A Reliable and Reconfigurable Signal Processing Framework for Estimation of Metabolic Equivalent of Task in Wearable Sensors

• Published in: IEEE journal of selected topics in signal processing Vol. 10; no. 5; pp. 842 - 853
• Main Authors: Alinia, Parastoo, Saeedi, Ramyar, Fallahzadeh, Ramin, Rokni, Ali, Ghasemzadeh, Hassan
• Format: Journal Article
• Language: English
• Published: New York IEEE 01.08.2016; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Algorithms; Estimation; Learning; Localization; Machine learning algorithms; Metabolic equivalent of task (MET); motion sensors; Networks; node localization; physical activities; Position (location); Reliability; sensor misplacement; Sensors; Signal processing; Signal processing algorithms; transfer learning; Wearable; Wearable sensors
• ISSN: 1932-4553; 1941-0484
• DOI: 10.1109/JSTSP.2016.2569472

Wearable motion sensors are widely used to estimate metabolic equivalent of task (MET) values associated with physical activities. However, one major obstacle in widespread adoption of current wearables is that any changes in configuration of the network requires new data collection and re-training of the underlying signal processing algorithms. For any wearable-based MET estimation framework to be considered a viable platform, it needs to be reconfigurable, reliable, and power-efficient. In this paper, we aim to address the issues of sensor misplacement, power efficiency, and new sensor addition and propose a reliable and reconfigurable MET estimation framework. We introduce a power-aware sensor localization approach that allows users to wear the sensors on different body locations without need for adhering to a specific installation protocol. Furthermore, we propose a novel transductive transfer learning approach, which gives end-users the ability to add new sensors to the network without need for collecting new training data. This is accomplished by transferring the knowledge of already trained sensors to the untrained sensors in real-time. Our experiments demonstrate that our sensor localization algorithm achieves an accuracy of 90.8% in detecting location of the wearable sensors. The integrated model of sensor localization and MET calculation achieves an R 2 of 0.8 in estimating MET values using a regression-based model. Furthermore, our transfer learning algorithm improves the R 2 value of MET estimation up to 60%.