TY - GEN
T1 - Heart Rate Anomaly Detection Using Contractive Autoencoder for Smartwatch-Based Health Monitoring
AU - Sivan, Keerthana Mannarapparambil
AU - Hu, Shanfeng
AU - Aslam, Nauman
AU - Chen, Xiaomin
AU - Sureephong, Pradorn
AU - Wongsila, Suwit
AU - Ahmed, Sabeela Q.
PY - 2023/12/8
Y1 - 2023/12/8
N2 - The widespread adoption of wearable devices enables continuous monitoring of physiological parameters like heart rate, offering valuable insights into health. However, consumer-grade wearable data exhibits real-world noise, variations, and discontinuities across diverse populations, posing significant challenges for anomaly detection models. This paper proposes a novel deep learning approach to address these challenges, utilizing a Contractive Autoencoder (CAE) model optimized and applied specifically to noisy temporal heart rate data from wearable devices. By incorporating a contractive regularization penalty in the loss function, the model learns more robust and stable representations of the irregular data with high accuracy. Comprehensive experiments on a real-world Fitbit dataset demonstrate the proposed CAE model accurately identifies anomalous heart rate patterns missed by traditional thresholding techniques. The research encountered key challenges in ensuring model generalizability across diverse populations with natural heart rate variations, handling missing and sparse data from unreliable real-world wearable devices, and obtaining properly labelled anomaly data for robust training. Although the current model achieved promising anomaly detection results, further extensive validation on diverse datasets is essential to fully assess its capabilities across expanded demographics and use cases. Overall, this research provides an important foundation for optimizing deep learning approaches on noisy real-world wearable data through rigorous evaluation.
AB - The widespread adoption of wearable devices enables continuous monitoring of physiological parameters like heart rate, offering valuable insights into health. However, consumer-grade wearable data exhibits real-world noise, variations, and discontinuities across diverse populations, posing significant challenges for anomaly detection models. This paper proposes a novel deep learning approach to address these challenges, utilizing a Contractive Autoencoder (CAE) model optimized and applied specifically to noisy temporal heart rate data from wearable devices. By incorporating a contractive regularization penalty in the loss function, the model learns more robust and stable representations of the irregular data with high accuracy. Comprehensive experiments on a real-world Fitbit dataset demonstrate the proposed CAE model accurately identifies anomalous heart rate patterns missed by traditional thresholding techniques. The research encountered key challenges in ensuring model generalizability across diverse populations with natural heart rate variations, handling missing and sparse data from unreliable real-world wearable devices, and obtaining properly labelled anomaly data for robust training. Although the current model achieved promising anomaly detection results, further extensive validation on diverse datasets is essential to fully assess its capabilities across expanded demographics and use cases. Overall, this research provides an important foundation for optimizing deep learning approaches on noisy real-world wearable data through rigorous evaluation.
KW - anomaly detection
KW - contractive autoencoder
KW - contractive loss
KW - heartrate anomaly
KW - outlier detection
UR - http://www.scopus.com/inward/record.url?scp=85184384523&partnerID=8YFLogxK
U2 - 10.1109/SKIMA59232.2023.10387334
DO - 10.1109/SKIMA59232.2023.10387334
M3 - Conference contribution
AN - SCOPUS:85184384523
SN - 9798350316568
T3 - International Conference on Software, Knowledge Information, Industrial Management and Applications, SKIMA
SP - 118
EP - 123
BT - 2023 15th International Conference on Software, Knowledge, Information Management and Applications, SKIMA 2023
PB - IEEE
CY - Piscataway, US
T2 - 15th International Conference on Software, Knowledge, Information Management and Applications, SKIMA 2023
Y2 - 8 December 2023 through 9 December 2023
ER -