Heartbeat-aware convolutional neural network for R-peak detection of wearable device ECG data / 南方医科大学学报
Journal of Southern Medical University
; (12): 375-383, 2022.
Article
in Zh
| WPRIM
| ID: wpr-936326
Responsible library:
WPRO
ABSTRACT
OBJECTIVE@#To develop a method for R-peak detection of ECG data from wearable devices to allow accurate estimation of the physiological parameters including heart rate and heart rate variability.@*METHODS@#A fully convolutional neural network was applied to predict the R-peak heatmap of ECG data and locate the R-peak positions. The heartbeat-aware (HA) module was introduced to enable the model to learn to predict the heartbeat number and R-peak heatmap simultaneously, thereby improving the capability of the model for extraction of the global context. The R-R interval estimated by the predicted heartbeat number was adopted to calculate the minimum horizontal distance for peak positioning. To achieve real-time R-peak detection on mobile devices, the deep separable convolution was adopted to reduce the number of parameters and the computational complexity of the model.@*RESULTS@#The proposed model was trained only with ECG data from wearable devices. At a tolerance window interval of 150 ms, the proposed method achieved R peak detection sensitivities of 100% for both wearable device ECG dataset and a public dataset (i.e. LUDB), and the true positivity rates exceeded 99.9%. As for the ECG signal of a 10 s duration, the CPU time of the proposed method for R-peak detection was about 23.2 ms.@*CONCLUSION@#The proposed method has good performance for R-peak detection of both wearable device ECG data and routine ECG data and also allows real-time R-peak detection of the ECG data.
Key words
Full text:
1
Index:
WPRIM
Main subject:
Algorithms
/
Signal Processing, Computer-Assisted
/
Neural Networks, Computer
/
Electrocardiography
/
Wearable Electronic Devices
/
Heart Rate
Type of study:
Diagnostic_studies
/
Prognostic_studies
Language:
Zh
Journal:
Journal of Southern Medical University
Year:
2022
Type:
Article