Abstract
Designing advanced health monitoring systems is still an active research topic. Wearable and remote monitoring devices enable monitoring of physiological and clinical parameters (heart rate, respiration rate, temperature, etc.) and analysis using cloud-centric machine-learning applications and decision-support systems to predict critical clinical states. This paper moves from a totally cloud-centric concept to a more distributed one, by transferring sensor data processing and analysis tasks to the edges of the network. The resulting solution enables the analysis and interpretation of sensor-data traces within the wearable device to provide actionable alerts without any dependence on cloud services. In this paper, we use a supervised-learning approach to detect heartbeats and classify arrhythmias. The system uses a window-based feature definition that is suitable for execution within an asymmetric multicore embedded processor that provides a dedicated core for hardware assisted pattern matching. We evaluate the performance of the system in comparison with various existing approaches, in terms of achieved accuracy in the detection of abnormal events. The results show that the proposed embedded system achieves a high detection rate that in some cases matches the accuracy of the state-of-the-art algorithms executed in standard processors.
Highlights
IntroductionNumerous portable devices have been introduced for the early detection and diagnosis of heart failure, since it is a common, costly, disabling, and deadly syndrome
We focus on the software executed on the wearable device, and on the processing and analysis of the data collected from the ECG sensors that are conducted either within the wearable or with the edge device
We evaluated the performance of the heartbeat-detection module as a standalone module and subsequently the performance of the entire system, that is, the heartbeat-detection followed by the arrhythmia-classification module
Summary
Numerous portable devices have been introduced for the early detection and diagnosis of heart failure, since it is a common, costly, disabling, and deadly syndrome. Accessories/H10_heart_rate_sensor), and Fitbit PurePulse (https://www.fitbit.com/purepulse)) to monitor and record variations in the heart rate, rhythm, and other patterns of its operation, by detecting electrical impulses generated by the polarization and depolarization of cardiac tissue. Such devices rely on nearby smartphones that act as a gateway for transmitting the recorded sensor signals to cloud services, where appropriate signal processing, analysis, and classification algorithms are applied
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