TY - GEN
T1 - Adaptive Lead Weighted ResNet Trained with Different Duration Signals for Classifying 12-lead ECGs
AU - Zhao, Zhibin
AU - Fang, Hui
AU - Relton, Samuel D.
AU - Yan, Ruqiang
AU - Liu, Yuhong
AU - Li, Zhijing
AU - Qin, Jing
AU - Wong, David C.
N1 - Publisher Copyright:
© 2020 Creative Commons; the authors hold their copyright.
PY - 2020/9/13
Y1 - 2020/9/13
N2 - Introduction: We describe the creation of a deep neural network architecture to classify cardiac abnormality from 12 lead ECGs. The model was created by the team 'between a ROC and a heart place' for the Phys-ioNet/Computing in Cardiology Challenge 2020. Methods: ECGs were downsampled to 257 Hz and then set to a consistent duration by randomly clipping or zero-padding the signal to 4096 samples. To learn effective features, we created a modified ResNet with larger kernel sizes that models long-term dependencies. We embedded a Squeeze-And-Excitation layer into the modified ResNet to learn the importance of each lead, adaptively. A simple constrained grid-search was applied to deal with class imbalance. Results: Using the bespoke weighted accuracy metric, we achieved a 5-fold cross-validation score of 0.684, sensitivity and specificity of 0.758 and 0.969, respectively. We scored 0.520 on the full test data, and ranked 2nd out of the 41 teams that participated in the challenge. Conclusion: The proposed prediction model performed well on the validation and hidden test data. Such models may be potentially used for ECG screening or diagnosis.
AB - Introduction: We describe the creation of a deep neural network architecture to classify cardiac abnormality from 12 lead ECGs. The model was created by the team 'between a ROC and a heart place' for the Phys-ioNet/Computing in Cardiology Challenge 2020. Methods: ECGs were downsampled to 257 Hz and then set to a consistent duration by randomly clipping or zero-padding the signal to 4096 samples. To learn effective features, we created a modified ResNet with larger kernel sizes that models long-term dependencies. We embedded a Squeeze-And-Excitation layer into the modified ResNet to learn the importance of each lead, adaptively. A simple constrained grid-search was applied to deal with class imbalance. Results: Using the bespoke weighted accuracy metric, we achieved a 5-fold cross-validation score of 0.684, sensitivity and specificity of 0.758 and 0.969, respectively. We scored 0.520 on the full test data, and ranked 2nd out of the 41 teams that participated in the challenge. Conclusion: The proposed prediction model performed well on the validation and hidden test data. Such models may be potentially used for ECG screening or diagnosis.
UR - https://www.scopus.com/pages/publications/85100926848
U2 - 10.22489/CinC.2020.112
DO - 10.22489/CinC.2020.112
M3 - 会议稿件
AN - SCOPUS:85100926848
T3 - Computing in Cardiology
BT - 2020 Computing in Cardiology, CinC 2020
PB - IEEE Computer Society
T2 - 2020 Computing in Cardiology, CinC 2020
Y2 - 13 September 2020 through 16 September 2020
ER -