachypnea (irregular/rapid) breathing patterns, the data were acquired from healthy subjects in the form of spectrograms. A cutting-edge deep learning algorithm known as Residual Neural Network (ResNet) is utilised to train, validate, and test the acquired spectrograms. The confusion matrix, precision, recall, F1-score, and accuracy are exploited to evaluate the ResNet model's performance. ResNet's unique skip-connection technique minimises the underfitting/overfitting problem, providing an accuracy rate of up to 97.5%.

Original language	English
Title of host publication	Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	136-141
Number of pages	6
ISBN (Electronic)	9781665409735
DOIs	https://doi.org/10.1109/SMARTTECH54121.2022.00040
State	Published - 2022
Externally published	Yes
Event	2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022 - Riyadh, Saudi Arabia Duration: 9 May 2022 → 11 May 2022

Publication series

Name	Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022

Conference

Conference	2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022
Country/Territory	Saudi Arabia
City	Riyadh
Period	9/05/22 → 11/05/22

Keywords

ResNet
UWB radar sensor
XeThru X4M200
deep learning
wireless healthcare

Access to Document

10.1109/SMARTTECH54121.2022.00040

Cite this

Badshah, S. S., Saeed, U., Momand, A., Shah, S. Y., Shah, S. I., Ahmad, J., Abbasi, Q. H., & Shah, S. A. (2022). UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms. In Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022 (pp. 136-141). (Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/SMARTTECH54121.2022.00040

Badshah, Syed Salman ; Saeed, Umer ; Momand, Asadullah et al. / UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms. Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022. Institute of Electrical and Electronics Engineers Inc., 2022. pp. 136-141 (Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022).

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title = "UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms",

abstract = "Regarding the health-related applications in infectious respiratory/breathing diseases including COVID-19, wireless (or non-invasive) technology plays a vital role in the monitoring of breathing abnormalities. Wireless techniques are particularly important during the COVID-19 pandemic since they require the minimum level of interaction between infected individuals and medical staff. Based on recent medical research studies, COVID-19 infected individuals with the novel COVID-19-Delta variant went through rapid respiratory rate due to widespread disease in the lungs. These unpleasant circumstances necessitate instantaneous monitoring of respiratory patterns. The XeThru X4M200 ultra-wideband radar sensor is used in this study to extract vital breathing patterns. This radar sensor functions in the high and low-frequency ranges (6.0-8.5 GHz and 7.25-10.20 GHz). By performing eupnea (regular/normal) and tachypnea (irregular/rapid) breathing patterns, the data were acquired from healthy subjects in the form of spectrograms. A cutting-edge deep learning algorithm known as Residual Neural Network (ResNet) is utilised to train, validate, and test the acquired spectrograms. The confusion matrix, precision, recall, F1-score, and accuracy are exploited to evaluate the ResNet model's performance. ResNet's unique skip-connection technique minimises the underfitting/overfitting problem, providing an accuracy rate of up to 97.5\%.",

keywords = "ResNet, UWB radar sensor, XeThru X4M200, deep learning, wireless healthcare",

author = "Badshah, \{Syed Salman\} and Umer Saeed and Asadullah Momand and Shah, \{Syed Yaseen\} and Shah, \{Syed Ikram\} and Jawad Ahmad and Abbasi, \{Qammer H.\} and Shah, \{Syed Aziz\}",

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year = "2022",

doi = "10.1109/SMARTTECH54121.2022.00040",

language = "English",

series = "Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

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Badshah, SS, Saeed, U, Momand, A, Shah, SY, Shah, SI, Ahmad, J, Abbasi, QH & Shah, SA 2022, UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms. in Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022. Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022, Institute of Electrical and Electronics Engineers Inc., pp. 136-141, 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022, Riyadh, Saudi Arabia, 9/05/22. https://doi.org/10.1109/SMARTTECH54121.2022.00040

UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms. / Badshah, Syed Salman; Saeed, Umer; Momand, Asadullah et al.
Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022. Institute of Electrical and Electronics Engineers Inc., 2022. p. 136-141 (Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms

AU - Badshah, Syed Salman

AU - Saeed, Umer

AU - Momand, Asadullah

AU - Shah, Syed Yaseen

AU - Shah, Syed Ikram

AU - Ahmad, Jawad

AU - Abbasi, Qammer H.

AU - Shah, Syed Aziz

PY - 2022

Y1 - 2022

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AB - Regarding the health-related applications in infectious respiratory/breathing diseases including COVID-19, wireless (or non-invasive) technology plays a vital role in the monitoring of breathing abnormalities. Wireless techniques are particularly important during the COVID-19 pandemic since they require the minimum level of interaction between infected individuals and medical staff. Based on recent medical research studies, COVID-19 infected individuals with the novel COVID-19-Delta variant went through rapid respiratory rate due to widespread disease in the lungs. These unpleasant circumstances necessitate instantaneous monitoring of respiratory patterns. The XeThru X4M200 ultra-wideband radar sensor is used in this study to extract vital breathing patterns. This radar sensor functions in the high and low-frequency ranges (6.0-8.5 GHz and 7.25-10.20 GHz). By performing eupnea (regular/normal) and tachypnea (irregular/rapid) breathing patterns, the data were acquired from healthy subjects in the form of spectrograms. A cutting-edge deep learning algorithm known as Residual Neural Network (ResNet) is utilised to train, validate, and test the acquired spectrograms. The confusion matrix, precision, recall, F1-score, and accuracy are exploited to evaluate the ResNet model's performance. ResNet's unique skip-connection technique minimises the underfitting/overfitting problem, providing an accuracy rate of up to 97.5%.

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Badshah SS, Saeed U, Momand A, Shah SY, Shah SI, Ahmad J et al. UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms. In Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022. Institute of Electrical and Electronics Engineers Inc. 2022. p. 136-141. (Proceedings - 2022 2nd International Conference of Smart Systems and Emerging Technologies, SMARTTECH 2022). doi: 10.1109/SMARTTECH54121.2022.00040

UWB Radar Sensing for Respiratory Monitoring Exploiting Time- Frequency Spectrograms

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Keywords

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