Enhancing Accuracy in WBANs Through Optimal Sensor Positioning and Signal Processing: A Systematic Methodology

Wireless Body Area Networks (WBANs) have transformed fitness monitoring by providing continuous real-time data collection from small sensors placed on or inside the human body. Even though WBANs have important benefits, their accuracy and dependability are jeopardized by issues with sensor placement...

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Bibliographic Details
Published in:2024 11th International Conference on Electrical Engineering, Computer Science and Informatics (EECSI) pp. 768 - 774
Main Authors: Al Barazanchi, Israa Ibraheem, Abdulrahman, Mayasa M., Thabit, Reema, Hashim, Wahidah, Dalavi, Amol M., Sekhar, Ravi
Format: Conference Proceeding
Language:English
Published: IEEE 26.09.2024
Subjects:
Accuracy
machine learning
Machine learning algorithms
Medical services
Modeling anatomically
Monitoring
Placement of Sensors
real-time feedback
Real-time systems
Reliability
Sensor placement
Sensors
Signal processing
Signals Processing
WBAN
Wireless communication
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Summary:Wireless Body Area Networks (WBANs) have transformed fitness monitoring by providing continuous real-time data collection from small sensors placed on or inside the human body. Even though WBANs have important benefits, their accuracy and dependability are jeopardized by issues with sensor placement and signal processing. Incorrect sensor positioning can lead to inaccurate information, while noisy surroundings make signal processing more challenging. This focuses on using a single methodical approach to improve sensor placement and enhance signal processing in WBANs. We suggest a comprehensive solution that tackles placement sensitivity and noise reduction by combining anatomical modeling, real-time feedback mechanisms, and innovative machine learning algorithms. Experimental results show a 25% increase in signal quality and a 35% improvement in data precision when compared to conventional techniques. This method not only enhances the dependability of health monitoring systems but also validates their ability to be scaled and their effectiveness in various medical uses. Our results highlight the potential of WBANs to transform health care services, providing more accurate diagnostics and customized treatments.
DOI:10.1109/EECSI63442.2024.10776392