稳健性(进化)
模式识别(心理学)
均方误差
人工智能
计算机科学
相关系数
波形
一致相关系数
皮尔逊积矩相关系数
噪音(视频)
相关性
卷积神经网络
块(置换群论)
线性模型
数学
支持向量机
标准差
可穿戴计算机
冗余(工程)
数据挖掘
限制
合成数据
重采样
特征提取
数据采集
人工神经网络
心电图
算法
一致性
作者
Rugved B. Parmar,Daoud Eldawud,M D Fahim,Adam S. Budzikowski
标识
DOI:10.1088/1361-6579/ae4a83
摘要
Objective.The standard 12-lead electrocardiogram (ECG) remains essential for cardiac diagnosis but requires ten physical electrodes, limiting long-term and wearable monitoring applications. We developed an anatomically grounded and physiologically interpretable framework to reconstruct the complete 12-lead ECG from four synthetic chest-torso electrodes derived using geometric vector principles and cardiac territorial anatomy.Approach.The 12 standard leads were partitioned into four physiologically coherent clusters representing septal/anterior, apical-lateral, inferior, and high-lateral depolarization vectors. Synthetic electrodes were constructed as weighted linear combinations of standard leads guided by frontal- and horizontal-plane vector geometry. A hybrid convolutional neural network-Transformer architecture mapped these four synthetic inputs to full 12-lead waveforms. The model was trained on 21 786 recordings from the PTB-XL dataset and externally validated on 500 recordings from the Chapman-Shaoxing dataset. Performance was evaluated using coefficient of determination (R2), Pearson correlation, root mean square error (RMSE), diagnostic concordance analysis, ablation testing, and noise robustness assessment.Main results.On the internal test set, the model achieved meanR2= 0.878 ± 0.070, Pearson correlationρ= 0.939 ± 0.030, and RMSE = 0.071 ± 0.030 mV. External validation demonstrated only 5% performance degradation. Waveform component preservation exceeded 94%, ST-segment correlation reached 0.964, and overall diagnostic concordance was 0.883, indicating preservation of approximately 88% of clinically relevant information. Reconstruction errors were symmetrically distributed around zero with minimal bias (0.001 mV) and maintained robustness at signal-to-noise ratios ⩾ 10 dB.Significance.This anatomically explainable reconstruction framework demonstrates the algorithmic feasibility of compact four-electrode ECG systems while preserving high diagnostic fidelity. By grounding electrode design in cardiac vector anatomy and validating performance across datasets, the approach provides a physiologically interpretable foundation for future wearable and ambulatory ECG reconstruction systems, establishing a reconstruction ceiling prior to hardware implementation.
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