Erfanian A, Mahmoudi B
Department of Biomedical Engineering, Faculty of Electrical Engineering, Iran University of Science and Technology, Narmak, Tehran-16844, Iran.
Med Biol Eng Comput. 2005 Mar;43(2):296-305. doi: 10.1007/BF02345969.
The paper presents an adaptive noise canceller (ANC) filter using an artificial neural network for real-time removal of electro-oculogram (EOG) interference from electro-encephalogram (EEG) signals. Conventional ANC filters are based on linear models of interference. Such linear models provide poorer prediction for biomedical signals. In this work, a recurrent neural network was employed for modelling the interference signals. The eye movement and eye blink artifacts were recorded by the placing of an electrode on the forehead above the left eye and an electrode on the left temple. The reference signal was then generated by the data collected from the forehead electrode being added to data recorded from the temple electrode. The reference signal was also contaminated by the EEG. To reduce the EEG interference, the reference signal was first low-pass filtered by a moving averaged filter and then applied to the ANC. Matlab Simulink was used for real-time data acquisition, filtering and ocular artifact suppression. Simulation results show the validity and effectiveness of the technique with different signal-to-noise ratios (SNRs) of the primary signal. On average, a significant improvement in SNR up to 27 dB was achieved with the recurrent neural network. The results from real data demonstrate that the proposed scheme removes ocular artifacts from contaminated EEG signals and is suitable for real-time and short-time EEG recordings.
本文提出了一种使用人工神经网络的自适应噪声消除器(ANC)滤波器,用于实时去除脑电图(EEG)信号中的眼电图(EOG)干扰。传统的ANC滤波器基于干扰的线性模型。这种线性模型对生物医学信号的预测较差。在这项工作中,采用了递归神经网络对干扰信号进行建模。通过将一个电极放置在左眼上方的前额上以及将一个电极放置在左颞部来记录眼球运动和眨眼伪迹。然后,通过将从前额电极收集的数据与从颞部电极记录的数据相加来生成参考信号。该参考信号也受到EEG的污染。为了减少EEG干扰,首先通过移动平均滤波器对参考信号进行低通滤波,然后将其应用于ANC。Matlab Simulink用于实时数据采集、滤波和眼伪迹抑制。仿真结果表明了该技术在不同主信号信噪比(SNR)下的有效性。平均而言,使用递归神经网络可使SNR显著提高至27 dB。实际数据结果表明,所提出的方案能够从受污染的EEG信号中去除眼伪迹,适用于实时和短时EEG记录。
