A deep learning approach to fetal-ECG signal reconstruction

2016 Twenty Second National Conference on Communication (NCC) Pub Date : 2016-03-04 DOI:10.1109/NCC.2016.7561206

P. R. Muduli, Rakesh Reddy Gunukula, A. Mukherjee

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引用次数: 30

Abstract

Fetal electrocardiogram (FECG) monitoring has become essential due to the current increase in the relative number of cardiac patients worldwide. This paper proposes to use a deep learning approach to compress/recover FECG signals, improving the computation speed in a telemonitoring system. The problem is analogous to the reconstruction of a non-sparse signal in compressive sensing (CS) framework. The architecture incorporates a non-linear mapping using a stacked denoising autoencoder (SDAE). The compression of the raw non-sparse FECG data takes place at the transmitter side using a deep neural network. After pre-training, the whole deep SDAE can be further fine tuned by the mini-batch gradient descent-based back-propagation algorithm. Although the training for SDAE is usually time-consuming, it does not affect the performance due to the one-time off-line training process. The real-time FECG reconstruction is faster due to a few matrix-vector multiplications at the receiver end. The simulations performed by employing standard non-invasive FECG databases shows promising results in terms of the reconstruction quality.

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胎儿心电信号重构的深度学习方法

由于目前世界范围内心脏病患者的相对数量增加，胎儿心电图(FECG)监测变得至关重要。本文提出利用深度学习方法压缩/恢复feg信号，提高远程监控系统的计算速度。该问题类似于压缩感知(CS)框架下非稀疏信号的重构。该体系结构采用了非线性映射，使用了堆叠去噪自动编码器(SDAE)。原始非稀疏FECG数据的压缩在发送端使用深度神经网络进行。经过预训练，整个深度SDAE可以通过基于小批量梯度下降的反向传播算法进一步微调。虽然SDAE的培训通常是耗时的，但由于是一次性的离线培训过程，并不影响性能。由于在接收端进行少量的矩阵-向量乘法，实时重构速度更快。采用标准的非侵入性FECG数据库进行的模拟在重建质量方面显示出令人满意的结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 Twenty Second National Conference on Communication (NCC)

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