Journal
IEEE TRANSACTIONS ON AUTOMATION SCIENCE AND ENGINEERING
Volume 19, Issue 2, Pages 1017-1029Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TASE.2021.3052483
Keywords
Sensors; Electrocardiography; Batteries; Monitoring; Oceans; Biomedical monitoring; Medical services; Cardiac events; constrained Markov decision process (CMDP); electrocardiography (ECG) sensing; mobile health (mHealth)
Categories
Funding
- National Natural Science Foundation of China [51705214]
- NSF I/UCRC Center for Healthcare Organization Transformation
- NSF I/UCRC [1624727]
- Div Of Industrial Innovation & Partnersh
- Directorate For Engineering [1624727] Funding Source: National Science Foundation
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The article introduces a constrained Markov decision process (CMDP) framework to optimize mobile electrocardiography (ECG) sensing under the constraint of the energy budget, and evaluates its performance in energy-constrained sensing of cardiac events, showing superior results compared to traditional policies.
Rapid advances in the smartphone, wearable sensing, and wireless communication provide an unprecedented opportunity to develop mobile systems for smart health management. Mobile cardiac sensing collects health-related data from individuals and enables the extraction of information pertinent to cardiac conditions. However, wireless sensors in ambulatory care settings operate on batteries. All-time sensing and monitoring will result in fast depletion of the battery in the mobile system. There is an urgent need to develop optimal sensing schemes that will reduce energy consumption while satisfying the requirements in the detection of cardiac events. In this article, we develop a constrained Markov decision process (CMDP) framework to optimize mobile electrocardiography (ECG) sensing under the constraint of the energy budget. We first characterize the cardiac states from ECG signals using the heterogeneous recurrence analysis. Second, we model the stochastic dynamics in cardiac processes as a continuous-time Markov chain (CTMC). Third, we optimize the ECG sensing through a CMDP framework under the constraint of energy budget. Finally, we validate and evaluate the performance of our CMDP policy in both simulation and real-world case studies. Experimental results demonstrate that the proposed CMDP policy significantly outperforms the traditional uniform and mean-time-to-event (MTTE) policies. Specifically, the error of state estimation is reduced by 34.0% in the real-world case study for energy-constrained sensing of cardiac events.
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